| 0 |
Invalid frequency output |
| 1 |
Key format invalid or invalid key (key possibly not correct for this CPU board's serial number) |
| 2 |
Invalid IP format |
| 3 |
Meter text was longer than can be displayed over the HART interface and was replaced by shorter text |
| 4 |
Invalid date code detected |
| 5 |
Baseline comment was longer than can be displayed over the HART interface and was replaced by shorter comment |
| 6 |
Device Image |
| 7 |
Uncorrected Volume Flow Rate |
| 8 |
Corrected Volume Flow Rate |
| 9 |
Average Flow Velocity |
| 10 |
Average Sound Velocity |
| 11 |
Energy Flow Rate |
| 12 |
Mass Flow Rate |
| 13 |
Pressure |
| 14 |
Temperature |
| 15 |
Flow Velocity |
| 16 |
Sound Velocity |
| 17 |
|
| 18 |
Path |
| 19 |
A1 |
| 20 |
A2 |
| 21 |
Performance (%) |
| 22 |
Gain (dB) |
| 23 |
SNR (dB) |
| 24 |
Signal (mV) |
| 25 |
Noise (mV) |
| 26 |
B1 |
| 27 |
B2 |
| 28 |
C1 |
| 29 |
C2 |
| 30 |
D1 |
| 31 |
D2 |
| 32 |
Flow Rate |
| 33 |
Rate 1 |
| 34 |
Rate 2 |
| 35 |
Rate 3 |
| 36 |
Rate 4 |
| 37 |
Rate 5 |
| 38 |
Rate 6 |
| 39 |
Rate 7 |
| 40 |
Rate 8 |
| 41 |
Rate 9 |
| 42 |
Rate 10 |
| 43 |
Rate 11 |
| 44 |
Rate 12 |
| 45 |
Value |
| 46 |
Factor |
| 47 |
Factor 1 |
| 48 |
Factor 2 |
| 49 |
Factor 3 |
| 50 |
Factor 4 |
| 51 |
Factor 5 |
| 52 |
Factor 6 |
| 53 |
Factor 7 |
| 54 |
Factor 8 |
| 55 |
Factor 9 |
| 56 |
Factor 10 |
| 57 |
Factor 11 |
| 58 |
Factor 12 |
| 59 |
Rate 1 |
| 60 |
Rate 2 |
| 61 |
Rate 3 |
| 62 |
Rate 4 |
| 63 |
Rate 5 |
| 64 |
Rate 6 |
| 65 |
Rate 7 |
| 66 |
Rate 8 |
| 67 |
Rate 9 |
| 68 |
Rate 10 |
| 69 |
Rate 11 |
| 70 |
Rate 12 |
| 71 |
Factor 1 |
| 72 |
Factor 2 |
| 73 |
Factor 3 |
| 74 |
Factor 4 |
| 75 |
Factor 5 |
| 76 |
Factor 6 |
| 77 |
Factor 7 |
| 78 |
Factor 8 |
| 79 |
Factor 9 |
| 80 |
Factor 10 |
| 81 |
Factor 11 |
| 82 |
Factor 12 |
| 83 |
Component |
| 84 |
CO2 |
| 85 |
Hydrogen |
| 86 |
CO |
| 87 |
Nitrogen |
| 88 |
Methane |
| 89 |
Ethane |
| 90 |
Propane |
| 91 |
H2O |
| 92 |
H2S |
| 93 |
Oxygen |
| 94 |
i-Butane |
| 95 |
n-Butane |
| 96 |
i-Pentane |
| 97 |
n-Pentane |
| 98 |
n-Hexane |
| 99 |
n-Heptane |
| 100 |
n-Octane |
| 101 |
n-Nonane |
| 102 |
n-Decane |
| 103 |
Helium |
| 104 |
Argon |
| 105 |
Mole % |
| 106 |
Item |
| 107 |
Item 1 |
| 108 |
Item 2 |
| 109 |
Item 3 |
| 110 |
Item 4 |
| 111 |
Item 5 |
| 112 |
Item 6 |
| 113 |
Item 7 |
| 114 |
Item 8 |
| 115 |
Item 9 |
| 116 |
Item 10 |
| 117 |
Selection |
| 118 |
Display Meter K-Factors |
| 119 |
Enter License Keys |
| 120 |
Setup Units |
| 121 |
Setup Outputs |
| 122 |
Setup HART |
| 123 |
Setup Baseline |
| 124 |
Disable |
| 125 |
Enable |
| 126 |
Analog Output 1 Trim |
| 127 |
Analog Output 2 Trim |
| 128 |
Local Display Test Mode |
| 129 |
Frequency Output Test |
| 130 |
Digital Output Test |
| 131 |
Set Transducer Type |
| 132 |
Locate Device |
| 133 |
Set/View Clock |
| 134 |
Reset Device |
| 135 |
Reset Chord Proportions |
| 136 |
AO1 Content Changed |
| 137 |
AO2 Content Changed |
| 138 |
Freq1 Content Changed |
| 139 |
Freq2 Content Changed |
| 140 |
Units Changed |
| 141 |
AGA8 Method Changed |
| 142 |
Refresh Alerts |
| 143 |
Variable Summary |
| 144 |
Acknowledge |
| 145 |
No Longer Active |
| 146 |
Not Currently Active - Requires Acknowledge |
| 147 |
F: Configuration Lost, Latched Until Acknowledged - Acknowledge |
| 148 |
F: Configuration Lost, Latched Until Acknowledged - Not Currently Active - Requires Acknowledge |
| 149 |
F: Acquisition Mode - Acknowledge |
| 150 |
F: Acquisition Mode - Not Currently Active - Requires Acknowledge |
| 151 |
F: Acquisition Module Error - Acknowledge |
| 152 |
F: Acquisition Module Error - Not Currently Active - Requires Acknowledge |
| 153 |
F: Too Few Operating Chords - Acknowledge |
| 154 |
F: Too Few Operating Chords - Not Currently Active - Requires Acknowledge |
| 155 |
F: Diagnostic Core File Generated, Latched Until Acknowledged - Acknowledge |
| 156 |
F: Diagnostic Core File Generated, Latched Until Acknowledged - No Longer Active |
| 157 |
F: Electronics Voltage Out Of Range |
| 158 |
F: Acquisition Module is Not Compatible with Firmware/configuration |
| 159 |
F: Watchdog Reset, Latched Until Acknowledged - Acknowledge |
| 160 |
F: Watchdog Reset, Latched Until Acknowledged - No Longer Active |
| 161 |
M: Possible Blockage Detected - Acknowledge |
| 162 |
M: Possible Blockage Detected - Not Currently Active - Requires Acknowledge |
| 163 |
M: Chord A Hard Failed |
| 164 |
M: Chord B Hard Failed |
| 165 |
M: Chord C Hard Failed |
| 166 |
M: Chord D Hard Failed |
| 167 |
M: Flow Pressure Invalid - Acknowledge |
| 168 |
M: Flow Pressure Invalid - Not Currently Active - Requires Acknowledge |
| 169 |
M: Flow Temperature Invalid - Acknowledge |
| 170 |
M: Flow Temperature Invalid - Not Currently Active - Requires Acknowledge |
| 171 |
M: Clock Invalid |
| 172 |
M: GC Alarm Condition is Present |
| 173 |
M: Communication Error with the GC |
| 174 |
M: Invalid Data Read From the GC |
| 175 |
M: Reset Required |
| 176 |
A: Abnormal Profile Detected - Acknowledge |
| 177 |
A: Abnormal Profile Detected - Not Currently Active - Requires Acknowledge |
| 178 |
A: Possible Bore Buildup Detected - Acknowledge |
| 179 |
A: Possible Bore Buildup Detected - Not Currently Active - Requires Acknowledge |
| 180 |
A: Liquids Possibly Present In Gas - Acknowledge |
| 181 |
A: Liquids Possibly Present In Gas - Not Currently Active - Requires Acknowledge |
| 182 |
A: Reverse Flow Detected - Acknowledge |
| 183 |
A: Reverse Flow Detected - Not Currently Active - Requires Acknowledge |
| 184 |
A: Sound Velocity Comparison Of AGA10 to Meter Error - Acknowledge |
| 185 |
A: Sound Velocity Comparison Of AGA10 to Meter Error - Not Currently Active - Requires Acknowledge |
| 186 |
A: Meter Velocity Above Maximum Limit - Acknowledge |
| 187 |
A: Meter Velocity Above Maximum Limit - Not Currently Active - Requires Acknowledge |
| 188 |
A: Flow-Condition Volumetric Flow Rate Validity |
| 189 |
A: AGA8 Base-Condition Calculation Validity |
| 190 |
A: AGA8 Flow-Condition Calculation Validity |
| 191 |
A: Forward Baseline Not Set - Acknowledge |
| 192 |
A: Forward Baseline Not Set - No Longer Active |
| 193 |
A: Reverse Baseline Not Set - Acknowledge |
| 194 |
A: Reverse Baseline Not Set - No Longer Active |
| 195 |
A: Energy Rate Validity |
| 196 |
A: Mass Flow Rate Validity |
| 197 |
A: Base-Condition Volumetric Flow Rate Validity |
| 198 |
A: Analog Output 1 Validity |
| 199 |
A: Analog Output 2 Validity |
| 200 |
A: Frequency Output 1 Data is Invalid |
| 201 |
A: Frequency Output 2 Data is Invalid |
| 202 |
A: HART Fourth Variable Validity |
| 203 |
A: HART Command 33 Slot 0 Validity |
| 204 |
A: HART Command 33 Slot 1 Validity |
| 205 |
A: HART Command 33 Slot 2 Validity |
| 206 |
A: HART Command 33 Slot 3 Validity |
| 207 |
A: HART Third Variable Validity |
| 208 |
A: Analog Output 1 (HART PV) is Saturated |
| 209 |
A: Analog Output 2 (HART SV) is Saturated |
| 210 |
A: Analog Output 1 (HART PV) is Fixed |
| 211 |
A: Analog Output 2 (HART SV) is Fixed |
| 212 |
A: Average Sound Velocity Out-Of-Limits |
| 213 |
A: Configuration Changed, Latched Until Acknowledged - Acknowledge |
| 214 |
A: Configuration Changed, Latched Until Acknowledged - No Longer Active |
| 215 |
A: Power Failure, Latched Until Acknowledged - Acknowledge |
| 216 |
A: Power Failure, Latched Until Acknowledged - No Longer Active |
| 217 |
A: Flow-Condition Pressure Out-Of-Limits |
| 218 |
A: Flow-Condition Temperature Out-Of-Limits |
| 219 |
A: Alarm Archive Log is Full |
| 220 |
A: Analog Output 1 Test Enable |
| 221 |
A: Analog Output 2 Test Enable |
| 222 |
A: Audit Archive Log is Full |
| 223 |
A: Daily Archive Log is Full |
| 224 |
A: Electronics Temperature is Out Of Nominal Range |
| 225 |
A: Enables Test Mode for Digital Output 1 Pair |
| 226 |
A: Enables Test Mode for Digital Output 2 Pair |
| 227 |
A: Frequency Output 1 Pair Test Enable |
| 228 |
A: Frequency Output 2 Pair Test Enable |
| 229 |
A: Hourly Archive Log is Full |
| 230 |
A: System Archive Log is Full |
| 231 |
Comm Status: Polled |
| 232 |
Overview |
| 233 |
Device Status: Good |
| 234 |
No Active Alerts |
| 235 |
Device Status: Failed |
| 236 |
Device Status: Maintenance |
| 237 |
Device Status: Advisory |
| 238 |
Device Information |
| 239 |
Identification |
| 240 |
Revisions |
| 241 |
Alarm Type and Security |
| 242 |
Licenses |
| 243 |
Cont Flow Analysis |
| 244 |
AGA10 Calculation |
| 245 |
GC Communications |
| 246 |
Configure |
| 247 |
Manual Setup |
| 248 |
HART |
| 249 |
Device Variables Mapping |
| 250 |
Units |
| 251 |
HART Parameters |
| 252 |
Outputs |
| 253 |
Analog Output 1 |
| 254 |
Analog Output 2 |
| 255 |
Freq/Dig Outputs |
| 256 |
Frequency/Digital Output 1 |
| 257 |
Frequency/Digital Output 2 |
| 258 |
Frequency/Digital Output 3 |
| 259 |
Freq & Dig Output 1 |
| 260 |
Frequency Output 1 |
| 261 |
Digital Output 1 |
| 262 |
Freq & Dig Output 2 |
| 263 |
Frequency Output 2 |
| 264 |
Digital Output 2 |
| 265 |
Inputs |
| 266 |
Analog Input 1 (Temperature) |
| 267 |
Live Temperature |
| 268 |
Temperature Alarm |
| 269 |
Analog Input 2 (Pressure) |
| 270 |
Live Pressure |
| 271 |
Pressure Alarm |
| 272 |
Digital Input |
| 273 |
Communications |
| 274 |
Ethernet |
| 275 |
Serial |
| 276 |
Port A |
| 277 |
Port B |
| 278 |
Modbus Units |
| 279 |
Gas Chromatograph |
| 280 |
Metrology |
| 281 |
Meter Body |
| 282 |
Flow Profile Corr |
| 283 |
Temp Exp Corr |
| 284 |
Pressure Exp Corr |
| 285 |
Meter Factors |
| 286 |
Zero Flow Cal Coeff |
| 287 |
Forward |
| 288 |
Reverse |
| 289 |
Flow Cal Coeff |
| 290 |
Piece-wise Linear |
| 291 |
Volumetric Flow Rates |
| 292 |
Factors |
| 293 |
Transducer Chord(s) |
| 294 |
Chord A |
| 295 |
Chord B |
| 296 |
Chord C |
| 297 |
Chord D |
| 298 |
Batch Parameters |
| 299 |
Signal |
| 300 |
Transducer Firing |
| 301 |
Batch |
| 302 |
Alarm Conditions |
| 303 |
Signal Parameters |
| 304 |
Transducer |
| 305 |
Amplitude |
| 306 |
Signal to Noise |
| 307 |
Pulse Width |
| 308 |
Transit Time |
| 309 |
Sampling |
| 310 |
Signal Target Parameters |
| 311 |
Pf Distance |
| 312 |
Pe Distance |
| 313 |
Norm Amplitude |
| 314 |
Measurement Limits |
| 315 |
Speed of Sound |
| 316 |
AGA8 |
| 317 |
Base |
| 318 |
Specific Gravity |
| 319 |
Vol Heating Value |
| 320 |
Molar Density |
| 321 |
Compressibility |
| 322 |
Gas Composition |
| 323 |
Fixed Gas Comp |
| 324 |
Local Display |
| 325 |
Display Items |
| 326 |
Meter Information |
| 327 |
General Information |
| 328 |
Archive Logs |
| 329 |
Daily Log |
| 330 |
Hourly Log |
| 331 |
Event Log |
| 332 |
Audit Log |
| 333 |
Alarm Log |
| 334 |
System Log |
| 335 |
License Keys |
| 336 |
Alert Setup |
| 337 |
Flow Analysis Alerts |
| 338 |
Detect Blockage |
| 339 |
Detect Liquid |
| 340 |
Detect Bore Buildup |
| 341 |
Detect Abnormal Profile |
| 342 |
Sound Velocity Comparison |
| 343 |
Detect Reverse Flow |
| 344 |
Set Flow Range Limits |
| 345 |
Baseline Parameters |
| 346 |
Forward Baseline Parameters |
| 347 |
Reverse Baseline Parameters |
| 348 |
Current Baseline Information |
| 349 |
Velocity Diagnostics |
| 350 |
Flow |
| 351 |
Service Tools |
| 352 |
Alerts |
| 353 |
Variables |
| 354 |
Flow Data |
| 355 |
Flow Values |
| 356 |
Flow Analysis |
| 357 |
Path Information |
| 358 |
Performance |
| 359 |
Gain |
| 360 |
SNR |
| 361 |
Noise |
| 362 |
Flow Totals |
| 363 |
Volume Totals |
| 364 |
Energy Totals |
| 365 |
Mass Totals |
| 366 |
All Variables |
| 367 |
Primary Variable |
| 368 |
Status: Good |
| 369 |
Status: Bad |
| 370 |
Status: Fixed |
| 371 |
Status: Degraded |
| 372 |
Secondary Variable |
| 373 |
Third Variable |
| 374 |
Status: Not Used |
| 375 |
Fourth Variable |
| 376 |
Trends |
| 377 |
Maintenance |
| 378 |
Routine Maintenance |
| 379 |
Reset/Restore |
| 380 |
Upper Range |
| 381 |
Lower Range |
| 382 |
.6g |
| 383 |
.6f |
| 384 |
Range Units |
| 385 |
Lower Range |
| 386 |
Specifies the Analog Output 1 (Primary Variable) value corresponding to the minimum current (4 mA). |
| 387 |
Upper Range |
| 388 |
Specifies the Analog Output 1 (Primary Variable) value corresponding to the maximum current (20 mA). |
| 389 |
Lower Range |
| 390 |
Specifies the Analog Output 2 (Secondary Variable) value corresponding to the minimum current (4 mA). |
| 391 |
Upper Range |
| 392 |
Specifies the Analog Output 2 (Secondary Variable) value corresponding to the maximum current (20 mA). |
| 393 |
Lower Range |
| 394 |
Upper Range |
| 395 |
Freq1TestModeOutputPercent |
| 396 |
Specifies the Frequency Output 1 pair test mode percentage of full-scale. This specifies the frequency (as a percentage of the full-scale frequency to force Freq1A and Freq1B when in the frequency test mode. |
| 397 |
DO1ATestVal |
| 398 |
Specifies the value (state) of Digital Output 1A when in the test mode. |
| 399 |
Low |
| 400 |
High |
| 401 |
DO1BTestVal |
| 402 |
Specifies the value (state) of Digital Output 1B when in the test mode. |
| 403 |
Lower Range |
| 404 |
Upper Range |
| 405 |
Freq2TestModeOutputPercent |
| 406 |
Specifies the Frequency Output 2 pair test mode percentage of full-scale. This specifies the frequency (as a percentage of the full-scale frequency to force Freq2A and Freq2B when in the frequency test mode. |
| 407 |
DO2ATestVal |
| 408 |
Specifies the value (state) of Digital Output 2A when in the test mode. |
| 409 |
DO2BTestVal |
| 410 |
Specifies the value (state) of Digital Output 2B when in the test mode. |
| 411 |
Pressure Source |
| 412 |
Not Used |
| 413 |
Live Analog |
| 414 |
Fixed |
| 415 |
Temperature Source |
| 416 |
Alarm Selection |
| 417 |
The pressure and/or temperature source when the corresponding input is in alarm. Either the last good, i.e. non-alarm, value or a fixed value is used. |
| 418 |
Hold Last Output Value |
| 419 |
Use Fixed Value |
| 420 |
Failed Detailed Status Byte 0 |
| 421 |
Reserved |
| 422 |
Acquisition Module is Not Compatible with Firmware/configuration |
| 423 |
Watchdog Reset, Latched Until Acknowledged |
| 424 |
Electronics Voltage Out Of Range |
| 425 |
Acquisition Module Error |
| 426 |
Diagnostic Core File Generated, Latched Until Acknowledged |
| 427 |
Maintenance Detailed Status Byte 0 |
| 428 |
Communication Error with the GC |
| 429 |
Invalid Data Read From the GC |
| 430 |
GC Alarm Condition is Present |
| 431 |
Advisory Detailed Status Byte 0 |
| 432 |
Mass Flow Rate Validity |
| 433 |
Energy Rate Validity |
| 434 |
AGA8 Flow-Condition Calculation Validity |
| 435 |
AGA8 Base-Condition Calculation Validity |
| 436 |
Base-Condition Volumetric Flow Rate Validity |
| 437 |
Flow-Condition Volumetric Flow Rate Validity |
| 438 |
Advisory Detailed Status Byte 1 |
| 439 |
Analog Output 1 (HART PV) is Fixed |
| 440 |
Analog Output 2 (HART SV) is Fixed |
| 441 |
Analog Output 1 Validity |
| 442 |
Analog Output 2 Validity |
| 443 |
Frequency Output 1 Data is Invalid |
| 444 |
Frequency Output 2 Data is Invalid |
| 445 |
Analog Output 1 Test Enable |
| 446 |
Analog Output 2 Test Enable |
| 447 |
Advisory Detailed Status Byte 2 |
| 448 |
HART Fourth Variable Validity |
| 449 |
HART Third Variable Validity |
| 450 |
System Archive Log is Full |
| 451 |
Alarm Archive Log is Full |
| 452 |
Audit Archive Log is Full |
| 453 |
Daily Archive Log is Full |
| 454 |
Hourly Archive Log is Full |
| 455 |
Advisory Detailed Status Byte 3 |
| 456 |
HART Command 33 Slot 3 Validity |
| 457 |
HART Command 33 Slot 2 Validity |
| 458 |
HART Command 33 Slot 1 Validity |
| 459 |
HART Command 33 Slot 0 Validity |
| 460 |
Flow-Condition Temperature Out-Of-Limits |
| 461 |
Flow-Condition Pressure Out-Of-Limits |
| 462 |
Average Sound Velocity Out-Of-Limits |
| 463 |
Meter Velocity Above Maximum Limit |
| 464 |
Date |
| 465 |
The date part of time value when the baseline is taken in the reverse direction. |
| 466 |
Time |
| 467 |
The time part of time value when the baseline is taken in the reverse direction. |
| 468 |
Date |
| 469 |
The date part of time value when the baseline is taken in the forward direction. |
| 470 |
Time |
| 471 |
The time part of time value when the baseline is taken in the forward direction. |
| 472 |
ms |
| 473 |
SetXdcrType |
| 474 |
Sets the type of transducer installed. Changing this point will overwrite transducer configuration parameters with default values. The bandpass filter may be enabled if required by the selected transducer. Once these values are written, the value of this point is automatically reset to zero. |
| 475 |
T-11 |
| 476 |
T-12 |
| 477 |
T-21 |
| 478 |
T-22 |
| 479 |
T-32 |
| 480 |
Firmware |
| 481 |
Meter CPU Firmware Revision |
| 482 |
Volume Units |
| 483 |
Selects the HART communication volume unit. The volumetric flow rate unit is derived from this. |
| 484 |
Flow Rate Time Units |
| 485 |
Selects the HART communication time unit for volumetric, energy and mass flow rates. |
| 486 |
Pressure Units |
| 487 |
Selects the HART communication unit for pressure. |
| 488 |
Temperature Units |
| 489 |
Selects the HART communication unit for temperature. |
| 490 |
Velocity Units |
| 491 |
Selects the HART communication unit for flow velocity. |
| 492 |
Mass Units |
| 493 |
Selects the HART communication mass unit. The mass rate unit is derived from this. |
| 494 |
Energy Units |
| 495 |
Selects the HART communication energy unit. The energy rate unit is derived from this. |
| 496 |
Length Units |
| 497 |
Selects the HART communication unit for length. |
| 498 |
Micro Length Units |
| 499 |
Selects the HART communication unit for pipe wall roughness. |
| 500 |
um |
| 501 |
uin |
| 502 |
Viscosity Units |
| 503 |
Selects the HART communication unit for dynamic viscosity. |
| 504 |
Pa s |
| 505 |
Young's Modulus Units |
| 506 |
Selects the HART communication unit for Young's Modulus. |
| 507 |
1E6 psi |
| 508 |
Volumetric Heating Units |
| 509 |
Selects the HART communication unit for volumetric gross heating value. |
| 510 |
KJ/Cudm |
| 511 |
Btu/Cuft |
| 512 |
Density Units |
| 513 |
Selects the HART communication unit for specified flow-condition gas mass density. |
| 514 |
Voltage Units |
| 515 |
HART communication voltage unit. |
| 516 |
Decibel Units |
| 517 |
HART communication decibel unit. |
| 518 |
Percent Units |
| 519 |
HART communication percent unit. |
| 520 |
Volumetric Flow Rate Unit |
| 521 |
Specifies the HART communication unit for volumetric flow rate. This unit is derived from the volume unit and the flow rate time unit. |
| 522 |
HART Mass Rate Unit |
| 523 |
Specifies the HART communication unit for mass flow rate. This unit is derived from the mass unit and the flow rate time unit. |
| 524 |
HART Energy Rate Unit |
| 525 |
Specifies the HART communication unit for energy flow rate. This unit is derived from the energy unit and the flow rate time unit. |
| 526 |
Expansion Coefficient Units |
| 527 |
Inv degC |
| 528 |
Inv degF |
| 529 |
Device Description |
| 530 |
Device Description Build |
| 531 |
Profile Factor |
| 532 |
An average of profile factor over one minute used for baselines. |
| 533 |
.3f |
| 534 |
Swirl Angle |
| 535 |
An average of swirl angle over one minute used for baselines. |
| 536 |
Symmetry |
| 537 |
An average of symmetry over one minute used for baselines. |
| 538 |
Cross-Flow |
| 539 |
An average of cross-flow over one minute used for baselines. |
| 540 |
Velocity |
| 541 |
An average of average flow velocity over one minute used for baselines. |
| 542 |
Temperature |
| 543 |
An average of flow-condition temperature over one minute used for baselines. |
| 544 |
.2f |
| 545 |
Pressure |
| 546 |
An average of flow-condition pressure over one minute used for baselines. |
| 547 |
.1f |
| 548 |
Content (Primary Variable) |
| 549 |
Selects the data to be represented by Analog Output 1. Is used for HART communication as the Primary Variable content. |
| 550 |
Content (Secondary Variable) |
| 551 |
Selects the data to be represented by Analog Output 2. Is used for HART communication as the Secondary Variable content. |
| 552 |
Specifies the Analog Output 1 velocity corresponding to the maximum current (20 mA) when the Analog Output 1 is set to average flow velocity or average sound velocity. |
| 553 |
Specifies the Analog Output 1 mass rate corresponding to the minimum current (4 mA) when the Analog Output 1 is set to mass rate. |
| 554 |
Specifies the Analog Output 1 mass rate corresponding to the maximum current (20 mA) when the Analog Output 1 is set to mass rate. |
| 555 |
Specifies the Analog Output 1 energy rate corresponding to the minimum current (4 mA) when the Analog Output 1 is set to energy rate. |
| 556 |
Specifies the Analog Output 1 energy rate corresponding to the maximum current (20 mA) when the Analog Output 1 is set to energy rate EnergyRate. |
| 557 |
Specifies the Analog Output 1 velocity corresponding to the minimum current (4 mA) when the Analog Output 1 is set to average flow velocity or average sound velocity. |
| 558 |
Content |
| 559 |
Selects the data to be represented by the Frequency Output 1 pair (Freq1A and Freq1B) to be directed to FODO 1, FODO 2 or FODO 3. See Gas Ultrasonic Installation, Operations, or Maintenance and Troubleshooting manuals. |
| 560 |
Content |
| 561 |
Selects the data to be represented by the Frequency Output 2 pair (Freq2A and Freq2B) to be directed to FODO 2 or FODO 3. See Gas Ultrasonic Installation, Operations, or Maintenance and Troubleshooting manuals. |
| 562 |
Direction |
| 563 |
Selects the flow direction represented by the Frequency Output 1 pair (Freq1A and Freq1B). When set to "Reverse" or "Forward", both channels A and B represent the specified content when the flow is in selected direction. When set to "Absolute", both channels A and B represent the specified content regardless of the flow direction. When set to "Bidirectional", channel A represents the specified content when the flow is in the forward direction and channel B represents the specified content when flow is in the reverse direction. See Gas Ultrasonic Installation, Operations, or Maintenance and Troubleshooting manuals. |
| 564 |
Absolute |
| 565 |
Bidirectional |
| 566 |
Direction |
| 567 |
Selects the flow direction represented by the Frequency Output 2 pair (Freq2A and Freq2B). When set to "Reverse" or "Forward", both channels A and B represent the specified content when the flow is in selected direction. When set to "Absolute", both channels A and B represent the specified content regardless of the flow direction. When set to "Bidirectional", channel A represents the specified content when the flow is in the forward direction and channel B represents the specified content when flow is in the reverse direction. See Gas Ultrasonic Installation, Operations, or Maintenance and Troubleshooting manuals. |
| 568 |
High Limit |
| 569 |
Temperature alert high limit. The temperature is invalid when the input flow temperature is at or above this limit. |
| 570 |
Low Limit |
| 571 |
Temperature alert low limit. The temperature is invalid when the input flow temperature is at or below this limit. |
| 572 |
Fixed Temperature |
| 573 |
Specifies the flow-condition temperature used in calculations when the enable temperature input is set to "Fixed". |
| 574 |
Flow velocity after application of dry-calibration coefficients (A coefficients) and before application of wet(flow)-calibration method to the average weighted flow velocity. |
| 575 |
Chord A Limit |
| 576 |
The percentage from the baseline value that the turbulence of chord A is allowed to vary before there is an indication of potential blockage. |
| 577 |
Chord B Limit |
| 578 |
The percentage from the baseline value that the turbulence of chord B is allowed to vary before there is an indication of potential blockage. |
| 579 |
Chord C Limit |
| 580 |
The percentage from the baseline value that the turbulence of chord C is allowed to vary before there is an indication of potential blockage. |
| 581 |
Chord D Limit |
| 582 |
The percentage from the baseline value that the turbulence of chord D is allowed to vary before there is an indication of potential blockage. |
| 583 |
Cross-Flow Limit |
| 584 |
The percentage from the baseline value the cross-flow is allowed to vary before there is an indication of potential blockage. |
| 585 |
Symmetry Limit |
| 586 |
The percentage from the baseline value the chord symmetry is allowed to vary before there is an indication of potential blockage. |
| 587 |
Disables blockage detection when set FALSE (0). Setting this to TRUE (1) will enable blockage detection if optional flow analysis features are enabled and the meter device number is 3414. |
| 588 |
Disabled |
| 589 |
Enabled |
| 590 |
Standard Deviation of Profile Factor Limit |
| 591 |
The percentage from the baseline value the profile factor is allowed to vary before there is an indication of potential liquids present. |
| 592 |
Standard Deviation of Cross-Flow Limit |
| 593 |
The percentage from the baseline value the cross-flow is allowed to vary before there is an indication of potential liquids present. |
| 594 |
Standard Deviation of Symmetry Limit |
| 595 |
The percentage from the baseline value the symmetry is allowed to vary before there is an indication of potential liquids present. |
| 596 |
Disables liquid present detection when set FALSE (0). Setting this to TRUE (1) will enable liquid present detection if optional flow analysis features are enabled and the meter device number is 3414. |
| 597 |
Detect Bore Buildup |
| 598 |
This is TRUE (1) when bore buildup detection is TRUE (1), optional flow analysis features are enabled and the meter device number is 3414. |
| 599 |
Detect Blockage |
| 600 |
This is TRUE (1) when blockage detection is TRUE (1), optional flow analysis features are enabled and the meter device number is 3414. |
| 601 |
Detect Liquid |
| 602 |
This is TRUE (1) when liquid detection is TRUE (1), optional flow analysis features are enabled and the meter device number is 3414 |
| 603 |
Detect Abnormal Profile |
| 604 |
This is TRUE (1) when abnormal profile detection is TRUE (1), optional flow analysis features are enabled and the meter device number is 3414. |
| 605 |
Sound Velocity Comparison |
| 606 |
Sound Velocity Comparison functioning.
TRUE (1) if the alarm is enabled, the options key is valid and the AGA8 method is set to detailed. |
| 607 |
Profile Factor |
| 608 |
The profile factor value when the baseline is taken in the forward direction. |
| 609 |
Profile Factor |
| 610 |
The profile factor value when the baseline is taken in the reverse direction. |
| 611 |
Pressure |
| 612 |
The flow pressure value when the baseline is taken in the forward direction. |
| 613 |
Pressure |
| 614 |
The flow pressure value when the baseline is taken in the reverse direction. |
| 615 |
Turbulence A |
| 616 |
The chord A turbulence value when the baseline is taken in the forward direction. |
| 617 |
Turbulence A |
| 618 |
The chord A turbulence value when the baseline is taken in the reverse direction. |
| 619 |
Turbulence B |
| 620 |
The chord B turbulence value when the baseline is taken in the forward direction. |
| 621 |
Turbulence B |
| 622 |
The chord B turbulence value when the baseline is taken in the reverse direction. |
| 623 |
Turbulence C |
| 624 |
The chord C turbulence value when the baseline is taken in the forward direction. |
| 625 |
Turbulence C |
| 626 |
The chord C turbulence value when the baseline is taken in the reverse direction. |
| 627 |
Turbulence D |
| 628 |
The chord D turbulence value when the baseline is taken in the forward direction. |
| 629 |
Turbulence D |
| 630 |
The chord D turbulence value when the baseline is taken in the reverse direction. |
| 631 |
Velocity |
| 632 |
The average flow value when the baseline is taken in the forward direction. |
| 633 |
Velocity |
| 634 |
The average flow value when the baseline is taken in the reverse direction. |
| 635 |
Cross-Flow |
| 636 |
The cross-flow value when the baseline is taken in the forward direction. |
| 637 |
Cross Flow |
| 638 |
The cross-flow value when the baseline is taken in the reverse direction. |
| 639 |
Swirl Angle |
| 640 |
The swirl angle value when the baseline is taken in the forward direction. |
| 641 |
Swirl Angle |
| 642 |
The swirl angle value when the baseline is taken in the reverse direction. |
| 643 |
Symmetry |
| 644 |
The symmetry value when the baseline is taken in the forward direction. |
| 645 |
Symmetry |
| 646 |
The symmetry value when the baseline is taken in the reverse direction. |
| 647 |
Temperature |
| 648 |
The flow temperature value when the baseline is taken in the forward direction. |
| 649 |
Temperature |
| 650 |
The flow temperature value when the baseline is taken in the reverse direction. |
| 651 |
Baseline Set Validity |
| 652 |
Some or all forward baseline values available in the meter are not set. The baseline captures the flow characteristics of the meter when installed so that the meter can monitor these parameters and use them to diagnose the health of the meter.
Recommended Actions:
1. Click Setup Baseline below to set the forward baseline parameters.
2. If the meter does not run in the forward direction or you do not wish to take advantage of the Continuous Flow Analysis features, acknowledge this alert to clear it. |
| 653 |
Baseline Set |
| 654 |
Baseline Not Set |
| 655 |
Some or all reverse baseline values used in Continuous Flow Analysis are not set. The baseline captures the flow characteristics of the meter when installed so that the meter can monitor these parameters and use them to diagnose the health of the meter.
Recommended Actions:
1. Click Setup Baseline below to set the reverse baseline parameters.
2. If the meter does not run in the reverse direction or you do not wish to take advantage of the Continuous Flow Analysis features, acknowledge this alert to clear it. |
| 656 |
AGA10 Calculation |
| 657 |
Optional AGA10 calculation and sound speed comparison. A unique "key" tied to the CPU board serial number enables the AGA10 calculation/sound speed comparison functionality. A value of 0 indicates the functionality is disabled. |
| 658 |
Gas Chromatograph Communications |
| 659 |
Optional GC interface. A unique "key" tied to the CPU board serial number enables this functionality. A value of 0 indicates the functionality is disabled. |
| 660 |
Continuous Flow Analysis |
| 661 |
Optional continuous flow analysis feature key interface. A unique "key" tied to the CPU board serial number enables this functionality. A value of 0 indicates the functionality is disabled. This key enables all optional features available. |
| 662 |
Indicates whether the optional AGA10 calculation/SOS comparison feature is enabled. Enabled if TRUE (1). |
| 663 |
No |
| 664 |
Yes |
| 665 |
Indicates whether the optional GC interface feature is enabled. Enabled if TRUE (1). |
| 666 |
Indicates whether the optional flow analysis features are enabled. Enabled if TRUE (1). |
| 667 |
Turbulence A |
| 668 |
Meter turbulence A is an estimate of the standard deviation of delta time as a percentage of delta time for chord A. A value of 0% indicates no appreciable turbulence. |
| 669 |
Turbulence B |
| 670 |
Meter turbulence B is an estimate of the standard deviation of delta time as a percentage of delta time for chord B. A value of 0% indicates no appreciable turbulence. |
| 671 |
Turbulence C |
| 672 |
Meter turbulence C is an estimate of the standard deviation of delta time as a percentage of delta time for chord C. A value of 0% indicates no appreciable turbulence. |
| 673 |
Turbulence D |
| 674 |
Meter turbulence D is an estimate of the standard deviation of delta time as a percentage of delta time for chord D. A value of 0% indicates no appreciable turbulence. |
| 675 |
SeniorSonic meter measure of symmetry. This compares the upper chord velocities to the lower chord velocities. For perfectly symmetrical flow, this value equals 1.0. |
| 676 |
SeniorSonic meter measure of cross flow. This compares the flow velocities from one side of the meter to the other side. This value is equal to 1.0 when there is no cross-flow. |
| 677 |
The ratio of the sum of the velocities of the inner chords to the sum of the velocities of the outer chords. This ratio is a numerical representation of the velocities taken in cross section in the direction of flow. When out of tolerance, it may be used to diagnose abnormal flow conditions. This is only applicable to SeniorSonic meters. |
| 678 |
The arctangent of the ratio of the tangential velocity, computed from the individual chordal velocities, to the average flow velocity. This is only calculated for SeniorSonic meters. |
| 679 |
Average flow velocity (per batch). This is the dry cal velocity with any selected wet-calibration method as well as the profile correction factor applied. |
| 680 |
AGA10 Sound Velocity |
| 681 |
(Optional) AGA10-calculated sound velocity. |
| 682 |
Sound Velocity Comparison Difference |
| 683 |
The percent difference between the optional AGA10 computed sound velocity, and the average measured sound velocity computed each Batch cycle. |
| 684 |
Flow Analysis Lower Velocity Range Limit |
| 685 |
The lower flow velocity limit for performing flow analysis diagnostics when enabled by the flow analysis key and gating "flow analysis gated" values in daily and hourly logs. This value may not be less than the lower velocity threshold. |
| 686 |
Flow Analysis Upper Velocity Range Limit |
| 687 |
The upper flow velocity limit for performing flow analysis diagnostics when enabled by the flow analysis key and gating "flow analysis gated" values in daily and hourly logs. |
| 688 |
Any Baseline Available |
| 689 |
Indicates whether or not the baselines are supported for this meter type. If the meter is a JuniorSonic, device number is 3411 or 3412, then the value is FALSE (0) and the baselines are not used. |
| 690 |
Available |
| 691 |
Not Available |
| 692 |
Model Number |
| 693 |
Changing this value requires warm-starting the meter. This value should only be changed at the factory or when replacing a CPU Module in the field. |
| 694 |
Forward Uncorrected Volume |
| 695 |
Accumulation of flow-condition volume (integer portion) in the forward direction. The total can be computed using this integer portion (digits to the left of the decimal) with the fractional portion(digits to the right of the decimal). Note that this value is incremented using internal units which may be different than those displayed and rolls over at an unsigned 64 bit integer (18,446,744,073,709,551,615 cubic meters). However, when read via Modbus, the value rolls from 999,999,999 to 0. |
| 696 |
Reverse Uncorrected Volume |
| 697 |
Accumulation of flow-condition volume (integer portion) in the reverse direction. The total can be computed using this integer portion (digits to the left of the decimal) with the fractional portion(digits to the right of the decimal). Note that this value is incremented using internal units which may be different than those displayed and rolls over at an unsigned 64 bit integer (18,446,744,073,709,551,615 cubic meters). However, when read via Modbus, the value rolls from 999,999,999 to 0. |
| 698 |
Forward Base Condition Volume |
| 699 |
Accumulation of base-condition volume (integer portion) in the forward direction. The total can be computed using this integer portion (digits to the left of the decimal) with the fractional portion(digits to the right of the decimal). Note that this value is incremented using internal units which may be different than those displayed and rolls over at an unsigned 64 bit integer (18,446,744,073,709,551,615 cubic meters). However, when read via Modbus, the value rolls from 999,999,999 to 0. |
| 700 |
Reverse Base Condition Volume |
| 701 |
Accumulation of base-condition volume (integer portion) in the reverse direction. The total can be computed using this integer portion (digits to the left of the decimal) with the fractional portion(digits to the right of the decimal). Note that this value is incremented using internal units which may be different than those displayed and rolls over at an unsigned 64 bit integer (18,446,744,073,709,551,615 cubic meters). However, when read via Modbus, the value rolls from 999,999,999 to 0. |
| 702 |
Forward Accumulated Energy |
| 703 |
This point is only applicable when the heating value is fixed (specified) or read from a gas chromatograph. The total can be computed using this integer portion (digits to the left of the decimal) with the fractional portion (digits to the right of the decimal). Note that this value is incremented using internal units which may be different than those displayed and rolls over at an unsigned 64 bit integer (18,446,744,073,709,551,615 MJ). However, when read via Modbus, the value rolls from 999,999,999 to 0. |
| 704 |
Reverse Accumulated Energy |
| 705 |
Forward Accumulated Mass |
| 706 |
This point is only applicable when the AGA8 calculations are performed internally or are performed externally with the mixture flow-condition mass density specified. The total can be computed using this integer portion (digits to the left of the decimal) with the fractional portion (digits to the right of the decimal). Note that this value is incremented using internal units which may be different than those displayed and rolls over at an unsigned 64 bit integer (18,446,744,073,709,551,615 KG). However, when read via Modbus, the value rolls from 999,999,999 to 0. |
| 707 |
Reverse Accumulated Mass |
| 708 |
Detection Error Limit |
| 709 |
Alarm limit on the error between the optional AGA10-calculated sound velocity and the meter-calculated sound velocity used to generate sound velocity comparison of AGA10 to meter error. |
| 710 |
Profile Factor Limit |
| 711 |
Abnormal profile detection alarm limit. |
| 712 |
.0f |
| 713 |
Disables abnormal profile detection when set FALSE (0). Setting this to TRUE (1) will enable abnormal profile present detection if Optional flow analysis features are enabled and the meter device number is 3414. |
| 714 |
Disables sound velocity comparison when set to FALSE (0). |
| 715 |
Disables bore buildup detection diagnostic when set FALSE (0). |
| 716 |
IP Address |
| 717 |
The static IP address of the meter's Ethernet port. The meter must be assigned a unique IP address if it is connected to a network via its Ethernet port. The meter may also be configured as a DHCP server. |
| 718 |
A0 |
| 719 |
The forward flow A0 coefficient used in dry calibration. The dry calibration "A" coefficients are always applied to the flow velocity to generate average flow velocity. |
| 720 |
m/s |
| 721 |
.5f |
| 722 |
A0 |
| 723 |
A1 |
| 724 |
The reverse flow A1 coefficient used in dry calibration. The dry calibration "A" coefficients are always applied to the flow velocity to generate average flow velocity. |
| 725 |
A1 |
| 726 |
The forward flow A1 coefficient used in dry calibration. The dry calibration "A" coefficients are always applied to the flow velocity to generate average flow velocity. |
| 727 |
A2 |
| 728 |
The reverse flow A2 coefficient used in dry calibration. The dry calibration "A" coefficients are always applied to the flow velocity to generate average flow velocity. |
| 729 |
s/m |
| 730 |
A2 |
| 731 |
The forward flow A2 coefficient used in dry calibration. The dry calibration "A" coefficients are always applied to the flow velocity to generate average flow velocity. |
| 732 |
A3 |
| 733 |
The reverse flow A3 coefficient used in dry calibration. The dry calibration "A" coefficients are always applied to the flow velocity to generate average flow velocity. |
| 734 |
s2/m2 |
| 735 |
A3 |
| 736 |
The forward flow A3 coefficient used in dry calibration. The dry calibration "A" coefficients are always applied to the flow velocity to generate average flow velocity. |
| 737 |
C0 |
| 738 |
The reverse flow C0 coefficient used in wet calibration. The wet calibration "C" coefficients are applied to the flow velocity to produce average flow velocity when selected via the wet calibration method selector. |
| 739 |
C0 |
| 740 |
The forward flow C0 coefficient used in wet calibration. The wet calibration "C" coefficients are applied to the flow velocity to produce average flow velocity when selected via the wet calibration method selector. |
| 741 |
C1 |
| 742 |
The reverse flow C1 coefficient used in wet calibration. The wet calibration "C" coefficients are applied to the flow velocity to produce average flow velocity when selected via the wet calibration method selector. |
| 743 |
C1 |
| 744 |
The forward flow C1 coefficient used in wet calibration. The wet calibration "C" coefficients are applied to the flow velocity to produce average flow velocity when selected via the wet calibration method selector. |
| 745 |
C2 |
| 746 |
The reverse flow C2 coefficient used in wet calibration. The wet calibration "C" coefficients are applied to the flow velocity to produce average flow velocity when selected via the wet calibration method selector. |
| 747 |
C2 |
| 748 |
The forward flow C2 coefficient used in wet calibration. The wet calibration "C" coefficients are applied to the flow velocity to produce average flow velocity when selected via the wet calibration method selector. |
| 749 |
C3 |
| 750 |
The reverse flow C3 coefficient used in wet calibration. The wet calibration "C" coefficients are applied to the flow velocity to produce average flow velocity when selected via the wet calibration method selector. |
| 751 |
C3 |
| 752 |
The forward flow C3 coefficient used in wet calibration. The wet calibration "C" coefficients are applied to the flow velocity to produce average flow velocity when selected via the wet calibration method selector. |
| 753 |
Units System |
| 754 |
Selects the units for Modbus communications and for the local display. Available options are U.S. Customary and Metric. The selected units system applies only to registers above 10000 and in the 2000-8999 range, other registers below 10000 are read in metric units only to maintain Mark II compatibility. Also, these are the units used by the Field Setup Wizard in Daniel MeterLink. US customary units is the default setting. |
| 755 |
U.S. Customary |
| 756 |
Metric |
| 757 |
Flow Rate Time Unit |
| 758 |
Selects the Modbus communication volumetric, energy or mass flow rate time unit for registers above 10000 and in the 2000-8999 range. |
| 759 |
Second |
| 760 |
Hour |
| 761 |
Day |
| 762 |
U.S. Customary Volume Unit |
| 763 |
Identifies the U.S. Customary volume unit used for Modbus communication for registers above 10000 and in the 2000-8999 range. |
| 764 |
Cubic Feet |
| 765 |
Metric Volume Unit |
| 766 |
Identifies the metric volume unit used for Modbus communication for registers above 10000 and in the 2000-8999 range. |
| 767 |
Cubic Meters |
| 768 |
Update Rate |
| 769 |
Specifies the minimum batch update period when there is no stacking. The "Rapid" update period can be selected only when there is no bandpass filtering, and may cause greater uncertainty in the measured flow rate. |
| 770 |
Standard - 1000 ms |
| 771 |
Rapid - 250 ms |
| 772 |
Stack Size |
| 773 |
Indicates the number of transducer firings to be point-by-point averaged to generate a signal for a single transit time measurement. A value of 1 indicates no stacking. When stacking is used, the batch period can differ from the user-specified value. Stacking is primarily used to reduce random (white) noise on the received signal. |
| 774 |
None |
| 775 |
2 |
| 776 |
4 |
| 777 |
8 |
| 778 |
16 |
| 779 |
Filter |
| 780 |
Bandpass filter switch. When set to TRUE (1) the bandpass filter is used on the received transducer signal to remove unwanted frequencies. |
| 781 |
Filter Off |
| 782 |
Filter On |
| 783 |
Flow Calibration Method |
| 784 |
Selects the wet calibration method to apply to the velocity measurement.
If set to "None" then the wet calibration has the same value as the dry calibration.
If set to "Polynomial Coefficients" then the "C" calibration coefficients are applied.
If set to "Piece-Wise Linear" then the piece-wise linearization flow rate and meter factor parameters are used to calculate the meter factor to be applied. |
| 785 |
Polynomial |
| 786 |
Piece-Wise Linear |
| 787 |
Co-located Meter Mode |
| 788 |
Configures the meter to operate as a non-co-located Meter ("Disabled", 0), a co-located primary meter ("Primary", 1) or a co-located secondary meter ("Secondary", 2) to configure the meter's mode for Transducer Firing Synchronization. Co-located meter mode can be set to primary ("Primary", 1) or secondary ("Secondary", 2) only if the Device Number is 3414. |
| 789 |
Primary |
| 790 |
Secondary |
| 791 |
Maximum Chord Deviation (CRange) |
| 792 |
Maximum percentage chord sound speed deviation. |
| 793 |
Maximum Meter Velocity |
| 794 |
The maximum for the meter's average flow velocity. This limit is used to generate an alert meter velocity above maximum limit, when the average flow velocity magnitude is above this limit. Note, however, that this limit does not affect the meter's measurement. |
| 795 |
Minimum Sound Speed |
| 796 |
Minimum sound speed. This is used to define the area to search for a signal when in Acquisition mode and is also used in emission rate determination. This minimum and the maximum sound speed may need to be adjusted to prevent problems acquiring the signal. |
| 797 |
Maximum Sound Speed |
| 798 |
Maximum sound speed. This is used to define the area to search for a signal when in Acquisition mode and is also used in emission rate determination. The minimum and this maximum sound speed may need to be adjusted to prevent problems acquiring the signal. |
| 799 |
Sound Velocity Low Alarm |
| 800 |
The low limit for the average speed of sound range error alert. It is used strictly for alarming purposes and does not impact any other meter functionality. This is different from the minimum acquisition mode speed of sound. |
| 801 |
Sound Velocity High Alarm |
| 802 |
The high limit for the average speed of sound range error alert. It is used strictly for alarming purposes and does not impact any other meter functionality. This is different from the maximum acquisition mode speed of sound. |
| 803 |
Minimum Velocity for CRange |
| 804 |
Minimum flow velocity for performing the inter-chord sound velocity check. |
| 805 |
Maximum Velocity for CRange |
| 806 |
Maximum flow velocity for performing the inter-chord sound velocity check. |
| 807 |
Reference Temperature |
| 808 |
Reference temperature for linear expansion. This is used to calculate the temperature-effect expansion correction factor (when the correction is enabled via the enable temperature-effect expansion correction). |
| 809 |
Fixed Correction Factor |
| 810 |
Specifies the (fixed) profile-effect correction factor (for single and dual-path meters only) either manually entered or calculated by the meter. A zero value indicates that the meter is to calculate the profile-effect correction factor based on pipe wall roughness, pipe inside diameter and Reynolds Number. Reynolds number requires that AGA8 calculations are performed by the meter or performed externally. |
| 811 |
Wall Roughness |
| 812 |
Pipe wall roughness. Only required for JuniorSonic meters when flow-profile correction is calculated. |
| 813 |
Viscosity |
| 814 |
Natural gas mixture dynamic viscosity. Only required for JuniorSonic meters when flow-profile correction is calculated. |
| 815 |
First Peak Threshold (Pk1Thrsh) |
| 816 |
The minimum amplitude of first peak of the signal required for it to be used. |
| 817 |
Min Signal to Noise Threshold (SNRatio) |
| 818 |
The minimum signal-to-noise threshold. If the ratio of the signal energy to the noise energy (SNR) is below this threshold, the signal for that firing of the transducer is discarded. If, in a batch, a chord has at least one signal discarded due to too low SNR, the chord's low alarm is set to TRUE (1). |
| 819 |
Min Signal Quality (MinSigQlty) |
| 820 |
The minimum acceptable signal quality based on signal and noise energies. |
| 821 |
Frequency (XdcrFreq) |
| 822 |
The output frequency of the transducers. Usually adjusted by setting the transducer type. A transducer frequency of 125 KHz requires a standard Acquisition Module. A transducer frequency higher than 125 KHz requires a High Frequency Acquisition Module. |
| 823 |
kHz |
| 824 |
Interval (SampInterval) |
| 825 |
The duration in nanoseconds of the signal sampling period. It is also used to compute the system delay. Usually adjusted by setting the transducer type. A sample interval of 800 ns requires a standard Acquisition Module. A sample interval less than 800 ns requires a High Frequency Acquisition Module. |
| 826 |
ns |
| 827 |
Samples Per Cycle (SampPerCycle) |
| 828 |
The number of times the waveform is sampled between two zero crossings with the same slope (one cycle), This value should only be changed at the factory or under the direction of Daniel technical support. |
| 829 |
10 |
| 830 |
Min Hold Time (MinHoldTime) |
| 831 |
The minimum sampling hold time limit. This is the minimum amount of time the meter waits after firing a transducer before sampling the receiving transducer's signal. This value should only be changed at the factory or under the direction of Daniel technical support. After a firmware upgrade, this value may be automatically adjusted to be within the required limits. |
| 832 |
us |
| 833 |
Max Hold Time (MaxHoldTm) |
| 834 |
The maximum sampling hold time limit. This is the maximum amount of time the meter waits after firing a transducer before sampling the receiving transducer's signal. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 835 |
Delta Time Check (DltChkSI) |
| 836 |
Delta time check parameter. |
| 837 |
si |
| 838 |
Min Negative (NegSpanSI) |
| 839 |
Minimum negative pulse width derived from the micro second version. This parameter is used to detect distorted waveforms and incorrect measurements. |
| 840 |
Min Positive (PosSpanSI) |
| 841 |
Minimum positive pulse width in sample intervals derived from the micro second version. This parameter is used to detect distorted waveforms and incorrect measurements. |
| 842 |
Deviation Factor (TmDevFctr1) |
| 843 |
Measurement Quality check transit time standard deviation factor. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 844 |
Max Peak (PkPlsWdthSI) |
| 845 |
Maximum selected peak pulse width. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 846 |
Min Negative (NegSpan) |
| 847 |
The minimum time the signal must remain negative adjacent to a zero crossing. It is converted to sample interval units internally for use by the meter. This parameter is used to detect distorted waveforms and incorrect measurements. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 848 |
Min Positive (PosSpan) |
| 849 |
The minimum time the signal must remain positive adjacent to a zero crossing. It is converted to sample interval units internally for use by the meter. This parameter is used to detect distorted waveforms and incorrect measurements. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 850 |
Deviation Threshold (TmDevLow1) |
| 851 |
The minimum standard deviation value of the transit time for which the quality check is evaluated. Paths with times closer to the mean are assumed to be valid without further evaluation. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 852 |
Max Peak (Pk1Wdth) |
| 853 |
The assumed time between zero crossings (one half cycle) used as the distance to search for the next peak value. This value is converted internally to sample intervals for use. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 854 |
Delta Time Check (DltChk) |
| 855 |
The maximum amount of time allowed for delta times (the difference between the up stream and down stream signal transit time). It is converted to sample interval units internally for use by the meter. |
| 856 |
Target (Tspf) |
| 857 |
The default for the targeted SPF which is the time in sample intervals (SI), or distance between the first motion (Pf) and the signal the zero crossing detection point (P1). It is also the value used for inactive paths. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 858 |
Automatically Reset By the Meter |
| 859 |
The first reverse meter factor used for piecewise linearization. It is paired with reverse flow rate 1 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 860 |
.4f |
| 861 |
The first forward meter factor used for piecewise linearization. It is paired with forward flow rate 1 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 862 |
The second reverse meter factor used for piecewise linearization. It is paired with reverse flow rate 2 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 863 |
The second forward meter factor used for piecewise linearization. It is paired with forward flow rate 2 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 864 |
The third reverse meter factor used for piecewise linearization. It is paired with reverse flow rate 3 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 865 |
The third forward meter factor used for piecewise linearization. It is paired with forward flow rate 3 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 866 |
The fourth reverse meter factor used for piecewise linearization. It is paired with reverse flow rate 4 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 867 |
The fourth forward meter factor used for piecewise linearization. It is paired with forward flow rate 4 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 868 |
The fifth reverse meter factor used for piecewise linearization. It is paired with reverse flow rate 5 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 869 |
The fifth forward meter factor used for piecewise linearization. It is paired with forward flow rate 5 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 870 |
The sixth reverse meter factor used for piecewise linearization. It is paired with reverse flow rate 6 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 871 |
The sixth forward meter factor used for piecewise linearization. It is paired with forward flow rate 6 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 872 |
The seventh reverse meter factor used for piecewise linearization. It is paired with reverse flow rate 7 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 873 |
The seventh forward meter factor used for piecewise linearization. It is paired with forward flow rate 7 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 874 |
The eighth reverse meter factor used for piecewise linearization. It is paired with reverse flow rate 8 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 875 |
The eighth forward meter factor used for piecewise linearization. It is paired with forward flow rate 8 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 876 |
The ninth reverse meter factor used for piecewise linearization. It is paired with reverse flow rate 9 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 877 |
The ninth forward meter factor used for piecewise linearization. It is paired with forward flow rate 9 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 878 |
The tenth reverse meter factor used for piecewise linearization. It is paired with reverse flow rate 10 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 879 |
The tenth forward meter factor used for piecewise linearization. It is paired with forward flow rate 10 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 880 |
The eleventh reverse meter factor used for piecewise linearization. It is paired with reverse flow rate 11 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 881 |
The eleventh forward meter factor used for piecewise linearization. It is paired with forward flow rate 11 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 882 |
The twelfth reverse meter factor used for piecewise linearization. It is paired with reverse flow rate 12 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 883 |
The twelfth forward meter factor used for piecewise linearization. It is paired with forward flow rate 12 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to unity (1). |
| 884 |
Serial Port |
| 885 |
Selects the serial port to use for the optional GC communication. Port B(2) is available when the optional I/O Module is installed. |
| 886 |
Protocol |
| 887 |
Selects the type of Modbus protocol (ASCII or RTU) used to communicate with the GC. |
| 888 |
ASCII |
| 889 |
RTU |
| 890 |
Baud Rate |
| 891 |
Baud rate used to communicate serially to a GC. |
| 892 |
bits/s |
| 893 |
1200 |
| 894 |
2400 |
| 895 |
9600 |
| 896 |
19200 |
| 897 |
38400 |
| 898 |
57600 |
| 899 |
115200 |
| 900 |
Communication Timeout |
| 901 |
GC communication timeout value. This is the amount of time the meter will wait for message responses from the GC. |
| 902 |
Modbus Address |
| 903 |
Modbus address of the GC. |
| 904 |
Stream Number |
| 905 |
Selects the stream for the data read from the GC. |
| 906 |
Stream Timeout |
| 907 |
GC stream timeout value. When communicating with a GC, this specifies the length of time to wait for the desired stream to be updated before declaring an error. |
| 908 |
Heating Value Type |
| 909 |
Selects GC heating value type. |
| 910 |
Btu-Dry |
| 911 |
Btu-Saturated |
| 912 |
Btu-Actual |
| 913 |
Heating Value Unit |
| 914 |
The heating (measurement) unit used for reading the heating value from the GC. |
| 915 |
Btu/ft3 |
| 916 |
KJ/m3 |
| 917 |
KJ/dm3 |
| 918 |
MJ/m3 |
| 919 |
KCal/m3 |
| 920 |
KWh/m3 |
| 921 |
AGA8 Method |
| 922 |
Selects the AGA8 calculation method. If the calculations are to be performed externally, then the base-condition pressure and temperature values must be specified and the flow-condition pressure and temperature values must be fixed or live and the calculation results must be specified. |
| 923 |
External |
| 924 |
Gross Method 1 |
| 925 |
Gross Method 2 |
| 926 |
Detailed Method |
| 927 |
Base Temperature |
| 928 |
The base-condition temperature used for calculating the base-condition (corrected) volumetric flow rate. |
| 929 |
Base Pressure |
| 930 |
The base-condition pressure used for calculating the base-condition (corrected) volumetric flow rate. |
| 931 |
Reference Temperature |
| 932 |
Reference temperature for specific gravity (relative density) (required for AGA8 Gross Methods 1 and 2). |
| 933 |
Reference Pressure |
| 934 |
Reference (absolute) pressure for specific gravity (relative density) (required for AGA8 Gross Methods 1 and 2). |
| 935 |
Reference Temperature |
| 936 |
Reference temperature for molar density (required for AGA8 Gross Method 1). |
| 937 |
Reference Pressure |
| 938 |
Reference (absolute) pressure for molar density (required for AGA8 Gross Method 1). |
| 939 |
Heating Value |
| 940 |
Volumetric gross heating value (required for AGA8 Gross Method 1 = Gross Method 1)). These gas property values are fixed and the heating value and its reference temperature are user specified. Reading the gas property data from a GC requires both communication port B available and a valid GC interface key. |
| 941 |
Reference Temperature |
| 942 |
Volumetric gross heating value reference temperature (required for AGA8 Gross Method 1). |
| 943 |
Gas specific gravity (relative density) (required for AGA8 Gross Methods 1 and 2). |
| 944 |
Flow Mass Density |
| 945 |
Specifies the flow-condition gas mass density. This is used when the AGA8 calculations are performed externally selected via AGA8 calculation method. This is used in calculating Reynolds Number (required when calculating the flow-profile-effect correction on single and dual-path meters). |
| 946 |
Flow Compressibility |
| 947 |
Specifies (fixes) the flow-condition gas compressibility. |
| 948 |
Base Compressibility |
| 949 |
Specifies the base-condition gas compressibility. |
| 950 |
Source |
| 951 |
Selects the gas composition source for the base corrections (AGA8) and sound speed calculation (AGA10). The settings are Fixed(0) or Live - GC(1). The ability to read the gas composition from a GC is an optional feature that is enabled via the GC interface key. |
| 952 |
Live - GC |
| 953 |
Data Source in Alarm Condition |
| 954 |
Selects the gas property data source to use when the GC is in an alarm condition. Available user selections are Last good value (0) or Fixed value (1).
If Fixed value is selected, the meter will start using the fixed gas composition stored in the meter.
If Last good value is selected, the meter will use the last gas composition collected from the GC before the GC started to report alarms.
When Last good value is selected, the in-use gas property data is not updated with the invalid GC-read gas property data.
When Fixed value is used, the in-use gas property data is updated with the fixed gas property data. |
| 955 |
Last Good Value |
| 956 |
Fixed Value |
| 957 |
Carbon dioxide gas component mole fraction. |
| 958 |
Hydrogen gas component mole fraction. |
| 959 |
Carbon monoxide gas component mole fraction. |
| 960 |
Nitrogen gas component (required for AGA8 Gross Method 2 and Detail Method). |
| 961 |
Methane gas component mole fraction. |
| 962 |
Ethane gas component mole fraction. |
| 963 |
Propane gas component mole fraction. |
| 964 |
Water gas component mole fraction. |
| 965 |
Hydrogen sulfide gas component mole fraction. |
| 966 |
Oxygen gas component mole fraction. |
| 967 |
Isobutane gas component mole fraction. |
| 968 |
N-Butane gas component mole fraction. |
| 969 |
Isopentane gas component mole fraction. |
| 970 |
N-Pentane gas component mole fraction. |
| 971 |
N-Hexane gas component mole fraction. |
| 972 |
N-Heptane gas component mole fraction. |
| 973 |
N-Octane gas component mole fraction. |
| 974 |
N-Nonane gas component mole fraction. |
| 975 |
N-Decane gas component mole fraction. |
| 976 |
Helium gas component mole fraction. |
| 977 |
Argon gas component mole fraction. |
| 978 |
Comment |
| 979 |
Optional comment to include with forward baseline data. |
| 980 |
Comment |
| 981 |
Optional comment to include with reverse baseline data. |
| 982 |
This selects the first value to be shown on the local display. Other display items will be displayed in sequence at a rate determined by the delay time. When selected as None (0), this item will be skipped. The units this item is displayed in are determined by the units system, the corresponding volume units, and/or the time units. |
| 983 |
QFLOW - Uncorrected Volume Flow Rate |
| 984 |
TDYVL - Current Day's Forward Uncorrected Volume |
| 985 |
TDYVL - Current Day's Reverse Uncorrected Volume |
| 986 |
YSTVL - Previous Day's Forward Uncorrected Volume |
| 987 |
YSTVL - Previous Day's Reverse Uncorrected Volume |
| 988 |
TOTVL - Forward Uncorrected Volume |
| 989 |
TOTVL - Reverse Uncorrected Volume |
| 990 |
QBASE - Corrected Volume Flow Rate |
| 991 |
TDYVL - Current Day's Forward Corrected Volume |
| 992 |
TDYVL - Current Day's Reverse Corrected Volume |
| 993 |
YSTVL - Previous Day's Forward Corrected Volume |
| 994 |
YSTVL - Previous Day's Reverse Corrected Volume |
| 995 |
TOTVL - Forward Corrected Volume |
| 996 |
TOTVL - Reverse Corrected Volume |
| 997 |
VEL - Average Flow Velocity |
| 998 |
SOS - Average Sound Velocity |
| 999 |
TEMP - Flow-Condition Temperature |
| 1000 |
PRESS - Flow-Condition Pressure |
| 1001 |
FRQ1A - Frequency Channel 1A |
| 1002 |
FRQ1B - Frequency Channel 1B |
| 1003 |
KFCT1 - Frequency 1 K-Factor |
| 1004 |
FRQ2A - Frequency Channel 2A |
| 1005 |
FRQ2B - Frequency Channel 2B |
| 1006 |
KFCT2 - Frequency 2 K-Factor |
| 1007 |
AO1 - Analog Output 1 Current |
| 1008 |
AO2 - Analog Output 2 Current |
| 1009 |
This selects the second value to be shown on the local display. Other display items will be displayed in sequence at a rate determined by the delay time. When selected as None (0), this item will be skipped. The units this item is displayed in are determined by the units system, the corresponding volume units, and/or the time units. |
| 1010 |
This selects the third value to be shown on the local display. Other display items will be displayed in sequence at a rate determined by the delay time. When selected as None (0), this item will be skipped. The units this item is displayed in are determined by the units system, the corresponding volume units, and/or the time units. |
| 1011 |
This selects the fourth value to be shown on the local display. Other display items will be displayed in sequence at a rate determined by the delay time. When selected as None (0), this item will be skipped. The units this item is displayed in are determined by the units system, the corresponding volume units, and/or the time units. |
| 1012 |
This selects the fifth value to be shown on the local display. Other display items will be displayed in sequence at a rate determined by the delay time. When selected as None (0), this item will be skipped. The units this item is displayed in are determined by the units system, the corresponding volume units, and/or the time units. |
| 1013 |
This selects the sixth value to be shown on the local display. Other display items will be displayed in sequence at a rate determined by the delay time. When selected as None (0), this item will be skipped. The units this item is displayed in are determined by the units system, the corresponding volume units, and/or the time units. |
| 1014 |
This selects the seventh value to be shown on the local display. Other display items will be displayed in sequence at a rate determined by the delay time. When selected as None (0), this item will be skipped. The units this item is displayed in are determined by the units system, the corresponding volume units, and/or the time units. |
| 1015 |
This selects the eighth value to be shown on the local display. Other display items will be displayed in sequence at a rate determined by the delay time. When selected as None (0), this item will be skipped. The units this item is displayed in are determined by the units system, the corresponding volume units, and/or the time units. |
| 1016 |
This selects the ninth value to be shown on the local display. Other display items will be displayed in sequence at a rate determined by the delay time. When selected as None (0), this item will be skipped. The units this item is displayed in are determined by the units system, the corresponding volume units, and/or the time units. |
| 1017 |
This selects the tenth value to be shown on the local display. Other display items will be displayed in sequence at a rate determined by the delay time. When selected as None (0), this item will be skipped. The units this item is displayed in are determined by the units system, the corresponding volume units, and/or the time units. |
| 1018 |
Volumetric Flow Rate Time Unit |
| 1019 |
The time units used by the local display, if applicable, to display the current item. |
| 1020 |
U. S. Customary Volume Unit |
| 1021 |
The volumetric units used by the local display, if applicable, to display the current item when the units system is selected to U.S. Customary (0). |
| 1022 |
Thousand Cubic Feet |
| 1023 |
Metric Volume Unit |
| 1024 |
The volumetric units used by the local display, if applicable, to display the current item when the units system is selected to Metric (1). |
| 1025 |
Thousand Cubic Meters |
| 1026 |
DampingValue |
| 1027 |
Specifies the damping value for all outputs and measurement data points. The damping value is the (worst case) time for the outputs and measurement data points to reach 63% of the steady-state value in response to a step input. This is a function of the desired batch update period. |
| 1028 |
Specifies the Analog Output 1 volumetric flow rate corresponding to the minimum current (4 mA) when the Analog Output 1 is set to uncorrected volume flow rate or corrected volume flow rate. |
| 1029 |
Specifies the Analog Output 1 volumetric flow rate corresponding to the maximum current (20 mA) when the Analog Output 1 is set to uncorrected volume flow rate or corrected volume flow rate. |
| 1030 |
Direction |
| 1031 |
Selects the flow direction represented by Analog Output 1. When set to "Reverse" or "Forward", the analog output represents the specified content when the flow is in selected direction. When set to "Absolute", the analog output represents the specified content regardless of the flow direction. |
| 1032 |
Direction |
| 1033 |
Selects the flow direction represented by Analog Output 2. When set to "Reverse" or "Forward", the analog output represents the specified content when the flow is in selected direction. When set to "Absolute", the analog output represents the specified content regardless of the flow direction. |
| 1034 |
Alarm Action |
| 1035 |
Specifies the action for Analog Output 1 current when the content is invalid. No special action is taken when set to None. |
| 1036 |
High - 20 mA |
| 1037 |
Low - 4 mA |
| 1038 |
Hold Last Value |
| 1039 |
Very Low - 3.5 mA |
| 1040 |
Very High - 20.5 mA |
| 1041 |
Alarm Action |
| 1042 |
Specifies the action for Analog Output 2 current when the content is invalid. No special action is taken when set to None. |
| 1043 |
Maximum Frequency |
| 1044 |
Selects the Frequency Output 1 pair maximum (full-scale) frequency used in determining the K-factor and inverse K-factor. |
| 1045 |
1000 |
| 1046 |
5000 |
| 1047 |
Maximum Frequency |
| 1048 |
Selects the Frequency Output 2 pair maximum (full-scale) frequency used in determining the K-factor and inverse K-factor. |
| 1049 |
B Phase Zeroed on Error |
| 1050 |
When TRUE (1), forces the Frequency Output 1 channel B frequency to zero when the frequency pair's data is invalid. |
| 1051 |
Not Forced to Zero on Error |
| 1052 |
Forced to Zero on Error |
| 1053 |
B Phase Zeroed on Error |
| 1054 |
When TRUE (1), forces the Frequency Output 2 channel B frequency to zero when the frequency pair's data is invalid. |
| 1055 |
B Phase |
| 1056 |
Selects the Frequency Output 1 pair channel B phase relative to the channel A phase based on the flow direction. |
| 1057 |
Lag Forward, Lead Reverse |
| 1058 |
Lead Forward, Lag Reverse |
| 1059 |
B Phase |
| 1060 |
Selects the Frequency Output 2 pair channel B phase relative to the channel A phase based on the flow direction. |
| 1061 |
Volume Feedback |
| 1062 |
Specifies the Frequency Output 1 pair percentage of error (determined by frequency feedback) to adjust for per batch. This only applies when the frequency pair content is selected to be a rate. |
| 1063 |
Volume Feedback |
| 1064 |
Specifies the Frequency Output 2 pair percentage of error (determined by frequency feedback) to adjust for per batch. This only applies when the frequency pair content is selected to be a rate. |
| 1065 |
Channel A Polarity |
| 1066 |
Selects the Digital Output 1A polarity as "Normal" or "Inverted". For "Normal" polarity, a high output indicates either valid frequency data or forward flow (depending upon the content selected via the DO1AContent data point). For "Inverted" polarity, a low output indicates either valid frequency data or forward flow. |
| 1067 |
Normal |
| 1068 |
Inverted |
| 1069 |
Channel A Polarity |
| 1070 |
Selects the Digital Output 2A polarity as "Normal" or "Inverted". For "Normal" polarity, a high output indicates either valid frequency data or forward flow (depending upon the content DO2AContent). For "Inverted" polarity, a low output indicates either valid frequency data or forward flow. |
| 1071 |
Channel A Content |
| 1072 |
Selects the content (Freq1 Validity (0) or Flow Direction (2)) for Digital Output 1A to be directed to FODO 1, FODO2 or FODO 3. |
| 1073 |
Frequency Output 1 Validity |
| 1074 |
Flow Direction |
| 1075 |
Channel A Content |
| 1076 |
Selects the content (Freq2 Validity (1) or Flow Direction (2)) for Digital Output 2A to be directed to FODO2 or FODO 3. |
| 1077 |
Frequency Output 2 Validity |
| 1078 |
Channel B Polarity |
| 1079 |
Selects the Digital Output 1B polarity as "Normal" or "Inverted". For "Normal" polarity, a high output indicates either valid frequency data or forward flow (depending upon the content selected via the DO1BContent data point). For "Inverted" polarity, a low output indicates either valid frequency data or forward flow. |
| 1080 |
Channel B Polarity |
| 1081 |
Selects the Digital Output 2B polarity as "Normal" or "Inverted". For "Normal" polarity, a high output indicates either valid frequency data or forward flow (depending upon the content selected via the Digital Output 2B content data point). For "Inverted" polarity, a low output indicates either valid frequency data or forward flow. |
| 1082 |
Channel B Content |
| 1083 |
Selects the content (Freq1 Validity (0) or Flow Direction (2)) for Digital Output 1B to be directed to FODO 1, FODO2 or FODO 3. |
| 1084 |
Channel B Content |
| 1085 |
Selects the content (Freq2 Validity (1) or Flow Direction (2)) for Digital Output 2B to be directed to FODO2 or FODO 3. |
| 1086 |
High Limit |
| 1087 |
Pressure alert high limit. The pressure is invalid when the input flow pressure is at or above this limit. |
| 1088 |
Low Limit |
| 1089 |
Pressure alert low limit. The pressure is invalid when the input flow pressure is at or below this limit. |
| 1090 |
Upper Range |
| 1091 |
Specifies the input flow pressure value that corresponds to the maximum (20 mA) input signal. |
| 1092 |
Lower Range |
| 1093 |
Specifies the input flow pressure value that corresponds to the minimum (4 mA) input signal. |
| 1094 |
Fixed Pressure |
| 1095 |
Specifies the flow-condition pressure used in calculations when the enable pressure input is set to "Fixed". |
| 1096 |
Gage or Absolute |
| 1097 |
Specifies whether the input pressure is absolute TRUE (1), or gage FALSE (0). If the input pressure is gage, then the absolute pressure is calculated as the sum of the input gage pressure and the atmospheric pressure. |
| 1098 |
Gage |
| 1099 |
Atmospheric Pressure |
| 1100 |
Specifies the atmospheric pressure. This value is required when the input pressure absolute/gage selector is Gage, so that flow-condition absolute pressure can be calculated. |
| 1101 |
Pressure Expansion Correction |
| 1102 |
Enables volumetric flow rate pressure-effect expansion correction when set to TRUE (1). This requires the flow-condition pressure to be fixed or live and the pipe outside diameter, Young's Modulus and Poisson's Ratio to be specified. |
| 1103 |
Upper Range |
| 1104 |
Specifies the input flow temperature value that corresponds to the maximum (20 mA) input signal. |
| 1105 |
Lower Range |
| 1106 |
Specifies the input flow temperature value that corresponds to the minimum (4 mA) input signal. |
| 1107 |
Temperature Expansion Correction |
| 1108 |
Enables volumetric flow rate temperature-effect expansion correction when set to TRUE (1). This requires the flow-condition temperature to be fixed or live and the pipe material linear expansion coefficient with reference temperature to be specified. |
| 1109 |
General Polarity |
| 1110 |
This value sets the polarity of digital input 1. A TRUE (1) value is normal polarity (default). A FALSE (0) value is inverted polarity. |
| 1111 |
Calibration Polarity |
| 1112 |
This point specifies the polarity for digital input 1 (DI1). |
| 1113 |
Digital Input 1 Calibrate Active High |
| 1114 |
Digital Input 1 Calibrate Active Low |
| 1115 |
Calibration Gating |
| 1116 |
This point specifies the calibration gating for digital input 1. |
| 1117 |
Digital Input 1 Calibrate Edge Gated |
| 1118 |
Digital Input 1 Calibrate State Gated |
| 1119 |
Number of Request Preambles |
| 1120 |
HART, via AO1, minimum number of Master command preamble bytes. |
| 1121 |
Test Mode Timeout |
| 1122 |
Non-normal operation timeout. The maximum length of time that a frequency output pair, digital output pair, analog output or calibration can remain in the test mode. In the event communications are lost between the Ultrasonic meter software and the meter (before a test mode is stopped), the meter will automatically end the test mode after the non-normal operation timeout has expired. This can be from 1 to 30 minutes depending on its settings. By default, the timeout is set to two minutes. |
| 1123 |
Running Average Turbulence A |
| 1124 |
An average of chord A turbulence over one minute used for baselines. |
| 1125 |
Running Average Turbulence B |
| 1126 |
An average of chord B turbulence over one minute used for baselines. |
| 1127 |
Running Average Turbulence C |
| 1128 |
An average of chord C turbulence over one minute used for baselines. |
| 1129 |
Running Average Turbulence D |
| 1130 |
An average of chord D turbulence over one minute used for baselines. |
| 1131 |
Running Average Standard Deviation of Cross-Flow |
| 1132 |
Running standard deviation of cross-flow over a minute. |
| 1133 |
Running Average Standard Deviation of Profile Factor |
| 1134 |
Running standard deviation of the profile factor over a minute. |
| 1135 |
Running Average Standard Deviation of Symmetry |
| 1136 |
Running standard deviation of symmetry over a minute. |
| 1137 |
Running Average Validity |
| 1138 |
Are the values in the one minute averages valid for use with the baseline |
| 1139 |
Not Valid |
| 1140 |
Valid |
| 1141 |
Flow direction indicator. |
| 1142 |
Chord A flow velocity. |
| 1143 |
Chord B flow velocity. |
| 1144 |
Chord C flow velocity. |
| 1145 |
Chord D flow velocity. |
| 1146 |
Chord A sound velocity. |
| 1147 |
Chord B sound velocity. |
| 1148 |
Chord C sound velocity. |
| 1149 |
Chord D sound velocity. |
| 1150 |
Average sound velocity (per batch) of all active chords. |
| 1151 |
Reverse Flow Volume |
| 1152 |
Volume flowed from continuous flow in reverse direction. This volume is compared to the reverse flow limit to determine the reverse flow alert. It is only accumulated when the flow velocity is below the reverse flow velocity threshold. |
| 1153 |
Signal A1 |
| 1154 |
Batch average of the signal amplitude when transducer A1 receives a signal. |
| 1155 |
Signal A2 |
| 1156 |
Batch average of the signal amplitude when transducer A2 receives a signal. |
| 1157 |
Signal B1 |
| 1158 |
Batch average of the signal amplitude when transducer B1 receives a signal. |
| 1159 |
Signal B2 |
| 1160 |
Batch average of the signal amplitude when transducer B2 receives a signal. |
| 1161 |
Signal C1 |
| 1162 |
Batch average of the signal amplitude when transducer C1 receives a signal. |
| 1163 |
Signal C2 |
| 1164 |
Batch average of the signal amplitude when transducer C2 receives a signal. |
| 1165 |
Signal D1 |
| 1166 |
Batch average of the signal amplitude when transducer D1 receives a signal. |
| 1167 |
Signal D2 |
| 1168 |
Batch average of the signal amplitude when transducer D2 receives a signal. |
| 1169 |
Noise A1 |
| 1170 |
Batch average of the noise amplitude when transducer A1 receives a signal. |
| 1171 |
Noise A2 |
| 1172 |
Batch average of the noise amplitude when transducer A2 receives a signal. |
| 1173 |
Noise B1 |
| 1174 |
Batch average of the noise amplitude when transducer B1 receives a signal. |
| 1175 |
Noise B2 |
| 1176 |
Batch average of the noise amplitude when transducer B2 receives a signal. |
| 1177 |
Noise C1 |
| 1178 |
Batch average of the noise amplitude when transducer C1 receives a signal. |
| 1179 |
Noise C2 |
| 1180 |
Batch average of the noise amplitude when transducer C2 receives a signal. |
| 1181 |
Noise D1 |
| 1182 |
Batch average of the noise amplitude when transducer D1 receives a signal. |
| 1183 |
Noise D2 |
| 1184 |
Batch average of the noise amplitude when transducer D2 receives a signal. |
| 1185 |
SNR A1 |
| 1186 |
Average signal-to-noise ratio (A1). |
| 1187 |
SNR A2 |
| 1188 |
Average signal-to-noise ratio (A2). |
| 1189 |
SNR B1 |
| 1190 |
Average signal-to-noise ratio (B1). |
| 1191 |
SNR B2 |
| 1192 |
Average signal-to-noise ratio (B2). |
| 1193 |
SNR C1 |
| 1194 |
Average signal-to-noise ratio (C1). |
| 1195 |
SNR C2 |
| 1196 |
Average signal-to-noise ratio (C2). |
| 1197 |
SNR D1 |
| 1198 |
Average signal-to-noise ratio (D1). |
| 1199 |
SNR D2 |
| 1200 |
Average signal-to-noise ratio (D2). |
| 1201 |
Performance A1 |
| 1202 |
The performance of path A1 indicated as the percentage of good signals in those received from that transducer in a batch. See also the minimum percentage of good measurements for working chord. |
| 1203 |
Performance A2 |
| 1204 |
The performance of path A2 indicated as the percentage of good signals in those received from that transducer in a batch. See also the minimum percentage of good measurements for working chord. |
| 1205 |
Performance B1 |
| 1206 |
The performance of path B1 indicated as the percentage of good signals in those received from that transducer in a batch. See also the minimum percentage of good measurements for working chord. |
| 1207 |
Performance B2 |
| 1208 |
The performance of path B2 indicated as the percentage of good signals in those received from that transducer in a batch. See also the minimum percentage of good measurements for working chord. |
| 1209 |
Performance C1 |
| 1210 |
The performance of path C1 indicated as the percentage of good signals in those received from that transducer in a batch. See also the minimum percentage of good measurements for working chord. |
| 1211 |
Performance C2 |
| 1212 |
The performance of path C2 indicated as the percentage of good signals in those received from that transducer in a batch. See also the minimum percentage of good measurements for working chord. |
| 1213 |
Performance D1 |
| 1214 |
The performance of path D1 indicated as the percentage of good signals in those received from that transducer in a batch. See also the minimum percentage of good measurements for working chord. |
| 1215 |
Performance D2 |
| 1216 |
The performance of path D2 indicated as the percentage of good signals in those received from that transducer in a batch. See also the minimum percentage of good measurements for working chord. |
| 1217 |
Gain A1 |
| 1218 |
Gain when transducer A1 is receiving a signal. Gain is applied to the received signal in hardware in volts/volt (hardware gain units). Conversion from hardware gain to decibels is gain (db) = 20 * log10(gain(hw)). |
| 1219 |
Gain A2 |
| 1220 |
Gain when transducer A2 is receiving a signal. Gain is applied to the received signal in hardware in volts/volt (hardware gain units). Conversion from hardware gain to decibels is gain (db) = 20 * log10(gain(hw)). |
| 1221 |
Gain B1 |
| 1222 |
Gain when transducer B1 is receiving a signal. Gain is applied to the received signal in hardware in volts/volt (hardware gain units). Conversion from hardware gain to decibels is gain (db) = 20 * log10(gain(hw)). |
| 1223 |
Gain B2 |
| 1224 |
Gain when transducer B2 is receiving a signal. Gain is applied to the received signal in hardware in volts/volt (hardware gain units). Conversion from hardware gain to decibels is gain (db) = 20 * log10(gain(hw)). |
| 1225 |
Gain C1 |
| 1226 |
Gain when transducer C1 is receiving a signal. Gain is applied to the received signal in hardware in volts/volt (hardware gain units). Conversion from hardware gain to decibels is gain (db) = 20 * log10(gain(hw)). |
| 1227 |
Gain C2 |
| 1228 |
Gain when transducer C2 is receiving a signal. Gain is applied to the received signal in hardware in volts/volt (hardware gain units). Conversion from hardware gain to decibels is gain (db) = 20 * log10(gain(hw)). |
| 1229 |
Gain D1 |
| 1230 |
Gain when transducer D1 is receiving a signal. Gain is applied to the received signal in hardware in volts/volt (hardware gain units). Conversion from hardware gain to decibels is gain (db) = 20 * log10(gain(hw)). |
| 1231 |
Gain D2 |
| 1232 |
Gain when transducer D2 is receiving a signal. Gain is applied to the received signal in hardware in volts/volt (hardware gain units). Conversion from hardware gain to decibels is gain (db) = 20 * log10(gain(hw)). |
| 1233 |
Reverse Flow Volume Limit |
| 1234 |
This is the limit for the reverse flow alert. If the volume for reverse flow exceeds this value with continuous reverse flow, the reverse flow alert will be set. |
| 1235 |
Reverse Flow Zero Cutoff |
| 1236 |
Velocity threshold below which the flow velocity is considered reversed (and thus the reverse flow volume is accumulated). |
| 1237 |
Detect Reverse Flow |
| 1238 |
Disables reverse flow detection when set FALSE (0). Setting this to TRUE (1) will enable reverse flow detection if the flow analysis feature enable is TRUE (1) and the device number is 3414. |
| 1239 |
Meter Serial Number |
| 1240 |
The serial number for the ultrasonic meter. The meter serial number is located on the tag attached to the ultrasonic meter body and is included in the maintenance log and reports file. |
| 1241 |
Subnet Mask |
| 1242 |
The meter's Ethernet port subnet mask. |
| 1243 |
Default Gateway |
| 1244 |
Ethernet default gateway address to use if the meter is behind a router and you want to access it from outside the router. If equal to 0.0.0.0, then the unit will not use this value. |
| 1245 |
Alternate Port |
| 1246 |
The TCP/IP port used for Modbus TCP/IP in addition to port 502. The alternate port cannot be set to any of the reserved or well-known ports 1, 7, 20, 21, 23, 42, 53, 67, 68, 502, 9877, 10000, 11000 or 11001. If the alternate port is changed while there are open connections on it then the connections shall be closed. |
| 1247 |
Unit Identifier |
| 1248 |
The Modbus address for Modbus TCP/IP on the Ethernet port. This is the "unit identifier" that is used if the Modbus TCP/IP network has a bridge to a serial Modbus network. |
| 1249 |
IsPortAAvail |
| 1250 |
Communication port A available indicator based on the CPU Module's I/O board and the optional I/O Module configuration. |
| 1251 |
IsPortBAvail |
| 1252 |
Communication port B available indicator based on the CPU Module's I/O board and the optional I/O Module configuration. |
| 1253 |
Baud Rate |
| 1254 |
The baud rate used for serial port A. |
| 1255 |
Baud Rate |
| 1256 |
The baud rate used for serial port B. |
| 1257 |
Address |
| 1258 |
The Modbus address used by communication Port A. The Modbus address is also used as a basis for the meter's IP address in the form 172.16.17.ModbusID when the meter is running a PPP server on the serial port. |
| 1259 |
Address |
| 1260 |
The Modbus address used by communication Port B. The Modbus address is also used as a basis for the meter's IP address in the form 172.16.17.ModbusID when the meter is running a PPP server on the serial port. |
| 1261 |
Hardware Protocol |
| 1262 |
The hardware protocol on port A. |
| 1263 |
RS-232 |
| 1264 |
RS-485 Half-Duplex |
| 1265 |
RS-485 Full-Duplex |
| 1266 |
Response Delay |
| 1267 |
Communication Port A response delay. The communication port will wait the specified amount of time before sending a response. |
| 1268 |
Response Delay |
| 1269 |
Communication Port B response delay. The communication port will wait the specified amount of time before sending a response. |
| 1270 |
Communication Timeout |
| 1271 |
The meter must respond to Modbus request messages within this time limit; if it cannot it will not respond at all. |
| 1272 |
Communication Timeout |
| 1273 |
RTS Off Delay |
| 1274 |
Communication Port A handshaking RTS off delay time. The meter will hold RTS active for this amount of time after sending the reply. |
| 1275 |
RTS On Delay |
| 1276 |
Communication Port A handshaking RTS on delay time. The meter will activate RTS for this amount of time before sending out the message. |
| 1277 |
PPP Connection Timeout |
| 1278 |
Specifies the inactivity timeout (no TCP/IP packets) before the meter automatically disconnects a PPP connection (direct serial or modem connection) on Port A. |
| 1279 |
PPP Connection Timeout |
| 1280 |
Specifies the inactivity timeout (no TCP/IP packets) before the meter automatically disconnects a PPP connection (direct serial or modem connection) on Port B. |
| 1281 |
Hardware Flow Control |
| 1282 |
When TRUE (1), enables communication Port A hardware flow control (RTS/CTS). |
| 1283 |
Maximum Datagram Size |
| 1284 |
The maximum MTU and MRU bytes in a datagram on serial port A. |
| 1285 |
Maximum Datagram Size |
| 1286 |
The maximum MTU and MRU bytes in a datagram on serial port B. |
| 1287 |
Chord |
| 1288 |
Chord A inactive control. When TRUE (1), Chord A is set to inactive. The chord's transducers are not fired. |
| 1289 |
Active |
| 1290 |
Inactive |
| 1291 |
Chord |
| 1292 |
Chord B inactive control. When TRUE (1), Chord B is set to inactive. The chord's transducers are not fired. |
| 1293 |
Chord |
| 1294 |
Chord C inactive control. When TRUE (1), Chord C is set to inactive. The chord's transducers are not fired. |
| 1295 |
Chord |
| 1296 |
Chord D inactive control. When TRUE (1), Chord D is set to inactive. The chord's transducers are not fired. |
| 1297 |
X Dimension |
| 1298 |
Chord A "X" dimension (component of LA in the direction of flow within the meter bore). The factory setting should only be changed when changing a transducer or after a meter cold start. |
| 1299 |
X Dimension |
| 1300 |
Chord B "X" dimension (component of LB in the direction of flow within the meter bore). The factory setting should only be changed when changing a transducer or after a meter cold start. |
| 1301 |
X Dimension |
| 1302 |
Chord C "X" dimension (component of LC in the direction of flow within the meter bore). The factory setting should only be changed when changing a transducer or after a meter cold start. |
| 1303 |
X Dimension |
| 1304 |
Chord D "X" dimension (component of LD in the direction of flow within the meter bore). The factory setting should only be changed when changing a transducer or after a meter cold start. |
| 1305 |
L Dimension |
| 1306 |
The distance between the transducer faces on chord A. The factory setting should only be changed when changing a transducer or after a meter cold start. |
| 1307 |
L Dimension |
| 1308 |
The distance between the transducer faces on chord B. The factory setting should only be changed when changing a transducer or after a meter cold start. |
| 1309 |
L Dimension |
| 1310 |
The distance between the transducer faces on chord C. The factory setting should only be changed when changing a transducer or after a meter cold start. |
| 1311 |
L Dimension |
| 1312 |
The distance between the transducer faces on chord D. The factory setting should only be changed when changing a transducer or after a meter cold start. |
| 1313 |
Average Delay |
| 1314 |
The chord-specific delay for chord A primarily due to the signal processing algorithm and acoustic propagation time within the transducer including the matching layer. It is used in conjunction with the overall system delay. |
| 1315 |
Average Delay |
| 1316 |
The chord-specific delay for chord B primarily due to the signal processing algorithm and acoustic propagation time within the transducer including the matching layer. It is used in conjunction with the overall system delay. |
| 1317 |
Average Delay |
| 1318 |
The chord-specific delay for chord C primarily due to the signal processing algorithm and acoustic propagation time within the transducer including the matching layer. It is used in conjunction with the overall system delay. |
| 1319 |
Average Delay |
| 1320 |
The chord-specific delay for chord D primarily due to the signal processing algorithm and acoustic propagation time within the transducer including the matching layer. It is used in conjunction with the overall system delay. |
| 1321 |
Delta Delay |
| 1322 |
The adjustment to the chord A delta times to ensure calibration at zero flow. |
| 1323 |
Delta Delay |
| 1324 |
The adjustment to the chord B delta times to ensure calibration at zero flow. |
| 1325 |
Delta Delay |
| 1326 |
The adjustment to the chord C delta times to ensure calibration at zero flow. |
| 1327 |
Delta Delay |
| 1328 |
The adjustment to the chord D delta times to ensure calibration at zero flow. |
| 1329 |
Contract Hour |
| 1330 |
Hour of day to log the daily record. This is expressed using military time: midnight is 0 hours, noon is 12 hours, 11PM is 23 hours. |
| 1331 |
Hysteresis Filter Count |
| 1332 |
Alarm log repetitive alarm filter count. This point, along with alarm log hysteresis filter time span, is used to prevent the alarm log from filling up in the event of a very repetitive alarm (such as the flow temperature fluctuating around one of its alarm limits). If a data point being monitored for the alarm log has this number of alarms within a specified length of time, then alarming is turned off for that point until no new alarms are received for that point within the specified length of time. |
| 1333 |
Hysteresis Filter Time |
| 1334 |
Alarm log repetitive alarm filter time. This point, along with alarm log hysteresis filter number of occurrences, is used to prevent the alarm log from filling up in the event of a very repetitive alarm (such as the flow temperature fluctuating around one of its alarm limits). If a data point being monitored for the alarm log has alarm log hysteresis filter number of occurrences alarms within this specified length of time, then alarming is turned off for that point until no new alarms are received for that point for this length of time. |
| 1335 |
Old Unread Records |
| 1336 |
Old (unread) alarm log records can be overwritten by new records when TRUE (1). If FALSE (0) and the log becomes full, logging will stop until oldest log records are marked as read to make room for new records. |
| 1337 |
Do Not Overwrite Old Records |
| 1338 |
Overwrite Old Records |
| 1339 |
Old Unread Records |
| 1340 |
Old (unread) audit log records can be overwritten by new records when TRUE (1). If FALSE (0) and the log becomes full, logging will stop until oldest log records are marked as read to make room for new records. |
| 1341 |
Old Unread Records |
| 1342 |
Old (unread) hourly log records can be overwritten by new records when TRUE (1). If FALSE (0) and the log becomes full, logging will stop until oldest log records are marked as read to make room for new records. |
| 1343 |
Old Unread Records |
| 1344 |
Old (unread daily) log records can be overwritten by new records when TRUE (1). If FALSE (0) and the log becomes full, logging will stop until oldest log records are marked as read to make room for new records. |
| 1345 |
Old Unread Records |
| 1346 |
Old (unread) system log records can be overwritten by new records when TRUE (1). If FALSE (0) and the log becomes full, logging will stop until oldest log records are marked as read to make room for new records. |
| 1347 |
Re-acquiring Constant Velocity Batches |
| 1348 |
The number of batches the average flow is held at the last measured value while re-acquiring the signal. |
| 1349 |
Smoothing |
| 1350 |
Batch smoothing factor. This is used to "smooth" the velocity measurement by averaging "new" and "old" data. This specifies the percentage of a batch's total data to be taken from previous batch period(s). When set to zero, then only new data will be used for a batch update. For example, if the batch smoothing factor is set to 20% and there are 32 new data sequences, then 8 sequences from the most recent batch(es) will also be used for the current batch (8=20% of (32+8)). |
| 1351 |
0 |
| 1352 |
20 |
| 1353 |
40 |
| 1354 |
60 |
| 1355 |
80 |
| 1356 |
Maximum No Data Batches |
| 1357 |
Maximum number of consecutive batches without new data before is alarmed. This can be caused if the Acquisition Module is disconnected or not communicating with the CPU Module. |
| 1358 |
Desired Firing Rate |
| 1359 |
The desired emission rate or time between the firing of two transducers in sequence based on the firing order. The actual emission rate used will not be less than the meter's calculated minimum based on the meter's geometry (pipe diameter, distance between transducers, axial distance between transducers , the minimum speed of sound and the physical characteristics of the transducers themselves. The actual emission rate used may also be impacted by stacking. A value of (0) ensures the use of fastest available rate determined by the meter. |
| 1360 |
Desired Stacking Firing Rate |
| 1361 |
The desired emission rate or time between firing of the same transducer when stacking is turned on, that is the stack size is not equal to (1). The actual emission rate used will not be less than the meter's calculated minimum based on the meter's geometry (pipe diameter, distance between transducers, axial distance between transducers , the minimum speed of sound and the physical characteristics of the transducers themselves. This value may impact the overall transducer to transducer emission rate selected by the emission rate desired. A value of (0) ensures the use of fastest available rate determined by the meter. |
| 1362 |
Sequence |
| 1363 |
The order in which the transducers fire. The meter fires at the fastest possible rate only when each chord's upstream/downstream transducers are not fired successively. |
| 1364 |
B1,B2,C1,C2,A1,A2,D1,D2 |
| 1365 |
A1,A2,B1,B2,C1,C2,D1,D2 |
| 1366 |
A1,B1,C1,D1,A2,B2,C2,D2 |
| 1367 |
Minimum Operating Chords |
| 1368 |
The minimum number of operating chords for a valid measurement. If the number of operating chords is less than this value, then the too few operating chords status is set. The range of values and default value are dependent upon the meter device number. |
| 1369 |
Batches for Chord Hard Failed |
| 1370 |
The number of consecutive batches that a chord must fail before being declared "hard failed." A chord hard failure is indicated by the corresponding chord A hard failed alert, chord B hard failed alert, chord C hard failed alert and chord D hard failed alert. |
| 1371 |
The meter installed backwards control used in setting the current flow direction indicator. Set the meter installed backwards control to TRUE (1) if the meter is installed backwards from the normal (forward) flow direction. |
| 1372 |
Meter In Normal Direction |
| 1373 |
Meter In Reverse Direction |
| 1374 |
Dithering |
| 1375 |
Turns dithering on when set to TRUE (1) which minutely alters the firing time to prevent problems associated with resonance from building up. |
| 1376 |
Chord Proportions Update Batches |
| 1377 |
Number of consecutive batches without chord failures required for updating chord proportions. The default value is 24 consecutive batches (minimum 1 and maximum value 1000). |
| 1378 |
Chord Proportion Update Factor |
| 1379 |
Chord proportion update factor. This controls how quickly the chord proportions change relative to the current velocity proportion values. The lower the factor, the more quickly the proportions change. |
| 1380 |
Minimum Good Measurements |
| 1381 |
The minimum percentage of good measurements for a working chord. A chord with a percentage of good measurements less than this threshold is considered failed. The percentage good measurements for a chord may vary slightly from the individual path good measurements since both the upstream and downstream paths must be good at the same time for a chord to be considered good. |
| 1382 |
Batch Size |
| 1383 |
Number of completed firing sequences between updating the signal gain, hold time, and tracking values. The default value is 20 firing sequences (minimum is 5 and maximum is 120). |
| 1384 |
Synchronization |
| 1385 |
Configure Transducer Firing Synchronization to be enabled ("Enabled", 1) or disabled ("Disabled", 0) between co-located meters. Transducer Firing Synchronization can only be enabled ("Enabled", 1) if Co-located meter mode is not disabled ("Disabled", 0). |
| 1386 |
Velocity Threshold |
| 1387 |
When the average weighted flow velocity is below this threshold the flow direction will not change. This value is also used along with the pipe area to compute the volumetric flow cut off which in turn prevents "flow gated" (FLOW_GATED) values from being accumulated. The flow analysis lower limit may not be set lower than this value. |
| 1388 |
Minimum Velocity for Chord Proportions |
| 1389 |
Minimum velocity for updating chord proportions. Chord proportions are not updated when the flow velocity is below this value. |
| 1390 |
Pipe Inside Diameter |
| 1391 |
The pipe inside diameter used to calculate the pipe area and port angle. |
| 1392 |
Pipe Outside Diameter |
| 1393 |
Pipe outside diameter. This is used to calculate the pressure-effect expansion correction factor (when the correction is enabled via the enable pressure-effect expansion correction). |
| 1394 |
Young's Modulus |
| 1395 |
Young's Modulus value (tensile stress to tensile strain ratio). This is used to calculate the strain per unit stress when expansion correction is enabled. |
| 1396 |
Poisson's Ratio |
| 1397 |
Poisson's Ratio value (absolute ratio of lateral strain to axial strain). This is used to calculate the strain per unit stress when expansion correction is enabled. |
| 1398 |
Linear Expansion Coefficient |
| 1399 |
Linear expansion coefficient. This is used to calculate the temperature-effect expansion correction factor (when the correction is enabled via the enable temperature-effect expansion correction). |
| 1400 |
Reference Pressure |
| 1401 |
Reference coefficient used to compute pressure-effect expansion correction. Normally this is one atmosphere. |
| 1402 |
Locate Signal Start (Pk1Pct) |
| 1403 |
The percentage of the maximum signal amplitude used as a threshold to find the first peak which is then used to determine the starting position of the sampled waveform. If conditions exist that make the start of the signal difficult to detect (peak switching) this level may be adjusted to get a stable signal. |
| 1404 |
Max Noise Energy Threshold (MaxNoise) |
| 1405 |
Maximum noise energy threshold. If the signal's noise energy is above this threshold, the signal for that transducer firing is discarded. |
| 1406 |
No. of Cycles (XdcrNumDriveCycles) |
| 1407 |
Number of cycles for transducer. Will be overwritten when transducer type changes. |
| 1408 |
Low Limit (TspfLo) |
| 1409 |
The lower limit or floor for the default and the individual path computed values. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 1410 |
High Limit (TspfHi) |
| 1411 |
The upper limit or ceiling for the default and the individual path computed values. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 1412 |
Sensitivity (TspfSen) |
| 1413 |
The sensitivity applied to the comparison of the individual peaks SPF to the paths targeted SPF. The sensitivity is used to generate similar magnitudes to the SPE and Amp comparisons used to score peaks in the process of selecting P1.This value should only be changed at the factory or under the direction of Daniel technical support. |
| 1414 |
Target (Tspe) |
| 1415 |
The default for the targeted SPE which is the time in sample intervals (SI), or distance between the first energy position (Pe) and the signal the zero crossing detection point (P1). It is also the value used for inactive paths. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 1416 |
Low Limit (TspeLo) |
| 1417 |
High Limit (TspeHi) |
| 1418 |
Sensitivity (TspeSen) |
| 1419 |
The sensitivity applied to the comparison of the individual peaks SPE to the paths targeted SPE. The sensitivity is used to generate similar magnitudes to the SPF and Amp comparisons used to score peaks in the process of selecting P1.This value should only be changed at the factory or under the direction of Daniel technical support. |
| 1420 |
Absolute (Pe-Pf) Limit (TspeLmt) |
| 1421 |
The Tspf and Tspe calculations are not performed if the distance (in SI) between Pe and Pf exceed this amount. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 1422 |
Target (Tamp) |
| 1423 |
The default for the targeted Amp which is the value of the peak following the zero crossing detection point (P1). It is also the value used for inactive paths. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 1424 |
Low Limit (TampLo) |
| 1425 |
The lower limit or floor for the magnitude (absolute value of) the default and the individual path computed values. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 1426 |
High Limit (TampHi) |
| 1427 |
The upper limit or ceiling for the magnitude (absolute value of) the default and the individual path computed values. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 1428 |
Sensitivity (TampSen) |
| 1429 |
The sensitivity applied to the comparison of the individual peaks Amp to the paths targeted Amp. The sensitivity is used to generate similar magnitudes to the SPE and SPF comparisons used to score peaks in the process of selecting P1. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 1430 |
Weighting Factor (TspfWt) |
| 1431 |
The weighting applied to the score generated by TspfSen when summed with TspeWt * TspeSen score and TampWt * TampSen score to generate an overall rating to select P1. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 1432 |
Weighting Factor (TspeWt) |
| 1433 |
The weighting applied to the score generated by TspeSen when summed with TspfWt * TspfSen score and TampWt * TampSen score to generate an overall rating to select P1. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 1434 |
Weighting Factor (TampWt) |
| 1435 |
The weighting applied to the score generated by TampSen when summed with TspeWt * TspeSen score and TspfWt * TspfSen score to generate an overall rating to select P1. This value should only be changed at the factory or under the direction of Daniel technical support. |
| 1436 |
Auto Reset Threshold (TspfMatch) |
| 1437 |
When the differences between the magnitudes of the computed upstream and downstream TSPF to exceed this percentage, they are reset to the default Tspf. A value of 100 forces the calculated values to never reset to the defaults. A value of zero forces them to remain at the defaults. |
| 1438 |
IsFreq1EnableTest |
| 1439 |
Frequency Output 1 is in test mode which means the pulses output do not reflect the process flow through the meter. Test mode allows the connection from this output to a flow computer to be verified.
Recommended Actions:
1. Use the Meter Outputs screen in Daniel MeterLink to disable the test mode for Frequency Output 1 to clear this alert and return the meter back to its normal mode of operation.
2. Unless Daniel MeterLink or another application through Modbus is re-enabling the test mode, the output will revert back to the normal mode of operation in a user configured timeout period which can be up to 30 minutes. |
| 1440 |
Disable Test |
| 1441 |
Enable Test |
| 1442 |
IsFreq2EnableTest |
| 1443 |
Frequency Output 2 is in test mode which means the pulses output do not reflect the process flow through the meter. Test mode allows the connection from this output to a flow computer to be verified.
Recommended Actions:
1. Use the Meter Outputs screen in Daniel MeterLink to disable the test mode for Frequency Output 2 to clear this alert and return the meter back to its normal mode of operation.
2. Unless Daniel MeterLink or another application through Modbus is re-enabling the test mode, the output will revert back to the normal mode of operation in a user configured timeout period which can be up to 30 minutes. |
| 1444 |
DO1PairTestEnable |
| 1445 |
Used to enable the test mode for Digital Output 1 pair. When set to TRUE (1), the test mode is enabled and digital outputs 1A and 1B are set to the levels specified by DO1A test mode value and DO1B test mode value. When this point is set to TRUE (1), the digital output pair remains in the test mode for a period of time set by non-normal operation timeout unless the test mode is explicitly exited by setting this point to FALSE (0). |
| 1446 |
DO2PairTestEnable |
| 1447 |
Used to enable the test mode for Digital Output 2 pair. When set to TRUE, the test mode is enabled and digital outputs 2A and 2B are set to the levels specified by DO2A test mode value and DO2B test mode value. When this point is set to TRUE (1), the digital output pair remains in the test mode for a period of time set by non-normal operation timeout unless the test mode is explicitly exited by setting this point to FALSE (0). |
| 1448 |
IsFODO1Avail |
| 1449 |
Frequency Output/Digital Output 1 available indicator based on the CPU Module's I/O board and the optional I/O Module configuration. The content is selected by the FODO1 source selector and the output levels by the FODO1 mode selector. |
| 1450 |
Source |
| 1451 |
Selects the source for Frequency/Digital Output 1 if Frequency/Digital Output 1 available is TRUE (1). |
| 1452 |
Frequency Output 1A |
| 1453 |
Frequency Output 1B |
| 1454 |
Digital Output 1A |
| 1455 |
Digital Output 1B |
| 1456 |
Mode |
| 1457 |
Selects the output levels for Frequency/Digital Output 1 when Frequency/Digital Output 1 available is TRUE (1). |
| 1458 |
TTL |
| 1459 |
Open Collector |
| 1460 |
IsFODO2Avail |
| 1461 |
Frequency Output/Digital Output 2 available indicator based on the CPU Module's I/O board and the optional I/O Module configuration. The content is selected by the FODO2 source selector and the output levels by the FODO2 mode selector. |
| 1462 |
Source |
| 1463 |
Selects the source for Frequency/Digital Output 2 if Frequency/Digital Output 2 available is TRUE (1). |
| 1464 |
Frequency Output 2A |
| 1465 |
Frequency Output 2B |
| 1466 |
Digital Output 2A |
| 1467 |
Digital Output 2B |
| 1468 |
Mode |
| 1469 |
Selects the output levels for Frequency/Digital Output 2 when Frequency/Digital Output 2 available is TRUE (1). |
| 1470 |
IsFODO3Avail |
| 1471 |
Frequency Output/Digital Output 3 available indicator based on the CPU Module's I/O board and the optional I/O Module configuration. The content is selected by the FODO3 source selector and the output levels by the FODO3 mode selector. |
| 1472 |
Source |
| 1473 |
Selects the source for Frequency/Digital Output 3 if Frequency/Digital Output 3 available is TRUE (1). |
| 1474 |
Mode |
| 1475 |
Selects the output levels for Frequency/Digital Output 3 when Frequency/Digital Output 3 available is TRUE (1). |
| 1476 |
Offset |
| 1477 |
Live flow-condition pressure calibration offset value. The calibrated live pressure is calculated by multiplying the raw live pressure sample by the live flow-condition pressure calibration gain value and then adding this offset. |
| 1478 |
Gain |
| 1479 |
Live flow-condition pressure calibration gain value. The calibrated live pressure is calculated by multiplying the raw live pressure sample by this gain and then adding the live flow-condition pressure calibration offset value. |
| 1480 |
Offset |
| 1481 |
Live flow-condition temperature calibration offset value. The calibrated live temperature is calculated by multiplying the raw live temperature by the live flow-condition temperature calibration gain value and then adding this offset. This value is applied to the temperature in Kelvin. Due to temperature conversion factors, use the Daniel Ultrasonic software Calibration/Analog Inputs Wizard to set this parameter. MODIFYING THIS POINT VIA MODBUS IS NOT RECOMMENDED. |
| 1482 |
Gain |
| 1483 |
Live flow-condition temperature calibration gain value. The calibrated live temperature is calculated by multiplying the raw live temperature by this gain and then adding the live flow-condition temperature calibration offset value. |
| 1484 |
The first and highest reverse flow rate used for piecewise linearization. It is paired with reverse meter factor 1 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. Flow rates above this point will simply apply reverse meter factor 1 as the linear meter factor. |
| 1485 |
The first and highest forward flow rate used for piecewise linearization. It is paired with forward meter factor 1 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. Flow rates above this point will simply apply forward meter factor 1 as the linear meter factor. |
| 1486 |
The second reverse flow rate used for piecewise linearization. It is paired with reverse meter factor 2 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1487 |
The second forward flow rate used for piecewise linearization. It is paired with forward meter factor 2 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1488 |
The third reverse flow rate used for piecewise linearization. It is paired with reverse meter factor 3 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1489 |
The third forward flow rate used for piecewise linearization. It is paired with forward meter factor 3 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1490 |
The fourth reverse flow rate used for piecewise linearization. It is paired with reverse meter factor 4 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1491 |
The fourth forward flow rate used for piecewise linearization. It is paired with forward meter factor 4 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1492 |
The fifth reverse flow rate used for piecewise linearization. It is paired with reverse meter factor 5 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1493 |
The fifth forward flow rate used for piecewise linearization. It is paired with forward meter factor 5 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1494 |
The sixth reverse flow rate used for piecewise linearization. It is paired with reverse meter factor 6 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1495 |
The sixth forward flow rate used for piecewise linearization. It is paired with forward meter factor 6 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1496 |
The seventh reverse flow rate used for piecewise linearization. It is paired with reverse meter factor 7 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1497 |
The seventh forward flow rate used for piecewise linearization. It is paired with forward meter factor 7 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1498 |
The eighth reverse flow rate used for piecewise linearization. It is paired with reverse meter factor 8 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1499 |
The eighth forward flow rate used for piecewise linearization. It is paired with forward meter factor 8 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1500 |
The ninth reverse flow rate used for piecewise linearization. It is paired with reverse meter factor 9 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1501 |
The ninth forward flow rate used for piecewise linearization. It is paired with forward meter factor 9 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1502 |
The tenth reverse flow rate used for piecewise linearization. It is paired with reverse meter factor 10 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1503 |
The tenth forward flow rate used for piecewise linearization. It is paired with forward meter factor 10 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1504 |
The eleventh reverse flow rate used for piecewise linearization. It is paired with reverse meter factor 11 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1505 |
The eleventh forward flow rate used for piecewise linearization. It is paired with forward meter factor 11 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1506 |
The twelfth and lowest reverse flow rate used for piecewise linearization. It is paired with reverse meter factor 12 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1507 |
The twelfth and lowest forward flow rate used for piecewise linearization. It is paired with forward meter factor 12 to form an endpoint of a line segment to the next lowest endpoint. This line segment is used to interpolate the linear meter factor based on the dry calibration flow velocity. If it is unused it should be set to zero. |
| 1508 |
Meter Name |
| 1509 |
The meter name as set by the user. |
| 1510 |
Station Name |
| 1511 |
Station name where meter is installed. |
| 1512 |
Address |
| 1513 |
Station address where meter is installed. |
| 1514 |
City |
| 1515 |
City where meter is installed. |
| 1516 |
State and Country |
| 1517 |
State and Country where meter is installed. |
| 1518 |
User Scratch 1 |
| 1519 |
User scratch point 1 for recording meter information. |
| 1520 |
User Scratch 2 |
| 1521 |
User scratch point 2 for recording meter information. |
| 1522 |
IsLocalDisplayAvail |
| 1523 |
When TRUE (1) the system has detected the presence of the local display. |
| 1524 |
Scroll Delay |
| 1525 |
The time interval in seconds used to change which item is shown on the local display. |
| 1526 |
IsLocalDisplayEnableTest |
| 1527 |
When set TRUE (1) the local display will perform a series of tests to exercise all the segments of the display. This value will automatically return to FALSE (0) when the test is complete. |
| 1528 |
Status |
| 1529 |
Primary Purpose Variable |
| 1530 |
Shortcuts |
| 1531 |
Device Identification |
| 1532 |
Revision Numbers |
| 1533 |
Configuration |
| 1534 |
Security |
| 1535 |
Write Protect Status represents the position of the PROTECT switch on the CPU module. |
| 1536 |
Continuous Flow Analysis |
| 1537 |
Gas Chromatograph Communications |
| 1538 |
Keys must be a 16 character uppercase hexadecimal value with no spaces or hyphens between characters. |
| 1539 |
Valid characters include: 0,1,2,3,4,5,6,7,8,9,A,B,C,D,E,F
Example: 48AF3B1273CA65D9 |
| 1540 |
Guided Setup |
| 1541 |
Initial Setup |
| 1542 |
After installation, run this wizard to configure units in which to display parameters when using HART interface. |
| 1543 |
After installation, run this wizard to configure meter outputs.
|
| 1544 |
After installation, run this wizard to setup the basic HART specific parameters. |
| 1545 |
After installation, run this wizard to baseline the characteristics of this meter which can be used to diagnose the health of the meter at a later time. |
| 1546 |
HART Units |
| 1547 |
Frequency/Digital Outputs |
| 1548 |
The meter contains output(s) that can be configured as either a frequency output or a digital output. The frequency output 1 and digital output 1 are paired together meaning the digital output 1 will report the status for the parameter for frequency output 1. Similarly, frequency/digital outputs 2 and frequency/digital outputs 3 are paired together. In addition, each frequency output has an A and B output phase. |
| 1549 |
Configure the available frequency and digital outputs. |
| 1550 |
Analog Outputs |
| 1551 |
Configure analog output 1 parameters. |
| 1552 |
Configure analog output 2 parameters. |
| 1553 |
Configure frequency and digital output parameters. |
| 1554 |
Refresh Note:
If changes are made to any source variable on this page, apply changes and navigate off to Guided Setup and back to Manual Setup for the changes to be reflected in other Manual Setup pages. |
| 1555 |
Frequency and Digital Output 1 |
| 1556 |
Frequency and Digital Output 2 |
| 1557 |
Output Test Mode |
| 1558 |
Configure analog input 1 (temperature) parameters. |
| 1559 |
Configure analog input 2 (pressure) parameters. |
| 1560 |
Configure digital input parameters. |
| 1561 |
Calibration |
| 1562 |
Pressure Type |
| 1563 |
Configure Ethernet connection settings of this meter. |
| 1564 |
Configure Modbus units settings of this meter. |
| 1565 |
Configure Gas Chromatograph connected to this meter. |
| 1566 |
Configure Serial connection settings of this meter. |
| 1567 |
Meter |
| 1568 |
Modbus TCP |
| 1569 |
Configure meter body parameters. |
| 1570 |
Configure meter correction factors. |
| 1571 |
Configure transducer chord(s) parameters. |
| 1572 |
Configure batch parameters related to data acquisition. |
| 1573 |
Configure signal parameters. |
| 1574 |
Configure signal target parameters. |
| 1575 |
Configure meter speed of sound and flow velocity limits. |
| 1576 |
Configure AGA8 calculations. |
| 1577 |
Flow Profile Correction |
| 1578 |
Temperature Expansion Correction |
| 1579 |
Pressure Expansion Correction |
| 1580 |
Zero Flow Calibration Polynomial Coefficients |
| 1581 |
Flow Calibration Polynomial Coefficients |
| 1582 |
Flow Calibration Piece-wise Linearization Coefficients |
| 1583 |
The flow calibration piece-wise linearization coefficients must be ordered by volumetric flow rate from highest to lowest. |
| 1584 |
Normalized Amplitude |
| 1585 |
Volumetric Gross Heating Value |
| 1586 |
Fixed Gas Composition |
| 1587 |
Log Configuration |
| 1588 |
Configure Blockage Detection |
| 1589 |
Blockage Detection |
| 1590 |
Turbulence |
| 1591 |
Configure Liquid Detection |
| 1592 |
Liquid Detection |
| 1593 |
Configure Abnormal Profile Detection |
| 1594 |
Abnormal Profile Detection |
| 1595 |
Configure Sound Velocity Comparison |
| 1596 |
Configure Reverse Flow Detection |
| 1597 |
Reverse Flow Detection |
| 1598 |
Flow Range Limits |
| 1599 |
Baseline the characteristics of this meter which can be used to diagnose the health of the meter at a later time. |
| 1600 |
View current forward flow baseline parameters. |
| 1601 |
View current reverse flow baseline parameters. |
| 1602 |
Active Alerts |
| 1603 |
This is a snapshot of the current alerts. To refresh, close and reopen this dialog.
|
| 1604 |
This is a snapshot of the current alerts. To refresh, navigate off and back on to this page.
|
| 1605 |
Failed - Fix Now |
| 1606 |
Maintenance - Fix Soon |
| 1607 |
Advisory |
| 1608 |
General |
| 1609 |
Perform digital to analog trim of the first milliamp output. |
| 1610 |
Perform digital to analog trim of the second milliamp output. |
| 1611 |
Put frequency outputs into test mode to force the outputs to a specific user defined value. |
| 1612 |
Put digital outputs into test mode to force the outputs to a specific user defined value. |
| 1613 |
Set transducer type which will overwrite signal target parameter values as per selected transducer type. |
| 1614 |
Identify device by displaying pattern (O-O-O-O) on the display. |
| 1615 |
Set or view real-time clock date and time. |
| 1616 |
This method will help identify the device in the field by displaying this pattern on the device display.
Click Next to start. |
| 1617 |
Reset device without losing configuration. |
| 1618 |
Reset chord proportions to default values. |
| 1619 |
Compare |
| 1620 |
Bore Buildup |
| 1621 |
AGA8 base condition calculations are invalid. AGA8 base condition becomes invalid if the gas properties in use are invalid or AGA8 base calculation status is a non-zero value.
Recommended Actions:
1. Other primary cause alerts will be present in the alert list. Resolve those alerts first and this alert will clear.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1622 |
|
| 1623 |
AGA8 flow condition calculations are invalid. The AGA8 flow compressibility becomes invalid if the AGA8 Base Calculation is invalid, pressure is invalid, or temperature is invalid or AGA8 flow calculation status is a non-zero value.
Recommended Actions:
1. Other primary cause alerts will be present in the alert list. Resolve those alerts first and this alert will clear.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1624 |
The meter's measured average sound velocity is out of limits. This alert is used for HART applications. The non-HART average sound velocity out of limits alert is used for other applications.
Recommended Actions:
1. Verify that all chords are measuring the same Speed of Sound within about 0.15%. Look for alerts that indicate transducer problems and resolve any of these issues. This could include failing transducers, debris buildup on transducers, or incorrectly entered path lengths in the configuration.
2. If the chords agree well, it is recommended to compare the meter's average speed of sound with an AGA10 calculated speed of sound. If they agree within 0.3%, it is recommended that the minimum or maximum sound speed be adjusted so the meter's average speed of sound falls within these limits.
3. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1625 |
The calculated energy flow rate is invalid. A problem has occurred with flow condition pressure and/or temperature inputs, AGA8 calculations, or heating value. The energy rate becomes invalid if either base-condition volumetric flow rate is invalid or if an invalid gas heating value is read from a gas chromatograph.
Recommended Actions:
1. If the base-condition volumetric flow rate is invalid, resolve this issue first before trying to resolve this alert.
2. Verify using Daniel MeterLink that a valid heating value is specified in the meter or a live gas chromatograph is configured and the meter reports no invalid GC alerts. Resolve these alerts if present.
3. If the issue is unresolved, collect a Maintenance log with Daniel MeterLink and contact your local area Daniel service representative. |
| 1626 |
Abnormal Profile Detected |
| 1627 |
The flow profile of the meter is abnormal and may affect the accuracy of measurement of the meter. This alert is configured as part of the Flow Analysis Alerts setup under the Alert Setup menu.
Recommended Actions:
1. Inspect the meter run and upstream flow conditioner for possible obstructions.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1628 |
Acquisition Mode |
| 1629 |
The meter is not measuring and is trying to acquire measurement data. Possible causes include transducer failures, miswired transducers, operating below minimum process pressure for meter, invalid geometry configuration, malfunctioning Acquisition Module and fluid type not supported by meter such as high levels of Carbon Dioxide.
Recommended Actions:
1. Verify meter is operating above the minimum process pressure indicated on the meter nameplate. If not, increase the operating pressure.
2. Verify the process fluid rate has not exceeded the maximum rate indicated on the meter nameplate. Lower the flow rate if necessary.
3. If this is a new meter or upgraded meter, verify geometry configuration distance between transducers (for four-path meters LA, LB, LC, and LD, for dual-path meters LA and LB, and for single-path meters LA) and correct if needed. If these parameters are incorrect, check all meter parameters against the meter Zero Flow Calibration report. This report can be requested from your local area Daniel service representative.
4. Check transducers wiring. Verify all connections are secure and that wires are connected to the correct terminals on the Acquisition Module.
5. Replace Acquisition Module with a spare to see if this corrects the issue. If it does and the meter is still under warranty, you may request a replacement module from your local area Daniel service representative.
6. Collect a Maintenance log with Daniel MeterLink if the issue is unresolved and contact your local area Daniel service representative. |
| 1630 |
Possible Blockage Detected |
| 1631 |
Conditions indicate that there may be a possible blockage upstream from the meter. The monitored conditions are from the hourly log data in the meter which means the alert condition is set or cleared once an hour. This alert can be configured and disabled from the Alert Setup menu.
Recommended Actions:
1. Inspect flow conditioners, flow straighteners, tube bundles or upstream piping for foreign objects.
2. If the issue is unresolved, collect a Maintenance Log, Archive Log, and Waveform stream file with Daniel MeterLink and contact your local area Daniel service representative. |
| 1632 |
Possible Bore Buildup Detected |
| 1633 |
Conditions indicate that there may be a possible buildup of material on the meter bore. The monitored conditions are from the daily log data in the meter which means the alert condition is set or cleared once a day. This alert can be disabled from the Alert Setup menu.
Recommended Actions:
1. Collect a Archive log using Daniel MeterLink and look at the Profile Factor chart on the Daily Log Charts worksheet. If the data trend shows a long term change in Profile Factor, this indicates a long term buildup. If the Profile Factor has an abrupt change in the last week, this indicates a possible upset condition that caused a buildup on the bore of the meter.
2. Inspect meter run for possible bore buildup.
3. If the issue is unresolved, collect a Maintenance Log and Archive log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1634 |
Forward Baseline Not Set |
| 1635 |
This indicates that a GC alarm condition is present.
Recommended Actions:
1. If possible, collect the System log from the meter using the Archive Logs screen in Daniel MeterLink. The System log will provide additional information to identify the cause of this alert.
2. Check the Gas Chromatograph Communications key is enabled in License Keys under Manual Setup. If disabled, contact your local area Daniel sales representative to acquire a valid key.
3. Verify that the port availability of the port the GC is connected to is set to 1 in the Meter Information Dialog of Daniel MeterLink. If set to 0, then the module is either not installed or the module is damaged. Reinstall or replace module.
4. If this alert is present, it could be that the meter is reading unrecognized component ids from the GC. The System Log will report "unrecognized component id <value>" if this is the issue. The GC component table must be modified in the GC to correct this issue. Contact your local area Daniel service representative for assistance.
5. If this alert is present it could be because the gas chromatograph stream number was not found within the specified stream timeout period. Using the Field Setup Wizard in Daniel MeterLink, verify that the GC stream number matches the stream number configured in the GC.
6. If this alert is present it could be because the GC reported alarm, Modbus Register 3046, bits 14 and/or 15 are set or the GC reported alarm, Modbus Register 3047, bits 0, 1, 2, and/or 3 are set. Use the Daniel MON/MON2000 Gas Chromatograph software to check the alarm state of the GC and correct any issues.
7. If the issue is unresolved, collect an Archive Log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1636 |
The meter is not able to communicate successfully with the GC.
Recommended Actions:
1. Verify you are using a GC compatible with Daniel Sim2251 communications.
2. Check communications cables to the GC. The GC must be wired to the port on the meter chosen by the serial port selector. Verify the hardware protocol for that port matches the GC.
3. Check the TX and RX LEDs to see if there is a poll message on the TX LED followed by a receive message on the RX LED.
4. Verify GC communication serial port settings is set to Modbus ASCII (7, Even, 1) or Modbus RTU (8, None, 1). Then verify the meter is configured to match using the Field Setup Wizard in Daniel MeterLink.
5. If possible, collect the System log from the meter using the Archive Logs screen in Daniel MeterLink. The System log will provide additional information to help identify the cause of this alert.
6. If the issue is unresolved, collect an Archive Log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1637 |
Indicates invalid data read from the GC.
Recommended Actions:
Any one of the following conditions could cause this alert.
1. The total unnormalized gas composition mole percentage of all the components read from the GC is not within the range of 85% to 115%. Use Daniel MON/MON2000 to verify the total gas composition totals between the specified percentage range. Correct any issues identified.
2. An individual gas composition mole percentage is not within the range of 0% to 100%. Use the Daniel MON/MON2000 Gas Chromatograph software to verify all the gas components are between the specified range. Correct any issues identified.
3. The specific gravity is not within the range of 0.2 to 0.8. Use the Daniel MON/MON2000 Gas Chromatograph software to verify the specific gravity is within this range. Correct any issues identified.
4. The heating value is greater than 50 kJ/cubic dm. This could be caused by a units mismatch between the GC configuration and the meter configuration. Run the Field Setup Wizard in Daniel MeterLink and verify the units with the units configured in the GC. Also verify the GC reports a heating value that meets the specification above.
5. If the issue is unresolved, collect an Archive Log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1638 |
Chord A Hard Failed |
| 1639 |
The meter is unable to obtain measurement data from this pair of transducers.
Recommended Actions:
1. If no other transducers are failed or are reporting status alerts, the issue is most likely isolated to this pair of transducers or its cabling. Check the transducer wiring for this pair of transducers to make sure connections are secure and wired correctly.
2. Remove the transducer cable from the transducer and measure the resistance with an Ohm meter across the two pins on the back of the transducer holder. If the value is over 2 ohms, replace the transducers.
3. If transducer cabling allows, swap cabling of failed transducer pair with a pair with equal path lengths. If the alert remains active for this chord, then the transducers are working properly. If this alert clears but the chord that was swapped now fails, the issue is with the transducer.
4. If this issue is unresolved, collect a Maintenance Log, Configuration file and Waveform stream file with Daniel MeterLink and contact your local area Daniel service representative. |
| 1640 |
Chord B Hard Failed |
| 1641 |
Chord C Hard Failed |
| 1642 |
Chord D Hard Failed |
| 1643 |
The meter is unable to obtain measurement data from this pair of transducers.
Recommended Actions:
1. If no other transducers are failed or are reporting status alerts, the issue is most likely isolated to this pair of transducers or its cabling. Check the transducer wiring for this pair of transducers to make sure connections are secure and wired correctly.
2. If this chord abruptly fails or fails intermittently, it could be the results of liquid in the bottom of the meter. A verification that liquids are not present should be conducted.
3. Remove the transducer cable from the transducer and measure the resistance with an Ohm meter across the two pins on the back of the transducer holder. If the value is over 2 ohms, replace the transducers.
4. If transducer cabling allows, swap cabling of failed transducer pair with a pair with equal path lengths. If the alert remains active for this chord, then the transducers are working properly. If this alert clears but the chord that was swapped now fails, the issue is with the transducer.
5. If this issue is unresolved, collect a Maintenance Log, Configuration file and Waveform stream file with Daniel MeterLink and contact your local area Daniel service representative. |
| 1644 |
Liquids Possibly Present In Gas |
| 1645 |
This alert condition indicates that there may be a possible presence of liquids in the meter. This alert is configured as part of the Flow Analysis Alerts setup under the Alert Setup menu.
Recommended Actions:
1. Verify the gas process conditions are such that the meter is operating above the dew point.
2. Inspect meter run for presence of liquids.
3. Check upstream system for faults that could allow liquids into meter run.
4. Verify meter is not at a low point in the meter run where liquids could be trapped.
5. If the issue is unresolved, collect a Maintenance log and Waveform stream file while alert is active and contact your local area Daniel service representative. |
| 1646 |
Reverse Baseline Not Set |
| 1647 |
Sound Velocity Comparison Of AGA10 to Meter Error |
| 1648 |
The absolute error between the AGA10-calculated sound velocity and the meter-calculated sound velocity is greater than the alert limit.
Recommended Actions:
1. If gas composition is from a live GC, using Daniel MeterLink check GC setup in the Field Setup Wizard and the time of the last GC update in the Monitor screen. Verify the correct stream number is configured to be collected.
2. Verify the pressure and temperature readings in use by the meter are accurate.
3. If the gas composition is from fixed user entered values, use Monitor screen in Daniel MeterLink to check the gas composition values.
4. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1649 |
The calculated mass flow rate is invalid. A problem has occurred with flow condition pressure and/or temperature inputs, or AGA8 calculations. Mass rate becomes invalid if either the flow-condition volumetric flow rate is invalid or the AGA8 flow calculation is invalid. This is only applicable when the AGA8 calculations are performed internally or are performed externally with the mixture flow-condition mass density specified.
Recommended Actions:
1. Other primary cause alerts will be present in the alert list. Resolve those alerts first and this alert will clear.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1650 |
Analog Output 1 (HART PV) is Saturated |
| 1651 |
Analog Output 1 is saturated (i.e. the loop current has reached its upper or lower endpoint and cannot increase or decrease any further).
Recommended Actions:
1. The analog output may need to be rescaled to prevent it from saturating. Use the Field Setup Wizard in Daniel MeterLink to configure Analog Output 1. |
| 1652 |
Analog Output 2 (HART SV) is Saturated |
| 1653 |
Analog Output 2 is saturated (i.e. the loop current has reached its upper or lower endpoint and cannot increase or decrease any further).
Recommended Actions:
1. The analog output may need to be rescaled to prevent it from saturating. Use the Setup Outputs wizard under Guided Setup to configure Analog Output 2. |
| 1654 |
Analog Output 1 (AO1) is invalid. The analog output is considered invalid if the analog output is in test mode or the content the analog output is trying to drive is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output on Analog Output 1, resolving that issue should clear this alert.
2. If the content selected for Analog Output 1 is not in alarm, then verify that the output is not fixed or set in test mode.
3. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1655 |
Analog Output 1 current is in test mode and fixed. The current can be fixed via HART command 40 or command 66.
Recommended Actions:
1. Once the Analog Output 1 is removed from test mode, this alert will clear. |
| 1656 |
Analog Output 2 (AO2) is invalid. The analog output is considered invalid if the analog output is in test mode or the content the analog output is trying to drive is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output on Analog Output 2, resolving that issue should clear this alert.
2. If the content selected for Analog Output 2 is not in alarm, then verify that the output is not fixed or set in test mode.
3. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1657 |
Analog Output 2 current is in test mode and fixed. The current can be fixed via the HART command 66.
Recommended Actions:
1. Once the Analog Output 2 is removed from test mode, this alert will clear. |
| 1658 |
Configuration Changed, Latched Until Acknowledged |
| 1659 |
HART configuration changed. It is set to TRUE when configuration writable via HART is modified. It is reset to FALSE when command 38 is issued by master and received configuration changed counter matches the device configuration change counter. |
| 1660 |
Configuration Lost, Latched Until Acknowledged |
| 1661 |
The meter has performed a cold start. The meter configuration has reset to default values and the meter is not configured correctly to measure flow.
Recommended Actions:
1. Unless the Cold Start occurred after upgrading firmware, it is recommended to have the CPU Module replaced. Contact your local area Daniel service representative.
2. If the cold start occurred after a firmware upgrade, you must fully re-configure the meter from a previously saved configuration .
3. The alert must be acknowledged to clear it from list of alerts per DidCnfgChksumChg.
4. If the issue is unresolved, contact your local area Daniel service representative. |
| 1662 |
Power Failure, Latched Until Acknowledged |
| 1663 |
The meter has had power removed for a period of time or the meter restarted itself such as after a firmware upgrade. The Audit log in the meter will indicate the power fail time.
Recommended Actions:
1. If this was a known power fail or restart of the meter just acknowledge this alert.
2. If this was an unexpected restart of the meter, verify the integrity of the power to the meter and make sure that the voltage level is in the range of 11-36 VDC at the meter.
3. The alert must be acknowledged to clear it from list of alerts.
4. If the issue is unresolved, collect a complete Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 1664 |
Enables Test Mode for Digital Output 2 Pair |
| 1665 |
Enables Test Mode for Digital Output 1 Pair |
| 1666 |
The flow-condition pressure is outside the limits.
Recommended Actions:
1. If connected to a pressure transducer, verify that the transducer is functioning properly. Verify that the wiring is correctly connected to TB2-B pins 1 & 2 (ANALOG IN PT- and PT+). Verify that the current is between 4 mA and 20 mA.
2. Verify the input is properly configured for your pressure input.
3. Adjust the gain and offset so the flow-condition pressure is correct.
4. If the issue is unresolved, collect a complete Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 1667 |
The flow-condition temperature is outside the limits.
Recommended Actions:
1. If connected to a temperature transducer, verify that the transducer is functioning properly. Verify that the wiring is correctly connected to TB2-B pins 3 & 4 (ANALOG IN TT- and TT+). Verify that the current is between 4 mA and 20 mA.
2. Verify the input is properly configured for your temperature input.
3. Adjust the gain and offset so the flow-condition temperature is correct.
4. If the issue is unresolved, collect a complete Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 1668 |
The parameter which the Frequency Output 1 is configured to represent is invalid or the output is currently in test mode.
Recommended Actions:
1. You can determine whether the output is in test mode by using Meter Outputs in Daniel MeterLink.
2. If the parameter for which Frequency Output 1 is configured is invalid, other alerts will be present that will help you resolve the issue.
3. If the issue is unresolved, collect a Maintenance log and Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 1669 |
The parameter which the Frequency Output 2 is configured to represent is invalid or the output is currently in test mode.
Recommended Actions:
1. You can determine whether the output is in test mode by using Meter Outputs in Daniel MeterLink.
2. If the parameter for which Frequency Output 2 is configured is invalid, other alerts will be present that will help you resolve the issue.
3. If the issue is unresolved, collect a Maintenance log and Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 1670 |
The HART Fourth Variable value as defined by the HART device variable selection is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output , resolving that issue should clear this alert.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1671 |
The HART Slot 0 value as defined by the HART device variable selection is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output , resolving that issue should clear this alert.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1672 |
The HART Slot 1 value as defined by the HART device variable selection is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output , resolving that issue should clear this alert.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1673 |
The HART Slot 2 value as defined by the HART device variable selection is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output , resolving that issue should clear this alert.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1674 |
The HART Slot 3 value as defined by the HART device variable selection is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output , resolving that issue should clear this alert.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1675 |
The HART Third Variable value as defined by the HART device variable selection is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output , resolving that issue should clear this alert.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1676 |
An Acquisition Module-related error has been detected. The CPU Module's measurement LED (MEAS) will flash green when proper communications with the Acquisition Module are restored.
Recommended Actions:
1. If the CPU Module's measurement LED (MEAS) is not flashing green, check interconnect cable between Acquisition Module and the CPU Module.
2. If the CPU Module's measurement LED (MEAS) is still not flashing green, check the Acquisition Module error reasons code
3. If the issue is unresolved, collect a complete Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 1677 |
The alarm archive log is full and the log is not configured to be overwritten automatically.
Recommended Actions:
1. Collect alarm archive log records using Daniel MeterLink and allow Daniel MeterLink to mark them as read which will allow them to be overwritten.
|
| 1678 |
Enables the Analog Output Test mode for Analog Output 1. When in the Analog Output Test mode, Analog Output 1 is fixed at the percentage of full scale specified via the Analog Output 1 test mode output percent configuration point (regardless of the actual data content value). If Analog Output 1 remains in Analog Output Test mode for longer than the non-normal mode timeout, Analog Output 1 automatically exits Analog Output Test mode and returns to normal operation. |
| 1679 |
Enables the Analog Output Test mode for Analog Output 2. When in the Analog Output Test mode, Analog Output 2 is fixed at the percentage of full scale specified via the Analog Output 2 test mode output percent configuration point (regardless of the actual data content value). If Analog Output 2 remains in Analog Output Test mode for longer than the non-normal mode timeout, Analog Output 2 automatically exits Analog Output Test mode and returns to normal operation. |
| 1680 |
The audit archive log is full and the log is not configured to be overwritten automatically.
Recommended Actions:
1. Collect audit archive log records using Daniel MeterLink and allow Daniel MeterLink to mark them as read which will allow them to be overwritten.
|
| 1681 |
Clock Invalid |
| 1682 |
The meter's hardware clock has been set to a date prior to Jan. 1, 2003.
Recommended Actions:
1. The real time clock has a power backup of about 2 weeks. If the meter remains unpowered for more than this time, the real time clock will reset back to Jan. 1, 2000. If this is the issue, use either the Field Setup Wizard or the Monitor screen in Daniel MeterLink to set the correct date and time.
2. If the meter has not been unpowered for more than 2 weeks, the CPU board should be replaced as the real time clock or its backup power source may be damaged.
3. Contact your local area Daniel service representative for assistance in getting a replacement CPU board. |
| 1683 |
A diagnostic core file has been generated which may indicate a problem with the meter.
Recommended Actions:
1. The alert must be acknowledged to clear it from list of alerts.
2. Collect an Archive log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1684 |
The daily archive log is full and the log is not configured to be overwritten automatically.
Recommended Actions:
1. Collect daily archive log records using Daniel MeterLink and allow Daniel MeterLink to mark them as read which will allow them to be overwritten.
|
| 1685 |
Electronics Temperature is Out Of Nominal Range |
| 1686 |
The temperature of the electronics is out of nominal operating range. Operating outside the nominal operating range could lead to a system failure.
Recommended Actions:
1. Attempt to warm or cool the meter electronics housing.
2. If the electronics is mounted to the meter and the process fluid in the meter is over 65 °C, you must remote mount the electronics off from the meter body.
3. Collect a Maintenance log using Daniel MeterLink while the meter is experiencing the issue, collect an Archive log (Daily/Hourly/Alarm/Audit/System) using Daniel MeterLink from the meter and contact your local area Daniel service representative. |
| 1687 |
The CPU Board system voltages or Acquisition Module system voltages are out-of-range. Valid CPU Module voltages are 1.0V, 1.2V, 2.5V, 3.3V or valid Acquisition Module System voltages are 1.2V, 2.5V or 3.3V.
Recommended Actions:
1. Replace the CPU Module if one or more of the CPU voltages is out-of-range.
2. Replace Acquisition Module if one or more of the Acquisition Module voltages is out-of-range.
3. If the issue is unresolved, contact your local area Daniel service representative. |
| 1688 |
Frequency Output 1 Pair Test Enable |
| 1689 |
Frequency Output 2 Pair Test Enable |
| 1690 |
The hourly archive log is full and the log is not configured to be overwritten automatically.
Recommended Actions:
1. Collect hourly archive log records using Daniel MeterLink and allow Daniel MeterLink to mark them as read which will allow them to be overwritten.
|
| 1691 |
Velocity is above the meter maximum velocity limit.
Recommended Actions:
1. Lower the velocity of the meter as this alert indicates you are running above a safe limit that could damage the meter run or could indicate you are running above your upper calibration limit where meter uncertainty could increase.
2. Change the value of the meter maximum velocity if desired. It is recommended to set this either to the maximum calibrated velocity of the meter or to the maximum safe operating velocity of the meter run. The maximum safe operating velocity typically is to prevent erosion of the pipe internal diameter and prevent damage to protrusions such as thermal wells. |
| 1692 |
Reverse Flow Detected |
| 1693 |
The meter has accumulated a reverse flow volume greater than a user configurable limit. This alert is configured as part of the Flow Analysis Alerts setup under the Alert Setup menu.
Recommended Actions:
1. Check valves for leaks.
2. If metering run is known to have some volume of reverse flow when flow is stopped, reconfigure the reverse flow volume limit to allow a greater volume.
3. If meter regularly flows in the reverse direction, this alert should be disabled. It is only intended to be used for unidirectional applications.
4. If the issue is unresolved, collect an Archive log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1694 |
The system archive log is full and the log is not configured to be overwritten automatically.
Recommended Actions:
1. Collect system archive log records using Daniel MeterLink and allow Daniel MeterLink to mark them as read which will allow them to be overwritten.
|
| 1695 |
Too Few Operating Chords |
| 1696 |
Number of operating chords is less than the minimum number for a valid measurement. Operating chords are those which are not manually set inactive and not marked as failed.
Recommended Actions:
1. Check the other alerts that indicate why a chord is hard failed. Resolving these should resolve this issue.
2. If this issue is unresolved, collect a Maintenance log and Archive log and contact your local area Daniel service representative. |
| 1697 |
The firmware cannot work with the installed Acquisition Module. The Acquisition Module may be newer than the firmware, and the firmware does not recognize it. The Acquisition Module may be installed on a meter running firmware for the opposite product (Gas/Liquid). The Acquisition Module may be installed on a meter configured with a transducer frequency or sample interval that is not supported by the module.
Recommended Actions:
1. Verify the transducer frequency and sample interval are set to values supported by the installed Acquisition Module.
2. Upgrade the firmware in the meter to the latest version using Daniel MeterLink. Contact your local area Daniel service representative to obtain the latest firmware.
3. If the latest firmware revision did not resolve the issue, replace the Acquisition Module.
4. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1698 |
Reset Required |
| 1699 |
The meter configuration has changed and requires a restart for the change to take effect.
Recommended Actions:
1. If you are unaware of changes made to the meter's configuration, collect the Audit log using the Archive Logs screen in Daniel MeterLink to review configuration changes. If the changes are valid, momentarily remove power from the meter to allow it to restart which will clear this alert.
2. If the Audit log shows no changes, contact your local area Daniel service representative for assistance. |
| 1700 |
Flow Pressure Invalid |
| 1701 |
Pressure is invalid if the flow pressure is outside the limits defined by the low and high pressure alert limits.
Recommended Actions:
First Time Startup Issues:
1. Verify that there is voltage to the pressure sensor, either from the terminal on the meter's power supply board or from an external power supply.
2. If using an analog pressure device, verify that the pressure sensor is properly wired to connector TB2-B pins 1 & 2 (ANALOG IN PT- & PT+) .
3. Verify the input is properly configured for your pressure input.
4. If using a flow computer to write pressure to the meter, verify that it is properly writing to fixed flow pressure in the proper units.
5. If the issue is unresolved, collect a Maintenance Log using Daniel MeterLink and contact your local area Daniel service representative.
Run Time Issues:
1. Adjust pressure of process fluid to within alarm limits.
2. If using an analog pressure device and input reading is 0, check if Analog Input 2 availability is equal to 1 in the Meter Information dialog in Daniel MeterLink. If it is not 1, either the I/O Board has been removed or is damaged. Reinstall or replace the board if this value is 0.
3. If using an analog pressure device, verify that the pressure sensor is working properly.
4. If using an analog pressure device, recheck wiring and switch settings as noted above under First Time Setup Issues.
5. If flow computer is writing values to the fixed flow pressure, verify that the flow computer is still writing valid values without Modbus write errors.
6. Reverify the pressure input settings are correct.
7. If the issue is unresolved, collect a Maintenance Log using Daniel MeterLink and contact your local area Daniel service representative.
|
| 1702 |
There is an error with the AGA8 base-condition volumetric flow rate. The base-condition volumetric flow rate becomes invalid if the flow-condition volumetric flow rate validity, pressure validity, temperature validity, or AGA8 flow calculation validity are set to invalid.
Recommended Actions:
1. Other primary cause alerts will be present in the alert list. Resolve those alerts first and this alert will clear.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 1703 |
The meter either has not collected enough information from the chords to make an accurate measurement or the pressure and/or temperature are invalid and meter is performing pressure or temperature expansion corrections on the meter internal diameter. This is an alert condition that shows the validity of the flow-condition volumetric flow rate. The flow-condition volumetric flow rate becomes invalid if the uncorrected flow-condition volumetric flow rate validity, temperature expansion correction validity, pressure expansion correction validity, or Flow-profile-effect correction validity is invalid.
Recommended Actions:
1. If a Pressure expansion correction validity alert is present, correcting it may clear this alert.
2. If a Temperature expansion correction validity alert is present, correcting it may clear this alert.
3. If an Uncorrected flow-condition volumetric flow rate validity alert is present, correcting it may clear this alert.
4. If a Flow-profile-effect correction validity alert is present, correcting it may clear this alert.
5. If the issue is unresolved, collect a Maintenance Log with Daniel MeterLink and contact your local area Daniel service representative. |
| 1704 |
Flow Temperature Invalid |
| 1705 |
Temperature is invalid if the flow temperature is outside the limits defined by the low and high temperature alert limits.
Recommended Actions:
First Time Startup Issues:
1. Verify that there is voltage to the temperature sensor, either from the terminal on the meter's power supply board or from an external power supply.
2. If using an analog temperature device, verify that the temperature sensor is properly wired to connector TB2-B pins 3 & 4 (ANALOG IN TT- & TT+) .
3. Verify the input is properly configured for your temperature input.
4. If using a flow computer to write temperature to the meter, verify that it is properly writing to fixed flow temperature in the proper units.
5. If the issue is unresolved, collect a Maintenance Log using Daniel MeterLink and contact your local area Daniel service representative.
Run Time Issues:
1. Adjust temperature of process fluid to within alarm limits.
2. If using an analog temperature device and input reading is 0, check if Analog Input 1 availability is equal to 1 in the Meter Information dialog in Daniel MeterLink. If it is not 1, either the I/O Board has been removed or is damaged. Reinstall or replace I/O board if this value is 0.
3. If using an analog temperature device, verify that the temperature sensor is working properly.
4. If using an analog temperature device, recheck wiring and switch settings as noted above under First Time Setup Issues.
5. If flow computer is writing values to the fixed flow temperature, verify that the flow computer is still writing valid values without Modbus write errors.
6. Reverify the temperature input settings are correct.
7. If the issue is unresolved, collect a Maintenance Log using Daniel MeterLink and contact your local area Daniel service representative.
|
| 1706 |
Software watchdog initiated a meter warm-start. The watchdog keeps track of the performance of all metrology processes in the meter to ensure a reliable measurement. When a process stops responding, the watchdog forces the meter to restart.
Recommended Actions:
1. Collect an Archive log using Daniel MeterLink and contact your local area Daniel service representative.
2. The alert must be acknowledged to clear it from list of alerts. |
| 1707 |
3410 Series Gas USM |
| 1708 |
Daniel Industries |
| 1709 |
MMBtu |
| 1710 |
Million Btu |
| 1711 |
MJ/s |
| 1712 |
Megajoules per second |
| 1713 |
MJ/d |
| 1714 |
Megajoules per day |
| 1715 |
MMBtu/s |
| 1716 |
Million Btu per second |
| 1717 |
MMBtu/h |
| 1718 |
Million Btu per hour |
| 1719 |
MMBtu/d |
| 1720 |
Million Btu per day |
| 1721 |
L/d |
| 1722 |
Liters per day |
| 1723 |
dB |
| 1724 |
Decibels |
| 1725 |
Primary Variable Out of Limits |
| 1726 |
Non-primary Variable Out of Limits |
| 1727 |
PV Analog Output Saturated |
| 1728 |
PV Analog Output Fixed |
| 1729 |
More Status Available |
| 1730 |
Cold Start |
| 1731 |
Configuration Changed |
| 1732 |
Field Device Malfunction |
| 1733 |
Maintenance Required |
| 1734 |
Device Variable Alert |
| 1735 |
Critical Power Failure |
| 1736 |
Simulation Active |
| 1737 |
The device is in simulation mode and the level output is not representative of the process. |
| 1738 |
Non-Volatile Memory Failure |
| 1739 |
The Non-Volatile memory check is invalid or maybe corrupt, or the battery of a battery-backed memory has failed. |
| 1740 |
Volatile Memory Error |
| 1741 |
The RAM memory check is invalid or maybe corrupt. |
| 1742 |
Watchdog Reset Executed |
| 1743 |
A watchdog reset has been performed. |
| 1744 |
Voltage Conditions Out of Range |
| 1745 |
A voltage condition is outside its allowable range. |
| 1746 |
Environmental Conditions Out of Range |
| 1747 |
An internal or environmental condition is beyond acceptable limits. |
| 1748 |
Electronic Failure |
| 1749 |
A hardware problem not related to the sensor has been detected. |
| 1750 |
Write Protect Status |
| 1751 |
Loop Current Mode |
| 1752 |
Thermal Expansion |
| 1753 |
Volumetric Energy Density |
| 1754 |
CPU Serial Number |
| 1755 |
Poll Address |
| 1756 |
Number of Response Preambles |
| 1757 |
Final Assembly Number |
| 1758 |
Universal |
| 1759 |
Hardware |
| 1760 |
Software |
| 1761 |
Field Device |
| 1762 |
Long Tag |
| 1763 |
Acquisition Module Error, Latched Until Acknowledged |
| 1764 |
Too Few Operating Chords, Latched Until Acknowledged |
| 1765 |
Acquisition Mode, Latched Until Acknowledged |
| 1766 |
Possible Blockage Detected, Latched Until Acknowledged |
| 1767 |
Flow Temperature Invalid, Latched Until Acknowledged |
| 1768 |
Flow Pressure Invalid, Latched Until Acknowledged |
| 1769 |
Gas Chromatograph Communications Error or Invalid Data |
| 1770 |
Meter Velocity Above Max Limit, Latched Until Acknowledged |
| 1771 |
Measurement and/or Output Data is Invalid |
| 1772 |
One or More Meter Archive Logs are Full |
| 1773 |
Reverse Flow Detected, Latched Until Acknowledged |
| 1774 |
Sound Velocity Comparison Of AGA10 to Meter Error, Latched Until Acknowledged |
| 1775 |
Possible Bore Buildup Detected, Latched Until Acknowledged |
| 1776 |
Abnormal Profile Detected, Latched Until Acknowledged |
| 1777 |
Liquids Possibly Present In Gas, Latched Until Acknowledged |
| 1778 |
PV Analog Channel Saturated |
| 1779 |
PV Analog Channel Fixed |
| 1780 |
Wireless |
| 1781 |
WirelessHART Device |
| 1782 |
IEEE 802.15.4 2.4GHz DSSS with O-QPSK Modulation |
| 1783 |
Primary Analog Channel |
| 1784 |
Secondary Analog Channel |
| 1785 |
Tertiary |
| 1786 |
Tertiary Analog Channel |
| 1787 |
Quaternary |
| 1788 |
Quaternary Analog Channel |
| 1789 |
Quinary |
| 1790 |
Quinary Analog Channel |
| 1791 |
Lock all |
| 1792 |
Trim not supported |
| 1793 |
Configuration cannot be changed |
| 1794 |
Locked by gateway |
| 1795 |
Analog Input Channel |
| 1796 |
Analog Output Channel |
| 1797 |
Secondary Analog Channel Saturated |
| 1798 |
Tertiary Analog Channel Saturated |
| 1799 |
Quaternary Analog Channel Saturated |
| 1800 |
Quinary Analog Channel Saturated |
| 1801 |
Secondary Analog Channel Fixed |
| 1802 |
Tertiary Analog Channel Fixed |
| 1803 |
Quaternary Analog Channel Fixed |
| 1804 |
Quinary Analog Channel Fixed |
| 1805 |
Simulation active |
| 1806 |
Non-Volatile memory failure |
| 1807 |
Volatile memory error |
| 1808 |
The RAM memory check is invalid or maybe corrupt |
| 1809 |
Watchdog reset executed |
| 1810 |
A watchdog reset has been performed |
| 1811 |
Voltage conditions out of range |
| 1812 |
A voltage condition is outside its allowable range |
| 1813 |
Environmental conditions out of range |
| 1814 |
Electronic failure |
| 1815 |
Subdevice list changed |
| 1816 |
Duplicate master detected |
| 1817 |
Capacity Denied |
| 1818 |
The device was unable to acquire the communication bandwidth required to support the Burst Messaging specified |
| 1819 |
Bandwidth allocation pending |
| 1820 |
Block transfer pending |
| 1821 |
Battery life |
| 1822 |
Percent range |
| 1823 |
Loop current |
| 1824 |
Primary variable |
| 1825 |
Secondary variable |
| 1826 |
Tertiary variable |
| 1827 |
Quaternary variable |
| 1828 |
Read receive time |
| 1829 |
Write date and time |
| 1830 |
Non-Volatile Clock |
| 1831 |
When set the device contains a battery-backed clock. In this case, the clock does not need to be reset if there is a power failure. |
| 1832 |
Clock Uninitialized |
| 1833 |
The real-time clock has never been set with the date and time. For example, the clock is volatile and power was removed from and restored to the device. |
| 1834 |
No restrictions |
| 1835 |
SI Only |
| 1836 |
Restricted to SI Unit codes only |
| 1837 |
Process automation device |
| 1838 |
Discrete device |
| 1839 |
Hybrid:Process automation+discrete |
| 1840 |
I/O System |
| 1841 |
WirelessHART Process automation device |
| 1842 |
WirelessHART Discrete device |
| 1843 |
WirelessHART Process automation+discrete |
| 1844 |
WirelessHART Gateway |
| 1845 |
WirelessHART Access point |
| 1846 |
WirelessHART Process adapter |
| 1847 |
WirelessHART Discrete adapter |
| 1848 |
WirelessHART enabled handheld/portable maintenance tool |
| 1849 |
Device Profile |
| 1850 |
US |
| 1851 |
United States of America |
| 1852 |
JP |
| 1853 |
Japan |
| 1854 |
DE |
| 1855 |
Germany |
| 1856 |
FR |
| 1857 |
France |
| 1858 |
ES |
| 1859 |
Spain |
| 1860 |
RU |
| 1861 |
Russian Federation |
| 1862 |
CN |
| 1863 |
People's Republic of China |
| 1864 |
Secondary Master |
| 1865 |
Primary Master |
| 1866 |
Device Diagnostic Status 0 |
| 1867 |
Device Diagnostic Status 1 |
| 1868 |
I/O and Subdevice Status |
| 1869 |
WirelessHART Status |
| 1870 |
Time Set Option |
| 1871 |
Real Time Clock Flags |
| 1872 |
Country |
| 1873 |
Country of intended device installation |
| 1874 |
SI Unit Control |
| 1875 |
Indicates if device should only display SI unit codes |
| 1876 |
Time Stamp |
| 1877 |
Relative time value on network |
| 1878 |
8u |
| 1879 |
Dynamic Variables Returned for Device Variables |
| 1880 |
Command Response Truncated |
| 1881 |
Configuration Change Counter Mismatch |
| 1882 |
Status bytes mismatch |
| 1883 |
Device Variable |
| 1884 |
Analog Channel Number |
| 1885 |
Analog Channel Number- Index into an array of Analog Channels. |
| 1886 |
Set Clock Date |
| 1887 |
Date to set the real-time clock in the field device to, or date that the real-time clock was last set |
| 1888 |
Set Clock Time |
| 1889 |
Time to set the real time clock in the field device to, or time that the real-time clock was last set |
| 1890 |
Current Date |
| 1891 |
Current Date based upon the real-time clock in the field device |
| 1892 |
Current Time |
| 1893 |
Current Time based upon the real-time clock in the field device |
| 1894 |
STX Count |
| 1895 |
Count of STX messages received by this device |
| 1896 |
ACK Count |
| 1897 |
Count of ACK messages received by this device |
| 1898 |
BACK Count |
| 1899 |
Count of BACK messages received by this device |
| 1900 |
K-Factor: %[g]{kFactor1} pulses/%{0}
Inverse K-Factor: %[g]{inverseKFactor1} %{0}/pulse
|
| 1901 |
K-Factor: %[g]{kFactor2} pulses/%{2}
Inverse K-Factor: %[g]{inverseKFactor2} %{2}/pulse
|
| 1902 |
Invalid upper range - cannot calculate K-factor 1. |
| 1903 |
K-factor 1 content is invalid. |
| 1904 |
Invalid upper range - cannot calculate K-factor 2. |
| 1905 |
K-factor 2 content is invalid. |
| 1906 |
Time units invalid. |
| 1907 |
Frequency Output 1
Content: |
| 1908 |
Frequency Output 2
Content: |
| 1909 |
Frequency Output 1
Not configured to a Frequency/Digital Output.
|
| 1910 |
Frequency Output 2
Not configured to a Frequency/Digital Output.
|
| 1911 |
K-Factor: Not Applicable to Velocity Output
|
| 1912 |
|
| 1913 |
Next |
| 1914 |
select |
| 1915 |
Checking Validity of key... |
| 1916 |
Error: Writing a key with all zeros will not enable the Continuous Flow Analysis feature in the meter. |
| 1917 |
Warning: Loop should be removed from automatic control. |
| 1918 |
Note: Loop may be returned to automatic control. |
| 1919 |
Select the output(s) to configure and click Next to continue. |
| 1920 |
Frequency/Digital Outputs;Analog Outputs;Exit |
| 1921 |
Back;Next |
| 1922 |
This utility allows you to baseline the flow characteristics of this meter in the forward and reverse flow directions which can be used to diagnose the health of the meter at a later time. |
| 1923 |
The baseline characteristics of a meter are unique to the direction of flow. This requires the meter to be baselined in both flow directions if the meter is a bidirectional meter.
Select the flow direction to baseline |
| 1924 |
Forward;Reverse |
| 1925 |
Current Forward Flow Baseline
%[L]{0}: %{0}
%[L]{1}: %{1} deg
%[L]{2}: %{2}
%[L]{3}: %{3}
Turbulence A: %[.2f]{turbA} %
Turbulence B: %[.2f]{turbB} %
Turbulence C: %[.2f]{turbC} %
Turbulence D: %[.2f]{turbD} %
%[L]{4}: %{4} %{7}
%[L]{5}: %{5} %{8}
%[L]{6}: %{6} %{9}
Click Next to Continue. |
| 1926 |
Do you want to modify baseline? |
| 1927 |
Yes;No, use current baseline and acknowledge Baseline Not Set alert |
| 1928 |
Yes;No |
| 1929 |
Two methods are available to update the baseline parameters. The purpose of the baseline is to capture the flow characteristics of the meter in a clean state when it was first installed.
Use Data from Meter: This is the preferred option when setting the baseline for a new meter. The meter must be under typical flowing conditions when the baseline is set.
Manually Enter Data: This option is intended to be used if the meter has already been installed in the field for a period of time and data is available from the initial start up to be entered manually.
Click Next to select the desired method on the following page. |
| 1930 |
Select baseline method |
| 1931 |
Use Data from Meter;Manually Enter Data |
| 1932 |
Error: Forward baseline not modified. The direction of flow through the meter is not in the forward direction. Verify the meter is flowing in the direction to baseline and run this utility again. |
| 1933 |
Error: Forward baseline not modified. The running averages are not valid, please wait for flow in one direction for more than 1 minute with all chords operating. The meter flow velocity must stay between %[.1f]{0} %{7} and %[.1f]{1} %{7}. |
| 1934 |
Current Running Averages
%[L]{0}: %{0}
%[L]{1}: %{1} deg
%[L]{2}: %{2}
%[L]{3}: %{3}
Turbulence A: %[.2f]{turbA} %
Turbulence B: %[.2f]{turbB} %
Turbulence C: %[.2f]{turbC} %
Turbulence D: %[.2f]{turbD} %
%[L]{4}: %{4} %{7}
%[L]{5}: %{5} %{8}
%[L]{6}: %{6} %{9}
Click Next to Continue. |
| 1935 |
Do you want to set the forward baseline with these values? |
| 1936 |
Error: Forward baseline not modified. There was an error in writing the baseline values in the meter. The error was: |
| 1937 |
Forward baseline set. |
| 1938 |
Forward baseline not modified. |
| 1939 |
Enter the average profile factor for the meter. The value, Profile Factor, may be found on the Raw Data sheet from a Daniel MeterLink generated Maintenance log. It can also be calculated with the following equation:
(Velocity Chord B + Velocity Chord C) / (Velocity Chord A + Velocity Chord D)
%[L]{0} |
| 1940 |
Enter the average swirl angle for the meter. The value, Swirl Angle, may be found on the Raw Data sheet from a Daniel MeterLink generated Maintenance log. If not available, it is recommended to leave the current value.
%[L]{1} |
| 1941 |
Enter the average symmetry for the meter. The value, Symmetry, may be found on the Raw Data sheet from a Daniel MeterLink generated Maintenance log. It can also be calculated with the following equation:
(Velocity Chord A + Velocity Chord B) / (Velocity Chord C + Velocity Chord D)
%[L]{2} |
| 1942 |
Enter the average cross-flow for the meter. The value, Cross-Flow, may be found on the Raw Data sheet from a Daniel MeterLink generated Maintenance log. It can also be calculated with the following equation:
(Velocity Chord A + Velocity Chord C) / (Velocity Chord B + Velocity Chord D)
%[L]{3} |
| 1943 |
Enter the average turbulence for Chord A of the meter. The value, Turbulence A, may be found on the Raw Data sheet from a Daniel MeterLink generated Maintenance log. If not available, it is recommended to leave the current value.
%[L]{0} |
| 1944 |
Enter the average turbulence for Chord B of the meter. The value, Turbulence B, may be found on the Raw Data sheet from a Daniel MeterLink generated Maintenance log. If not available, it is recommended to leave the current value.
%[L]{1} |
| 1945 |
Enter the average turbulence for Chord C of the meter. The value, Turbulence C, may be found on the Raw Data sheet from a Daniel MeterLink generated Maintenance log. If not available, it is recommended to leave the current value.
%[L]{2} |
| 1946 |
Enter the average turbulence for Chord D of the meter. The value, Turbulence D, may be found on the Raw Data sheet from a Daniel MeterLink generated Maintenance log. If not available, it is recommended to leave the current value.
%[L]{3} |
| 1947 |
Enter the average flow velocity of the meter at which the previously entered baseline parameters were taken. The value, Velocity, may be found on the Raw Data sheet from a Daniel MeterLink generated Maintenance Log.
%[L]{4} |
| 1948 |
Enter the average process temperature at which the previously entered baseline parameters were taken. The value, Temperature, may be found on the Raw Data sheet from a Daniel MeterLink generated Maintenance log or from an associated flow computer's data log.
%[L]{5} |
| 1949 |
Enter the average process pressure at which the previously entered baseline parameters were taken. The value, Pressure, may be found on the Raw Data sheet from a Daniel MeterLink generated Maintenance log or from an associated flow computer's data log.
%[L]{6} |
| 1950 |
New Forward Flow Baseline
%[L]{0}: %{0}
%[L]{1}: %{1} deg
%[L]{2}: %{2}
%[L]{3}: %{3}
Turbulence A: %[.2f]{turbA} %
Turbulence B: %[.2f]{turbB} %
Turbulence C: %[.2f]{turbC} %
Turbulence D: %[.2f]{turbD} %
%[L]{4}: %{4} %{7}
%[L]{5}: %{5} %{8}
%[L]{6}: %{6} %{9}
Click Next to write this configuration to the meter |
| 1951 |
Enter the baseline comment for the meter.
Comment |
| 1952 |
Enter the baseline date for the meter.
Date |
| 1953 |
Enter the baseline time for the meter.
Time |
| 1954 |
Forward baseline not modified and Forward Baseline Not Set alert acknowledged. |
| 1955 |
Current Reverse Flow Baseline
%[L]{0}: %{0}
%[L]{1}: %{1} deg
%[L]{2}: %{2}
%[L]{3}: %{3}
Turbulence A: %[.2f]{turbA} %
Turbulence B: %[.2f]{turbB} %
Turbulence C: %[.2f]{turbC} %
Turbulence D: %[.2f]{turbD} %
%[L]{4}: %{4} %{7}
%[L]{5}: %{5} %{8}
%[L]{6}: %{6} %{9}
Click Next to Continue. |
| 1956 |
Error: Reverse baseline not modified. The direction of flow through the meter is not in the reverse direction. Verify the meter is flowing in the direction to baseline and run this utility again. |
| 1957 |
Error: Reverse baseline not modified. The running averages are not valid, please wait for flow in one direction for more than 1 minute with all chords operating. The meter flow velocity must stay between %[.1f]{0} %{7} and %[.1f]{1} %{7}. |
| 1958 |
Do you want to set the reverse baseline with these values? |
| 1959 |
Error: Reverse baseline not modified. There was an error in writing the baseline values in the meter. The error was: |
| 1960 |
Reverse baseline set. |
| 1961 |
Reverse baseline not modified. |
| 1962 |
New Reverse Flow Baseline
%[L]{0}: %{0}
%[L]{1}: %{1} deg
%[L]{2}: %{2}
%[L]{3}: %{3}
Turbulence A: %[.2f]{turbA} %
Turbulence B: %[.2f]{turbB} %
Turbulence C: %[.2f]{turbC} %
Turbulence D: %[.2f]{turbD} %
%[L]{4}: %{4} %{7}
%[L]{5}: %{5} %{8}
%[L]{6}: %{6} %{9}
Click Next to write this configuration to the meter |
| 1963 |
Reverse baseline not modified and Reverse Baseline Not Set alert acknowledged. |
| 1964 |
This feature can not be enabled because a valid Continuous Flow Analysis key has not been entered into the meter.
Would you like to enter the key now? |
| 1965 |
Enter a valid Continuous Flow Analysis key on the following page.
Keys must be a 16 character uppercase hexadecimal value with no spaces or hyphens between characters.
Valid characters include: 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, A, B, C, D, E, F
Example: 48AF3B1273CA65D9 |
| 1966 |
Enter Continuous Flow Analysis key and click Next to write key to the meter. |
| 1967 |
Error: There was an error writing the Continuous Flow Analysis key to the meter. The error was Too few data bytes received. |
| 1968 |
Error: There was an error writing the Continuous Flow Analysis key to the meter. The error was Key format invalid or invalid key. |
| 1969 |
Error: There was an error writing the Continuous Flow Analysis key to the meter. The error Busy. |
| 1970 |
Continuous Flow Analysis key entered successfully. |
| 1971 |
Error: Detect Blockage not enabled. The error was Invalid selection. |
| 1972 |
Error: Detect Blockage not enabled. The error was Value was too high. |
| 1973 |
Error: Detect Blockage not enabled. The error was Value was too low. |
| 1974 |
Error: Detect Blockage not enabled. The error was Too few data bytes received. |
| 1975 |
Error: Detect Blockage not enabled. The error was In write protect mode. |
| 1976 |
Error: Detect Blockage not enabled. The error was Busy. |
| 1977 |
Error: Detect Blockage not disabled. The error was Invalid selection. |
| 1978 |
Error: Detect Blockage not disabled. The error was Value was too high. |
| 1979 |
Error: Detect Blockage not disabled. The error was Value was too low. |
| 1980 |
Error: Detect Blockage not disabled. The error was Too few data bytes received. |
| 1981 |
Error: Detect Blockage not disabled. The error was In write protect mode. |
| 1982 |
Error: Detect Blockage not disabled. The error was Busy. |
| 1983 |
Detect Blockage enabled. |
| 1984 |
Detect Blockage disabled. |
| 1985 |
Error: Detect Liquid not enabled. The error was Invalid selection. |
| 1986 |
Error: Detect Liquid not enabled. The error was Value was too high. |
| 1987 |
Error: Detect Liquid not enabled. The error was Value was too low. |
| 1988 |
Error: Detect Liquid not enabled. The error was Too few data bytes received. |
| 1989 |
Error: Detect Liquid not enabled. The error was In write protect mode. |
| 1990 |
Error: Detect Liquid not enabled. The error was Busy. |
| 1991 |
Error: Detect Liquid not disabled. The error was Invalid selection. |
| 1992 |
Error: Detect Liquid not disabled. The error was Value was too high. |
| 1993 |
Error: Detect Liquid not disabled. The error was Value was too low. |
| 1994 |
Error: Detect Liquid not disabled. The error was Too few data bytes received. |
| 1995 |
Error: Detect Liquid not disabled. The error was In write protect mode. |
| 1996 |
Error: Detect Liquid not disabled. The error was Busy. |
| 1997 |
Detect Liquid enabled. |
| 1998 |
Detect Liquid disabled. |
| 1999 |
Error: Detect Bore Buildup not enabled. The error was Invalid selection. |
| 2000 |
Error: Detect Bore Buildup not enabled. The error was Value was too high. |
| 2001 |
Error: Detect Bore Buildup not enabled. The error was Value was too low. |
| 2002 |
Error: Detect Bore Buildup not enabled. The error was Too few data bytes received. |
| 2003 |
Error: Detect Bore Buildup not enabled. The error was In write protect mode. |
| 2004 |
Error: Detect Bore Buildup not enabled. The error was Busy. |
| 2005 |
Error: Detect Bore Buildup not disabled. The error was Invalid selection. |
| 2006 |
Error: Detect Bore Buildup not disabled. The error was Value was too high. |
| 2007 |
Error: Detect Bore Buildup not disabled. The error was Value was too low. |
| 2008 |
Error: Detect Bore Buildup not disabled. The error was Too few data bytes received. |
| 2009 |
Error: Detect Bore Buildup not disabled. The error was In write protect mode. |
| 2010 |
Error: Detect Bore Buildup not disabled. The error was Busy. |
| 2011 |
Detect Bore Buildup enabled. |
| 2012 |
Detect Bore Buildup disabled. |
| 2013 |
Error: Detect Abnormal Profile not enabled. The error was Invalid selection. |
| 2014 |
Error: Detect Abnormal Profile not enabled. The error was Value was too high. |
| 2015 |
Error: Detect Abnormal Profile not enabled. The error was Value was too low. |
| 2016 |
Error: Detect Abnormal Profile not enabled. The error was Too few data bytes received. |
| 2017 |
Error: Detect Abnormal Profile not enabled. The error was In write protect mode. |
| 2018 |
Error: Detect Abnormal Profile not enabled. The error was Busy. |
| 2019 |
Error: Detect Abnormal Profile not disabled. The error was Invalid selection. |
| 2020 |
Error: Detect Abnormal Profile not disabled. The error was Value was too high. |
| 2021 |
Error: Detect Abnormal Profile not disabled. The error was Value was too low. |
| 2022 |
Error: Detect Abnormal Profile not disabled. The error was Too few data bytes received. |
| 2023 |
Error: Detect Abnormal Profile not disabled. The error was In write protect mode. |
| 2024 |
Error: Detect Abnormal Profile not disabled. The error was Busy. |
| 2025 |
Detect Abnormal Profile enabled. |
| 2026 |
Detect Abnormal Profile disabled. |
| 2027 |
Error: Sound Velocity Comparison not enabled. The error was Invalid selection. |
| 2028 |
Error: Sound Velocity Comparison not enabled. The error was Value was too high. |
| 2029 |
Error: Sound Velocity Comparison not enabled. The error was Value was too low. |
| 2030 |
Error: Sound Velocity Comparison not enabled. The error was Too few data bytes received. |
| 2031 |
Error: Sound Velocity Comparison not enabled. The error was In write protect mode. |
| 2032 |
Error: Sound Velocity Comparison not enabled. The error was Busy. |
| 2033 |
Error: Sound Velocity Comparison not disabled. The error was Invalid selection. |
| 2034 |
Error: Sound Velocity Comparison not disabled. The error was Value was too high. |
| 2035 |
Error: Sound Velocity Comparison not disabled. The error was Value was too low. |
| 2036 |
Error: Sound Velocity Comparison not disabled. The error was Too few data bytes received. |
| 2037 |
Error: Sound Velocity Comparison not disabled. The error was In write protect mode. |
| 2038 |
Error: Sound Velocity Comparison not disabled. The error was Busy. |
| 2039 |
Sound Velocity Comparison enabled. |
| 2040 |
The Sound Velocity Comparison was enabled but the feature is not active. Verify the AGA8 Calculation is enabled and set to Detailed method using the Field Setup Wizard in Daniel MeterLink. |
| 2041 |
Sound Velocity Comparison disabled. |
| 2042 |
Enter the minimum reverse flow velocity above which to accumulate flow in the reverse direction for this alert. Enter as a positive value.
%[L]{0} |
| 2043 |
Enter the accumulated volume limit above which an alert will be generated.
%[L]{1} |
| 2044 |
Error: Detect Reverse Flow not enabled. The error was Invalid selection. |
| 2045 |
Error: Detect Reverse Flow not enabled. The error was Value was too high. |
| 2046 |
Error: Detect Reverse Flow not enabled. The error was Value was too low. |
| 2047 |
Error: Detect Reverse Flow not enabled. The error was Too few data bytes received. |
| 2048 |
Error: Detect Reverse Flow not enabled. The error was In write protect mode. |
| 2049 |
Error: Detect Reverse Flow not enabled. The error was Invalid unit. |
| 2050 |
Error: Detect Reverse Flow not enabled. The error was Busy. |
| 2051 |
Error: Detect Reverse Flow not disabled. The error was Invalid selection. |
| 2052 |
Error: Detect Reverse Flow not disabled. The error was Value was too high. |
| 2053 |
Error: Detect Reverse Flow not disabled. The error was Value was too low. |
| 2054 |
Error: Detect Reverse Flow not disabled. The error was Too few data bytes received. |
| 2055 |
Error: Detect Reverse Flow not disabled. The error was In write protect mode. |
| 2056 |
Error: Detect Reverse Flow not disabled. The error was Invalid unit. |
| 2057 |
Error: Detect Reverse Flow not disabled. The error was Busy. |
| 2058 |
Detect Reverse Flow enabled. |
| 2059 |
Detect Reverse Flow disabled. |
| 2060 |
Connect reference meter. |
| 2061 |
About to set analog output 1 to %[.3f]{0} mA |
| 2062 |
Enter Meter Value |
| 2063 |
Is field device %[.3f]{0} mA output equal to reference meter? |
| 2064 |
Returning field device to original output. |
| 2065 |
About to set analog output 2 to %[.3f]{0} mA |
| 2066 |
Enable local display test mode? |
| 2067 |
Local display test mode enabled. |
| 2068 |
Enter Timeout Value |
| 2069 |
Enter Percentage of Full Scale to Output |
| 2070 |
Frequency Output 1 is fixed at %0% of full scale. |
| 2071 |
Frequency Output 2 is fixed at %0% of full scale. |
| 2072 |
Change Timeout Value |
| 2073 |
Enter Frequency Output 1 Test Mode |
| 2074 |
Enter Frequency Output 2 Test Mode |
| 2075 |
Exit Test Mode |
| 2076 |
Current test mode timeout selection is %0 min.
Meter will automatically end the test mode after the timeout has expired. |
| 2077 |
; |
| 2078 |
Select Digital Output 1A Test Mode Value |
| 2079 |
Digital Output 1A is fixed %0. |
| 2080 |
Select Digital Output 1B Test Mode Value |
| 2081 |
Digital Output 1B is fixed %0. |
| 2082 |
Select Digital Output 2A Test Mode Value |
| 2083 |
Digital Output 2A is fixed %0. |
| 2084 |
Select Digital Output 2B Test Mode Value |
| 2085 |
Digital Output 2B is fixed %0. |
| 2086 |
Enter Digital Output 1 Test Mode |
| 2087 |
Enter Digital Output 2 Test Mode |
| 2088 |
Warning: Setting transducer type is necessary only after a swap-out of all transducers. Select transducer type carefully as incorrect selection may cause incorrect measurement.
Do you want to set transducer type? |
| 2089 |
Select Transducer Type and click Next to write to the meter. |
| 2090 |
Transducer type set successfully. |
| 2091 |
It may take up to 60 seconds until the display is returned to normal operation. |
| 2092 |
Device is now displaying the pattern (O-O-O-O) on the device display until Cancel is pressed. |
| 2093 |
Select action and click Next to continue. |
| 2094 |
Set Clock;View Clock;Exit |
| 2095 |
Enter Date |
| 2096 |
Enter Time |
| 2097 |
Current Date: %0
Current Time: %1 |
| 2098 |
Device reset is equivalent to cycling power off and then back on to the device.
Reset device? |
| 2099 |
Resetting device...
Please wait. |
| 2100 |
Device reset completed successfully. |
| 2101 |
Reset Required alert detected.
Device reset is equivalent to cycling power off and then back on to the device.
Reset device? |
| 2102 |
Warning: Selecting 'Yes' will reset chord proportions to default values.
Reset chord proportions to default values? |
| 2103 |
Chord proportions reset to default values. |
| 2104 |
You must write analog output 1 content (the device variable mapped to PV) to the meter to refresh dependent values. |
| 2105 |
You must write analog output 2 content to the meter to refresh dependent values. |
| 2106 |
You must write frequency output 1 content to the meter to refresh dependent values. |
| 2107 |
You must write frequency output 2 content to the meter to refresh dependent values. |
| 2108 |
You must write units to the meter to refresh dependent values. |
| 2109 |
You must write AGA8 Method to the meter to refresh dependent values. |
| 2110 |
Reading Device Status... |
| 2111 |
PV: %{0}
Value: %1 %2
Status: Bad |
| 2112 |
PV: %{0}
Value: %1 %2
Status: Fixed |
| 2113 |
PV: %{0}
Value: %1 %2
Status: Degraded |
| 2114 |
PV: %{0}
Value: %1 %2
Status: Good |
| 2115 |
SV: %{3}
Value: %4 %5
Status: Bad |
| 2116 |
SV: %{3}
Value: %4 %5
Status: Fixed |
| 2117 |
SV: %{3}
Value: %4 %5
Status: Degraded |
| 2118 |
SV: %{3}
Value: %4 %5
Status: Good |
| 2119 |
TV: %{0}
Value: %1 %2
Status: Not Used |
| 2120 |
TV: %{0}
Value: %1 %2
Status: Bad |
| 2121 |
TV: %{0}
Value: %1 %2
Status: Fixed |
| 2122 |
TV: %{0}
Value: %1 %2
Status: Degraded |
| 2123 |
TV: %{0}
Value: %1 %2
Status: Good |
| 2124 |
QV: %{3}
Value: %4 %5
Status: Not Used |
| 2125 |
QV: %{3}
Value: %4 %5
Status: Bad |
| 2126 |
QV: %{3}
Value: %4 %5
Status: Fixed |
| 2127 |
QV: %{3}
Value: %4 %5
Status: Degraded |
| 2128 |
QV: %{3}
Value: %4 %5
Status: Good |
| 2129 |
Keys must be a 16 character uppercase hexadecimal value with no spaces or hyphens between characters.
Valid characters include: 0,1,2,3,4,5,6,7,8,9,A,B,C,D,E,F
Example: 48AF3B1273CA65D9 |
| 2130 |
Enter Cont Flow Analysis Key |
| 2131 |
Enter AGA10 Calculation Key |
| 2132 |
Enter GC Communications Key |
| 2133 |
F: Configuration Lost, Latched Until Acknowledged - Acknowledge
Priority: Failed - Fix Now
Description:
The meter has performed a cold start. The meter configuration has reset to default values and the meter is not configured correctly to measure flow.
Recommended Actions:
1. Unless the Cold Start occurred after upgrading firmware, it is recommended to have the CPU Module replaced. Contact your local area Daniel service representative.
2. If the cold start occurred after a firmware upgrade, you must fully re-configure the meter from a previously saved configuration .
3. The alert must be acknowledged to clear it from list of alerts per DidCnfgChksumChg.
4. If the issue is unresolved, contact your local area Daniel service representative. |
| 2134 |
F: Configuration Lost, Latched Until Acknowledged - Not Currently Active - Requires Acknowledge
Priority: Failed - Fix Now
Description:
The meter has performed a cold start. The meter configuration has reset to default values and the meter is not configured correctly to measure flow.
Recommended Actions:
1. Unless the Cold Start occurred after upgrading firmware, it is recommended to have the CPU Module replaced. Contact your local area Daniel service representative.
2. If the cold start occurred after a firmware upgrade, you must fully re-configure the meter from a previously saved configuration .
3. The alert must be acknowledged to clear it from list of alerts per DidCnfgChksumChg.
4. If the issue is unresolved, contact your local area Daniel service representative. |
| 2135 |
Do you want to acknowledge the Alert? |
| 2136 |
F: Acquisition Mode - Acknowledge
Priority: Failed - Fix Now
Description:
The meter is not measuring and is trying to acquire measurement data. Possible causes include transducer failures, miswired transducers, operating below minimum process pressure for meter, invalid geometry configuration, malfunctioning Acquisition Module and fluid type not supported by meter such as high levels of Carbon Dioxide.
Recommended Actions:
1. Verify meter is operating above the minimum process pressure indicated on the meter nameplate. If not, increase the operating pressure.
2. Verify the process fluid rate has not exceeded the maximum rate indicated on the meter nameplate. Lower the flow rate if necessary.
3. If this is a new meter or upgraded meter, verify geometry configuration distance between transducers (for four-path meters LA, LB, LC, and LD, for dual-path meters LA and LB, and for single-path meters LA) and correct if needed. If these parameters are incorrect, check all meter parameters against the meter Zero Flow Calibration report. This report can be requested from your local area Daniel service representative.
4. Check transducers wiring. Verify all connections are secure and that wires are connected to the correct terminals on the Acquisition Module.
5. Replace Acquisition Module with a spare to see if this corrects the issue. If it does and the meter is still under warranty, you may request a replacement module from your local area Daniel service representative.
6. Collect a Maintenance log with Daniel MeterLink if the issue is unresolved and contact your local area Daniel service representative. |
| 2137 |
F: Acquisition Mode - Not Currently Active - Requires Acknowledge
Priority: Failed - Fix Now
Description:
The meter is not measuring and is trying to acquire measurement data. Possible causes include transducer failures, miswired transducers, operating below minimum process pressure for meter, invalid geometry configuration, malfunctioning Acquisition Module and fluid type not supported by meter such as high levels of Carbon Dioxide.
Recommended Actions:
1. Verify meter is operating above the minimum process pressure indicated on the meter nameplate. If not, increase the operating pressure.
2. Verify the process fluid rate has not exceeded the maximum rate indicated on the meter nameplate. Lower the flow rate if necessary.
3. If this is a new meter or upgraded meter, verify geometry configuration distance between transducers (for four-path meters LA, LB, LC, and LD, for dual-path meters LA and LB, and for single-path meters LA) and correct if needed. If these parameters are incorrect, check all meter parameters against the meter Zero Flow Calibration report. This report can be requested from your local area Daniel service representative.
4. Check transducers wiring. Verify all connections are secure and that wires are connected to the correct terminals on the Acquisition Module.
5. Replace Acquisition Module with a spare to see if this corrects the issue. If it does and the meter is still under warranty, you may request a replacement module from your local area Daniel service representative.
6. Collect a Maintenance log with Daniel MeterLink if the issue is unresolved and contact your local area Daniel service representative. |
| 2138 |
F: Acquisition Module Error - Acknowledge
Priority: Failed - Fix Now
Description:
An Acquisition Module-related error has been detected. The CPU Module's measurement LED (MEAS) will flash green when proper communications with the Acquisition Module are restored.
Recommended Actions:
1. If the CPU Module's measurement LED (MEAS) is not flashing green, check interconnect cable between Acquisition Module and the CPU Module.
2. If the CPU Module's measurement LED (MEAS) is still not flashing green, check the Acquisition Module error reasons code
3. If the issue is unresolved, collect a complete Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 2139 |
F: Acquisition Module Error - Not Currently Active - Requires Acknowledge
Priority: Failed - Fix Now
Description:
An Acquisition Module-related error has been detected. The CPU Module's measurement LED (MEAS) will flash green when proper communications with the Acquisition Module are restored.
Recommended Actions:
1. If the CPU Module's measurement LED (MEAS) is not flashing green, check interconnect cable between Acquisition Module and the CPU Module.
2. If the CPU Module's measurement LED (MEAS) is still not flashing green, check the Acquisition Module error reasons code
3. If the issue is unresolved, collect a complete Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 2140 |
F: Too Few Operating Chords - Acknowledge
Priority: Failed - Fix Now
Description:
Number of operating chords is less than the minimum number for a valid measurement. Operating chords are those which are not manually set inactive and not marked as failed.
Recommended Actions:
1. Check the other alerts that indicate why a chord is hard failed. Resolving these should resolve this issue.
2. If this issue is unresolved, collect a Maintenance log and Archive log and contact your local area Daniel service representative. |
| 2141 |
F: Too Few Operating Chords - Not Currently Active - Requires Acknowledge
Priority: Failed - Fix Now
Description:
Number of operating chords is less than the minimum number for a valid measurement. Operating chords are those which are not manually set inactive and not marked as failed.
Recommended Actions:
1. Check the other alerts that indicate why a chord is hard failed. Resolving these should resolve this issue.
2. If this issue is unresolved, collect a Maintenance log and Archive log and contact your local area Daniel service representative. |
| 2142 |
F: Diagnostic Core File Generated, Latched Until Acknowledged - Acknowledge
Priority: Failed - Fix Now
Description:
A diagnostic core file has been generated which may indicate a problem with the meter.
Recommended Actions:
1. The alert must be acknowledged to clear it from list of alerts.
2. Collect an Archive log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2143 |
F: Diagnostic Core File Generated, Latched Until Acknowledged - No Longer Active
Priority: Failed - Fix Now
Description:
A diagnostic core file has been generated which may indicate a problem with the meter.
Recommended Actions:
1. The alert must be acknowledged to clear it from list of alerts.
2. Collect an Archive log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2144 |
F: Electronics Voltage Out Of Range
Priority: Failed - Fix Now
Description:
The CPU Board system voltages or Acquisition Module system voltages are out-of-range. Valid CPU Module voltages are 1.0V, 1.2V, 2.5V, 3.3V or valid Acquisition Module System voltages are 1.2V, 2.5V or 3.3V.
Recommended Actions:
1. Replace the CPU Module if one or more of the CPU voltages is out-of-range.
2. Replace Acquisition Module if one or more of the Acquisition Module voltages is out-of-range.
3. If the issue is unresolved, contact your local area Daniel service representative. |
| 2145 |
F: Acquisition Module is Not Compatible with Firmware/configuration
Priority: Failed - Fix Now
Description:
The firmware cannot work with the installed Acquisition Module. The Acquisition Module may be newer than the firmware, and the firmware does not recognize it. The Acquisition Module may be installed on a meter running firmware for the opposite product (Gas/Liquid). The Acquisition Module may be installed on a meter configured with a transducer frequency or sample interval that is not supported by the module.
Recommended Actions:
1. Verify the transducer frequency and sample interval are set to values supported by the installed Acquisition Module.
2. Upgrade the firmware in the meter to the latest version using Daniel MeterLink. Contact your local area Daniel service representative to obtain the latest firmware.
3. If the latest firmware revision did not resolve the issue, replace the Acquisition Module.
4. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2146 |
F: Watchdog Reset, Latched Until Acknowledged - Acknowledge
Priority: Failed - Fix Now
Description:
Software watchdog initiated a meter warm-start. The watchdog keeps track of the performance of all metrology processes in the meter to ensure a reliable measurement. When a process stops responding, the watchdog forces the meter to restart.
Recommended Actions:
1. Collect an Archive log using Daniel MeterLink and contact your local area Daniel service representative.
2. The alert must be acknowledged to clear it from list of alerts. |
| 2147 |
F: Watchdog Reset, Latched Until Acknowledged - No Longer Active
Priority: Failed - Fix Now
Description:
Software watchdog initiated a meter warm-start. The watchdog keeps track of the performance of all metrology processes in the meter to ensure a reliable measurement. When a process stops responding, the watchdog forces the meter to restart.
Recommended Actions:
1. Collect an Archive log using Daniel MeterLink and contact your local area Daniel service representative.
2. The alert must be acknowledged to clear it from list of alerts. |
| 2148 |
M: Possible Blockage Detected - Acknowledge
Priority: Maintenence - Fix Soon
Description:
Conditions indicate that there may be a possible blockage upstream from the meter. The monitored conditions are from the hourly log data in the meter which means the alert condition is set or cleared once an hour. This alert can be configured and disabled from the Alert Setup menu.
Recommended Actions:
1. Inspect flow conditioners, flow straighteners, tube bundles or upstream piping for foreign objects.
2. If the issue is unresolved, collect a Maintenance Log, Archive Log, and Waveform stream file with Daniel MeterLink and contact your local area Daniel service representative. |
| 2149 |
M: Possible Blockage Detected - Not Currently Active - Requires Acknowledge
Priority: Maintenence - Fix Soon
Description:
Conditions indicate that there may be a possible blockage upstream from the meter. The monitored conditions are from the hourly log data in the meter which means the alert condition is set or cleared once an hour. This alert can be configured and disabled from the Alert Setup menu.
Recommended Actions:
1. Inspect flow conditioners, flow straighteners, tube bundles or upstream piping for foreign objects.
2. If the issue is unresolved, collect a Maintenance Log, Archive Log, and Waveform stream file with Daniel MeterLink and contact your local area Daniel service representative. |
| 2150 |
M: Chord A Hard Failed
Priority: Maintenence - Fix Soon
Description:
The meter is unable to obtain measurement data from this pair of transducers.
Recommended Actions:
1. If no other transducers are failed or are reporting status alerts, the issue is most likely isolated to this pair of transducers or its cabling. Check the transducer wiring for this pair of transducers to make sure connections are secure and wired correctly.
2. Remove the transducer cable from the transducer and measure the resistance with an Ohm meter across the two pins on the back of the transducer holder. If the value is over 2 ohms, replace the transducers.
3. If transducer cabling allows, swap cabling of failed transducer pair with a pair with equal path lengths. If the alert remains active for this chord, then the transducers are working properly. If this alert clears but the chord that was swapped now fails, the issue is with the transducer.
4. If this issue is unresolved, collect a Maintenance Log, Configuration file and Waveform stream file with Daniel MeterLink and contact your local area Daniel service representative. |
| 2151 |
M: Chord B Hard Failed
Priority: Maintenence - Fix Soon
Description:
The meter is unable to obtain measurement data from this pair of transducers.
Recommended Actions:
1. If no other transducers are failed or are reporting status alerts, the issue is most likely isolated to this pair of transducers or its cabling. Check the transducer wiring for this pair of transducers to make sure connections are secure and wired correctly.
2. Remove the transducer cable from the transducer and measure the resistance with an Ohm meter across the two pins on the back of the transducer holder. If the value is over 2 ohms, replace the transducers.
3. If transducer cabling allows, swap cabling of failed transducer pair with a pair with equal path lengths. If the alert remains active for this chord, then the transducers are working properly. If this alert clears but the chord that was swapped now fails, the issue is with the transducer.
4. If this issue is unresolved, collect a Maintenance Log, Configuration file and Waveform stream file with Daniel MeterLink and contact your local area Daniel service representative. |
| 2152 |
M: Chord C Hard Failed
Priority: Maintenence - Fix Soon
Description:
The meter is unable to obtain measurement data from this pair of transducers.
Recommended Actions:
1. If no other transducers are failed or are reporting status alerts, the issue is most likely isolated to this pair of transducers or its cabling. Check the transducer wiring for this pair of transducers to make sure connections are secure and wired correctly.
2. Remove the transducer cable from the transducer and measure the resistance with an Ohm meter across the two pins on the back of the transducer holder. If the value is over 2 ohms, replace the transducers.
3. If transducer cabling allows, swap cabling of failed transducer pair with a pair with equal path lengths. If the alert remains active for this chord, then the transducers are working properly. If this alert clears but the chord that was swapped now fails, the issue is with the transducer.
4. If this issue is unresolved, collect a Maintenance Log, Configuration file and Waveform stream file with Daniel MeterLink and contact your local area Daniel service representative. |
| 2153 |
M: Chord D Hard Failed
Priority: Maintenence - Fix Soon
Description:
The meter is unable to obtain measurement data from this pair of transducers.
Recommended Actions:
1. If no other transducers are failed or are reporting status alerts, the issue is most likely isolated to this pair of transducers or its cabling. Check the transducer wiring for this pair of transducers to make sure connections are secure and wired correctly.
2. If this chord abruptly fails or fails intermittently, it could be the results of liquid in the bottom of the meter. A verification that liquids are not present should be conducted.
3. Remove the transducer cable from the transducer and measure the resistance with an Ohm meter across the two pins on the back of the transducer holder. If the value is over 2 ohms, replace the transducers.
4. If transducer cabling allows, swap cabling of failed transducer pair with a pair with equal path lengths. If the alert remains active for this chord, then the transducers are working properly. If this alert clears but the chord that was swapped now fails, the issue is with the transducer.
5. If this issue is unresolved, collect a Maintenance Log, Configuration file and Waveform stream file with Daniel MeterLink and contact your local area Daniel service representative. |
| 2154 |
M: Flow Pressure Invalid - Acknowledge
Priority: Maintenence - Fix Soon
Description:
Pressure is invalid if the flow pressure is outside the limits defined by the low and high pressure alert limits.
Recommended Actions:
First Time Startup Issues:
1. Verify that there is voltage to the pressure sensor, either from the terminal on the meter's power supply board or from an external power supply.
2. If using an analog pressure device, verify that the pressure sensor is properly wired to connector TB2-B pins 1 & 2 (ANALOG IN PT- & PT+) .
3. Verify the input is properly configured for your pressure input.
4. If using a flow computer to write pressure to the meter, verify that it is properly writing to fixed flow pressure in the proper units.
5. If the issue is unresolved, collect a Maintenance Log using Daniel MeterLink and contact your local area Daniel service representative.
Run Time Issues:
1. Adjust pressure of process fluid to within alarm limits.
2. If using an analog pressure device and input reading is 0, check if Analog Input 2 availability is equal to 1 in the Meter Information dialog in Daniel MeterLink. If it is not 1, either the I/O Board has been removed or is damaged. Reinstall or replace the board if this value is 0.
3. If using an analog pressure device, verify that the pressure sensor is working properly.
4. If using an analog pressure device, recheck wiring and switch settings as noted above under First Time Setup Issues.
5. If flow computer is writing values to the fixed flow pressure, verify that the flow computer is still writing valid values without Modbus write errors.
6. Reverify the pressure input settings are correct.
7. If the issue is unresolved, collect a Maintenance Log using Daniel MeterLink and contact your local area Daniel service representative.
|
| 2155 |
M: Flow Pressure Invalid - Not Currently Active - Requires Acknowledge
Priority: Maintenence - Fix Soon
Description:
Pressure is invalid if the flow pressure is outside the limits defined by the low and high pressure alert limits.
Recommended Actions:
First Time Startup Issues:
1. Verify that there is voltage to the pressure sensor, either from the terminal on the meter's power supply board or from an external power supply.
2. If using an analog pressure device, verify that the pressure sensor is properly wired to connector TB2-B pins 1 & 2 (ANALOG IN PT- & PT+) .
3. Verify the input is properly configured for your pressure input.
4. If using a flow computer to write pressure to the meter, verify that it is properly writing to fixed flow pressure in the proper units.
5. If the issue is unresolved, collect a Maintenance Log using Daniel MeterLink and contact your local area Daniel service representative.
Run Time Issues:
1. Adjust pressure of process fluid to within alarm limits.
2. If using an analog pressure device and input reading is 0, check if Analog Input 2 availability is equal to 1 in the Meter Information dialog in Daniel MeterLink. If it is not 1, either the I/O Board has been removed or is damaged. Reinstall or replace the board if this value is 0.
3. If using an analog pressure device, verify that the pressure sensor is working properly.
4. If using an analog pressure device, recheck wiring and switch settings as noted above under First Time Setup Issues.
5. If flow computer is writing values to the fixed flow pressure, verify that the flow computer is still writing valid values without Modbus write errors.
6. Reverify the pressure input settings are correct.
7. If the issue is unresolved, collect a Maintenance Log using Daniel MeterLink and contact your local area Daniel service representative.
|
| 2156 |
M: Flow Temperature Invalid - Acknowledge
Priority: Maintenence - Fix Soon
Description:
Temperature is invalid if the flow temperature is outside the limits defined by the low and high temperature alert limits.
Recommended Actions:
First Time Startup Issues:
1. Verify that there is voltage to the temperature sensor, either from the terminal on the meter's power supply board or from an external power supply.
2. If using an analog temperature device, verify that the temperature sensor is properly wired to connector TB2-B pins 3 & 4 (ANALOG IN TT- & TT+) .
3. Verify the input is properly configured for your temperature input.
4. If using a flow computer to write temperature to the meter, verify that it is properly writing to fixed flow temperature in the proper units.
5. If the issue is unresolved, collect a Maintenance Log using Daniel MeterLink and contact your local area Daniel service representative.
Run Time Issues:
1. Adjust temperature of process fluid to within alarm limits.
2. If using an analog temperature device and input reading is 0, check if Analog Input 1 availability is equal to 1 in the Meter Information dialog in Daniel MeterLink. If it is not 1, either the I/O Board has been removed or is damaged. Reinstall or replace I/O board if this value is 0.
3. If using an analog temperature device, verify that the temperature sensor is working properly.
4. If using an analog temperature device, recheck wiring and switch settings as noted above under First Time Setup Issues.
5. If flow computer is writing values to the fixed flow temperature, verify that the flow computer is still writing valid values without Modbus write errors.
6. Reverify the temperature input settings are correct.
7. If the issue is unresolved, collect a Maintenance Log using Daniel MeterLink and contact your local area Daniel service representative.
|
| 2157 |
M: Flow Temperature Invalid - Not Currently Active - Requires Acknowledge
Priority: Maintenence - Fix Soon
Description:
Temperature is invalid if the flow temperature is outside the limits defined by the low and high temperature alert limits.
Recommended Actions:
First Time Startup Issues:
1. Verify that there is voltage to the temperature sensor, either from the terminal on the meter's power supply board or from an external power supply.
2. If using an analog temperature device, verify that the temperature sensor is properly wired to connector TB2-B pins 3 & 4 (ANALOG IN TT- & TT+) .
3. Verify the input is properly configured for your temperature input.
4. If using a flow computer to write temperature to the meter, verify that it is properly writing to fixed flow temperature in the proper units.
5. If the issue is unresolved, collect a Maintenance Log using Daniel MeterLink and contact your local area Daniel service representative.
Run Time Issues:
1. Adjust temperature of process fluid to within alarm limits.
2. If using an analog temperature device and input reading is 0, check if Analog Input 1 availability is equal to 1 in the Meter Information dialog in Daniel MeterLink. If it is not 1, either the I/O Board has been removed or is damaged. Reinstall or replace I/O board if this value is 0.
3. If using an analog temperature device, verify that the temperature sensor is working properly.
4. If using an analog temperature device, recheck wiring and switch settings as noted above under First Time Setup Issues.
5. If flow computer is writing values to the fixed flow temperature, verify that the flow computer is still writing valid values without Modbus write errors.
6. Reverify the temperature input settings are correct.
7. If the issue is unresolved, collect a Maintenance Log using Daniel MeterLink and contact your local area Daniel service representative.
|
| 2158 |
M: Clock Invalid
Priority: Maintenence - Fix Soon
Description:
The meter's hardware clock has been set to a date prior to Jan. 1, 2003.
Recommended Actions:
1. The real time clock has a power backup of about 2 weeks. If the meter remains unpowered for more than this time, the real time clock will reset back to Jan. 1, 2000. If this is the issue, use either the Field Setup Wizard or the Monitor screen in Daniel MeterLink to set the correct date and time.
2. If the meter has not been unpowered for more than 2 weeks, the CPU board should be replaced as the real time clock or its backup power source may be damaged.
3. Contact your local area Daniel service representative for assistance in getting a replacement CPU board. |
| 2159 |
M: GC Alarm Condition is Present
Priority: Maintenence - Fix Soon
Description:
This indicates that a GC alarm condition is present.
Recommended Actions:
1. If possible, collect the System log from the meter using the Archive Logs screen in Daniel MeterLink. The System log will provide additional information to identify the cause of this alert.
2. Check the Gas Chromatograph Communications key is enabled in License Keys under Manual Setup. If disabled, contact your local area Daniel sales representative to acquire a valid key.
3. Verify that the port availability of the port the GC is connected to is set to 1 in the Meter Information Dialog of Daniel MeterLink. If set to 0, then the module is either not installed or the module is damaged. Reinstall or replace module.
4. If this alert is present, it could be that the meter is reading unrecognized component ids from the GC. The System Log will report "unrecognized component id <value>" if this is the issue. The GC component table must be modified in the GC to correct this issue. Contact your local area Daniel service representative for assistance.
5. If this alert is present it could be because the gas chromatograph stream number was not found within the specified stream timeout period. Using the Field Setup Wizard in Daniel MeterLink, verify that the GC stream number matches the stream number configured in the GC.
6. If this alert is present it could be because the GC reported alarm, Modbus Register 3046, bits 14 and/or 15 are set or the GC reported alarm, Modbus Register 3047, bits 0, 1, 2, and/or 3 are set. Use the Daniel MON/MON2000 Gas Chromatograph software to check the alarm state of the GC and correct any issues.
7. If the issue is unresolved, collect an Archive Log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2160 |
M: Communication Error with the GC
Priority: Maintenence - Fix Soon
Description:
The meter is not able to communicate successfully with the GC.
Recommended Actions:
1. Verify you are using a GC compatible with Daniel Sim2251 communications.
2. Check communications cables to the GC. The GC must be wired to the port on the meter chosen by the serial port selector. Verify the hardware protocol for that port matches the GC.
3. Check the TX and RX LEDs to see if there is a poll message on the TX LED followed by a receive message on the RX LED.
4. Verify GC communication serial port settings is set to Modbus ASCII (7, Even, 1) or Modbus RTU (8, None, 1). Then verify the meter is configured to match using the Field Setup Wizard in Daniel MeterLink.
5. If possible, collect the System log from the meter using the Archive Logs screen in Daniel MeterLink. The System log will provide additional information to help identify the cause of this alert.
6. If the issue is unresolved, collect an Archive Log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2161 |
M: Invalid Data Read From the GC
Priority: Maintenence - Fix Soon
Description:
Indicates invalid data read from the GC.
Recommended Actions:
Any one of the following conditions could cause this alert.
1. The total unnormalized gas composition mole percentage of all the components read from the GC is not within the range of 85% to 115%. Use Daniel MON/MON2000 to verify the total gas composition totals between the specified percentage range. Correct any issues identified.
2. An individual gas composition mole percentage is not within the range of 0% to 100%. Use the Daniel MON/MON2000 Gas Chromatograph software to verify all the gas components are between the specified range. Correct any issues identified.
3. The specific gravity is not within the range of 0.2 to 0.8. Use the Daniel MON/MON2000 Gas Chromatograph software to verify the specific gravity is within this range. Correct any issues identified.
4. The heating value is greater than 50 kJ/cubic dm. This could be caused by a units mismatch between the GC configuration and the meter configuration. Run the Field Setup Wizard in Daniel MeterLink and verify the units with the units configured in the GC. Also verify the GC reports a heating value that meets the specification above.
5. If the issue is unresolved, collect an Archive Log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2162 |
M: Reset Required
Priority: Maintenence - Fix Soon
Description:
The meter configuration has changed and requires a restart for the change to take effect.
Recommended Actions:
1. If you are unaware of changes made to the meter's configuration, collect the Audit log using the Archive Logs screen in Daniel MeterLink to review configuration changes. If the changes are valid, momentarily remove power from the meter to allow it to restart which will clear this alert.
2. If the Audit log shows no changes, contact your local area Daniel service representative for assistance. |
| 2163 |
A: Abnormal Profile Detected - Acknowledge
Priority: Advisory
Description:
The flow profile of the meter is abnormal and may affect the accuracy of measurement of the meter. This alert is configured as part of the Flow Analysis Alerts setup under the Alert Setup menu.
Recommended Actions:
1. Inspect the meter run and upstream flow conditioner for possible obstructions.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2164 |
A: Abnormal Profile Detected - Not Currently Active - Requires Acknowledge
Priority: Advisory
Description:
The flow profile of the meter is abnormal and may affect the accuracy of measurement of the meter. This alert is configured as part of the Flow Analysis Alerts setup under the Alert Setup menu.
Recommended Actions:
1. Inspect the meter run and upstream flow conditioner for possible obstructions.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2165 |
A: Possible Bore Buildup Detected - Acknowledge
Priority: Advisory
Description:
Conditions indicate that there may be a possible buildup of material on the meter bore. The monitored conditions are from the daily log data in the meter which means the alert condition is set or cleared once a day. This alert can be disabled from the Alert Setup menu.
Recommended Actions:
1. Collect a Archive log using Daniel MeterLink and look at the Profile Factor chart on the Daily Log Charts worksheet. If the data trend shows a long term change in Profile Factor, this indicates a long term buildup. If the Profile Factor has an abrupt change in the last week, this indicates a possible upset condition that caused a buildup on the bore of the meter.
2. Inspect meter run for possible bore buildup.
3. If the issue is unresolved, collect a Maintenance Log and Archive log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2166 |
A: Possible Bore Buildup Detected - Not Currently Active - Requires Acknowledge
Priority: Advisory
Description:
Conditions indicate that there may be a possible buildup of material on the meter bore. The monitored conditions are from the daily log data in the meter which means the alert condition is set or cleared once a day. This alert can be disabled from the Alert Setup menu.
Recommended Actions:
1. Collect a Archive log using Daniel MeterLink and look at the Profile Factor chart on the Daily Log Charts worksheet. If the data trend shows a long term change in Profile Factor, this indicates a long term buildup. If the Profile Factor has an abrupt change in the last week, this indicates a possible upset condition that caused a buildup on the bore of the meter.
2. Inspect meter run for possible bore buildup.
3. If the issue is unresolved, collect a Maintenance Log and Archive log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2167 |
A: Liquids Possibly Present In Gas - Acknowledge
Priority: Advisory
Description:
This alert condition indicates that there may be a possible presence of liquids in the meter. This alert is configured as part of the Flow Analysis Alerts setup under the Alert Setup menu.
Recommended Actions:
1. Verify the gas process conditions are such that the meter is operating above the dew point.
2. Inspect meter run for presence of liquids.
3. Check upstream system for faults that could allow liquids into meter run.
4. Verify meter is not at a low point in the meter run where liquids could be trapped.
5. If the issue is unresolved, collect a Maintenance log and Waveform stream file while alert is active and contact your local area Daniel service representative. |
| 2168 |
A: Liquids Possibly Present In Gas - Not Currently Active - Requires Acknowledge
Priority: Advisory
Description:
This alert condition indicates that there may be a possible presence of liquids in the meter. This alert is configured as part of the Flow Analysis Alerts setup under the Alert Setup menu.
Recommended Actions:
1. Verify the gas process conditions are such that the meter is operating above the dew point.
2. Inspect meter run for presence of liquids.
3. Check upstream system for faults that could allow liquids into meter run.
4. Verify meter is not at a low point in the meter run where liquids could be trapped.
5. If the issue is unresolved, collect a Maintenance log and Waveform stream file while alert is active and contact your local area Daniel service representative. |
| 2169 |
A: Reverse Flow Detected - Acknowledge
Priority: Advisory
Description:
The meter has accumulated a reverse flow volume greater than a user configurable limit. This alert is configured as part of the Flow Analysis Alerts setup under the Alert Setup menu.
Recommended Actions:
1. Check valves for leaks.
2. If metering run is known to have some volume of reverse flow when flow is stopped, reconfigure the reverse flow volume limit to allow a greater volume.
3. If meter regularly flows in the reverse direction, this alert should be disabled. It is only intended to be used for unidirectional applications.
4. If the issue is unresolved, collect an Archive log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2170 |
A: Reverse Flow Detected - Not Currently Active - Requires Acknowledge
Priority: Advisory
Description:
The meter has accumulated a reverse flow volume greater than a user configurable limit. This alert is configured as part of the Flow Analysis Alerts setup under the Alert Setup menu.
Recommended Actions:
1. Check valves for leaks.
2. If metering run is known to have some volume of reverse flow when flow is stopped, reconfigure the reverse flow volume limit to allow a greater volume.
3. If meter regularly flows in the reverse direction, this alert should be disabled. It is only intended to be used for unidirectional applications.
4. If the issue is unresolved, collect an Archive log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2171 |
A: Sound Velocity Comparison Of AGA10 to Meter Error - Acknowledge
Priority: Advisory
Description:
The absolute error between the AGA10-calculated sound velocity and the meter-calculated sound velocity is greater than the alert limit.
Recommended Actions:
1. If gas composition is from a live GC, using Daniel MeterLink check GC setup in the Field Setup Wizard and the time of the last GC update in the Monitor screen. Verify the correct stream number is configured to be collected.
2. Verify the pressure and temperature readings in use by the meter are accurate.
3. If the gas composition is from fixed user entered values, use Monitor screen in Daniel MeterLink to check the gas composition values.
4. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2172 |
A: Sound Velocity Comparison Of AGA10 to Meter Error - Not Currently Active - Requires Acknowledge
Priority: Advisory
Description:
The absolute error between the AGA10-calculated sound velocity and the meter-calculated sound velocity is greater than the alert limit.
Recommended Actions:
1. If gas composition is from a live GC, using Daniel MeterLink check GC setup in the Field Setup Wizard and the time of the last GC update in the Monitor screen. Verify the correct stream number is configured to be collected.
2. Verify the pressure and temperature readings in use by the meter are accurate.
3. If the gas composition is from fixed user entered values, use Monitor screen in Daniel MeterLink to check the gas composition values.
4. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2173 |
A: Meter Velocity Above Maximum Limit - Acknowledge
Priority: Advisory
Description:
Velocity is above the meter maximum velocity limit.
Recommended Actions:
1. Lower the velocity of the meter as this alert indicates you are running above a safe limit that could damage the meter run or could indicate you are running above your upper calibration limit where meter uncertainty could increase.
2. Change the value of the meter maximum velocity if desired. It is recommended to set this either to the maximum calibrated velocity of the meter or to the maximum safe operating velocity of the meter run. The maximum safe operating velocity typically is to prevent erosion of the pipe internal diameter and prevent damage to protrusions such as thermal wells. |
| 2174 |
A: Meter Velocity Above Maximum Limit - Not Currently Active - Requires Acknowledge
Priority: Advisory
Description:
Velocity is above the meter maximum velocity limit.
Recommended Actions:
1. Lower the velocity of the meter as this alert indicates you are running above a safe limit that could damage the meter run or could indicate you are running above your upper calibration limit where meter uncertainty could increase.
2. Change the value of the meter maximum velocity if desired. It is recommended to set this either to the maximum calibrated velocity of the meter or to the maximum safe operating velocity of the meter run. The maximum safe operating velocity typically is to prevent erosion of the pipe internal diameter and prevent damage to protrusions such as thermal wells. |
| 2175 |
A: Flow-Condition Volumetric Flow Rate Validity
Priority: Advisory
Description:
The meter either has not collected enough information from the chords to make an accurate measurement or the pressure and/or temperature are invalid and meter is performing pressure or temperature expansion corrections on the meter internal diameter. This is an alert condition that shows the validity of the flow-condition volumetric flow rate. The flow-condition volumetric flow rate becomes invalid if the uncorrected flow-condition volumetric flow rate validity, temperature expansion correction validity, pressure expansion correction validity, or Flow-profile-effect correction validity is invalid.
Recommended Actions:
1. If a Pressure expansion correction validity alert is present, correcting it may clear this alert.
2. If a Temperature expansion correction validity alert is present, correcting it may clear this alert.
3. If an Uncorrected flow-condition volumetric flow rate validity alert is present, correcting it may clear this alert.
4. If a Flow-profile-effect correction validity alert is present, correcting it may clear this alert.
5. If the issue is unresolved, collect a Maintenance Log with Daniel MeterLink and contact your local area Daniel service representative. |
| 2176 |
A: AGA8 Base-Condition Calculation Validity
Priority: Advisory
Description:
AGA8 base condition calculations are invalid. AGA8 base condition becomes invalid if the gas properties in use are invalid or AGA8 base calculation status is a non-zero value.
Recommended Actions:
1. Other primary cause alerts will be present in the alert list. Resolve those alerts first and this alert will clear.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2177 |
A: AGA8 Flow-Condition Calculation Validity
Priority: Advisory
Description:
AGA8 flow condition calculations are invalid. The AGA8 flow compressibility becomes invalid if the AGA8 Base Calculation is invalid, pressure is invalid, or temperature is invalid or AGA8 flow calculation status is a non-zero value.
Recommended Actions:
1. Other primary cause alerts will be present in the alert list. Resolve those alerts first and this alert will clear.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2178 |
A: Forward Baseline Not Set - Acknowledge
Priority: Advisory
Description:
Some or all forward baseline values available in the meter are not set. The baseline captures the flow characteristics of the meter when installed so that the meter can monitor these parameters and use them to diagnose the health of the meter.
Recommended Actions:
1. Click Setup Baseline below to set the forward baseline parameters.
2. If the meter does not run in the forward direction or you do not wish to take advantage of the Continuous Flow Analysis features, acknowledge this alert to clear it. |
| 2179 |
A: Forward Baseline Not Set - No Longer Active
Priority: Advisory
Description:
Some or all forward baseline values available in the meter are not set. The baseline captures the flow characteristics of the meter when installed so that the meter can monitor these parameters and use them to diagnose the health of the meter.
Recommended Actions:
1. Click Setup Baseline below to set the forward baseline parameters.
2. If the meter does not run in the forward direction or you do not wish to take advantage of the Continuous Flow Analysis features, acknowledge this alert to clear it. |
| 2180 |
Do you want to setup forward baseline? |
| 2181 |
This utility allows you to baseline the flow characteristics of this meter in the forward flow directions which can be used to diagnose the health of the meter at a later time. |
| 2182 |
A: Reverse Baseline Not Set - Acknowledge
Priority: Advisory
Description:
Some or all reverse baseline values used in Continuous Flow Analysis are not set. The baseline captures the flow characteristics of the meter when installed so that the meter can monitor these parameters and use them to diagnose the health of the meter.
Recommended Actions:
1. Click Setup Baseline below to set the reverse baseline parameters.
2. If the meter does not run in the reverse direction or you do not wish to take advantage of the Continuous Flow Analysis features, acknowledge this alert to clear it. |
| 2183 |
A: Reverse Baseline Not Set - No Longer Active
Priority: Advisory
Description:
Some or all reverse baseline values used in Continuous Flow Analysis are not set. The baseline captures the flow characteristics of the meter when installed so that the meter can monitor these parameters and use them to diagnose the health of the meter.
Recommended Actions:
1. Click Setup Baseline below to set the reverse baseline parameters.
2. If the meter does not run in the reverse direction or you do not wish to take advantage of the Continuous Flow Analysis features, acknowledge this alert to clear it. |
| 2184 |
This utility allows you to baseline the flow characteristics of this meter in the reverse flow directions which can be used to diagnose the health of the meter at a later time. |
| 2185 |
A: Energy Rate Validity
Priority: Advisory
Description:
The calculated energy flow rate is invalid. A problem has occurred with flow condition pressure and/or temperature inputs, AGA8 calculations, or heating value. The energy rate becomes invalid if either base-condition volumetric flow rate is invalid or if an invalid gas heating value is read from a gas chromatograph.
Recommended Actions:
1. If the base-condition volumetric flow rate is invalid, resolve this issue first before trying to resolve this alert.
2. Verify using Daniel MeterLink that a valid heating value is specified in the meter or a live gas chromatograph is configured and the meter reports no invalid GC alerts. Resolve these alerts if present.
3. If the issue is unresolved, collect a Maintenance log with Daniel MeterLink and contact your local area Daniel service representative. |
| 2186 |
A: Mass Flow Rate Validity
Priority: Advisory
Description:
The calculated mass flow rate is invalid. A problem has occurred with flow condition pressure and/or temperature inputs, or AGA8 calculations. Mass rate becomes invalid if either the flow-condition volumetric flow rate is invalid or the AGA8 flow calculation is invalid. This is only applicable when the AGA8 calculations are performed internally or are performed externally with the mixture flow-condition mass density specified.
Recommended Actions:
1. Other primary cause alerts will be present in the alert list. Resolve those alerts first and this alert will clear.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2187 |
A: Base-Condition Volumetric Flow Rate Validity
Priority: Advisory
Description:
There is an error with the AGA8 base-condition volumetric flow rate. The base-condition volumetric flow rate becomes invalid if the flow-condition volumetric flow rate validity, pressure validity, temperature validity, or AGA8 flow calculation validity are set to invalid.
Recommended Actions:
1. Other primary cause alerts will be present in the alert list. Resolve those alerts first and this alert will clear.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2188 |
A: Analog Output 1 Validity
Priority: Advisory
Description:
Analog Output 1 (AO1) is invalid. The analog output is considered invalid if the analog output is in test mode or the content the analog output is trying to drive is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output on Analog Output 1, resolving that issue should clear this alert.
2. If the content selected for Analog Output 1 is not in alarm, then verify that the output is not fixed or set in test mode.
3. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2189 |
A: Analog Output 2 Validity
Priority: Advisory
Description:
Analog Output 2 (AO2) is invalid. The analog output is considered invalid if the analog output is in test mode or the content the analog output is trying to drive is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output on Analog Output 2, resolving that issue should clear this alert.
2. If the content selected for Analog Output 2 is not in alarm, then verify that the output is not fixed or set in test mode.
3. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2190 |
A: Frequency Output 1 Data is Invalid
Priority: Advisory
Description:
The parameter which the Frequency Output 1 is configured to represent is invalid or the output is currently in test mode.
Recommended Actions:
1. You can determine whether the output is in test mode by using Meter Outputs in Daniel MeterLink.
2. If the parameter for which Frequency Output 1 is configured is invalid, other alerts will be present that will help you resolve the issue.
3. If the issue is unresolved, collect a Maintenance log and Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 2191 |
A: Frequency Output 2 Data is Invalid
Priority: Advisory
Description:
The parameter which the Frequency Output 2 is configured to represent is invalid or the output is currently in test mode.
Recommended Actions:
1. You can determine whether the output is in test mode by using Meter Outputs in Daniel MeterLink.
2. If the parameter for which Frequency Output 2 is configured is invalid, other alerts will be present that will help you resolve the issue.
3. If the issue is unresolved, collect a Maintenance log and Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 2192 |
A: HART Fourth Variable Validity
Priority: Advisory
Description:
The HART Fourth Variable value as defined by the HART device variable selection is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output , resolving that issue should clear this alert.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2193 |
A: HART Command 33 Slot 0 Validity
Priority: Advisory
Description:
The HART Slot 0 value as defined by the HART device variable selection is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output , resolving that issue should clear this alert.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2194 |
A: HART Command 33 Slot 1 Validity
Priority: Advisory
Description:
The HART Slot 1 value as defined by the HART device variable selection is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output , resolving that issue should clear this alert.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2195 |
A: HART Command 33 Slot 2 Validity
Priority: Advisory
Description:
The HART Slot 2 value as defined by the HART device variable selection is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output , resolving that issue should clear this alert.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2196 |
A: HART Command 33 Slot 3 Validity
Priority: Advisory
Description:
The HART Slot 3 value as defined by the HART device variable selection is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output , resolving that issue should clear this alert.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2197 |
A: HART Third Variable Validity
Priority: Advisory
Description:
The HART Third Variable value as defined by the HART device variable selection is invalid.
Recommended Actions:
1. If an alert exists for the content selected to be output , resolving that issue should clear this alert.
2. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2198 |
A: Analog Output 1 (HART PV) is Saturated
Priority: Advisory
Description:
Analog Output 1 is saturated (i.e. the loop current has reached its upper or lower endpoint and cannot increase or decrease any further).
Recommended Actions:
1. The analog output may need to be rescaled to prevent it from saturating. Use the Field Setup Wizard in Daniel MeterLink to configure Analog Output 1. |
| 2199 |
A: Analog Output 2 (HART SV) is Saturated
Priority: Advisory
Description:
Analog Output 2 is saturated (i.e. the loop current has reached its upper or lower endpoint and cannot increase or decrease any further).
Recommended Actions:
1. The analog output may need to be rescaled to prevent it from saturating. Use the Setup Outputs wizard under Guided Setup to configure Analog Output 2. |
| 2200 |
A: Analog Output 1 (HART PV) is Fixed
Priority: Advisory
Description:
Analog Output 1 current is in test mode and fixed. The current can be fixed via HART command 40 or command 66.
Recommended Actions:
1. Once the Analog Output 1 is removed from test mode, this alert will clear. |
| 2201 |
A: Analog Output 2 (HART SV) is Fixed
Priority: Advisory
Description:
Analog Output 2 current is in test mode and fixed. The current can be fixed via the HART command 66.
Recommended Actions:
1. Once the Analog Output 2 is removed from test mode, this alert will clear. |
| 2202 |
A: Average Sound Velocity Out-Of-Limits
Priority: Advisory
Description:
The meter's measured average sound velocity is out of limits. This alert is used for HART applications. The non-HART average sound velocity out of limits alert is used for other applications.
Recommended Actions:
1. Verify that all chords are measuring the same Speed of Sound within about 0.15%. Look for alerts that indicate transducer problems and resolve any of these issues. This could include failing transducers, debris buildup on transducers, or incorrectly entered path lengths in the configuration.
2. If the chords agree well, it is recommended to compare the meter's average speed of sound with an AGA10 calculated speed of sound. If they agree within 0.3%, it is recommended that the minimum or maximum sound speed be adjusted so the meter's average speed of sound falls within these limits.
3. If the issue is unresolved, collect a Maintenance log using Daniel MeterLink and contact your local area Daniel service representative. |
| 2203 |
A: Configuration Changed, Latched Until Acknowledged - Acknowledge
Priority: Advisory
Description:
HART configuration changed. It is set to TRUE when configuration writable via HART is modified. It is reset to FALSE when command 38 is issued by master and received configuration changed counter matches the device configuration change counter. |
| 2204 |
A: Configuration Changed, Latched Until Acknowledged - No Longer Active
Priority: Advisory
Description:
HART configuration changed. It is set to TRUE when configuration writable via HART is modified. It is reset to FALSE when command 38 is issued by master and received configuration changed counter matches the device configuration change counter. |
| 2205 |
A: Power Failure, Latched Until Acknowledged - Acknowledge
Priority: Advisory
Description:
The meter has had power removed for a period of time or the meter restarted itself such as after a firmware upgrade. The Audit log in the meter will indicate the power fail time.
Recommended Actions:
1. If this was a known power fail or restart of the meter just acknowledge this alert.
2. If this was an unexpected restart of the meter, verify the integrity of the power to the meter and make sure that the voltage level is in the range of 11-36 VDC at the meter.
3. The alert must be acknowledged to clear it from list of alerts.
4. If the issue is unresolved, collect a complete Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 2206 |
A: Power Failure, Latched Until Acknowledged - No Longer Active
Priority: Advisory
Description:
The meter has had power removed for a period of time or the meter restarted itself such as after a firmware upgrade. The Audit log in the meter will indicate the power fail time.
Recommended Actions:
1. If this was a known power fail or restart of the meter just acknowledge this alert.
2. If this was an unexpected restart of the meter, verify the integrity of the power to the meter and make sure that the voltage level is in the range of 11-36 VDC at the meter.
3. The alert must be acknowledged to clear it from list of alerts.
4. If the issue is unresolved, collect a complete Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 2207 |
A: Flow-Condition Pressure Out-Of-Limits
Priority: Advisory
Description:
The flow-condition pressure is outside the limits.
Recommended Actions:
1. If connected to a pressure transducer, verify that the transducer is functioning properly. Verify that the wiring is correctly connected to TB2-B pins 1 & 2 (ANALOG IN PT- and PT+). Verify that the current is between 4 mA and 20 mA.
2. Verify the input is properly configured for your pressure input.
3. Adjust the gain and offset so the flow-condition pressure is correct.
4. If the issue is unresolved, collect a complete Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 2208 |
A: Flow-Condition Temperature Out-Of-Limits
Priority: Advisory
Description:
The flow-condition temperature is outside the limits.
Recommended Actions:
1. If connected to a temperature transducer, verify that the transducer is functioning properly. Verify that the wiring is correctly connected to TB2-B pins 3 & 4 (ANALOG IN TT- and TT+). Verify that the current is between 4 mA and 20 mA.
2. Verify the input is properly configured for your temperature input.
3. Adjust the gain and offset so the flow-condition temperature is correct.
4. If the issue is unresolved, collect a complete Archive log from the meter using Daniel MeterLink and contact your local area Daniel service representative. |
| 2209 |
A: Alarm Archive Log is Full
Priority: Advisory
Description:
The alarm archive log is full and the log is not configured to be overwritten automatically.
Recommended Actions:
1. Collect alarm archive log records using Daniel MeterLink and allow Daniel MeterLink to mark them as read which will allow them to be overwritten.
|
| 2210 |
A: Analog Output 1 Test Enable
Priority: Advisory
Description:
Enables the Analog Output Test mode for Analog Output 1. When in the Analog Output Test mode, Analog Output 1 is fixed at the percentage of full scale specified via the Analog Output 1 test mode output percent configuration point (regardless of the actual data content value). If Analog Output 1 remains in Analog Output Test mode for longer than the non-normal mode timeout, Analog Output 1 automatically exits Analog Output Test mode and returns to normal operation. |
| 2211 |
A: Analog Output 2 Test Enable
Priority: Advisory
Description:
Enables the Analog Output Test mode for Analog Output 2. When in the Analog Output Test mode, Analog Output 2 is fixed at the percentage of full scale specified via the Analog Output 2 test mode output percent configuration point (regardless of the actual data content value). If Analog Output 2 remains in Analog Output Test mode for longer than the non-normal mode timeout, Analog Output 2 automatically exits Analog Output Test mode and returns to normal operation. |
| 2212 |
A: Audit Archive Log is Full
Priority: Advisory
Description:
The audit archive log is full and the log is not configured to be overwritten automatically.
Recommended Actions:
1. Collect audit archive log records using Daniel MeterLink and allow Daniel MeterLink to mark them as read which will allow them to be overwritten.
|
| 2213 |
A: Daily Archive Log is Full
Priority: Advisory
Description:
The daily archive log is full and the log is not configured to be overwritten automatically.
Recommended Actions:
1. Collect daily archive log records using Daniel MeterLink and allow Daniel MeterLink to mark them as read which will allow them to be overwritten.
|
| 2214 |
A: Electronics Temperature is Out Of Nominal Range
Priority: Advisory
Description:
The temperature of the electronics is out of nominal operating range. Operating outside the nominal operating range could lead to a system failure.
Recommended Actions:
1. Attempt to warm or cool the meter electronics housing.
2. If the electronics is mounted to the meter and the process fluid in the meter is over 65 °C, you must remote mount the electronics off from the meter body.
3. Collect a Maintenance log using Daniel MeterLink while the meter is experiencing the issue, collect an Archive log (Daily/Hourly/Alarm/Audit/System) using Daniel MeterLink from the meter and contact your local area Daniel service representative. |
| 2215 |
A: Enables Test Mode for Digital Output 1 Pair
Priority: Advisory
Description:
Used to enable the test mode for Digital Output 1 pair. When set to TRUE (1), the test mode is enabled and digital outputs 1A and 1B are set to the levels specified by DO1A test mode value and DO1B test mode value. When this point is set to TRUE (1), the digital output pair remains in the test mode for a period of time set by non-normal operation timeout unless the test mode is explicitly exited by setting this point to FALSE (0). |
| 2216 |
A: Enables Test Mode for Digital Output 2 Pair
Priority: Advisory
Description:
Used to enable the test mode for Digital Output 2 pair. When set to TRUE, the test mode is enabled and digital outputs 2A and 2B are set to the levels specified by DO2A test mode value and DO2B test mode value. When this point is set to TRUE (1), the digital output pair remains in the test mode for a period of time set by non-normal operation timeout unless the test mode is explicitly exited by setting this point to FALSE (0). |
| 2217 |
A: Frequency Output 1 Pair Test Enable
Priority: Advisory
Description:
Frequency Output 1 is in test mode which means the pulses output do not reflect the process flow through the meter. Test mode allows the connection from this output to a flow computer to be verified.
Recommended Actions:
1. Use the Meter Outputs screen in Daniel MeterLink to disable the test mode for Frequency Output 1 to clear this alert and return the meter back to its normal mode of operation.
2. Unless Daniel MeterLink or another application through Modbus is re-enabling the test mode, the output will revert back to the normal mode of operation in a user configured timeout period which can be up to 30 minutes. |
| 2218 |
A: Frequency Output 2 Pair Test Enable
Priority: Advisory
Description:
Frequency Output 2 is in test mode which means the pulses output do not reflect the process flow through the meter. Test mode allows the connection from this output to a flow computer to be verified.
Recommended Actions:
1. Use the Meter Outputs screen in Daniel MeterLink to disable the test mode for Frequency Output 2 to clear this alert and return the meter back to its normal mode of operation.
2. Unless Daniel MeterLink or another application through Modbus is re-enabling the test mode, the output will revert back to the normal mode of operation in a user configured timeout period which can be up to 30 minutes. |
| 2219 |
A: Hourly Archive Log is Full
Priority: Advisory
Description:
The hourly archive log is full and the log is not configured to be overwritten automatically.
Recommended Actions:
1. Collect hourly archive log records using Daniel MeterLink and allow Daniel MeterLink to mark them as read which will allow them to be overwritten.
|
| 2220 |
A: System Archive Log is Full
Priority: Advisory
Description:
The system archive log is full and the log is not configured to be overwritten automatically.
Recommended Actions:
1. Collect system archive log records using Daniel MeterLink and allow Daniel MeterLink to mark them as read which will allow them to be overwritten.
|