Coriolis Mass Flow Meter P Series High Precision Coriolis Mass Flow Meter Xi an Tosilon Automation Co., Ltd No.299, Daqing Rd, Lianhu District, Xi'an Shaanxi, China Tel: +86-29-8823 8550 info@tosilon.com; www.tosilon.com Component Parts of P Series Coriolis Mass Flow Meter P Series Coriolis Mass Flow Meter is defined as P Series Mass Flow Meter with Flow Accuracy Rate of 0.1, consisting of "P Series Mass Flow Sensor" and "DPT Transmitter" Features and Benefits of P Series Coriolis Mass Flow Meter - Double U or Double C Measuring Tube Design - Gas Measurement Available - Easy Installation, no need rectifier, filter parts, no special requirements for installing direct pipe section. - High Stability, no need deploying frequent disassemble calibration - Allow Low-Range Run, reducing pressure loss and energy consumption & waste - Integrated Installation saving installation cost - High Stability, expert in "Custody Transfer / Fiscal Metering of Oil & Gas" Selection Principle - In the application of Coriolis Mass Flow Meter, the Max. Flow is decided by "Pressure Loss", while the Min. Flow by "Measurement Accuracy". - When selecting the instrumentation, please refer to this manual, and please provide data associated to the application such as accuracy requirement, flow range, pressure loss, density, viscosity, which ensures the correct selection and application.
Performance Index Liquid Flow Rate Performance Index Max. Mass Flow Rate Sensor Type Mass Flow (kg/h) Volumetric Flow [1] (l/h) P10 1,000 1,000 P15 3,000 3,000 P20 6,300 6,300 P25 17,000 17,000 P50 63,000 63,000 P80 160,000 160,000 P100 360,000 360,000 P150 550,000 550,000 P200 1,100,000 1,100,000 P250 1,800,000 1,800,000 Mass Flow Accuracy [2] 15:1, Within Measure Ratio [3] ±0.1% 15:1, Beyond Measure Ratio ± (Zero Stability / Instant Flow Rate) x 100% Volume Flow Accuracy [2] Whole Measure Range ±0.15± (Zero Stability / Instant Flow Rate) x 100% Repeatability 15:1, Within Measure Ratio ±0.05% 15:1, Beyond Measure Ratio ±1/2 (Zero Stability / Instant Flow Rate) x 100% Zero Stability Sensor Type kg/h P10 0.10 P15 0.30 P20 0.63 P25 1.70 P50 6.30 P80 16.0 P100 36.0 P150 55.0 P200 110.0 P250 180.0 [1]. The criterion of volume flow is as per density 1000kg/m 3. Regarding to the process liquid density isn't 1000kg/m 3, the value of volume flow is value of maximum mass flow divided by liquid density. [2]. Flow Accuracy includes repeatability, linearity and comprehensive effect of delay. [3]. Measure Ratio is defined as the value of maximum flow divided by minimum flow.
Typical Accuracy, Measure Ratio and Pressure Drop of P50 matched DPT100 Transmitter Performance Index Measure Ratio(from the maximum flow) 20:1 15:1 5:1 1.5:1 1:1 Accuracy ±% 0.14 0.1 0.1 0.1 0.1 Pressure Drop MPa 0.001 0.002 0.02 0.1 0.23 Remark: When the maximum flow rate exceeds the given flow rate range, the noise from the pipe will affect the accuracy. Gas Measurement Performance Mass Flow Accuracy Mass Flow Repeatability flow rate>zero stability/0.005 ± 0.5% flow rate<zero stability/0.005 ± (Zero Stability/Instant Flow Rate) 100% flow rate>zero stability/0.005 ± 0.25% flow rate<zero stability/0.005 ± 1/2(Zero Stability/Instant Flow Rate) 100% Standard Volume In most application areas, customers are used to use standard volume-determining the volume under pressure and temperature, standard volume also called as standard quality flow unit to the fixed component liquid. Applied to the density under standard condition (receiving from reference data), flow meter would be output under the configuration of standard volume unit, which means that could be calculated between measured liquid quality and entrained liquid standard density, but no need the compensation of pressure, temperature and density. Pressure Loss Loss of pressure is affected by the sensor geometric form, gas density and flow rate. While customers are suggested that the sensor loss of pressure couldn't surpass 0.127Mpa when design type selection. Flow Rate The flow rate of gas measure is much greater than the flow rate of liquid measure, the higher flow rate leads to the noise will affect the signal of flow meter. So the flow rate within sensor pipe should be lower 0.5 time than sounds rate when the loss of pressure of flow meter under 0.127Mpa.
Performance Index Accuracy and Loss of Pressure Data Samples of P50 Type Flow Meter Measure Different Medium Under Different Pressure Density Performance Index (only liquid) Accuracy [1] ± 0.001 g/cc ± 1.0 kg/m 3 Repeatability ± 0.0005 g/cc ± 0.5 kg/m 3 Measuring Range 0.2 3.0 g/cc 200 3000 kg/m 3 [1]: Flow Accuracy includes repeatability, linearity and comprehensive effect of delay, density accuracy index of ± 1 kg/m3 is calculated under the condition of 20 Deg. C and 1-2 bar water.
Performance Index Temperature Performance Index Accuracy All Types ± 0.5 Deg. C Repeatability All Types ± 0.2 Deg. C Temperature Limits [2] All Types match all Devices Electronics Options [2]. Temperature Limits maybe need explosion Protection for further limit because installation in hazardous area, reference page9. The Temperature must be heated to the local ambient temperature between -40 to 55 Deg. C (such as using steam tracing way) when the temperature below -40 Deg. C. Temperature Range Measured (Deg. C) Liquid Temperature Measured (Deg. C) Ambient Temperature (Deg. C) -50 350 (PT100) Integrated Installation -40 125 Divided Installation -40 350 Storage -40 70 Application -40 55 Power Supply & Power Consumption Match DPT100 Maximum 10W For sensor P100 P150 P200 P250, the power amplifiers should be provided with extra power supply. 220VAC (or 24VDC) power supply Maximum 30W (20W) Note: The DC Starting Current of Flow Meter is Less Than 1A (Without Power Amplifier).
Environmental Influence Process Temperature Influence Process Temperature Influence (Process Temperature Influence is defined as below) Regarding to Mass Flow Measurement, Process Temperature Influence is the maximum zero variation which is caused by the Process temperature depar tures zero coordinate temperature. Regarding to Density Measurement, Process Temperature Influence is the maximum measure variation which is caused by the Process temperature departures density calibrated temperature. Process Temperature Influence Sensor Type %Maximum Flow Rate Value/ o C Density Accuracy/ o C (kg/m) P10 ± 0.000125 ± 0.015 P15 ± 0.000125 ± 0.015 P20 ± 0.000125 ± 0.015 Maximum Accuracy P25 ± 0.000125 ± 0.015 P50 ± 0.0005 ± 0.015 P80 ± 0.0005 ± 0.015 P100 ± 0.00075 ± 0.015 P150 ± 0.00025 ± 0.015 P200 ± 0.00025 ± 0.015 P250 ± 0.00025 ± 0.015 Pressure Influence Pressure Influence Pressure Influence is defined as The variation of sensor flow and density is caused by process liquid departures calibrated pressure. Pressure Influence can be modified. Sensor Type Flow Accuracy Influenced by Pressure [1] Density Accuracy Influenced by Pressure [1] %Flow Value / MPa kg/m 3 / MPa P10 - - P15 - +0.58 P20 - -0.29 P25-0.03-0.87 P50-0.01 +0.145 P80-0.25 +0.029 P100-0.58-1.45 P150-0.35-0.41 P200-0.20-0.37 P250-0.14-0.21 The Data is achieved from pressure influence of flow rate, the specific value is as per the value of sensor nameplate. The maximum calibrated pressure we apply in our factory is 0.4MPa.
Usage Limits Pressure Rating Flow Tube Pressure Rating Sensor Type Standard Pressure-Proof MPa Max. Pressure-Proof MPa P10 4 6.3 P15 4 6.3 P20 4 6.3 P25 4 6.3 P50 4 6.3 P80 4 6.3 P100 4 6.3 P150 4 6.3 P200 4 6.3 P250 4 6.3 The pressure (the unlisted temperature can be calculated by the linear insert method) should be lowered down as per the follow terms if operating temperature surpass 148 Deg. C: 316L Sensor Measuring Tube 304 Sensor Less than 148 No need No need To 204 o C Lower down 7.2% Lower down 5.4% To 260 o C Lower down 13.8% Lower down 11.4% To 316 o C Lower down 19.2% Lower down 16.2% To 343 o C Lower down 21.0% Lower down 18.0% To 371 o C Lower down 22.8% Lower down 19.2% Vibration Limits In accordance with GB/T2423.11 to bear 50 periods at the condition of a=1g (g=9.8m 2 /s), (20-500) Hz Frequency-scanned. Suggested to apply divided installation if the application area vibration surpass a=0.5g Safety & Protection Tested and issued certification by National Explosive-proof Electrical Products Quality Supervising and Testing Center Explosion-proof Mark: P10 ~ P80 Ex ib IIC T3-T6 P100~P250 Ex d ib IIC T6 Gb Explosion-proof Certification No.: P10~P80 CNEx 10.0468 P100~P250 CNEx 12.2660 Protection Class: IP67 (Sensor)
Usage Limits T group refers to the maximum surface temperature of the sensor at the working temperature of 55 Deg. C Explosion-proof performance is accordance with GB3836.1-2010, GB3836.3-2010, GB3836.4-2010 Applications: T1~T6 group explosive dangerous location 1 zone and 2 zone, device class llc, downward compatibility lla, IIB The ex-proof performance will not be affected by the installation of sensor and transmitter(separated or integrated).
Structure Material Wetted Part Measuring Tube 00Cr17Ni14Mo2 (316L) Separated Liquid Flange Cover Sensor 0Cr18Ni9 (304) Transmitter Junction Box 0Cr18Ni9 (304) or 00Cr17Ni14Mo2 (316L) 0Cr18Ni9 (304) or 00Cr17Ni14Mo2 (316L) Casted aluminum alloy(coated polyester epoxy) Casted aluminum alloy(coated polyester epoxy) Structure Parameter Weight Weight Supplied: GB / T9115.1 2000 The weight of Steel pipe welding neck flanges with male and female face flow meter for PN 40. counts. All weights as per (kg) for Sensor Type Integrated Installation (kg) Divided Installation (kg) P10 9.5 6.5 P15 10.5 7.5 P20 14.0 11.0 P25 24.0 21.5 P50 50.0 46.0 P80 89.0 P100-208.0 P150-248.0 P200-365.0 P250-580.0
Dimension P10 Integrated Installation Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face Flange (HG/T20592-2009) A B L C H E M I D F 15 4.0 162 320 170 223 436 76 14 65 95 180 Flange (ASME B16.5) A B L C H E M I D F 15 300 190 320 170 223 436 76 16 66.5 95 180
P10 Divided Installation Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face. Flange (HG/T20592-2009) A B L C H E M I D 15 4.0 162 320 170 223 357 76 14 65 95 Flange (ASME B16.5) A B L C H E M I D 15 300 190 320 170 223 357 76 16 66.5 95
P15 Integrated Installation Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face Flange (HG/T20592-2009) A B L C H E M I D F 15 4.0 162 370 190 250 458 94 14 65 95 180 Flange (ASME B16.5) A B L C H E M I D F 15 300 190 370 190 250 458 94 16 66.5 95 180
P15 Divided Installation Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face. Flange (HG/T20592-2009) A B L C H E M I D 15 4.0 162 370 190 250 379 94 14 65 95 Flange (ASME B16.5) A B L C H E M I D 15 300 190 370 190 250 379 94 16 66.5 95
P20 Integrated Installation Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face Flange (HG/T20592-2009) A B L C H E M I D F 25 4.0 202 480 265 337 540 114 14 85 115 180 Flange (ASME B16.5) A B L C H E M I D F 25 300 246 480 265 337 540 114 18 89 125 180
P20 Divided Installation Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face. Flange (HG/T20592-2009) A B L C H E M I D 25 4.0 202 480 265 337 460 114 14 85 115 Flange (ASME B16.5) A B L C H E M I D 25 300 246 480 265 337 460 114 18 89 125
P25 Integrated Installation Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face Flange (HG/T20592-2009) A B L C H E M I D F 40 4.0 274 615 295 383 563 146 18 110 150 180 Flange (ASME B16.5) A B L C H E M I D F 40 300 320 615 295 383 563 146 22 114.5 155 180
P25 Divided Installation Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face. Flange (HG/T20592-2009) A B L C H E M I D 40 4.0 274 615 295 383 513 146 18 110 150 Flange (ASME B16.5) A B L C H E M I D 40 300 320 615 295 383 513 146 22 114.5 155
P50 Integrated Installation Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face Flange (HG/T20592-2009) A B L C H E M I D F 50 (Standard) 4.0 562 460 595 702 930 201 18 125 165 180 65 (Option) 4.0 570 460 595 702 903 201 18 145 185 180 Flange (ASME B16.5) A B L C H E M I D F 50 (Standard) 300 606 460 595 702 930 201 18 127 165 180 65 (Option) 300 620 460 595 702 930 201 22 149 190 180
P50 Divided Installation Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face Flange (HG/T20592-2009) A B L C H E M I D 50 (Standard) 4.0 562 460 595 702 847 201 18 125 165 65 (Option) 4.0 570 460 595 702 903 201 18 145 185 Flange (ASME B16.5) A B L C H E M I D 50 (Standard) 300 606 460 595 702 847 201 18 127 165 65 (Option) 300 620 460 595 702 847 201 22 149 190
P80 Mass Flow Sensor Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face Flange (HG/T20592-2009) A B C D E F H I M 80 (Standard) 4.0 850 774 937 200 214 277 310 160 18 100 (Option) 4.0 864 774 937 235 214 277 310 190 22 Flange (ASME B16.5) A B C D E F H I M 80 (Standard) 300 892 774 937 210 214 277 310 168.5 22 100 (Option) 300 904 774 937 255 214 277 310 200 22
P100 Mass Flow Sensor Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face Flange (HG/T20592-2009) A B C D E H I M n 100 (Standard) 4.0 890 824 1135 235 264 285 190 22 8 150 (Option) 4.0 910 824 1135 300 264 285 250 26 8 Flange (ASME B16.5) A B C D E H I M n 100 (Standard) 300 932 824 1135 255 264 285 200 22 8 150 (Option) 300 956 824 1135 320 264 285 270 22 12
P150 Mass Flow Sensor Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face Flange (HG/T20592-2009) A B C D E H I M n 150 (Standard) 4.0 1090 950 1050 300 290 285 250 26 8 200 (Option) 4.0 1116 950 1050 375 290 285 320 30 12 Flange (ASME B16.5) A B C D E H I M n 150 (Standard) 300 1136 950 1050 320 290 285 270 22 12 200 (Option) 300 1162 950 1050 380 290 285 330 26 12
P200 Mass Flow Sensor Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face Flange (HG/T20592-2009) A B C E F H M I D n 200 (Standard) 4.0 1211 1005 1415 380 290 285 30 320 375 12 250 (Option) 4.0 1245 1005 1415 380 290 285 33 385 450 12 Flange (ASME B16.5) A B C E F H M I D n 200 (Standard) 300 1257 1005 1415 380 290 285 26 330 380 12 250 (Option) 300 1269 1005 1415 380 290 285 29.5 387.5 445 16
P250 Mass Flow Sensor Note: listed flanges in the above form are steel pipe welding neck flanges with male and female face Flange (HG/T20592-2009) A B C E F H M I D n 250 (Standard) 4.0 1370 1120 1690 450 320 328 33 385 450 12 300 (Option) 4.0 1390 1120 1690 450 320 328 33 450 515 16 Flange (ASME B16.5) A B C E F H M I D n 250 (Standard) 300 1394 1120 1690 450 320 328 29.5 387.5 445 16 300 (Option) 300 1420 1120 1690 450 320 328 32.5 451 520 16
Note: For P100, P150, P200, P250, the ambient temperature of the power amplifiers is -20 ~ 55 (Deg. C), it is not allowed to cover or wrap, nor apply heat tracing to the power amplifiers in the process of heat tracing, otherwise the interior components will be damaged.
Order Guide Item Code Description Instrumentation Series P Precise Coriolis Mass Flow Meter 10 1,000 kg/h 15 3,000 kg/h 20 6,300 kg/h 25 17,000 kg/h Sensor Type Transmitter Type Sensor Type Power Supply Process Connection Type Process Connection Dimension 50 63,000 kg/h 80 160,000 kg/h 100 360,000 kg/h 150 550,000 kg/h 200 1,100,000 kg/h 250 1,800,000 kg/h W000 None D100 DPT100 [Accuracy 0.1,Chinese interface,ip65,exde[ib]iict6,divided installation] D101 DPT100 [Accuracy 0.1,Chinese interface,ip65,exde[ib]iict6,integrated installation] D102 DPT100 [Accuracy 0.1,English interface,ip65,exde[ib]iict6,divided installation] D103 DPT100 [Accuracy 0.1,English interface,ip65,exde[ib]iict6,integrated installation] D104 DPT100 [Accuracy 0.1,Russian interface,ip65,exde[ib]iict6,divided installation] D105 DPT100 [Accuracy 0.1,Russian interface,ip65,exde[ib]iict6,integrated installation] B 316L & 304 Stainless Steel, Temperature-Resistance 250 o C C 316L Stainless Steel, Temperature-Resistance 350 o C R 316L Stainless Steel, Steam Heat Tracking Type D 316L & 304 Stainless Steel, Electric Heating Tracing L 316L Stainless Steel H Hastelloy C22 T Special Requirement 0 None 1 18 VDC 36 VDC 2 85 VAC 265 VAC 3 Smart Power 4 Sensor 220 VAC; Transmitter 24 VDC A GB/T9115.1-2000 RF; Welding Neck Flange 4 MPa RF C GB/T9115.1-2000 RF; Welding Neck Flange 6.3 MPa RF E HG/T20615-2009 RF; Welding Neck Flange Class300 WN-RF F ASME B16.5-1988 RF; Welding Neck Flange Class150 WN-RF G ASME B16.5-1988 RF; Welding Neck Flange Class300 WN-RF I HG/T20592-2009 RF; Welding Neck Flange 4 MPa WN-RF T Special Request B DN 15 D DN 25 F DN 40 G DN 50 H DN 65 I DN 80 J DN 100
Accessory Electrical Connection Communication & Data Collection Methods Measurement Mode L DN 150 M DN 200 N DN 250 O DN 300 T As Requests 0 None 1 10m Cable 2 Carbon steel flange, bolt and nut, Metal gasket, 10m Cable 3 Stainless steel flange, bolt and nut, Metal gasket, 10m Cable 4 Carbon steel flange, bolt and nut, Metal gasket 5 Stainless steel flange, bolt and nut, Metal gasket 9 As requests W None M M20 N 1/2 NPT P 3/4 NPT G G 1/2 E G 3/4 T As request 0 None 1 Active circulation (4~20mA), Active frequency (0~10KHz), RS-485 2 Active circulation (4~20mA), RS-485 3 Active frequency (0~10KHz), RS-485 4 Passive frequency (0~10KHz), RS-485 5 Active circulation (4~20mA), Active frequency (0~10KHz), Passive HART 6 Active circulation (4~20mA), Active frequency (0~10KHz), Active HART 7 Passive frequency (0~10KHz), Active HART 9 As request G Custody Transfer / Fiscal Metering Type B Standard Measurement Type D Gas Measurement Type (Accuracy 0.35) Z Undefined