基于主动式激光辐射测温技术的黑体腔底真实温度测量研究

doi:10.3969/j.issn.1000-1158.2024.04.08

摘要
图/表
参考文献(17)
相关文章 (15)

全文: PDF (6678 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要黑体腔底真实温度及均匀性是影响空腔发射率评价的关键因素,然而,现有研究对于温度均匀性的表征多基于亮度温度。应用一种能够免发射率进行温度测量的主动式激光辐射测温技术,开展针对973K的黑体辐射源腔底的表面真实温度及均匀性测量研究;同时基于实测温场数据,采用蒙特卡洛法对空腔有效发射率分布进行数值模拟,获取典型位置的模拟结果,结合亮度温度数据得到腔底真实温场。与主动式激光辐射测温法的表面真实温度直接测量结果进行对比,结果表明:对于所选的9个测量点,两者的相对偏差在0.04%～0.77%之间,良好的一致性验证了主动式激光辐射测温技术在黑体辐射源腔底的真实温度测量中的可行性。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	王鑫宇
	安保林
	章欣达
	董伟
	闫全英
	赵云龙
	翟慧星

关键词 ：辐射测温, 黑体辐射源, 温场, 红外激光, 蒙特卡洛法

Abstract：The true temperature and uniformity of the blackbody cavity bottom are the key factors affecting the evaluation of the cavity emissivity, but the existing studies for the temperature uniformity characterization are mostly based on the brightness temperature. An active laser radiation thermometry technique, which is capable of emissivity-free temperature measurement, is applied to carry out a study on the real surface temperature and uniformity measurement of the cavity bottom of a blackbody radiation source in 973K. Meanwhile, based on the measured temperature field data, the Monte-Carlo method was used to numerically simulate the effective emissivity distribution of the cavity, obtaining the simulation results at typical positions and combining with the bright temperature data to obtain the true temperature field at the bottom of the cavity. And compared with the direct measurement results of the surface real temperature by active laser radiation thermometry, the results show that for the nine selected measurement points, the relative deviations of the two are between 0.04% and 0.77%. The good agreement verifies the feasibility of the active laser radiometric thermometry technique for true temperature measurements at the bottom of the cavity of a blackbody radiation source.

Key words： radiation thermometry blackbody radiation source temperature field infrared laser Monte-Carlo method

收稿日期: 2023-11-21 发布日期: 2024-04-03

PACS:

TB942

基金资助:国家重点研发计划(2022YFF0610804);财政部公益性科研项目(AKYZZ2105)

通讯作者: 闫全英(1970-),女,河北宣化人,北京建筑大学副教授,从事相变材料储能方面研究。Email:yanquanying@bucea.edu.cn 董伟(1981-),男,河南荥阳人,中国计量科学研究院研究员,从事材料热物性方面研究。Email:dongw@nim.ac.cn E-mail: dongw@nim.ac.cn

作者简介: 王鑫宇(1999-),女,北京人,北京建筑大学硕士,研究方向为供热、供燃气、通风及空调工程。Email:18301652108@163.com

引用本文:

王鑫宇,安保林,章欣达,董伟,闫全英,赵云龙,翟慧星. 基于主动式激光辐射测温技术的黑体腔底真实温度测量研究[J]. 计量学报, 2024, 45(4): 514-519.
WANG Xinyu,AN Baolin,ZHANG Xinda,DONG Wei,YAN Quanying,ZHAO Yunlong,ZHAI Huixing. Measurement of the True Temperature at the Bottom of a Blackbody Cavity Based on Active Laser Radiation Thermometry. Acta Metrologica Sinica, 2024, 45(4): 514-519.

链接本文:

http://jlxb.china-csm.org:81/Jwk_jlxb/CN/10.3969/j.issn.1000-1158.2024.04.08 或 http://jlxb.china-csm.org:81/Jwk_jlxb/CN/Y2024/V45/I4/514

［2］	工作用辐射温度计检定规程: JJG856-2015 ［S］.
［3］	原遵东, 郝小鹏, 王景辉, 等. 黑体辐射源的多波长有效亮度温度校准和不同溯源方式特点分析［J］. 计量学报, 2017, 38(2): 135-140.
［17］	ZHANG Z M, TSAI B K, MACHIN G. Radiometric temperature measurements: 1. fundamentals ［M］. New York: Academic Press, 2009.
	WANG H, MIAO L. Calibration method for blackbody radiation sources and assessment of brightness temperature uncertainty ［J］. Brand and Standardization, 2022 (4): 34-36.
［6］	潘奕捷, 原遵东, 陆启迪, 等. 黑体辐射源HT-9500的空腔温场测量［J］. 计量技术, 2018(4): 10-13.
	YUAN Z D, HAO X P, WANG J H, et al. Multi-wavelength Effective Radiance Temperature Calibration and Characteristics Analysis of Traceable Approaches of the Blackbody Radiation Sources［J］. Acta Metrologica Sinica, 2017, 38(2): 135-140.
	ZHANG L, CAI J, LU L F. Analysis of Factors Affecting Application of Blackbody Radiator for Radiation Thermometry［J］. Metrology and Measurement Technology, 2020, 40(4): 1-4.
	WU Q, HAO X P, SONG J, et al. The Investigation on the Temperature Field Uniformity of a High?precision Vacuum Blackbody［J］. Acta Metrologica Sinica, 2022, 43(10): 1279-1284.
［7］	王阔传, 张俊祺, 张奇. 激光吸收法辐射测温技术研究［J］. 宇航计测技术, 2018, 38(4): 23-27.
［8］	DEWITT D, KUNZ H. Theory and Technique for Surface Temperature Determinations by Measuring the Radiance Temperatures and the Absorption Ratio for two Wavelengths［J］. Temp Measurement and Control in Science and Industry, 1972, 4: 599-610.
［9］	LOARER T, GREFFET J J, HUETZ-AUBERT M. Noncontact surface temperature measurement by means of a modulated photothermal effect, ［J］. Applied Optics, 1990, 29: 979-987.
	WANG K C, ZHANG J Q, ZHANG Q. Research on radiation temperature measurement technology by laser absorption method［J］. Aerospace Measurement Technology, 2018, 38(4): 23-27
［11］	LEVICK A, EDWARDS G. A Fibre-Optic Based Laser Absorption Radiation Thermometry (LART) Instrument for Surface Temperature Measurement［J］. Analytical Sciences, 2007, 17(1): 438-441.
［13］	AN B L, QU Y, SONG X Y, et al. On surface temperature measurement of low emittance artefact coating by active infrared laser radiation thermometry［J］. Infrared Physics & Technology, 2021, 115:103696.
［14］	AN B L, GU Q T, DONG W, et al. Investigation of the effective wavelength applied on the active dual wavelength infrared temperature measurement［J］. Infrared physics & technology, 2022, 125: 104284.
［16］	曲岩. 基于双波长红外激光主动式测温技术研究［D］. 长春: 长春理工大学, 2021.
［1］	王浩, 苗丽. 黑体辐射源校准方法及亮度温度不确定度评定［J］. 品牌与标准化, 2022 (4): 34-36.
［4］	张岚, 蔡静, 路林锋. 影响辐射测温用黑体辐射源应用的因素分析［J］. 计测技术, 2020, 40(4): 1-4.
［5］	武强, 郝小鹏, 宋健, 等. 高精度真空黑体温度场均匀性研究［J］. 计量学报, 2022, 43(10): 1279-1284.
	PAN Y J, YUAN Z D, LU Q D, et al. Cavity Temperature Field Measurements of the Blackbody Radiation Source HT-9500［J］. Measurement Technology, 2018(4): 10-13.
［10］	LOARER T, GREFFET J J. Application of the pulsed photothermal effect to fast surface temperature measurements［J］. Applied Optics, 1992, 31(25): 5350-5358.
［12］	LEVICK A, LOBATO K, EDWARDS G. Development of the laser absorption radiation thermometry technique to measure thermal diffusivity in addition to temperature［J］. Review of Scientific Instruments, 2003, 74(1): 612-614.
［15］	曲岩, 宦克为, 安保林, 等. 主动式双波长红外激光测温标定实验研究［J］. 计量学报, 2021, 42(2): 137-143.
	QU Y, HUAN K W, AN B L, et al. Experimental study on calibration of active dual-wavelength infrared laser temperature measurement ［J］. Acta Metrologica Sinica, 2021, 42(2): 137-143.