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Research on dynamic error compensation for an armored K type thermocouple

HAO Xiao-jian1,2, XING En-pu1,2, ZAN Qing-bo1,2, WANG Heng-fei3, ZHOU Han-chang1,2

 

(1. Science and Technology on Electronic Test & Measurement Laboratory,North University of China,Taiyuan 030051,China; 2. Key Laboratory of Instrumentation Science & Dynamic Measurement (North University of China), Ministry of Education, Taiyuan 030051, China;3. The 41st Institute of China Electronics Technology Group Corporation, Qingdao 266555, China)

 

Abstract: A new method was proposed, in which a high-power CO2 laser modulated by high frequency was used as the driving source to heat up a surface-temperature sensor. The continual beam and the pulsed beam sent out by the same laser could be used in the same system to carry on the static calibration of the radiation thermometer and the dynamic calibration of the temperature sensor to be checked. The frequency-response characteristics of high-speed radiation thermometer surpassed that of the temperature sensor, therefore it could be used as the reference value to calibrate the latter and let system error be corrected. Differences in the environment of the sensor installing and the error caused by the change of thermo-physical property could be avoided. Thus, the difficult problem of traceable dynamic calibration of temperature was solved. In experiment, to obtain the frequency characteristics of the thermocouple and the dynamic performance of the K type thermocouple, which could compensate the dynamic characteristics of the sensor, the sensor was dynamically corrected by using the method, and then the mathematical model was established.

 

Key words: thermocouple; surface-temperature; dynamic calibration; error compensation; traceability

 

 

CLD number: TN248.4 Document code: A

 

Article ID: 1674-8042(2014)04-0010-06   doi: 10.3969/j.issn.1674-8042.2014.04.003

 


References

 

[1] Eke R, Kavasoglu A S, Kavasoglu N. Design and implementation of a low-cost multi-channel temperature measurement system for photovoltaic modules. Measurement, 2012, 45(6): 1499-1509.
[2] Zimmerschied R, Isermann R. Nonlinear time constant estimation and dynamic compensation of temperature sensors. Control Engineering Practice, 2010, 18: 300-310.
[3] JIA Xiao-wen. The research of optical dynamic calibration technology of temperature sensor which was based on CO2 laser and the reflective surface of off-axis parabolic. Master thesis. Taiyuan: North University of China, 2011.
[4] Keskin M, Kantar E. Dynamic compensation temperatures in a mixed spin-1 and spin-3/2 Ising system under a time-dependent oscillating magnetic field. Journal of Magnetism and Magnetic Materials, 2010, 322(18): 2789-2796.
[5] Ramana-Murthy C V, Parveen S. Heat and mass transfer in free convection flow past an oscillating plate in porous media. International Journal of Mathematics, 2011, 2(4): 602-609.
[6] Chamarthy P, Garimella S V, Wereley S T. Measurement of the temperature non-uniformity in a microchannel heat sink using microscale laser-induced fluorescence. International Journal of Heat and Mass Transfer, 2010, 53(15/16): 3275-3283.
[7] Ewinger A, Rinke G, Urban A, et al. In situ measurement of the temperature of water in microchannels using laser Raman spectroscopy. Chemical Engineering Journal, 2013, 223: 129-134.
[8] CHEN Shu-yue, CHENG Rong. Research on temperature measurement by X-ray transmission intensity. Nuclear Instruments and Methods in Physics Research Section B, 2013, 296: 61-65.
[9] Zhang Y F, Chan C C, Sun J. Enhancement of temperature measurement by using photonic bandgap effect. Sensors and Actuators A, 2010, 157(2): 276-279.
[10]  Hattori K, Baba J, Mori M, et al. Shibuya. Dimensional temperature measurement on YBCO thin film during S/N transition period by use of RuO2 chip resistor. Physics Procedia, 2012, 36: 1236-1241.
[11] SUN Yi-peng, CHUN Lou, ZHOU Huai-chun. A simple judgment method of gray property of flames based on spectral analysis and the two-color method for measurements of temperatures and emissivity. In: Proceedings of the Combustion Institute, 2011, 33(1): 735-741.

 

铠装K型热电偶动态响应误差补偿研究

 

郝晓剑1,2, 邢恩普1,2, 昝清波1,2, 王恒飞3, 周汉昌1,2

 

(1. 中北大学 电子测试技术重点实验室, 山西 太原 030051;2. 中北大学 仪器科学与动态测试教育部重点实验室, 山西 太原 030051; 3. 中国电子科技集团第四十一研究所, 山东 青岛 266555)

 

摘要:提出了一种利用同一可高频调制的高功率CO2激光器发出的连续激光和脉冲激光作为激励热源,  在同一系统中进行辐射温度计(红外探测器)静态校准和被校表面温度传感器动态校准的新方法, 由于高速辐射温度计的频率响应特性优于被校温度传感器, 因此以前者的响应作为真值来校准后者并获取系统误差的修正值,  避免了因传感器安装环境差异及热物性的变化所产生的误差, 解决了表面温度传感器动态校准的溯源难题。  利用该方法对K型热电偶进行了动态校准实验, 建立了数学模型, 获得了该热电偶的频率特性和动态性能指标, 对该传感器的动态特性进行补偿。 

 

关键词:热电偶; 表面温度; 动态校准; 误差补偿; 溯源

 

引用格式:HAO Xiao-jian, XING En-pu, ZAN Qing-bo, et al. Research on dynamic error compensation for an armored K type thermocouple. Journal of Measurement Science and Instrumentation, 2014, 5(4): 10-15. [doi: 10.3969/j.issn.1674-8042.2014.04.003]


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