轻质长条形反射镜结构优化设计

王朋朋,辛宏伟,朱俊青,等. 轻质长条形反射镜结构优化设计[J]. 光电工程,2020,47(8):200109. doi: 10.12086/oee.2020.200109
引用本文: 王朋朋,辛宏伟,朱俊青,等. 轻质长条形反射镜结构优化设计[J]. 光电工程,2020,47(8):200109. doi: 10.12086/oee.2020.200109
Wang P P, Xin H W, Zhu J Q, et al. Structural optimization design of lightweight rectangular reflective mirror[J]. Opto-Electron Eng, 2020, 47(8): 200109. doi: 10.12086/oee.2020.200109
Citation: Wang P P, Xin H W, Zhu J Q, et al. Structural optimization design of lightweight rectangular reflective mirror[J]. Opto-Electron Eng, 2020, 47(8): 200109. doi: 10.12086/oee.2020.200109

轻质长条形反射镜结构优化设计

  • 基金项目:
    国家自然科学基金青年基金资助项目(11803036)
详细信息
    作者简介:
    通讯作者: 辛宏伟(1970-),男,博士,研究员,主要从事空间相机光机结构的研究。E-mail:xinhwciomp@sina.com
  • 中图分类号: TH751

Structural optimization design of lightweight rectangular reflective mirror

  • Fund Project: Supported by the Youth Program of National Nature Science Foundation of China (11803036)
More Information
  • 为解决空间反射镜镜体质量和面形精度在轻量化设计过程中会引起相互冲突的问题,针对某型离轴三反光学系统的长条形主反射镜进行了结构优化设计研究,提出了一种基于SiC材料的中心支撑的轻量化结构,同时引入了多目标集成优化方法,以镜体质量(Mass)和面形(RMS)同时作为优化目标,得到一个反射镜最佳结构模型,其质量为2.32 kg,轻量化率达到了73.8%;然后,对反射镜支撑结构进行了结构设计和说明,并对该组件进行了仿真分析,在XYZ三轴方向1 g重力工况下的RMS值分别达到2.5 nm、2.2 nm、7.3 nm,4 ℃均匀温升载荷工况下的RMS值为3.2 nm,远小于设计要求的RMS≤λ/50(λ=632.8 nm),满足设计要求。

  • Overview: The research area of this paper is the field of off-axis three-reflective space optical remote sensor. As a core element of the system, the rectangular reflective mirror has been the focus. Increasing the degree of lightweight will also bring new problems, which cause a certain degree of structural strength reduction. Obviously, RMS(root mean square) will get worse. The purpose of this paper is to propose a feasible solution to this conflict of performance. First of all, select SiC as the mirror body material. Secondly, a flexible structure is based on the center support, which facilitates lightweight and reduces the overall design difficulty. Next, use the classical theoretical formula to create the initial structure of the mirror. The most important step is to introduce a multi-objective optimization method. The structural parameters of the lens body are used as design variables, and then the surface RMS values under X and Y gravity conditions are used as constraints. It is the mass of the mirror and the RMS values under the most sensitive Z-direction gravity conditions that are commonly set as the optimization goal. Furthermore, using GRSM(global response surface method) algorithm for optimization iterations. A mirror optimal structure model is obtained with a mass of 2.32 kg. Compared with the solid mirror, the lightweight ratio is 73.8%. Besides, the mirror subassembly is designed. It includes a cone sleeve, a flexible component, and a backplane. The main considerations of the assembly are the stiffness of the materials and the thermal compatibility between each other. The specific explanation is as follows. Thermal expansion coefficient of the cone sleeve and the mirror need to be the same, and these are connected by glue. The flexible component adopts a flexible hinge structure so as to improve RMS of the mirror due to thermal stress. The backplane connects the mirror assembly to one space remote sensor. Therefore, the rigidity of the backplane must be qualified. Finally, the integrated performance of the assembly is simulated. It shows that the RMS value of the mirror reaches respectively 2.5 nm, 2.2 nm and 7.3 nm when gravity load is applied in the directions of X, Y and Z axes. Furthermore, the RMS value is 3.2 nm when the mirror subassembly is under the load condition of uniform temperature rise of 4 ℃, which is far less than the requirement of RMS≤λ/50(λ=632.8 nm). As a result, the data meets the design requirements. To sum up, the method provides reference experience for structural optimization design of the same type of lightweight rectangular reflective mirror.

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  • 图 1  反射镜的初步设计几何结构模型

    Figure 1.  Original geometry structure of reflective mirror

    图 2  角度变量转化成坐标变量示意图

    Figure 2.  Schematic of changing angle variable to coordinate variable

    图 3  多目标集成优化流程图

    Figure 3.  Flow chart of multi-objective optimization

    图 4  体支撑结构爆炸图

    Figure 4.  Explosion chart of mirror support structure

    图 5  柔性元件

    Figure 5.  Flexible component

    图 6  反射镜组件有限元模型

    Figure 6.  FEM model of reflective mirror subassembly

    图 7  组件一阶固有模态分析

    Figure 7.  First constraint eigenfrequency of reflective mirror subassembly

    图 8  轴向重力作用时反射镜的变形结

    Figure 8.  Displacement of reflective mirror subassembly under axial gravity

    图 9  加速度频率响应曲线。

    Figure 9.  Frequency response curves of acceleration.

    表 1  常用反射镜材料的性能

    Table 1.  Performance of rational materials for mirror

    材料 密度ρ/(g/cm3) 弹性模量E /(GPa) 比刚度E/ρ /(GN·(m/g)) 线胀系数α /(10-6/K) 导热系数λ /(W/(m·K)) 比热容c/(J/(kg·K)) 热稳定性λ/α 综合品质(λ/α)·(E/ρ)
    FS 2.19 72.00 32.88 0.50 1.40 750.00 2.80 92.05
    Zerodur 2.53 91.00 35.97 0.05 1.64 821.00 32.80 1179.76
    Al 2.70 68.00 25.19 22.50 167.00 896.00 7.42 186.93
    Be 1.85 287.00 155.14 11.40 216.00 1925.00 18.95 2962.53
    Si 2.33 131.00 56.22 2.60 137.00 710.00 52.69 2962.53
    SiC 3.20 400.00 125.00 2.40 155.00 650.00 64.58 8072.92
    下载: 导出CSV

    表 2  设计变量和优化结果

    Table 2.  Design variables and optimization results

    Name Height Face thickness Hole thickness Side thickness θ(Chamfer) Rib thickness Mass RMS_X RMS_Y RMS_Z
    Ranges [30, 60] [5, 30] [5, 20] [1.5, 10] [0, 60] [1.5, 10] (0, 5] [0, 12] [0, 12] [0, 12]
    Value 42 mm 8 mm 9.4 mm 4 mm 23° 4 mm 2.32 kg 3.0 nm 1.8 nm 4.5 nm
    下载: 导出CSV

    表 3  空间主要应用的结构材料列表

    Table 3.  Main structural materials in space

    材料 密度ρ/(g/cm3) 弹性模量E/(GPa) 比刚度E/ρ/(GN·(m/g)) 线胀系数α/(10-6/K) 导热系数λ/(W/(m·K)) 比热容c/(J/(kg·K)) 热稳定性λ/α 综合品质(λ/α)·(E/ρ)
    TC4 4.40 114.00 25.91 9.10 7.40 611.00 0.81 21.07
    Invar 8.90 141.00 15.84 0.65 13.70 460.00 21.08 333.92
    高体份SiC/Al 3.00 180.00 60.00 8.00 225.00 7115.00 28.13 1687.50
    下载: 导出CSV
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收稿日期:  2020-03-31
修回日期:  2020-06-06
刊出日期:  2020-08-01

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