North Carolina State Univ., Reactor Thermal Power and Scram Setpoint Determination

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REACTOR THERMAL POWER AND SCRAM SETPOINT DETERMINATION Nuclear Reactor Program NORTH CAROLINA STATE UNIVERSITY RALEIGH, NORTH CAROLINA 27695 LICENSE NO. R-120 DOCKET NO. 50-297 11-FEBRUARY-2020

1 INTRODUCTION The following uncertainty and safety system setpoint calculations have been performed according to the general guidance and methodology provided in NRC Reg Guide 1.105[1]. Total one-sigma uncertainties calculated for the flow and temperature channels include terms for standard calibration uncertainty and all channel process module uncertainties. Uncertainty terms are summed in quadrature and result in total one-sigma uncertainties of 1.31% for the flow channel and 1.12%

for the temperature channels. Flow and temperature values are then utilized to determine true reactor power as detailed below.

2 FLOW MEASURING SYSTEM UNCERTAINTIES The nominal volumetric flow rate for the primary coolant system is 1000 gpm. Converting to a mass flow rate, assuming a temperature of 100°F, yields:

= 1000

x 60

x 8.2877

= 497262

EQ 1 The flow measuring system consists of an annubar sensor and transmitter, a panel meter, and a recorder. A precision manometer is used during the calibration procedure.

Annubar System (sensor and transmitter) 1 = Uncertainty = +/-0.8%[2]

Calibration Manometer 2 = Uncertainty = +/-0.025 in-H2O (resolution of ruler scale)

Where 1000 gpm = 9.265 in-H2O[3]

0.025 inH2O/9.265 in-H2O = 0.27%

Simpson Hawk 3 Panel Gauge (Model Number: H345-3-71-2-4-2) 3 = Input Module Uncertainty = +/-0.05% [4]

4 = Output Module Uncertainty = +/-0.05% [4]

Readings would be at 1000 gpm Yokogawa Recorder 5 = Input Module Uncertainty (0-10 volts) = +/-0.05% [5]

Reading would be at 1000 gpm Averaging Flow Measurement Uncertainty 6 = 5-minute average - Standard Deviation = 1.0%

Total Flow Measuring System Uncertainty:

= (1 )2 + (2 )2 + (3 )2 + (4 )2 + (5 )2 + (6 )2 EQ 2

= (. 008)2 + (. 0027)2 + (. 0005)2 + (. 0005)2 + (. 0005)2 + (. 01)2 EQ 3

= 1.31%

EQ 4 Using the conversion from Equation 1, the total flow measuring system uncertainty in units of mass flow rate yields,

= 1.31% x 497262

= 6514

EQ 5 3 TEMPERATURE MEASURING SYSTEM UNCERTAINTIES A primary coolant temperature of 37.8°C (100°F) is assumed.

The temperature measuring system consists of Pt-100 RTDs, transmitters, and a recorder. A precision Pt-100 calibration RTD is used during the calibration procedure.

Transmitter System Uncertainty [6]

Digital Accuracy - +/- 0.10°C D/A Conversion Accuracy (+/- 0.02% of 100°C span) - +/- 0.02°C Digital Accuracy Ambient Temperature Effect - +/- 0.015°C D/A Conversion Accuracy Ambient Temperature Effect - +/- 0.01°C 1 = Total System Uncertainty = +/- 0.10°C = +/- 0.18°F = 0.18%

Calibration RTD 2 = Calibration RTD Uncertainty [7] = +/- 0.5°F = 0.5%

Temperature Recorder 3 = Input Module Uncertainty (4-20 volts) = +/-0.3% of reading at 100°F [5]

Averaging Temperature Measurement Uncertainty 4 = 5-minute average - Standard Deviation = +/- 0.5%

Total Temperature Measuring System Uncertainty:

= (1)2 + (2)2 + (3)2 + (4)2 EQ 6

= (0.0018)2 + (. 005)2 + (. 003)2 + (. 005)2 EQ 7

= 0.79%, = 0.79%

EQ 8 A differential temperature of 13.8°F across the core equates to 2 MW reactor core power. Therefore, the uncertainty in the differential temperature calculation is:

2 =

2

+

2 EQ 9

2 = (0.0079)2 + (0.0079)2 EQ 10

= 1.12%

EQ 11

= 1.12% x 13.8= 0.15 EQ 12 4 REACTOR THERMAL POWER UNCERTAINTY The reactor thermal power can be calculated using the following equation:

= ()

EQ 13

where,

=

= ( 1) = 497262

= = 0.998

= = 13.8 Reactor power can be calculated using the average data including their associated uncertainties.

The error of the calculation can be expressed as:

2 =

2 2

+

2

2 EQ 14

where,

= ()

EQ 15

=

EQ 16

=

= ( 5) = 6514

= ( 12) = 0.15 Using Equation 14 and substituting to calculate the uncertainty in reactor power:

2 =

2 ()

2

+

2 2

EQ 17

2 = (65142) 0.998

(13.8) 2

+ (0.15)2 (497262)

0.998

2 EQ 18

= 1.18 x 105

= 0.0345 EQ 19 Therefore, at a thermal power of 2 MW the uncertainty is:

= 0.0345 2

= 1.73%

2= 0.069 2

= 3.45%

5 DETERMINATION OF OPERATING LIMITS AND SETPOINTS (2)

As shown above, the total 2 uncertainty for true reactor power is 3.45%. This value is utilized to determine the Limiting Safety System Settings (LSSS) and maximum Safety System Setting (SSSmax) and is summarized in Table 1 below. The maximum setpoint for the scram channel also has to account for the 0.5% measurement uncertainty of that channel[8], therefore the maximum scram setpoint would be 1.92 MW. For operational purposes the actual scram setpoint will be 1.90 MW.

Table 1 - Setpoints for 2 MW Forced Convection Mode Power Level Description

= 2.0 Maximum power level allowed by license.

= 2.0 Maximum safety system setpoint for power level

= 2.0 (2.0 3.45%) = 1.93 Maximum safety system setpoint for power level accounting for the total power calibration uncertainty at the 2-sigma level.

= 1.93 (2.0 0.5%) = 1.92 Maximum safety system setpoint for power level accounting SCRAM channel uncertainty.

= 2.0 (2.0 5.0%) = 1.90 Actual safety system setpoint for SCRAM.

= 2.0 (2.0 7.5%) = 1.85 Actual safety system setpoint for Reverse Drive.

= 2.0 (2.0 10.0%) = 1.80 Nominal operating power level.

6

REFERENCES:

[1]

Regulatory Guide 1.105 Setpoints for Safety-Related Instrumentation, Revision 3, US Nuclear Regulatory Commission, December 1999.

[2]

Rosemount 3051 SF DP Flowmeters, Product Data Sheet, Part# 00813-0100-4485, Rev GA, Table 5, Page 36, June 2017, Emerson Process Management, Rosemount Inc., Chanhassen, MN.

[3]

3051 SFA - Annubar Flowmeter Calculation Data Sheet, Tag No. Enercon, 8/21/2012

[4]

Simpson Hawk 3 Operators Manual Part# 06-117287, Edition 13, Table 1-2, Page 9, April 2016, Simpson Electric Company, Lac du Flambeau, MI.

[5]

Yokogawa GX90XA I/O Module General Specifications, GS 04L53B01-01EN, 4th Edition, Page 2, October 27, 2014, Yokogawa Electric Corporation, Japan.

[6]

Rosemount 3144P Temperature Transmitter, Reference Manual, Part# 00809-0100-4021, Rev GB, July 2012, Emerson Process Management, Rosemount Inc., Chanhassen, MN.

[7]

NIST Traceable RTD Calibration Certificate.

[8]

Wide Range Linear Signal Processor, Instruction Manual No.222B Rev2, Gamma-metrics, Feb 1995.

Reactor Thermal Power and SCRAM Setpoint Determination Appendix A - References North Carolina State University PULSTAR Reactor 11-FEB-2020

36 Rosemount DP Flow February 2017 Emerson.com/Rosemount Specifications Performance specifications Performance assumptions include: measured pipe I.D, transmitter is trimmed for optimum flow accuracy, and performance is dependent on application parameters.

Table 4. Multivariable Flow Performance - Flow Reference Accuracy (Measurement Type 1)(1)(2) 1.

Measurement types 2-4 assume the unmeasured variables are constant. Additional uncertainty will depend on the variation in the unmeasured variables.

2.

Range 1 flowmeters experience an additional uncertainty up to 0.9 percent. Consult your Emerson Representative for exact specifications.

Rosemount 3051SFA Annubar Flowmeter Classic MV (8:1 flow turndown)

Ultra for flow (14:1 flow turndown)

Ranges 2-3

+/-1.15% of flow rate

+/-0.80% of flow rate Rosemount 3051SFC_A Compact Annubar Flowmeter - Rosemount Annubar option A Classic MV (8:1 flow turndown)

Ultra for flow (14:1 flow turndown)

Ranges 2-3 Standard

+/-1.60% of flow rate

+/-1.55% of flow rate Calibrated

+/-1.00% of flow rate

+/-0.80% of flow rate Rosemount 3051SFC Compact Orifice Flowmeter - Conditioning option C Classic MV (8:1 flow turndown)

Ultra for flow (14:1 flow turndown)

Ranges 2-3

+/-1.45% of flow rate

+/-1.15% of flow rate Rosemount 3051SFC Compact Orifice Flowmeter - Orifice option P(3) 3.

For line size less than 2-in. (50 mm) or greater than 8-in. (200 mm), add an additional 0.5 percent uncertainty.

Classic MV (8:1 flow turndown)

Ultra for Flow (14:1 flow turndown)

Ranges 2-3

= 0.4

+/-1.45% of flow rate

+/-1.30% of flow rate

= 0.50, 0.65

+/-1.45% of flow rate

+/-1.30% of flow rate Rosemount 3051SFP Integral Orifice Flowmeter Classic MV (8:1 flow turndown)

Ultra for flow (14:1 flow turndown)

Ranges 2-3

< 0.1

+/-2.65% of flow rate

+/-2.60% of flow rate 0.1 <

< 0.2

+/-1.60% of flow rate

+/-1.40% of flow rate 0.2 <

<0.6

+/-1.25% of flow rate

+/-0.95% of flow rate 0.6 <

< 0.8

+/-1.80% of flow rate

+/-1.60% of flow rate Table 5. Flow Performance - Flow Reference Accuracy (Measurement Type D)(1)(2)(3)

Rosemount 3051SFA Annubar Flowmeter Classic (8:1 flow turndown)

Ultra (8:1 flow turndown)

Ultra for flow (14:1 flow turndown)

Ranges 2-3

+/-1.25% of flow rate

+/-0.95% of flow rate

+/-0.80% of flow rate Rosemount 3051SFC_A Compact Annubar Flowmeter - Rosemount Annubar option A Classic (8:1 flow turndown)

Ultra (8:1 flow turndown)

Ultra for flow (14:1 flow turndown)

Ranges 2-3 Uncalibrated

+/-1.70% of flow rate

+/-1.65% of flow rate

+/-1.55% of flow rate Calibrated

+/-1.25% of flow rate

+/-0.95% of flow rate

+/-0.80% of flow rate Rosemount 3051SFC Compact Orifice Flowmeter - Conditioning option C Classic (8:1 flow turndown)

Ultra (8:1 flow turndown)

Ultra for flow (14:1 flow turndown)

Ranges 2-3

+/-1.40% of flow rate

+/-1.25% of flow rate

+/-1.15% of flow rate Rosemount 3051SFC Compact Orifice Flowmeter - Orifice Option P(4)

Classic (8:1 flow turndown)

Ultra (8:1 flow turndown)

Ultra for Flow (14:1 flow turndown)

Ranges 2-3

= 0.4

+/-1.80% of flow rate

+/-1.35% of flow rate

+/-1.30% of flow rate

= 0.65

+/-1.80% of flow rate

+/-1.35% of flow rate

+/-1.30% of flow rate

REFERENCE 2

Engineering Report Burlington Reactor Piping Upgrade Appendix 5, Rev. 0 Page 7 of 7 GENERAL DATA Customer:

ROSEMOUNT INC.

3051SFA - Annubar Flowmeter CALCULATION DATA SHEET Project:

Pavelka FY12 Q3 S. O. No:

P. O. No:

Calc. Date:

Model No:

3051SFADL100CSHPS2T100032AA1A2 Tag No:

Enercon PRODUCT DESCRIPTION Product Type:

Sensor Size:

Pak-Lok Sensor Size 2 Instrument Valve:

Valve Material:

Wetted Material:

316 Stainless Steel Line Size: 10-in. (250 mm)

Transmitter Conn.:

Direct-Mount, Integral 3-valve Manifold Pipe Sch.: 40 Mounting Conn. Material:

Mounting Type:

INPUT DATA 316 Stainless Steel Compression/Threaded Connection Pipe Orientation: Horizontal Fluid Type:

Liquid Wall:

0.365 inch Fluid Name:

WATER Pipe I.D. (Span):

10.020 inch Body I.D.:

10.020 inch Base Pressure:

14.696 psia Duct W idth:

inch Base Temperature:

60.00 F Pressure:

22.000 psig Temperature at Flow:

100.00 F Absolute Viscosity:

0.68120 cP Base Density:

62.3800 lb/ft3 Isentropic Exponent:

Atmospheric Pressure:

14.696 psia Compressibility at Flow:

Density at Flow:

62.0046 lb/ft3 Flow Rates Minimum:

500.00 USGPM Normal:

1000.00 USGPM Maximum:

2000.00 USGPM Full Scale:

2000.00 USGPM CALCULATED DATA (Calculation Performed atttNormal C o oon nnd ddiittii o oon nns ss.. DP iinn inH2O@68F)

DP at Min Flow:

2.316 inH2O@68F Flow Coefficient:

0.5754 DP at Normal Flow:

9.265 inH2O@68F DP at Max Flow:

37.060 inH2O@68F Rod Reynolds Number (Minimum):

24327 DP at Full Scale Flow:

37.060 inH2O@68F Rod Reynolds Number (Normal):

48654 Resonant Frequency:

468 Hz Gas Expansion Factor:

Wake Frequency:

9 Hz Permanent Pressure Loss:

Blockage:

0.13 at Normal Flow:

1.25 inH2O@68F at Maximum Flow:

4.99 inH2O@68F Velocity at Max Flow:

8.13 ft/sec GUIDELINES Primary Element Min Limit:

256.92 USGPM Recommended Min Rod Reynolds Number:

12500 Structural Limit (Flow):

8281.80 USGPM Recommended Min DP:

0.250 inH2O@68F Structural Limit (DP):

635.5 inH2O@68F Max. Allow. Pressure@Temp.:

1440.0 psig 100 F Max. Allow. Temp.:

500 F Design Pressure/Temperature:

22.00 psig 100.00 F WARNINGS NOTES This report is provided according to the terms and conditions of the Instrument Toolkit(TM) End-Use Customer License Agreement. Version:

3.0 (Build177A)

Printed On:

21-Aug-2012 REFERENCE 3

RS-485 Specications (only available on H345) 2 wire / Half duplex, Baud rate: 9600 baud, 1ms delay per character, 32 Nodes Maximum on Bus. Opti-cally and magnetically isolated for ground loop elimination MECHANICAL Bezel 3.92 x 2.0 x 0.52 (99.8mm x 51.9mm x 132mm)

Depth 3.24 (82.3mm) behind panel Panel cutout 3.62 x 1.77 (92mm x 45mm) 1/8 DIN Weight 10 oz. (283.5 g)

Cover NEMA 4X Rated front panel ELECTRICAL Accuracy Listed as % of reading at 25°C. Add 100ppm/°C to compensate for drift.

Tested at 50Hz, include +/-1 count for every 100Hz above 50 Hz Transient Overvoltage Installation Category III, Pollution Degree 2 Analog Output Sampling Rate = 100 mSec. Reaction Time 0 to Full Scale = 10 Sec Table 1 - 1 Input Board Type Range Resolution 4-1/2 Resolution 3-1/2 Input Impedance Overload Accuracy 4-1/2 Accuracy 3-1/2 DC Voltage V

m 0

0 2

10 V

.1 mV 1M 5 DCV

+/-.05% of reading +/- 1 count

+/-.1% of reading +/- 1 count V

2

.1 mV 1 mV 1M 5 DCV

+/-.05% of reading +/- 1 count

+/-.1% of reading +/- 1 count 20 V 1 mV 10 mV 1M 300 DCV

+/-.05% of reading +/- 1 count

+/-.1% of reading +/- 1 count 200 V 10 mV

.1 V 1M 300 DCV

+/-.05% of reading +/- 1 count

+/-.1% of reading +/- 1 count 600 V

.1 V 1 V 1M 1K DCV

+/-.1% of reading +/- 1 count

+/-.2% of reading +/- 1 count Table 1 - 3 Input Board Type Range Resolution 4-1/2 Resolution 3-1/2 Input Impedance Overload Accuracy 4-1/2 Accuracy 3-1/2 AC Voltage (Same for TRMS

• @ 60 Hz)

V m

0 0

2 10 V

.1 mV 200K 5 DCV

+/-.05% of reading +/- 1 count

+/-.1% of reading +/- 1 count V

2

.1 mV 1 mV 200K 5 DCV

+/-.05% of reading +/- 1 count

+/-.1% of reading +/- 1 count 20 V 1 mV 10 mV 1M 300 DCV

+/-.05% of reading +/- 1 count

+/-.1% of reading +/- 1 count 200 V 10 mV

.1 V 1M 300 DCV

+/-.05% of reading +/- 1 count

+/-.1% of reading +/- 1 count 600 V

.1 V 1 V 1M 1K DCV

+/-.1% of reading +/- 1 count

+/-.2% of reading +/- 1 count Table 1 - 2 Input Board Type Range Resolution 4-1/2 Resolution 3-1/2 Input Impedance Overload Accuracy 4-1/2 Accuracy 3-1/2 DC Current 200 A

10 nA

.1 A 1K 4.5 mA DC

+/-.05% of reading +/- 1 count

+/-.1% of reading +/- 1 count A

m 2

.1 A 1 A 100 45 mA DC

+/-.05% of reading +/- 1 count

+/-.1% of reading +/- 1 count 20 mA 1 A 10 A 10 200 mA DC

+/-.05% of reading +/- 1 count

+/-.1% of reading +/- 1 count 200 mA 10 A

.1 mA 1

600 mA DC

+/-.05% of reading +/- 1 count

+/-.1% of reading +/- 1 count 2 A

.1 mA 1 mA

.013 5.5 A DC

+/-.2% of reading +/- 1 count

+/-.3% of reading +/- 1 count 5 A 1 mA 10 mA

.013 5.5 A DC

+/-.2% of reading +/- 1 count

+/-.3% of reading +/- 1 count Table 1 - 4 Input Board Type Range Resolution 4-1/2 Resolution 3-1/2 Input Impedance Overload Accuracy 4-1/2 Accuracy 3-1/2 AC Current (Same for TRMS

• @ 60 Hz) 200 A

10 nA

.1 A 1K 4.5 mA DC

+/-.1% of reading +/- 1 count

+/-.2% of reading +/- 2 count A

m 2

.1 A 1 A 100 45 mA DC

+/- 1% of reading +/- 2 count

+/-.2% of reading +/- 2 count 20 mA 1 A 10 A 10 200 mA DC

+/-.1% of reading +/- 2 count

+/-.2% of reading +/- 2 count 200 mA 10 A

.1 mA 1

600 mA DC

+/-.1% of reading +/- 2 count

+/-.2% of reading +/- 2 count 2 A

.1 mA 1 mA

.013 5.5 A DC

+/-.2% of reading +/- 2 count

+/-.3% of reading +/- 2 count 5 A 1 mA 10 mA

.013 5.5 A DC

+/-.2% of reading +/- 2 count

+/-.3% of reading +/- 2 count 9

REFERENCE 4

• INPUT/OUTPUT MODULE SPECIFICATIONS ANALOG INPUT MODULE (Model GX90XA or GX/GP main unit options /UxxO)

Number of inputs: 1 O Input Type:

Suffix Code Input Type

-U2 DC voltage, standard signal. thermocou~e (TC), resistance temperature detector (RTO), DI (voltage, contact), and OC current (by adding an external shunt resistor)

-C1 DC current (mA). OC current standard signal (4-20 mA)

-L1 OC voltage. standard signal, thermocouple (TC). DI (voltage. contact).

and OC current (by adding an external shunt resistor)

-T1 OC vottage, standard signal, thermocouple (TC). DI (voltage, contact),

and DC rurrent (by adding an extemaJ shunt resistor)

Description Universal Current input Low withstand voltage relay Electromagnetic relay Measurement interval: 100 *1 *2. 200 *1 *2. 500 ms*1, 1, 2, 5 s GX90XA Input range: -5% or more and 105% or less (accuracy is guaranteed in the range from 0% to 100% inclusive)

Measurement ranges and accuracies*3 (However. the number of display digits can be increased by scaling.)

' 1 Cannot be specified for the electromagnetic relay scanner type (Type Suffix Code: -T1 ).

'2 Cannot be specified for L-model DCVffC/DI, scanner type (Type Suffix Code: -L 1).

• 3 The following specifications apply to operation or the recorder under standard operation conditions.

Temperature: 23 +/- 2 ' C. Humidity: 55% +/- 10% RH. Power supply voltage: 90 to 132 or 180 to 264 VAC, Power supply frequency: 50/60 Hz +/- 1 %. VVarm-up time: At least 30 min. Other ambient conditions such as vibration should not adversely affect recorder operation.

Input Type Rango Measurement range Measurement accuracy (digital display)

Mox.

2 resolution of AID integration time: 16.7ms or more AJDintegr.rtiontimo: 1.67ms digital display ocv 20mV

-20000 to 20.000mV

+/-(0.05 % of rdg + 12 µV)

+/-(0. 1 % of rdg

• 40 µV) 1 µV 60mV

-6000 to 60.00mV

+/-(0.05 % of rdg + 0.03 mV)

+/-(0.1 o/o of rdg+0.15mV) 10µV 200 mV

-200.00 to 200.00mV

+/-(0.05 % of rdg + 0.03 mV)

+/-(0. 1 % of rdg + 0.4 mV) 10µV 1V

-1.0000 to 1.0000V

+/-(0.05 % of rdg + 1.2 mV)

+/-(0. 1 % ofrdg

• 4 mV) 100µV 2V

-20000 to 2.0000V t(0.05 % ofrdg + 1.2 mV)

+/-(0.1 % of rdg + 4 mV) 100 µV 6V

,6.000 to 6.000V

+/-(0.05 % of rdg

• 3 mV)

+/-(0.1 % ofrdg+ 15mV) 1mV 20V

-20000 to 20.000V

+/-(0.05 % of rdg + 3 mV)

+/-(0. 1 % of rdg + 40 mV) 1mV SO V

-5000 to SO.DOV

+/-(0.05 % of rdg + 0.03 V)

+/-(0.1 % of rdg + 0.15V) 10mV Standard signal 0.4-2V 0.3200 to 2.0800V

+/-(0.05 % of rdg + 1.2 mV)

+/-(0.1 % ofrdg+4mV) 100µV 1-5V 0800 to 5.200V

+/-(0.05 % of rdg + 3 mV)

+/-(0. 1 % of rdg + 15 mV) 1mV OCcixrent 0-20mA 0000 to 20.000mA

+/-(0.3 % of rdg + 5 µA)

+/-(0.3 % of rdg + 90 µA) 1 µV DC current 4-20mA 3.200 to 20.800mA (standard s,gnal TC R *4 0.0 to 1760.0 "C

+/-(0.15 % ofrdg+ 1.0 "C) t(0.2 % of rdg + 6.0 ' C) 0.1 *c (Exdud1ng RJC 5 "4 However, R, S. 0.0 to 800.0 ' C +/-2.2 'C, However. R. S. 0.0 to 800.0 ' C* +/-7.6 ' C.

accuracy) 0.0 to 11so.o *c B, 400.o to 800.o *c: +/-3.o *c B, 400.0 to 800.0 ' C +/-11.0 'C 9 '4 0.0 to 18200' C Accuracy at less than 400.0 *c 1s not guaranteed Accuracy at less than 400.0 °C is not guaranteed K "4

-270.0 to 13100 *c

+/-(0.15 % of rdg + 0.7 ' C) t(0.2 % of rdg + 5.0 ' C) 0.1 *c

• 200.0 soo.o *c However. -200.0 to 0.0 *c. +/-(0.35 % of rdg + 0.7 "C)

However, -200.0 to 0.0 ' C: 1(3 % of rdg

• 5.0 ' C) to Accuracy at less than -200.0 *c IS not gua,anteed Accuracy at less than -200.0 *c rs not guaranteed E "4

-270.0 to 800.o *c

+/-(0. 15 % of rdg + 0.5 ' C)

+/-(0.2 % of rdg + 4.0 ' C) o 1 *c J *4

-200.0 1100.o *c However. -200.0 to 0.0 'C: +/-(0.35 % of rdg + 0.5 'C)

However. -200.0 to 0.0 *c : 1(2 % of rdg

• 4.0 ' C) to Accuracy at less than -200.0 *c IS not guaranteed Accuracy at less lhan -200.0 *c is not guaranteed T -4

-270.0 to 400.0 ' C

+/-(0. 15 % of rdg + 0.5 'C)

+/-(0.2 % of rdg + 2.5 ' CJ 0.1 *c However, -200.0 to 0.0 'C: +/-(0.35 % of rdg + 0.5 ' C)

However. -200.0 to 0.0 *c : 1(2 % of rdg + 2.5 ' C)

A<curacy at less than -200.0 *c,. not guaranteed Acc... cy at less than -200 o *c IS not guaranteed N "4

-270.0 to 1300o*c

+/-(0. 15 o/, of rdg + 0.7 ' C)

+/-(0.3 % of rdg + 6.0 ' C) 0.1 *c However. -200.0 to 0.0 'C: 1(0.7 % of rdg + 0.7 C)

However, -200.0 lo 0.0 *c : 1(5 % of rdg + 6.0 ' C)

Accuracy at less than -200.0 *c 1s not guaranteed Accuracy at less than -200.0 *c IS not guaranteed w "5 0.0 to 2315.o *c

+/-(0. 15 % ofrdg + 1.5 ' C)

+/-(0.3 % of rdg + 14.0 ' C) o 1 C However. more than 1000.0 *c 1(0.8 % of rdg

• 9.0'C)

L "6

-200.0 to 900.o *c

+/-(0.15 % ofrdg + 0.5 ' C)

+/-(0.2 % of rdg + 4.0 ' C) o 1 *c Less than o.o *c * +/-(0.5 % of rdg + 0.5 ' C)

Less than 0.0 ' C: +/-(3 % of rdg + 4.0 ' C) u "6

-200.0 to 400.0 "C

+/-(0.15 % ot rdg + 0.5 ' C)

+/-(0.2 % of rdg + 2.5 'C) o 1 *c Less than 0.0 *c : +/-(0.7 % of rdg + 0.5 ' C)

Less than 0.0 ' C: +/-(3 % of rdg + 2.5 ' C)

\\'.fle3-25 0.0 to 2320.0 "C

+/-(0.2 % of rdg + 2.5 'C)

+/-180 ' C 01 *c

'7 More U,an 2000.0 ' C* +/-0.9 % of rdg All Rights Reserved. Copyright ~ 2014, Yokogawa Electric Corporation GS 04L53B0 1-01EN Oct. 27, 2014-00 REFERENCE 5

Specifications and Reference Data 181 Specifications and Reference Data April 2017 Reference Manual 00809-0100-4021, Rev JA Transmitter accuracy Sensor options Sensor reference Input ranges Minimum span(1)

Digital accuracy(2)

Enhanced accuracy (3)

D/A accuracy(4)(5) 2-, 3-, 4-wire RTDs

°C

°F

°C

°F

°C

°F

°C Pt 100

( = 0.00385)

IEC 751

-200 to 850

-328 to 1562 10 18

+/-0.10

+/-0.18

+/-0.08

+/-0.02% of span Rosemount' X-well' Pt 100

( = 0.00385)

IEC 751

-50 to 300

-58 to 572 10 18

+/-0.29

+/-0.52 N/A

+/-0.02% of span Pt 200

( = 0.00385)

IEC 751

-200 to 850

-328 to 1562 10 18

+/-0.22

+/-0.40

+/-0.176

+/-0.02% of span Pt 500

( = 0.00385)

IEC 751

-200 to 850

-328 to 1562 10 18

+/-0.14

+/-0.25

+/-0.112

+/-0.02% of span Pt 1000

( = 0.00385)

IEC 751

-200 to 300

-328 to 572 10 18

+/-0.10

+/-0.18

+/-0.08

+/-0.02% of span Pt 100

( = 0.003916)

JIS 1604

-200 to 645

-328 to 1193 10 18

+/-0.10

+/-0.18

+/-0.08

+/-0.02% of span Pt 200

( = 0.003916)

JIS 1604

-200 to 645

-328 to 1193 10 18

+/-0.22

+/-0.40

+/-0.176

+/-0.02% of span Ni 120 Edison Curve No. 7

-70 to 300

-94 to 572 10 18

+/- 0.08

+/- 0.14

+/-0.64

+/-0.02% of span Cu 10 Edison Copper Winding No. 15

-50 to 250

-58 to 482 10 18

+/-1.00

+/-1.80

+/-0.08

+/-0.02% of span Pt 50

(=0.00391)

GOST 6651-94

-200 to 550

-328 to 1022 10 18

+/-0.20

+/-0.36

+/-0.16

+/-0.02% of span Pt 100

(=0.00391)

GOST 6651-94

-200 to 550

-328 to 1022 10 18

+/-0.10

+/-0.18

+/-0.08

+/-0.02% of span Cu 50

(=0.00426)

GOST 6651-94

-50 to 200

-58 to 392 10 18

+/-0.34

+/-0.61

+/-0.272

+/-0.02% of span Cu 50

(=0.00428)

GOST 6651-94

-185 to 200

-301 to 392 10 18

+/-0.34

+/-0.61

+/-0.272

+/-0.02% of span Cu 100

(=0.00426)

GOST 6651-94

-50 to 200

-58 to 392 10 18

+/-0.17

+/-0.31

+/-0.136

+/-0.02% of span Cu 100

(=0.00428)

GOST 6651-94

-185 to 200

-301 to 392 10 18

+/-0.17

+/-0.31

+/-0.136

+/-0.02% of span Thermocouples(6)

Type B(7)

NIST Monograph 175, IEC 584 100 to 1820 212 to 3308 25 45

+/-0.75

+/-1.35 N/A

+/-0.02% of span Type E NIST Monograph 175, IEC 584

-50 to 1000

-58 to 1832 25 45

+/-0.20

+/-0.36 N/A

+/-0.02% of span Type J NIST Monograph 175, IEC 584

-180 to 760

-292 to 1400 25 45

+/-0.25

+/-0.45 N/A

+/-0.02% of span Type K(8)

NIST Monograph 175, IEC 584

-180 to 1372

-292 to 2501 25 45

+/-0.25

+/-0.45 N/A

+/-0.02% of span Type N NIST Monograph 175, IEC 584

-200 to 1300

-328 to 2372 25 45

+/-0.40

+/-0.72 N/A

+/-0.02% of span Type R NIST Monograph 175, IEC 584 0 to 1768 32 to 3214 25 45

+/-0.60

+/-1.08 N/A

+/-0.02% of span REFERENCE 6

Specifications and Reference Data 183 Specifications and Reference Data April 2017 Reference Manual 00809-0100-4021, Rev JA Ambient temperature effect Table A-1. Ambient Temperature Effect Sensor options Digital accuracy per 1.0 °C (1.8 °F) change in ambient(1)(2)

Range D/A effect(3) 2-, 3-, or 4-wire RTDs Pt 100 ( = 0.00385) 0.0015 °C (0.0027 °F)

Entire sensor input range 0.001% of span Rosemount X-well Pt 100

( = 0.00385) 0.0058 °C (0.0104 °F)

Entire sensor input range 0.001% of span Pt 200 ( = 0.00385) 0.0023 °C (0.00414 °F)

Entire sensor input range 0.001% of span Pt 500 ( = 0.00385) 0.0015 °C (0.0027 °F)

Entire sensor input range 0.001% of span Pt 1000 ( = 0.00385) 0.0015 °C (0.0027 °F)

Entire sensor input range 0.001% of span Pt 100 (a = 0.003916) 0.0015 °C (0.0027 °F)

Entire sensor input range 0.001% of span Pt 200 (a = 0.003916) 0.0023 °C (0.00414 °F)

Entire sensor input range 0.001% of span Ni 120 0.0010 °C (0.0018 °F)

Entire sensor input range 0.001% of span Cu 10 0.015 °C (0.027 °F)

Entire sensor input range 0.001% of span Pt 50 (a = 0.00391) 0.003 °C (0.0054 °F)

Entire sensor input range 0.001% of span Pt 100 (a = 0.00391) 0.0015 °C (0.0027 °F)

Entire sensor input range 0.001% of span Cu 50 (a = 0.00426) 0.003 °C (0.0054 °F)

Entire sensor input range 0.001% of span Cu 50 (a = 0.00428) 0.003 °C (0.0054 °F)

Entire sensor input range 0.001% of span Cu 100 (a = 0.00426) 0.0015 °C (0.0027 °F)

Entire sensor input range 0.001% of span Cu 100 (a = 0.00428) 0.0015 °C (0.0027 °F)

Entire sensor input range 0.001% of span Thermocouples Type B 0.014 °C 0.029 °C - (0.0021% of [T - 300])

0.046 °C - (0.0086% of [T - 100])

R 1000 °C 300 °C R < 1000 °C 100 °C R < 300 °C 0.001% of span Type E 0.004 °C + (0.00043% of T) 0.001% of span Type J 0.004 °C + (0.00029% of T) 0.004 °C + (0.0020% of absolute value T)

T 0 °C T< 0 °C 0.001% of span Type K 0.005 °C + (0.00054% of T) 0.005 °C + (0.0020% of absolute value T)

T 0 °C T < 0 °C 0.001% of span Type N 0.005 °C + (0.00036% of T)

All 0.001% of span Types R 0.015 °C 0.021 °C - (0.0032% of T)

T 200 °C T < 200 °C 0.001% of span Types S 0.015 °C 0.021 °C - (0.0032% of T)

T 200 °C T < 200 °C 0.001% of span Type T 0.005 °C 0.005 °C + (0.0036% of absolute value) T)

T 0 °C T < 0 °C 0.001% of span DIN Type L 0.0054 °C + (0.00029% of T) 0.0054 °C + (0.0025% of absolute value T)

T 0 °C T < 0 °C 0.001% of span DIN Type U 0.0064 °C 0.0064 °C + (0.0043% of absolute value T)

T 0 °C T < 0 °C 0.001% of span REFERENCE 6

Specifications and Reference Data April 2017 Reference Manual 00809-0100-4021, Rev JA Specifications and Reference Data 184 Transmitters may be installed in locations where the ambient temperature is between -40 and 85 °C (-40 and 185 °F).

To maintain excellent accuracy performance, each transmitter is individually characterized over this ambient temperature range at the factory.

Temperature effects example When using a Pt 100 ( = 0.00385) sensor input with a 0 to 100 °C span at 30 °C ambient temperature, the following statements would be true:

Digital temp effects 0.0015 °C/°C  (30 °C-20 °C) = 0.015 °C D/A effects (HART/4-20 mA only)

(0.001% /°C of span)  l(ambient temp-calibrated temp)l= D/A effects (0.001% /f °C 100)  l(30-20)l = 0.01 °C Worst case error Digital + D/A + digital temp effects + D/A effects

= 0.10 °C + 0.02 °C + 0.015 °C + 0.01 °C = 0.145 °C Worst case error Digital + D/A + digital temp effects + D/A effects

= 0.10 °C + 0.02 °C + 0.015 °C + 0.01 °C = 0.145 °C Total probable error Process temperature effects Temperature effects example When using a Pt 100 ( = 0.00385) sensor input with a 0 to 100 °C span at 30 °C ambient temperature, the following statements would be true:

Digital temp effects

D/A effects (HART/4-20 mA only)

Worst case error Digital + D/A + Digital temp effects + D/A effects

= 0.10 °C + 0.02 °C + 0.015 °C + 0.01 °C = 0.145 °C Type W5Re/W26Re 0.016 °C 0.023 °C + (0.0036% of T)

T 200 °C T < 200 °C 0.001% of span GOST Type L 0.005 °C 0.005 °C + (0.003% of T)

T ³ 0 °C T < 0 °C 0.001% of span Millivolt Input 0.00025 mV Entire sensor input range 0.001% of span 2-, 3-, 4-wire Ohm Input 0.007 ohms Entire sensor input range 0.001% of span

1.

Change in ambient is in reference to the calibration temperature of the transmitter (20 °C [68 °F]).

2.

Ambient temperature effect specification valid over minimum temperature span of 28 °C(50 °F).

3.

Applies to HART/4-20 mA devices.

Sensor options Digital accuracy per 1.0 °C (1.8 °F) change in ambient(1)(2)

Range D/A effect(3) 0.102 0.022 0.0152 0.012

+

+

+

0.10 °C

=

Table A-2. Ambient and Process Temperature Difference Effect on Digital Accuracy Sensor option Sensor reference Effects per 1.0 °C(1.8 °F) difference in ambient and process temperature(1)

1. Valid under steady state process and ambient conditions.

Input temperature (T)

Rosemount X-well Pt 100 ( = 0.00385)

IEC 751

+/- 0.01 °C (0.018 °F)

Entire sensor input range 0.0015 °C

°C 30 20 °C

(

)

x 0.015 °C

=

0.001%/°Cof span

[

]

100 °C 30 20°C

(

)

x x

°C DA effect

=

0.001%/°C 100 x

[

]

30 20

(

)

x 0.001°C

=

REFERENCE 6

Wide Range Linear Signal Processor N.C. State Page4 1.1. PERFORMANCE SPECIFICATIONS ELECTRICAL Detector Input Range Output Range Decades covered Total Ranges Accuracy Temp Drift %/°C Response Time (0- 63%)

Bistable Trip Contact Ratings Service Conditions Power MECHANICAL size (H x w x D)

Weight Instruction Manual No. 222B 1 x 10-12 to 1 x 10-4 A 30mW-1MW 8

16

+/-3%from30mWto lOW

+/-1% from lOWto lOKW

+/-0.5% from 10 KW to 1 MW

+/-0.05%

200 mSec from 30 mW to 10 W 1.5 mSec from 10 W to 10 KW 0.8 mSec from 10 KW to 1 MW 2A@28Vdc 0.3 A@ 117Vac 0 to 60°C, 10% to 95% RH 117 Vac +/-10%, 60Hz, 2 A 8.75 X 19 X 22 in.

35 lbs.

GENERAL DESCRIPTION

,~.

REFERENCE 8