| 0 |
DLT9000 |
| 1 |
DDTOP GROUP |
| 2 |
Writes enabled |
| 3 |
Setting this field either allows writing to the instrument, or prevents any writes to the instrument |
| 4 |
Writes disabled |
| 5 |
|
| 6 |
Process Temperature Sensor Failed |
| 7 |
Free Time Limit Exceeded |
| 8 |
NVM Write Limit Exceeded |
| 9 |
Reference Voltage Limit Failed |
| 10 |
Hall Current Readback Limit Failed |
| 11 |
Torque Tube A/D Input Failed |
| 12 |
Not defined. |
| 13 |
Electronics Temperature Exceeds Lo Alarm Threshold |
| 14 |
Electronics Temperature Exceeds Hi Alarm Threshold |
| 15 |
Process Temperature Exceeds Lo Alarm Threshold |
| 16 |
Process Temperature Exceeds Hi Alarm Threshold |
| 17 |
PV Exceeds Lo-Lo Alarm Threshold |
| 18 |
PV Exceeds Lo Alarm Threshold |
| 19 |
PV Exceeds Hi-Hi Alarm Threshold |
| 20 |
PV Exceeds Hi Alarm Threshold |
| 21 |
PV % range |
| 22 |
% range |
| 23 |
Selects the analog output commanded in an alarm condition .choices are:Low=3.7mA, or High =22.5mA. |
| 24 |
Level |
| 25 |
Instrument Primary Variable expressed in Engineering Units. Valid only if sensor. Calibration has been completed and accurate displacer and process fluid data have been entered in instrument memory |
| 26 |
Level Units |
| 27 |
Feet, Units for length of displacer and driver rod. |
| 28 |
Meters, Units for length of displacer and driver rod. |
| 29 |
Inches, Units for length of displacer and driver rod. |
| 30 |
Centimeters, Units for length of displacer and driver rod. |
| 31 |
Millimeters, Units for length of displacer and driver rod. |
| 32 |
.3f |
| 33 |
8.3f |
| 34 |
7d |
| 35 |
High Alarm |
| 36 |
Hi Alarm threshold for PV in current engineering units .if this alarm is enabled,instrument will set a bit-flag when this limit is exceeded. |
| 37 |
High High Alarm |
| 38 |
Hi-Hi Alarm threshold for PV in current engineering units .if this alarm is enabled,instrument will set a bit-flag and force the current to the jumper-selected value when this limit is exceeded. |
| 39 |
Low Alarm |
| 40 |
Lo Alarm threshold for PV in current engineering units .if this alarm is enabled,instrument will set a bit-flag when this limit is exceeded. |
| 41 |
Low Low Alarm |
| 42 |
Lo-Lo Alarm threshold for PV in current engineering units .if this alarm is enabled,instrument will set a bit-flag and force the current to the jumper-selected value when this limit is exceeded. |
| 43 |
Interface |
| 44 |
Interface Units |
| 45 |
Device Variable 1 |
| 46 |
Density |
| 47 |
Density Units |
| 48 |
Device Variable 2 |
| 49 |
Process Temp |
| 50 |
Process Temperature measurement ,either from an RTD or entered via HART |
| 51 |
Temp Units |
| 52 |
Sensor Temperature Units-Engineering unit to be displayed with Sensor Temperature. |
| 53 |
degC, Units for reading temperature. |
| 54 |
degF, Units for reading temperature. |
| 55 |
Process Temp High Alarm |
| 56 |
High alarm threshold for process temperature |
| 57 |
Process Temp High High Alarm |
| 58 |
Process Temp Low Alarm |
| 59 |
Low alarm threshold for process temperature |
| 60 |
Process Temp Low Low Alarm |
| 61 |
Elect Temp |
| 62 |
Temperature of the Instrument |
| 63 |
Elect Temp High Alarm |
| 64 |
High alarm threshold for electronics temperature.Note:Transducer Magnets will be partially demagnetized ifelectronics temperature exceeds 85C (185 F). |
| 65 |
Elect Temp High High Alarm |
| 66 |
Elect Temp Low Alarm |
| 67 |
Low alarm threshold for electronics temperature |
| 68 |
Elect Temp Low Low Alarm |
| 69 |
Process variable being measured is: level of a single fluid with a given SG. |
| 70 |
Process variable being measured is: interface between two fluids of different SGs. |
| 71 |
Process variable being measured is: density of a single fluid . |
| 72 |
Process_Temp |
| 73 |
Elect_Temp |
| 74 |
Weight index |
| 75 |
Weight |
| 76 |
Volume index |
| 77 |
Volume |
| 78 |
Length index |
| 79 |
Length |
| 80 |
Disp Rod index |
| 81 |
Disp Rod |
| 82 |
Level Offset index |
| 83 |
Level Offset |
| 84 |
Process Temp Value index |
| 85 |
Process Temp Value |
| 86 |
Proc Temp Offset index |
| 87 |
Proc Temp Offset |
| 88 |
Elect Temp Offset index |
| 89 |
Elect Temp Offset |
| 90 |
TTube Rate index |
| 91 |
TTube Rate |
| 92 |
Weight Units |
| 93 |
Grams, Units for weight of displacer. |
| 94 |
Kilograms, Units for weight of displacer. |
| 95 |
Pounds, Units for weight of displacer. |
| 96 |
Ounces, Units for weight of displacer. |
| 97 |
Weight of displacer as indicated on the nameplate |
| 98 |
Volume Units |
| 99 |
Liters, Units for volume of displacer. |
| 100 |
Cuin, Units for volume of displacer. |
| 101 |
mm3 |
| 102 |
cubic millimeters, Units for volume of displacer. |
| 103 |
ml |
| 104 |
millilites, Units for volume of displacer. |
| 105 |
volume of displacer as indicated on the nameplate |
| 106 |
Length Units |
| 107 |
Length of displacer as indicated on the nameplate |
| 108 |
Length of TT driver rod (CL of displacer to CL of TT).-------type 249:in-- mm¡ªA 2.50 63.5 C,CP 6.64 173. --type 249:in-- mm--,B,BP,W 8.00 203. L, Pp 9.01 229. K,n 10.51 267 .V(std) 13.51 343. V (custom) -as spcfd. |
| 109 |
Offset to align instrument PV with an independent external measurement. Available only in level or interface mode |
| 110 |
Offset added to process temperature measurement to trim output to an independent refrence |
| 111 |
Offset added to electronics temperature measurement to trim output to an independent refrence |
| 112 |
TTube Rate Units |
| 113 |
Units for Torque Tube Rate Based on the nameplate information or specification sheet |
| 114 |
lbf-in per deg |
| 115 |
lbf-in per deg, Units for Torque Tube Rate Based on the nameplate information or specification sheet |
| 116 |
newton-m per deg |
| 117 |
newton-m per deg, Units for Torque Tube Rate Based on the nameplate information or specification sheet |
| 118 |
dyne-cm per deg |
| 119 |
dyne-cm per deg, Units for Torque Tube Rate Based on the nameplate information or specification sheet |
| 120 |
compound torsion rate of torque tube pilot shaft and instrument flexure ¨Cdetermined by instrument during calibration if calibration is not possible at installation a theoretical value may be entered to get instrument operational |
| 121 |
Ref coupling Pt index |
| 122 |
Ref coupling Pt |
| 123 |
Trend Interval index |
| 124 |
Trend Interval |
| 125 |
Free Time index |
| 126 |
Free Time Pt index |
| 127 |
Free Time |
| 128 |
Level Sensor Limit index |
| 129 |
Level Sensor Limit |
| 130 |
Level Sensor Drive index |
| 131 |
Level Sensor Drive |
| 132 |
A/D Ref. Limit index |
| 133 |
A/D Ref. Limit |
| 134 |
Input Filter index |
| 135 |
Input Filter |
| 136 |
A/D Torque Tube index |
| 137 |
A/D Torque Tube |
| 138 |
PV Alrm Deadband index |
| 139 |
PV Alrm Deadband |
| 140 |
Temp Alrm Deadband index |
| 141 |
Temp Alrm Deadband |
| 142 |
Sensor Degrees |
| 143 |
Ref coupling Pt |
| 144 |
Angle of torque tube representing zero buoyancy condition of displacer primary adjustment of pv zero when impossible to mark this at zero buoyancy condition the trim pv zero command must be used to align pv measurement value with external reference |
| 145 |
Trend Interval |
| 146 |
Time between samples of trend parameter |
| 147 |
Free Time |
| 148 |
Microprocessor free time limit |
| 149 |
Limit for A/D reference voltage monito |
| 150 |
HALL sensor signal amplifier output |
| 151 |
change in torque tube deflection from coupling point typically between 0 and 6 det when coupling point is near the neutral lever position of 0 deg. |
| 152 |
HALL sensor bias current monitor (uA) |
| 153 |
Time constant for A/D convertor filter.Time to reach 63%of step input. |
| 154 |
Deadband for pv alarms pv must move inside threshold by deadband To clear alarm |
| 155 |
Deadband for clearing temperature alarms .valid range is 0 to 10 C,(18F) |
| 156 |
Alrm Enable |
| 157 |
Allows PV alarm to be turned on or off |
| 158 |
Lo-Lo Alrm Enable |
| 159 |
Lo Alrm Enable |
| 160 |
Hi-Hi Alrm Enable |
| 161 |
Hi Alrm Enable |
| 162 |
Temp Alrm Enable |
| 163 |
Allows temperature alarms to be turned on or off. |
| 164 |
Elect Temp Lo Alrm Enable |
| 165 |
Elect Temp Hi Alrm Enable |
| 166 |
Proc Temp Lo Alrm Enable |
| 167 |
Proc Temp Hi Alrm Enable |
| 168 |
Torque Tube Material |
| 169 |
Material the torque tube is constructed from .used to selet temperature coefficient table for torque tubecompensation |
| 170 |
304 SST (S30400) |
| 171 |
SST 316(S31600) |
| 172 |
N010276 |
| 173 |
Alloy 20 (No8020) |
| 174 |
INCONEL600 |
| 175 |
K-MONEL |
| 176 |
SS347 |
| 177 |
NO10665 |
| 178 |
NI3301 |
| 179 |
316Lss(S31603) |
| 180 |
304L SST(S30403) |
| 181 |
Incoloy 800 (No8800) |
| 182 |
UNKNOWN |
| 183 |
SPECIAL |
| 184 |
Instrument mounting |
| 185 |
Left of Displacer |
| 186 |
While looking at DLT9000 LCDisplay, DLT9000 will be either to left or right of the displacer. This determines positive sensor of torque tube rotation for increasing level. |
| 187 |
Right of Displacer |
| 188 |
Meter Installed |
| 189 |
Selects whether or not LC Display is installed. |
| 190 |
Not Installed |
| 191 |
Installed |
| 192 |
Display Type |
| 193 |
Slects from:a constant display of PV only;or %Range only; or alternating displays of :PV/ Process Temperature or PV/%Range. |
| 194 |
PV only |
| 195 |
PV/Elect Temp |
| 196 |
%Range only |
| 197 |
% Range only |
| 198 |
PV/%Range |
| 199 |
Decimal Places |
| 200 |
Number of digits after the decimal point to display. |
| 201 |
0 |
| 202 |
Number of digits after the decimal point to display.0 will autoscale the display. |
| 203 |
1 |
| 204 |
2 |
| 205 |
3 |
| 206 |
4 |
| 207 |
Trend Var |
| 208 |
Selects which variable to trend |
| 209 |
Off |
| 210 |
PV |
| 211 |
Process Temp RTD |
| 212 |
Configure and calibrate 100 ohm platinum RTD to measure process temperature for PV compensation. |
| 213 |
Close Current Out |
| 214 |
Nomarl |
| 215 |
0x03100030 index |
| 216 |
0x03100030 |
| 217 |
0x03100040 index |
| 218 |
0x03100040 |
| 219 |
0x03100050 index |
| 220 |
0x03100050 |
| 221 |
0x03080060 index |
| 222 |
0x03080060 |
| 223 |
0x03100000 index |
| 224 |
0x03100000 |
| 225 |
0x03100060 index |
| 226 |
0x03100060 |
| 227 |
0x03080000 index |
| 228 |
0x03080000 |
| 229 |
Degrees New |
| 230 |
DDry |
| 231 |
theoretical TT total deflection for dry displacer =weight *(driver rod )/TTRate |
| 232 |
F_buoy |
| 233 |
buoyant force = degreesnew * Rcor_div_l |
| 234 |
Rcor_div_L |
| 235 |
TTRate /(Driver rod ). Check against torque tube rate and driver rod |
| 236 |
SG_app |
| 237 |
apparent specific gravity =f_buoy/(displacer volume *H20_density) currently used only in density mode should be in the range of 0 to 1.5 |
| 238 |
Vol times dens |
| 239 |
Displacer volume *H20_density: Theoretical buoyant force of displacer when completely covered with water (@ SG=1) |
| 240 |
PV_norm |
| 241 |
In level mode amount of displacer volume (in3) covered by liquid in interface mode amount of displacer length(in)coverde by lower fluid, in Densigy mode fluid density (LB/in3) |
| 242 |
PV_abs |
| 243 |
PVnorm *length/volume |
| 244 |
Procv |
| 245 |
PVvalue(including level offset and displacer rise corrections in level and interface mode) |
| 246 |
SG of Lower Fluid |
| 247 |
Lower fluid SG adjusted for process temperature by user-entered table |
| 248 |
SG of Upper Fluid |
| 249 |
Upper fluid SG adjusted for process temperature by user-entered table |
| 250 |
Rcor |
| 251 |
AD Temp Scalar |
| 252 |
Mag Temp Corr |
| 253 |
Temperature correction for magnetic field strength and hall effect |
| 254 |
Displacer S/N index |
| 255 |
Displacer S/N |
| 256 |
Instrument S/N index |
| 257 |
Instrument S/N |
| 258 |
Serial Number of Instrument |
| 259 |
Serial Number of Displacer |
| 260 |
SG of Upper Fluid index |
| 261 |
SG of Lower Fluid index |
| 262 |
Torque Tube index |
| 263 |
Torque Tube |
| 264 |
Num index |
| 265 |
5 |
| 266 |
6 |
| 267 |
7 |
| 268 |
8 |
| 269 |
9 |
| 270 |
Temp |
| 271 |
torque_tube |
| 272 |
.6f |
| 273 |
8.6f |
| 274 |
trend index |
| 275 |
B |
| 276 |
Trend Value 0 |
| 277 |
Trend Value 1 |
| 278 |
Trend Value 2 |
| 279 |
Trend Value 3 |
| 280 |
Trend Value 4 |
| 281 |
Level index |
| 282 |
Interface index |
| 283 |
Density index |
| 284 |
Process Temp index |
| 285 |
Elect Temp index |
| 286 |
HC12 NVM |
| 287 |
Elect NVM |
| 288 |
Hall NVM |
| 289 |
Sensor Degree Offset index |
| 290 |
Sensor Degree Offset |
| 291 |
Sensor Degree Scale index |
| 292 |
Sensor Degree Scale |
| 293 |
Mag Temp Corr index |
| 294 |
Device ID index |
| 295 |
Device ID |
| 296 |
Index |
| 297 |
Mark Dry Coupling |
| 298 |
stores torque tube angle representing zero displacer buoyancy for the PV calculation. Displacer must be connected to torque tube, not resting on a travel stop, and the torque tube coupled to DLT9000 with shipping lock released before this command is executed.If impossible to mark at zero buoyancy condition, an offset to the PV will result, which must be removed by the trim zero command. |
| 299 |
Specific Gravity |
| 300 |
Allows entry of custom table of up to 10X,y pairs defining fluid SG vs. temperature by liner segments. |
| 301 |
Wet/dry Cal |
| 302 |
Use when an independent measurement of intermediate values of PV is not available for calibration, but dry and completely submerged displacer states can be achieved and identified. Requires prior entry of specific gravity of test fluid, volume of displacer, and displacer rod length. Small nonlinearities will be present at displacer endcaps. |
| 303 |
signle_piont_value |
| 304 |
Instrument Primary Variable expressed in Engineering Units.Valid only if sensor calibration has been completed and accurate displacer and process fluid data have been entered in instrument memory |
| 305 |
Single Point |
| 306 |
Use when PV condition can be independently measured but not adjusted for the calibration. The dry coupling point must be previously marked, either by isolating cage or by hanging an equivalent weight on the driver rod with the 249 off the process. Requires prior entry of specific gravity of test fluid(s), volume of displacer and displacer rod length. |
| 307 |
Trim Pv Zero |
| 308 |
Computers correction required to align the digital process value to an independent external observation. Necessary for corret PV reading if marked coupling point is not at dry displacer condition.should be performed after TT tate has been calibrated by one of the following methods: Weight-based, wet/dry, two point, or entering theoretical value of Ttrate in review menu. |
| 309 |
weight_based_cal_low_value |
| 310 |
Weight of displacer as indicated on the nameplate. |
| 311 |
weight_based_cal_up_value |
| 312 |
lower_limit_sg_value |
| 313 |
Weight-based Cal |
| 314 |
Use when other methods are impreactical ,and TT arm can be removed from process and moved to bench.calibrates Torque Tube Rate using external weights. |
| 315 |
two_point_low_value |
| 316 |
two_point_up_value |
| 317 |
Two Point |
| 318 |
Use when PV condition can be independently measured and adjusted for the calibration. Requires prior entry of specific gravity of test fluid(s), volume of displacer and displacer rod length. |
| 319 |
Need assistance |
| 320 |
Yes |
| 321 |
Selecting "Yes" will enable extra assistance screens |
| 322 |
No |
| 323 |
Direct |
| 324 |
Direct Acting :Fluid level increases as analog output increases from 4 to 20mA |
| 325 |
Reverse |
| 326 |
Reverse Acting :Fluid level decrease as analog output increases from 4 to 20mA |
| 327 |
Allows correction of SG values and TT rate for variations in process temperature If a 100ohm RTD is not installed in displacer/TT chamber then a user-entered value of process temperature can be supplied to the instrument. |
| 328 |
measurement_application |
| 329 |
Setup Wizard |
| 330 |
Guides user through initial configuration and calibration process |
| 331 |
Set Zero(4mA) |
| 332 |
Sets lower range value (4mA output) to the present internal PV value. Works like a zero control on an analog device- the span between upper and lower range values is preserved, so the URV moves also. This command does not adjust the internal PV calibration vs. the input condition ¨Conly the relationship between input condition ¨Conly the relationship between internal values and the output current. |
| 333 |
Set Span(20mA) |
| 334 |
Sets upper range value (20mA output) to the present internal PV value. Works like a span control on an analog device ¨C the existing lower range value will remain the same, only the span will be changed. This command does not adjust the internal PV calibration vs. the input condition ¨C only the relationship between internal PV values and output current. |
| 335 |
measure_level |
| 336 |
Instrument Primary Variable expressed in Engineering Units.Valid only if sensor calibration has been entered in instrument memory. |
| 337 |
Measure Spec Gr |
| 338 |
Provides an estimate of SG of a new process fluid by comparing internal PV value with external level measurement .assumes instrument has been calibrated with water |
| 339 |
Change Material |
| 340 |
Material the torque tube is constructed from.used to select temperature coefficient table for Torque Tube compensation. |
| 341 |
TTube Temp Coeff |
| 342 |
Allows entry of custom table of modulus of rigidity vs temperature normalized to unity at 70F (21¡ãC) for users torque tube material |
| 343 |
Read Trend |
| 344 |
Torque tube should be coupled to DLT9000 and the lock released displacer should be in the DRY position |
| 345 |
Meter |
| 346 |
Allows the LC meter to be tested by displaying different patterns. |
| 347 |
Display Alarms |
| 348 |
Reports any PV or temperature alarms that are active |
| 349 |
Check and reports status of instrument internal alarms. |
| 350 |
Save as factory |
| 351 |
restore to factory |
| 352 |
restore to default factory |
| 353 |
PV Range |
| 354 |
Hardware Alarms |
| 355 |
NVM |
| 356 |
Sensor Calibrate |
| 357 |
Temp. Calibration |
| 358 |
Guids user through initial configuration and calibration process. |
| 359 |
PV Setup |
| 360 |
PV & Temp Units |
| 361 |
Set Zero & Span |
| 362 |
Sensors |
| 363 |
Displacer |
| 364 |
Displacer Info |
| 365 |
Displacer Units |
| 366 |
Digital Proc Temp |
| 367 |
Allows manual entry of process Temperature value for PV temperature compensation when RTD is not installed. |
| 368 |
LCD Meter |
| 369 |
Configure Alarms |
| 370 |
Process Var |
| 371 |
Temperature |
| 372 |
Device Information |
| 373 |
HART |
| 374 |
Version Info |
| 375 |
Serial Numbers |
| 376 |
Trending |
| 377 |
Review |
| 378 |
Device Params |
| 379 |
Device Info |
| 380 |
Device Troubleshoo |
| 381 |
Factory Settings |
| 382 |
Common Tables |
| 383 |
Interoperable * |
| 384 |
Universal |
| 385 |
Common Practice |
| 386 |
Pressure Universal |
| 387 |
Pressure Common |
| 388 |
Menu |
| 389 |
Rosemount Magflow |
| 390 |
Rosemount Pressure |
| 391 |
Moore Products |
| 392 |
Siemens Pressure |
| 393 |
P2 Common |
| 394 |
Wireless |
| 395 |
Munge |
| 396 |
Analytical Oxygen/Combustion/Methane/CO |
| 397 |
Flow Totalizer - Rate Indicator |
| 398 |
Flow Variable Area |
| 399 |
Flow Coriolis Mass |
| 400 |
Flow Ultrasonic - Gas |
| 401 |
Flow Ultrasonic - Liquid |
| 402 |
Level Ultrasonic |
| 403 |
Level Radar - Microwave |
| 404 |
Pressure Absolute |
| 405 |
Level Capacitance |
| 406 |
Pressure Differential |
| 407 |
Level Hydrostatic |
| 408 |
Pressure Absolute/Relative |
| 409 |
Level Microwave |
| 410 |
Level Radar |
| 411 |
Level Density - Nuclear |
| 412 |
Flow Electromagnetic |
| 413 |
Flow Vortex |
| 414 |
Flow Magmeter - Rack Version |
| 415 |
Flow High Performance Magmeter |
| 416 |
Flow Mass |
| 417 |
Flow Ultrasonic |
| 418 |
Flow Magnetic |
| 419 |
Flow Magnetic - Custody Transfer |
| 420 |
Flow 2-wire Magnetic |
| 421 |
Flow Coriolis Mass - Custody Transfer |
| 422 |
Flow 2-wire Vortex |
| 423 |
Flow Thermal |
| 424 |
Temperature Head Mounted |
| 425 |
Temperature Compact |
| 426 |
Temperature DIN Rail Mounted |
| 427 |
Analytical pH |
| 428 |
Analytical Conductivity - Conductive |
| 429 |
Analytical Conductivity - Inductive |
| 430 |
Temperature Sensor |
| 431 |
Level Servo |
| 432 |
Temperature DIN Rail |
| 433 |
Analytical ORP |
| 434 |
Analytical pION |
| 435 |
Analytical IConc |
| 436 |
Analytical Electrode Conductivity |
| 437 |
Analytical Toroidal Conductivity |
| 438 |
Valve Positioner |
| 439 |
Valve Controller |
| 440 |
Pressure |
| 441 |
Pressure Multivariable |
| 442 |
Analytical pH/ORP |
| 443 |
Flow Coriolis |
| 444 |
Analytical Conductivity |
| 445 |
Valve Positioner/Pneumatic |
| 446 |
Valve Actuator - Electrical |
| 447 |
Temperature Dual Input |
| 448 |
Valve Actuator |
| 449 |
Analytical Corrosion |
| 450 |
Analytical Density - Nuclear |
| 451 |
Level Continuous Gamma |
| 452 |
Level Laser Ranging |
| 453 |
Pressure Safety |
| 454 |
Flow Vortex/Swirl |
| 455 |
Flow |
| 456 |
Analytical 4 Electrode Conductivity |
| 457 |
Analytical 2 Electrode Conductivity |
| 458 |
Analytical Troidal Conductivity |
| 459 |
Analytical pH/ORP/pIon/Ion Conc |
| 460 |
Analytical Oxygen |
| 461 |
Pressure P, dP + Multivariable |
| 462 |
Temperature 2-wire |
| 463 |
Pressure w/ PID |
| 464 |
Pressure Saturated Steam |
| 465 |
Analytical Density - Gamma Ray |
| 466 |
Level Gamma Ray |
| 467 |
Analytical Weight - Gamma Ray |
| 468 |
Level w/ Density - Gamma Ray |
| 469 |
Analytical Motorized Density |
| 470 |
Flow Multivariable Mass |
| 471 |
Temperature Multivariable |
| 472 |
Specialty HART-to-Analog Signal Conv |
| 473 |
Flow dP |
| 474 |
Pressure Low Power |
| 475 |
Pressure Certified SIL2 |
| 476 |
Interoperable |
| 477 |
Analytical Density |
| 478 |
Valve Positioner/Electropneumatic |
| 479 |
Flow Magnetic Inductive |
| 480 |
Analytical |
| 481 |
Analytical Opacity Monitor |
| 482 |
Analytical Oxygen/Combustion |
| 483 |
Analytical 2-wire Conductivity |
| 484 |
Analytical 2-wire Conductivity w/ pure H20 |
| 485 |
Analytical 2-wire Conductivity w/ % conc |
| 486 |
Analytical 2-wire Oxygen/Chlorine/Ozone |
| 487 |
Analytical 2-wire pH/ORP |
| 488 |
Analytical 2-wire Contacting/Toroidal |
| 489 |
Analytical Oxygen - High Temperature |
| 490 |
Analytical Conductivity w/ % conc |
| 491 |
Analytical pH/ORP/ISE |
| 492 |
Analytical Amperometric Analyzer |
| 493 |
Analytical Dual Input Analyzer |
| 494 |
Pressure Pressure/Level |
| 495 |
Analytical Consistency |
| 496 |
Analytical Microwave-Pulp Consistency |
| 497 |
Analytical Microwave Consistency |
| 498 |
Valve Digital Positioner |
| 499 |
Valve Smart Valve Positioner |
| 500 |
Temperature Differential |
| 501 |
Analytical Dissolved Oxygen |
| 502 |
Analytical pH Controller |
| 503 |
Analytical Conductivity/Resistivity Controller |
| 504 |
Analytical Conductivity/Resistivity |
| 505 |
Level Displacement |
| 506 |
Temperature w/ PID |
| 507 |
Valve Universal Positioner |
| 508 |
Level Radar - Reflex |
| 509 |
Pressure Gauge |
| 510 |
Pressure Sealed Gauge |
| 511 |
Valve Digital Positioner w/ PID |
| 512 |
Valve Intelligent Positioner |
| 513 |
Analytical Gas Detector |
| 514 |
Analytical Infrared Gas Detector |
| 515 |
Analytical Electrochemical Gas Detector |
| 516 |
Analytical Measuring Instruments |
| 517 |
Level Magnostrictive |
| 518 |
Valve On/Off Valve Controller |
| 519 |
Level Radar - Pulse |
| 520 |
Level Continuous Capactive |
| 521 |
Valve Damper Actuator |
| 522 |
Valve Electric Damper Actuator |
| 523 |
Flow Electronic |
| 524 |
Flow Vortex - Multiparameter Mass |
| 525 |
Analytical UV Flame Detector |
| 526 |
Analytical UVIR Flame Detector |
| 527 |
Analytical IR Flame Detector |
| 528 |
Analytical Fire Detector |
| 529 |
Analytical Gas Detector Display Interface |
| 530 |
Analytical Toxic Gas Detector |
| 531 |
Analytical Flame Detector |
| 532 |
Level Nuclear |
| 533 |
Analytical Microwave |
| 534 |
Analytical Density - Radiometric |
| 535 |
Level Radiometric |
| 536 |
Analytical Gas/Steam |
| 537 |
Level Nucleonic |
| 538 |
Analytical Blade Consistency |
| 539 |
Analytical Rotary Consistency |
| 540 |
Pressure Absolute/Differential |
| 541 |
Positioner |
| 542 |
Analytical Combustible Gas Detector |
| 543 |
Analytical Point Infrared Gas Detector |
| 544 |
Analytical Multi-Detector Monitor System |
| 545 |
Valve Positioner/Electro-hydraulic |
| 546 |
Valve Monitor |
| 547 |
Enable on token-passing data link layer only |
| 548 |
Enable on TDMA data link layer only |
| 549 |
Enable on both TDMA and token-passing data link layer |
| 550 |
WirelessHART Device |
| 551 |
IEEE 802.15.4 2.4GHz DSSS with O-QPSK Modulation |
| 552 |
Primary |
| 553 |
Primary Analog Channel |
| 554 |
Secondary |
| 555 |
Secondary Analog Channel |
| 556 |
Tertiary |
| 557 |
Tertiary Analog Channel |
| 558 |
Quaternary |
| 559 |
Quaternary Analog Channel |
| 560 |
Quinary |
| 561 |
Quinary Analog Channel |
| 562 |
Critical Power Failure |
| 563 |
Lock all |
| 564 |
Trim not supported |
| 565 |
Configuration cannot be changed |
| 566 |
Locked by gateway |
| 567 |
Analog Input Channel |
| 568 |
Analog Output Channel |
| 569 |
Secondary Analog Channel Saturated |
| 570 |
Tertiary Analog Channel Saturated |
| 571 |
Quaternary Analog Channel Saturated |
| 572 |
Quinary Analog Channel Saturated |
| 573 |
Secondary Analog Channel Fixed |
| 574 |
Tertiary Analog Channel Fixed |
| 575 |
Quaternary Analog Channel Fixed |
| 576 |
Quinary Analog Channel Fixed |
| 577 |
Simulation active |
| 578 |
The device is in simulation mode and the level output is not representative of the process. |
| 579 |
Non-Volatile memory failure |
| 580 |
The Non-Volatile memory check is invalid or maybe corrupt, or the battery of a battery-backed memory has failed. |
| 581 |
Volatile memory error |
| 582 |
The RAM memory check is invalid or maybe corrupt |
| 583 |
Watchdog reset executed |
| 584 |
A watchdog reset has been performed |
| 585 |
Voltage conditions out of range |
| 586 |
A voltage condition is outside its allowable range |
| 587 |
Environmental conditions out of range |
| 588 |
An internal or environmental condition is beyond acceptable limits. |
| 589 |
Electronic failure |
| 590 |
A hardware problem not related to the sensor has been detected. |
| 591 |
Subdevice list changed |
| 592 |
Duplicate master detected |
| 593 |
Capacity Denied |
| 594 |
The device was unable to acquire the communication bandwidth required to support the Burst Messaging specified |
| 595 |
Bandwidth allocation pending |
| 596 |
Block transfer pending |
| 597 |
Continuous |
| 598 |
The Burst Message is published continuously at (worst case) the Minimum Update Period. |
| 599 |
Window |
| 600 |
The Burst Message is triggered when the source value deviates more than the specified trigger value |
| 601 |
Rising |
| 602 |
The Burst Message is triggered when source value Rises Above the specified trigger value. |
| 603 |
Falling |
| 604 |
The Burst Message is triggered when the source value Falls Below the specified trigger value. |
| 605 |
On-change |
| 606 |
The Burst Message is triggered when any value in the message changes. |
| 607 |
Battery life |
| 608 |
Percent range |
| 609 |
Loop current |
| 610 |
Primary variable |
| 611 |
Secondary variable |
| 612 |
Tertiary variable |
| 613 |
Quaternary variable |
| 614 |
Enable event notification on token-passing data link layer |
| 615 |
Enable event notification on TDMA data link layer |
| 616 |
Enable event notification on TDMA and token-passing data link layer |
| 617 |
Configuration changed event pending |
| 618 |
Device status event pending |
| 619 |
More status available event pending |
| 620 |
Disable |
| 621 |
Enable single data point trending |
| 622 |
Enable filtered trending |
| 623 |
The sample is filtered using a time constant equal to one-third the trend sample period |
| 624 |
Enable average trending |
| 625 |
The value obtained by dividing the sum of all samples in the period by the total number of samples |
| 626 |
Read receive time |
| 627 |
Write date and time |
| 628 |
Non-Volatile Clock |
| 629 |
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. |
| 630 |
Clock Uninitialized |
| 631 |
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. |
| 632 |
Line Power |
| 633 |
Device is powered via a hardwired connection to a plant power source. |
| 634 |
Battery Power |
| 635 |
Device operates solely of its (internal) battery. |
| 636 |
Recharg.B./Power Sc. |
| 637 |
Rechargeable battery power or power scavenging. The device has a short-term supply of energy (must be at least one hour) that is continuously being replenished. The device's power is being replenished by harvesting and converting energy from the environment surrounding the device (e.g. solar, vibration, heat). |
| 638 |
Idle |
| 639 |
Active search |
| 640 |
Looking for neighbors. |
| 641 |
Negotiating |
| 642 |
Quarantined |
| 643 |
Operational |
| 644 |
Suspended |
| 645 |
Deep sleep |
| 646 |
Ultra-low power |
| 647 |
Wireless Signal Found |
| 648 |
Network packets have been recognized |
| 649 |
Wireless Signal Identified |
| 650 |
Wireless Time Synchronized |
| 651 |
WirelessHart Signal Identified |
| 652 |
Network Admission Requested |
| 653 |
Set on transmission of first join request |
| 654 |
Join Retrying |
| 655 |
Set after the first join request retry (i.e. when number of join requests > 2). Cleared when device is authenticated or when Active Search started. |
| 656 |
Join Failed |
| 657 |
Set on transition from Active Search mode to Deep Sleep mode. Cleared on transition from Deep Sleep to Active Search. |
| 658 |
Network Security Clearance Granted |
| 659 |
Network Manager Session Established |
| 660 |
Network Joined |
| 661 |
Network Joined. Normal superframe and links obtained. |
| 662 |
Network Bandwidth Requested |
| 663 |
Negotiating Network Properties. Gateway session obtained. |
| 664 |
Join Complete |
| 665 |
Normal operating mode. |
| 666 |
None |
| 667 |
No restrictions |
| 668 |
SI Only |
| 669 |
Restricted to SI Unit codes only |
| 670 |
Open - accept all devices |
| 671 |
Use Whitelist for access |
| 672 |
Use Blacklist |
| 673 |
Use Whitelist and Blacklist |
| 674 |
Lockdown - disable join links |
| 675 |
Process automation device |
| 676 |
Discrete device |
| 677 |
Hybrid:Process automation+discrete |
| 678 |
I/O System |
| 679 |
WirelessHART Process automation device |
| 680 |
WirelessHART Discrete device |
| 681 |
WirelessHART Process automation+discrete |
| 682 |
WirelessHART Gateway |
| 683 |
WirelessHART Access point |
| 684 |
WirelessHART Process adapter |
| 685 |
WirelessHART Discrete adapter |
| 686 |
WirelessHART enabled handheld/portable maintenance tool |
| 687 |
Don't attempt to join |
| 688 |
Join now |
| 689 |
Attempt to join immediately on powerup or reset |
| 690 |
US |
| 691 |
United States of America |
| 692 |
JP |
| 693 |
Japan |
| 694 |
DE |
| 695 |
Germany |
| 696 |
FR |
| 697 |
France |
| 698 |
ES |
| 699 |
Spain |
| 700 |
RU |
| 701 |
Russian Federation |
| 702 |
CN |
| 703 |
People's Republic of China |
| 704 |
Nominal |
| 705 |
Device Power Status is nominal |
| 706 |
Low |
| 707 |
Device Power Status is low |
| 708 |
Critically Low |
| 709 |
Device Power Status is critically low |
| 710 |
Recharging - Low |
| 711 |
Recharging - High |
| 712 |
Secondary Master |
| 713 |
Primary Master |
| 714 |
PV Analog Channel Saturated |
| 715 |
PV Analog Channel Fixed |
| 716 |
Device Profile |
| 717 |
Device Diagnostic Status 0 |
| 718 |
Device Diagnostic Status 1 |
| 719 |
I/O and Subdevice Status |
| 720 |
WirelessHART Status |
| 721 |
Time Set Option |
| 722 |
Real Time Clock Flags |
| 723 |
Country |
| 724 |
Country of intended device installation |
| 725 |
SI Unit Control |
| 726 |
Indicates if device should only display SI unit codes |
| 727 |
Burst Trigger Units |
| 728 |
Burst Trigger Class |
| 729 |
Wired HART Enabled |
| 730 |
Enabled on Wired HART device connection only |
| 731 |
Wireless HART Enabled |
| 732 |
Enabled on WirelessHART device connection only |
| 733 |
Both Wired and WirelessHart Enabled |
| 734 |
Enabled on both Wired and WirelessHART connections |
| 735 |
Burst Msg Trigger Mode |
| 736 |
Event Status |
| 737 |
Event Notification Control |
| 738 |
Operate mode Mask |
| 739 |
Not Defined |
| 740 |
Power Source |
| 741 |
Power source of the device |
| 742 |
Wireless Mode |
| 743 |
Join Status |
| 744 |
The current location in the joining sequence of operations. |
| 745 |
Network Access Mode |
| 746 |
Join Mode |
| 747 |
Power Status |
| 748 |
Power status of the device |
| 749 |
Master Mode |
| 750 |
This sets the I/O System's Data Link Layer operation on all channels as either primary or secondary master mode. |
| 751 |
Trend Units |
| 752 |
Trend Device Variable Unit Code |
| 753 |
Trend Classification |
| 754 |
Trend Device Variable Classification |
| 755 |
Trend Control |
| 756 |
Device Status Mask |
| 757 |
Ext dev status Mask |
| 758 |
Device Diagnostic Status 0 Mask |
| 759 |
Device Diagnostic Status 1 Mask |
| 760 |
Device Diagnostic Status 2 Mask |
| 761 |
Device Diagnostic Status 3 Mask |
| 762 |
AO saturated Mask |
| 763 |
AO fixed Mask |
| 764 |
Latched Device Status |
| 765 |
Latched Ext dev status |
| 766 |
Latched Operate Mode |
| 767 |
Latched Device Diagnostic Status 0 |
| 768 |
Latched Device Diagnostic Status 1 |
| 769 |
Latched Device Diagnostic Status 2 |
| 770 |
Latched Device Diagnostic Status 3 |
| 771 |
Latched AO saturated |
| 772 |
Latched AO fixed |
| 773 |
Wireless Module Device Type |
| 774 |
Device type of the Wireless Radio |
| 775 |
Wireless Module Manufacturer ID |
| 776 |
Manufacturer of the Wireless Radio contained in this device |
| 777 |
Subdevice Device Type |
| 778 |
Device type of the subdevice attached to this system. |
| 779 |
Subdevice Manufacturer Id |
| 780 |
Manufacturer of the subdevice attached to this system. |
| 781 |
Time Stamp |
| 782 |
Relative time value on network |
| 783 |
8u |
| 784 |
Dynamic Variables Returned for Device Variables |
| 785 |
Command Response Truncated |
| 786 |
Configuration Change Counter Mismatch |
| 787 |
Status bytes mismatch |
| 788 |
Device Variable |
| 789 |
Variable to trim |
| 790 |
New coupling point marked (zaro reference for buoyancy calculation) |
| 791 |
To improve accurancy fo the PV measurement perform one of the sensor calibrations listed in menu |
| 792 |
Input Specific Gravity of Fluid |
| 793 |
Adjuest liquid level until displacer is dry |
| 794 |
Is Displacer completely out of the fluid? |
| 795 |
Adjust liquid level until displacer is completely submerged. |
| 796 |
Is Displacer completely submerged? |
| 797 |
Torque Tube Rate Calibrated.Loop may be returned to AUTO |
| 798 |
Mark Coupling point at dry condition or Trim PV zero to sight glass reading to complete sensor calibration. |
| 799 |
To set relationship of 4 to 20mA output to internal PV ,set LRV and URV in PV range menu. |
| 800 |
Torque Tube Rate Calibrated Failed.Loop may be returned to AUTO |
| 801 |
Yes;No |
| 802 |
This trim procedure provides a technique to precisely calibrate the sensor |
| 803 |
The dry coupling point must already be marked,as it provides the initial data point. |
| 804 |
The level of the fluid must be non-zero and able to be measured independently |
| 805 |
If the fluid level cannot be measured please abort now,or press ok to continue. |
| 806 |
Allow the fluid level to stabilize ,with the displacer at least partially submerged. |
| 807 |
Enter externally measured Level intcurrent PV unit |
| 808 |
Enter externally measured Level in current PV unit |
| 809 |
Range values should be checked as the new offset will affect the pv value. |
| 810 |
Finished with offset trim procedure.Loop may be returned to AUTO. |
| 811 |
All references to weight are in kgrams |
| 812 |
Lower Limit SG |
| 813 |
Upper Limit SG |
| 814 |
Place a weight on the displacer rod of approximately: %{f_weight_dry} kg |
| 815 |
Actual value of the weight |
| 816 |
Couple DLT9000 to Torque Tube ,(if not already coupled),and release the lock |
| 817 |
Place a weight on the displacer rod of approximately: %{f_weight_wet} kg |
| 818 |
This trim procedure provides a thchnique to precisely calibrate the sensor |
| 819 |
To perform this ,the level of the fluid must be able to be measured independently |
| 820 |
If the fluid lever cannot be measured please abort now,or press ok to continue. |
| 821 |
Adjuest the fluid level to a position near the top or bottom of the displace |
| 822 |
Adjuest the fluid level to a position near the bottom or top of the displacer,opposite prior position |
| 823 |
Adjuest the fluid level to a position near the top or bottom of the displacer |
| 824 |
Single Value for SG or Table Vs Temp? |
| 825 |
Single Point;Table of SG vs T |
| 826 |
Specific Gravity of Process Fluid |
| 827 |
Upper Specific Gravity of Process Fluid |
| 828 |
Lower Specific Gravity of Process Fluid |
| 829 |
The temperature compensation tables for SG will hold up to 10 temperature/SG entries |
| 830 |
If less than 10 entries are needed,enter "0.0"for the SG value of the final entry |
| 831 |
Once created,the table may be reviewed or modified using:
Basic Setup->
PV Setup->
Specific Gravity-> |
| 832 |
Enter SG vs. Temperature. |
| 833 |
Enter temp for point %{choice1} Lower Table |
| 834 |
Enter SG for point %{choice1} at temp %{1} Lower Table(Enter "0.0"to terminate) |
| 835 |
Enter Upper SG vs. Temperature. |
| 836 |
Enter temp for point %{choice1} Upper Table |
| 837 |
Enter Upper SG for point %{choice1} at temp %{1} Upper Table(Enter "0.0"to terminate) |
| 838 |
Enter Lower SG vs. Temperature. |
| 839 |
Enter Lower SG for point %{choice1} at temp %{1} Lower Table(Enter "0.0"to terminate) |
| 840 |
Displacer Length Units |
| 841 |
Displacer Weight Units |
| 842 |
Displacer volume Units |
| 843 |
Displacer Length |
| 844 |
Displacer Weight |
| 845 |
Displacer Volume |
| 846 |
Mement Arm Length |
| 847 |
If using water or weights,enter SG =1.For other test fluids,enter SG of fluid used. |
| 848 |
After calibrating in level mode ,the instrument can be switched to interface or density mode.... |
| 849 |
then enter actual process fluid specific gravity(s) and range values as required. |
| 850 |
If calibrating in the actual process fluid(s) at operating conditions ,the final mode and/ or fluid SG must be selected now. |
| 851 |
Selectn Measurement Application |
| 852 |
WARN-Remove loop from automatic control before sending. You may return loop to automatic control after sending. |
| 853 |
The lower and upper range values are being set based on displacer size. |
| 854 |
The lower and upper range value (LRV/URV)are the PV values at 4~20 mA loop current |
| 855 |
These range values may be edited after choosing the units for pv. |
| 856 |
In a reverse acting, instrument ,the loop current will decrease as fluid level increases. |
| 857 |
Do you wish to make the instrument direct or reverse acting? |
| 858 |
Engineering Units for PV |
| 859 |
Upper Range Value (PV Value at 20mA) |
| 860 |
Lower Range Value (PV Value at 4mA) |
| 861 |
Alarm values are being set to the following values: |
| 862 |
Span=ABS(URV-LRV)
Hihi alarm=100% span
Hi alarm=95% span
Lo alarm=5% span
LoLo alarm=0% span |
| 863 |
Alarm Deadband is being reset to zero |
| 864 |
Alarm must be enabled to operate ,only HiHi and LoLo affect analog output |
| 865 |
Use the Configure Alarms menu to enable and edit the alarms |
| 866 |
Do you wish to use process temperature compensation? |
| 867 |
Load the Torque Tube Rate Table with Defaults? |
| 868 |
Finished with Torque Tube Material |
| 869 |
TTube Temp Comp Table |
| 870 |
Enter New Table;Review New Table;Edit a Table Entry;Load K-Monel Table;Exit |
| 871 |
The temperature compensation tables will hold up to 10 temperature/TT_Coeff entries |
| 872 |
If less than 10 entries "0.0" for the TT_Coeff value of the final entry |
| 873 |
Enter temp for point %{choice1} Torque Tube Corr |
| 874 |
Enter normalized modulus for point %{choice1} at Temp %{1} (Enter "0.0"to terminate) |
| 875 |
degC correction
%{choice1}: %{0} %{1} |
| 876 |
Edit a Table Entry |
| 877 |
Edit Entry 1;Edit Entry 2;Edit Entry 3;Edit Entry 4;Edit Entry 5;Edit Entry 6;Edit Entry 7;Edit Entry 8;Edit Entry 9;Edit Entry 10;Exit |
| 878 |
Next step in normal use is to Mark Coupling Point under Sensor Calibrate Menu. |
| 879 |
Lower Specific Gravity Must be greater than Upper Specific Gravity. |
| 880 |
Finished with Setup Wizard |
| 881 |
This function will use the current PV as the Lower Range value. |
| 882 |
The span from LRV to URV will remain the same .press OK when ready. |
| 883 |
New Lower Range Value Marked.Loop may be returned to AUTO |
| 884 |
This function will use the current PV as the upper Range value. press OK when ready. |
| 885 |
New Upper Range Value Marked.Loop may be returned to AUTO |
| 886 |
This procedure provides a technique to measure Specific Gravity. |
| 887 |
The level of the fluid must be non-zero and able to be measured independently . |
| 888 |
If the fluid level cannot be measured ,please abort now ,or press OK to continue |
| 889 |
The dry coupling point must already be marked ,as it provides the initial data point. |
| 890 |
If the coupling point was not marked with the liquid at the bottom of the displacer ,please abort now. |
| 891 |
Enter externally measured Level in current PV units |
| 892 |
Calculated SG is %{1} |
| 893 |
Updata Instrument with this value ? |
| 894 |
Finished with SG Measurement. Loop may be returned to AUTO |
| 895 |
Finished with Tarque Tube Material. |
| 896 |
Value0: %{0}
Value1: %{1}
Value2: %{2}
Value3: %{3}
Value4: %{4}
|
| 897 |
Select Display Mode |
| 898 |
Turn Cells Off;Turn Cells On |
| 899 |
Press OK to end Meter Test and return to normal |
| 900 |
No Alarms Set |
| 901 |
Would you like to save as factory setting? |
| 902 |
Succeeded in saving as factory setting. |
| 903 |
Failed to save as factory setting. |
| 904 |
Would you like to restore to factory setting? |
| 905 |
Succeeded in restoring factory Setting. |
| 906 |
Failed to restore factory Setting. |
| 907 |
Would you like to restore to default factory setting? |
| 908 |
Succeeded in restoring to default factory Setting. |
| 909 |
Failed to restore to default factory Setting. |
| 910 |
Trim will be Scaled From 4.000 to 20.000 |
| 911 |
Procced;Change |