Design of high-precision temperature and pressure control system in spectral measuring instrument

Abstract

Abstract: As the main factors affecting the accuracy of spectral measurement, temperature and pressure are the research focus of developing high-precision spectral measuring instrument. Regarding to that, a high-precision temperature and pressure control system can be used in spectral measuring instrument is developed. The system is designed and optimized from the aspects of instrument structure, circuit design and control algorithm, so the long-term temperature control accuracy of the system can reach 0.003 ℃, and long-term pressure control accuracy can reach 5.33 Pa. Under the condition of pressure control but without temperature control, the measurement results of methane gas concentration with a volume fraction of 300×10-6 fluctuates by 12.06×10-6 and the deviation  is 3.26×10-6.While under the condition of both temperature and pressure control, the fluctuation of the corresponding measurement results is 4.03×10-6 and the deviation  is 0.57 ×10-6. The results show that the high-precision temperature and pressure control system can improve the measurement accuracy and stability of the spectral measuring instrument, and also verify the reliability and feasibility of the system. It is shown that the developed temperature and pressure control system for spectral measuring instrument has reached the experimental and production standards, which provides reference for the development of similar high-precision spectral measuring instruments.

Key words: spectroscopy, spectral measuring instrument, temperature, pressure, control system

CLC Number:

O433.1

ZHOU Xinyu, DONG Yang, WANG Kunyang, LIU Kun, GAO Xiaoming, . Design of high-precision temperature and pressure control system in spectral measuring instrument[J]. Chinese Journal of Quantum Electronics, 2020, 37(3): 266-272.

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