CR1000 Manual - Campbell Scientific

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Section 8. Operation Table 66. Limits of Error on CR1000 Thermocouple Polynomials TC Type Range °C Limits of Error °C Relative to NIST Standards -130 to 200 ±0.005 200 to 1000 ±0.02 K -50 to 1372 -50 to 950 ±0.01 950 to 1372 ±0.04 8.1.4.1.7 Reference-Junction Error Thermocouple instructions TCDiff() and TCSe() include the parameter TRef to incorporate the reference-junction temperature into the measurement. A referencejunction compensation voltage is computed from TRef as part of the thermocouple instruction, based on the temperature difference between the reference junction and 0°C. The polynomials used to determine the reference-junction compensation voltage do not cover the entire thermocouple range, as illustrated in tables Limits of Error on CR1000 Thermocouple Polynomials (p. 309) and Reference- Temperature Compensation Range and Polynomial Error (p. 310). Substantial errors in the reference junction compensation voltage will result if the reference-junction temperature is outside of the polynomial-fit ranges given. The reference-junction temperature measurement can come from a PanelTemp() instruction or from any other temperature measurement of the reference junction. The standard and extended (-XT) operating ranges for the CR1000 are -25 to 50°C and -55 to 85°C, respectively. These ranges also apply to the referencejunction temperature measurement using PanelTemp(). Two sources of error arise when the reference temperature is out of the polynomial-fit range. The most significant error is in the calculated compensation voltage; however, a small error is also created by non-linearities in the Seebeck coefficient. Table 67. Reference-Temperature Compensation Range and Error TC Type Range °C Limits of Error °C 1 T -100 to 100 ± 0.001 E -150 to 206 ± 0.005 J -150 to 296 ± 0.005 K -50 to 100 ± 0.01 1 Relative to ITS-90 Standard in NIST Monograph 175 8.1.4.1.8 Thermocouple Error Summary Errors in the thermocouple- and reference-temperature linearizations are extremely small, and error in the voltage measurement is negligible. 310
Section 8. Operation The magnitude of the errors discussed in Error Analysis (p. 302) show that the greatest sources of error in a thermocouple measurement are usually, • The typical (and industry accepted) manufacturing error of thermocouple wire • The reference temperature The table Thermocouple Error Examples (p. 311) tabulates the relative magnitude of these errors. It shows a worst case example where, • A temperature of 45°C is measured with a type-T thermocouple and all errors are maximum and additive: • Reference-RTD temperature is 25°C, but it is indicating 25.1°C. • The terminal to which the thermocouple is connected is 0.05°C cooler than the reference thermistor (0.15°C error). Table 68. Thermocouple Error Examples Error: °C : % of Total Error Source Single Differential 250 µs Integration Reversing Differential 50/60 Hz Rejection Integration ANSI TC Error (1°C) TC Error 1% Slope ANSI TC Error (1°C) TC Error 1% Slope Reference Temperature 0.15° : 11.5% 0.15° : 29.9% 0.15° : 12.2% 0.15° : 34.7% TC Output 1.0° : 76.8% 0.2° : 39.8% 1.0° : 81.1% 0.2° : 46.3% Voltage Measurement 0.12° : 9.2% 0.12° : 23.9% 0.07° : 5.7% 0.07° : 16.2% Noise 0.03° : 2.3% 0.03° : 6.2% 0.01° : 0.8% 0.01° : 2.3% Reference Linearization 0.001° : 0.1% 0.001° : 0.2% 0.001° : 0.1% 0.001° : 0.25% Output Linearization 0.001° : 0.1% 0.001° : 0.2% 0.001° : 0.1% 0.001° : 0.25% Total Error 1.302° : 100% 0.502° : 100% 1.232° : 100% 0.432° : 100% 8.1.4.2 Use of External Reference Junction An external junction in an insulated box is often used to facilitate thermocouple connections. It can reduce the expense of thermocouple wire when measurements are made long distances from the CR1000. Making the external junction the reference junction, which is preferable in most applications, is accomplished by running copper wire from the junction to the CR1000. Alternatively, the junction box can be used to couple extension-grade thermocouple wire to the thermocouples, with the PanelTemp() instruction used to determine the reference junction temperature. Extension-grade thermocouple wire has a smaller temperature range than standard thermocouple wire, but it meets the same limits of error within that range. One situation in which thermocouple extension wire is advantageous is when the junction box temperature is outside the range of reference junction compensation provided by the CR1000. This is only a factor when using type K thermocouples, since the upper limit of the reference compensation polynomial fit range is 100°C and the upper limit of the extension grade wire is 200°C. With the other types of thermocouples, the reference compensation polynomial-fit range equals or is 311
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CR1000 Measurement and Control Syst
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Assistance Products may not be retu
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Table of Contents Section 5. System
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Section 1. Introduction Italic —
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Section 9. Maintenance 9.1 Moisture
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Appendix A. CRBasic Programming Ins
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Appendix C. Serial Port Pinouts C.1
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Appendix D. ASCII / ANSI Table Amer
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Appendix E. FP2 Data Format FP2 dat
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Appendix F. Other Campbell Scientif
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Index 1 12V Terminal...............
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Index Communications Memory Errors
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Index Expression...................
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Index IP Information...............
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Index PanelTemp....................
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Index Runtime Errors...............
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Index TCDiff ......................
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