引用本文:
【打印本页】   【HTML】   【下载PDF全文】   查看/发表评论  【EndNote】   【RefMan】   【BibTex】
←前一篇|后一篇→ 过刊浏览    高级检索
本文已被:浏览 220次   下载 154 本文二维码信息
码上扫一扫!
分享到: 微信 更多
近地小行星2016HO3表面温度建模研究
贾晓宇1, 杨晨2, 王彤1, 文毅2
1.北京空间飞行器总体设计部, 北京 100094;2.中国空间技术研究院, 北京 100094
摘要:
2019年4月18日,中国国家航天局(CNSA)公布了小行星探测计划,将近地小行星2016HO3作为探测任务目标之一。主要梳理了2016HO3热环境分析的要素,通过调研国际上目前观测数据,得到2016HO3的初步环境参数,使用近地小行星热模型(NEATM)与小行星热物理模型(TPM)开展了小行星2016HO3表面温度场建模与分析,综合得出小行星温度上限为412 K;同时结合其可能的自转条件,仿真分析了不同位置的昼夜温差变化特性,发现2016HO3最大温差大约为30 K。由于两个模型均不能直接处理极夜情况,在TPM模型基础上采用对自转周期光照进行平均思路,给出了极夜条件下的温度分析方法,并获得小行星2016HO3的温度下限。
关键词:  近地小行星;2016HO3;热物理模型;热环境;仿真
DOI:10.15982/j.issn.2095-7777.2019.05.008
分类号:P185.7
基金项目:
Modeling of Surface Temperature for Near-Earth Asteroid 2016HO3
JIA Xiaoyu1, YANG Chen2, WANG Tong1, WEN Yi2
1.Institute of Spacecraft System Engineering, Beijing 100094, China;2.China Academy of Space Techndogy, Beijing 100094, China
Abstract:
On April 18, 2019, the China National Space Administration (CNSA) published the plan of asteroid exploration, which would select the near-earth asteroid 2016HO3 as one of its targets. On this paper, the parameters of 2016HO3 for thermal environment analysis were discussed. By investigating the current international observation data, the environmental parameters of 2016HO3 are obtained preliminarily. Then the near-Earth asteroid thermal model(NEATM) and asteroid thermal physics model (TPM) were used to model and analyze the surface temperature of 2016HO3, and the upper boulder of the temperature was 412 K. Considering the spinning effect, the day and night temperature difference at different locations was simulated and analyzed, and the temperature analysis method under the polar night conditions was proposed, then the maximum temperature difference at any position was determined to be about 30 K. Last on the basis of TPM, by the idea of the average illumination during the rotation period, the temperature analysis method of the polar night was proposed, and lower limit of temperature of 2016HO3 was achieved.
Key words:  near Earth-asteroid;2016HO3;thermal physics model;thermal environment;simulation