无拖曳航天任务检验质量的设计和比较 -

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无拖曳航天任务检验质量的设计和比较

doi:10.3788/CO.20191203.0463

傅江良^{1, 3,},
甘庆波^2,,,
张扬¹,
赵柯昕^{2, 3},
袁洪¹

1.
中国科学院光电研究院, 北京 100094
2.
中国科学院国家天文台, 北京 100101
3.
中国科学院大学, 北京 100049

基金项目:

国家自然科学基金资助项目11303029

国家自然科学基金资助项目U1731131

中国科学院青年创新促进会2018183

详细信息

作者简介:
傅江良(1993-), 男, 浙江绍兴人, 硕士研究生, 2016年于浙江工业大学获得学士学位, 现为中国科学院大学硕士研究生, 主要研究方向为航天器编队飞行、动力学与控制。E-mail:fujiangliang@outlook.com
甘庆波(1982-), 男, 江西萍乡人, 博士, 副研究员, 2004年于中南大学获得学士学位, 2011年于中国科学院研究生院获得博士学位, 现为中国科学院国家天文台副研究员, 主要研究方向为天体测量与天体力学。E-mail:ganqingbo@nao.cas.cn

中图分类号:V44
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出版历程
- 收稿日期:2018-11-08
- 修回日期:2019-01-04
- 刊出日期:2019-06-01

Design and trade-off study of proof masses for future spatial drag-free missions

1.
Academy of Opto-Electronics, Chinese Academy of Sciences, Beijing 100094, China
2.
National Astronomical Observatories, Chinese Academy of Sciences, Beijing 100101, China
3.
University of Chinese Academy of Sciences, Beijing 100049, China

Funds:

National Natural Science Foundation of China11303029

National Natural Science Foundation of ChinaU1731131

Youth Innovation Promotion Association of Chinese Academy of Sciences2018183

More Information

Corresponding author:GAN Qing-bo, E-mail:ganqingbo@nao.cas.cn

摘要

摘要:检验质量是无拖曳航天器的惯性参考基准，对检验质量进行结构优化设计、材料选择以及不同配置方案的分析比较，能够为今后无拖曳航天任务中引力参考敏感器的模块化设计提供参考。本文首先分析了检验质量形状的取决要素和设计准则，以空间等效原理检验实验中圆柱体检验质量为例，建立了点质量引力源对检验质量的引力耦合模型，推导了检验质量形状尺寸的优化设计过程，并针对检验质量约束作用面和主惯性矩的特殊考量，分析了其对形状尺寸设计的影响。然后从最大化科学测量信号强度和最小化噪声扰动两方面对检验质量的材料进行选择，得到低磁化率、高密度、低热膨胀系数等属性的材料作为检验质量的备选。最后以空间引力波探测实验为例，从加速度噪声性能指标、方案继承性和技术成熟度、无拖曳控制复杂度等方面对检验质量的不同配置方案进行权衡取舍和比较研究。
- 无拖曳卫星/
- 检验质量/
- 形状尺寸设计/
- 材料选择/
- 配置方案比较
Abstract:As the gravitational reference object for drag-free spacecrafts, the structural optimal design, choice of material and related configuration comparisons of proof masses could provide information for gravitational reference sensors' modular designs in future spatial drag-free missions. Firstly, the determinants and design criteria of proof mass shape are discussed. The model of gravitational coupling between a point mass source and a cylindrical proof mass is established in test of the equivalence principle experiment. The optimization procedure for the structural dimension of proof masses is deduced in detail and the effects on structural design induced by special considerations for proof mass constraint surfaces and their principal moments of inertia are analyzed. Secondly, the choice of material for proof masses is determined by maximizing scientific measurement signal intensity and/or minimizing non-gravitational acceleration disturbance. Results show that materials with low magnetic susceptibility, high density and a low thermal expansion coefficient could be suitable. Finally, a trade-off study of several configurations of proof masses utilized in future space gravitational wave detection is performed from the following aspects:acceleration noise performance, flight heritage, technology maturity and drag-free control complexity.
- drag-free satellite/
- proof mass/
- structural dimension design/
- material choosing/
- configuration comparison

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图 1空间等效原理实验的检验质量示意图

Figure 1.Schematic of possible proof masses for test of equivalence principle in space

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图 2检验质量尺寸设计流程图

Figure 2.Size design diagram of proof mass

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图 3空心圆柱体检验质量与点质量引力源的相互作用

Figure 3.Gravitational interaction between a point source mass and the hollow cylindrical proof mass

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图 4环带形/直圆柱体混合结构的检验质量

Figure 4.Proof masses with hybrid structure of ring-shaped/straight cylinder

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图 5带有平面的空心圆柱体检验质量

Figure 5.A hollow cylindrical proof mass with 'flats'

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图 6球形检验质量的本体极迹运动

Figure 6.Polhode motion of spherical proof mass

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图 7部分镂空的球体结构

Figure 7.Sphere structure with partial hollow

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表 1无拖曳卫星应用实例及其检验质量形状

Table 1.Application examples of drag-free satellite and their proof mass shapes

科学任务	实例	检验质量形状
轨道预测	TRIAD I	球体
地球重力场测量	CHAMP、GRACE、GOCE	立方体
等效原理检验	MICROSCOPE	圆柱体
广义相对论效应测量	GP-B	球体
引力波探测	LISA Pathfinder	立方体

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表 2LISA检验质量的4种配置方案

Table 2.Four configurations of LISA proof mass

	配置方案1	配置方案2	配置方案3	配置方案4
检验质量构型示意图
检验质量形状	立方体	立方体	球体	球体
每个航天器中检验质量个数	2	1	1	1
是否主动控制检验质量旋转	否	否	是	否
检验质量相对运动状态测量系统	静电测量+光学测量	光学测量	光学测量	光学测量
检验质量是否需要静电悬浮	是	是	否	否

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表 3LISA不同配置方案中总的加速度噪声比较

Table 3.Comparison of the total acceleration noises for four LISA configurations

加速度噪声δa/(10^-16ms^-2Hz^-1/2)	方案1	方案2	方案3	方案4
环境噪声δa_env	10.7	10.7	8.49	8.49
刚度相关的噪声δa_stiff	5.75	1.17	0.15	6.0
静电悬浮系统引入的噪声δa_f	10.8	2.15	无	无
传感器引入的噪声δa_s	3.88	3.88	可忽略	可忽略
总的加速度扰动δa_total	16.7	11.64	8.5	10.4
附注：

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表 4LISA不同配置方案中控制自由度数量比较

Table 4.Control DOF count comparison for four LISA configurations

自由度数量		方案1	方案2	方案3/4
单个航天器	平动	9	6	6
	转动	9	6	3
	其它	1	1	1
三个航体器总计		57	39	30
控制矩阵维数		57×57	39×39	30×30

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