Abstract
The infrared temperature sensor has a small thermal inertia, which could be used to measure the temperature of the moving object or the fast changing temperature. It is widely used in modern industry, military and medicine. Planck’s law points out that the infrared temperature measurement is based on the infrared radiation of normal radiation as a standard measure. However, due to the actual measurement environment and cost constraint, there usually exits a changed incident angle between infrared sensor and measured object in the case of actual infrared measurement. A compensation algorithm of incident angle on temperature measurement is the focus of this paper. Facing the surface temperature measurement and cooling system of roller in aluminum plate manufacturing process, the paper put forward and designed a real-time temperature measurement scheme based on infrared sensor. Through experimental study and data analysis, the paper has explored the influence law of the incident angle in the infrared temperature measurement of the surface. Inthemeantime, because this article selects the strong reflective body as the research sample, and selects the low-temperature as the temperature measurement, so the research should overcome the interference of the physical properties of strong reflective sample and the complex nature of low temperature inaccurately measured. Though summing up the research achievements, the paper set up an incident Angle compensation algorithm, which is used to solve the influence of the incident angle on the temperature measurement result. The results of this study are of great significance to the application for accurately measure the surface temperature of strong reflector with infrared sensors.
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Tian, G., Wang, J.: Talking about how to choose and use infrared thermometer. Instrum. Stand. Metrol. 02, 47–48 (2013)
Shi, D.-P., Wu, C.: The influence of infrared temperature measurement based on reflection temperature compensation and incident temperature compensation. Electron. Measur. Technol. 08, 2321–2326 (2015)
Faria, I., Salustiano, R., Martinez, M.: A prediction of distribution transformers aging based on tank infrared temperature measurements. In: Proceedings of 22nd International Conference and Exhibition on Electricity Distribution (CIRED) (2013)
Zhang, Z.-D., Liu, J.-Y., Gao, R.-T., Xue, Z.-Q.: The application of infrared temperature measurement in the heat detection of ground system of dry reactor. Power Capacit. React. Power Compens. 01, 100–104 (2017)
Wu, Y.Z., Shen, G.Q.: Research of temperature measurement for pigs base on infrared temperature measurement system. In: Proceedings 2013 International Conference on Mechatronic Sciences, Electric Engineering and Computer (MEC) (2013)
Tanda, G.: Skin temperature measurements by infrared thermography during running exercise. Exp. Therm. Fluid Sci. 71, 103–113 (2016)
Xu, K., Zhao, L., Yuan, Y., Zhang, X.L., Lin, L.D.: Measurement error analysis and compensation experiment of medical infrared thermometer. Electron. Measur. Technol. 10, 104–108 (2014)
Xie, H.-Y., Qian, M.-L.: The design of the ear thermometer based on digital infrared thermoelectric reactor sensor. China Med. Device J. 05, 336–339 (2013)
Luo, W.-X.: Non-contact temperature measuring instrument based on AT89S52 single chip microcomputer. Pract. Electron. 13, 63 (2015)
Zhang, L.-N., Li, X.: The design of the non-contact infrared temperature measurement system based on MLX90615 sensor. Electron. Test 96, 94–109 (2014)
Xu, X.-J., Liu, T.-D., Mao, S.-J., Li, D.-Y., Xie, S.-L.: The design of new medical infrared thermometer. Med. Sanit. Equip. 11, 44–47 (2016)
Li, J.-X., Tong, Z.-X., et al.: Infrared radiation experiment and simulation of aircraft engine. Infrared Laser Eng. 03, 549–555 (2013)
Peng, J., Pei, D.H., Zhao, Y.J., Wang, K.Q., Lu, D.H., Zhang, D.H.: Application of aerial infrared technology in the exploration of coal fire area. Geol Rev. S1, 127–128 (2017)
Wang, Y.-S., Dong, X.-M., Liu, W., Huang, M.-G., Li, X., Cui, H.-X.: Research progress of high temperature test technology of aviation engine. Measur. Control Technol. 09, 1–6 (2017)
Peng, R., Fang, M.: Compensation and adjustment analysis in infrared temperature measurement system. Pract. Electron. 22, 9 (2013)
Long, Z.-L.: Infrared temperature measurement system based on 51 MCU. Pract. Electron. 20, 7 (2013)
McManus, C., Tanure, C.B., Peripolli, V., Seixas, L., Fischer, V., Gabbi, A.M., Menegassi, S.R., Stumpf, M.T., Kolling, G.J., Dias, E., Costa, J.B.G.: Infrared thermography in animal production: an overview. Comput. Electron. Agric. 123, 10–16 (2016)
Tian, M., Xiong, L.-J.: The principle, error and solution of infrared temperature measurement are analyzed. Instrum. Meter Stand. Measur. 02, 40–42 (2016)
Wang, X.-L., Sun, Y.-Q.: The comparison and calibration of online infrared thermometer. China Metrol. 04, 100–101 (2017)
Liao, P.-P., Zhang, J.-M.: Study of the influence factors and compensation methods of infrared temperature measurement. Infrared Technol. 02, 173–177 (2017)
Zhang, Y.C., Chen, Y.M., Fu, X.B., Luo, C.: A method for reducing the influence of measuring distance on infrared thermal imager temperature measurement accuracy. Appl. Therm. Eng. 100, 1095–1101 (2016)
Zhang, Z.-M., Liu, B., Zhao, P., Jiang, Y.-X.: The slag detection system is based on infrared temperature measurement principle. Infrared Laser Eng. 02, 469–473 (2014)
Shi, L.-G.: Talking about the principle and application of infrared thermometer. Orient. Enterp. Cult. 19, 213 (2013)
Wang, H.-W.: Research on the key technology of temperature field measurement based on infrared thermal imaging. In: Proceedings of Graduate School of Chinese Academy of Sciences (xi ’an Optical Precision Machinery Research Institute) (2013)
Zhang, X.-L., Liu, Y., Wang, J., Zhou, H., Sun, Q.: Infrared temperature measurement technology of different nonuniformity correction temperature. Chin. Opt. 01, 104–108 (2014)
Imaz, E., Alonso, R., Heras, C., Salinas, I., Carretero, E., Carretero, C.: Infrared thermometry system for temperature measurement in induction heating appliances. IEEE Trans. Ind. Electron. 61, 2622–2630 (2014)
Wang, Y., Du, Y., Wu, J., Li, S.B., Lu, H.B.: Integrated design of new infrared imaging temperature sensor. Instrum. Anal. Monit. 01, 8–11 (2017)
Zhang, X.: Design of infrared temperature measurement system based on ARM. In: Proceedings of University of Electronic Science and Technology (2014)
Zeng, L., Li, X., He, X., Li, G., Wang, Z., Bao, H.: Key factors on the accuracy of measurement temperature by using infrared thermometer. In: Proceedings of 2014 International Conference on Reliability Maintainability and Safety (ICRMS) (2014)
Zhang, Y.C., Chen, Y.M., Fu, X.B., Luo, C.: The research on the effect of atmospheric transmittance for the measuring accuracy of infrared thermal imager. Infrared Phys. Technol. 77, 375–381 (2016)
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This work was supported in part by A Project of Shandong Province Higher Educational Science and Technology Program (J13LB04) and Dr. Fund of Henan Polytechnic University (B2016-29).
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Wei, S., Qin, W., Han, L. et al. The research on compensation algorithm of infrared temperature measurement based on intelligent sensors. Cluster Comput 22 (Suppl 3), 6091–6100 (2019). https://doi.org/10.1007/s10586-018-1828-5
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DOI: https://doi.org/10.1007/s10586-018-1828-5