Influence of temperature gradient on thermal stability tolerance of large aperture reflective mirror

Yang Xun; Xu Shuyan; Li Xiaobo; Zhang Xusheng; Ma Hongcai

doi:10.3788/IRLA201948.0916003

Volume 48 Issue 9

Oct. 2019

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Yang Xun, Xu Shuyan, Li Xiaobo, Zhang Xusheng, Ma Hongcai. Influence of temperature gradient on thermal stability tolerance of large aperture reflective mirror[J]. Infrared and Laser Engineering, 2019, 48(9): 916003-0916003(10). doi: 10.3788/IRLA201948.0916003

Citation:

Yang Xun, Xu Shuyan, Li Xiaobo, Zhang Xusheng, Ma Hongcai. Influence of temperature gradient on thermal stability tolerance of large aperture reflective mirror[J]. Infrared and Laser Engineering, 2019, 48(9): 916003-0916003(10). doi: 10.3788/IRLA201948.0916003

Influence of temperature gradient on thermal stability tolerance of large aperture reflective mirror

doi: 10.3788/IRLA201948.0916003

1.
Changchun Institute of Optics,Fine Mechanics and Physics,Chinese Academy of Sciences,Changchun 130033,China

Received Date: 2019-04-05
Rev Recd Date: 2019-05-10
Publish Date: 2019-09-25

Abstract

In order to investigate the influence of temperature on the radius of curvature and the RMS value of the large aperture SiC reflective mirror, a finite element model was established for a 2 m-aperture SiC primary mirror of a space telescope, and the effects of uniform temperature field, axial temperature gradient and radial temperature gradient on the radius of curvature and RMS of the mirror were analyzed. The accuracies of the simulation method and results were verified by experiment theoretical arithmetic. The results show that the influence of temperature gradient on the radius of curvature and the RMS value of the mirror is much greater than the effect of uniform temperature. The change of curvature radius is most sensitive to the axial temperature gradient, and the RMS value of the surface figure is most sensitive to the radial temperature gradient. The change in radius of curvature caused by the 1℃ axial temperature gradient is 48 times greater than the change in radius of curvature caused by the same uniform temperature rise. The RMS of surface figure caused by the 1℃ radial temperature gradient can be 202 times larger than that caused by the same uniform temperature rise. The influence of axial temperature gradient and radial temperature gradient on the thermal stability tolerance must be considered in determining the thermal control index of the mirror.
- temperature gradient,
- thermal distortion,
- radius of curvature,
- surface figure,
- SiC reflective mirror

References

[1]	Ding Yanwei, You Zheng, Lu E. Influences of temperature change on dimension stability of sensor opto-structural system[J]. Journal of OptoelectronicsLaser, 2004, 15(10):1170-1173. (in Chinese)丁延卫, 尤政, 卢锷. 温度变化对遥感器光机结构尺寸稳定性的影响[J]. 光电子激光, 2004, 15(10):1170-1173.
[2]	Gong Dun, Tian Tieyin, Wang Hong. Thermal optical analysis of off-axis three-mirror system and its thermal control require-ments[J]. Opt Precision Eng, 2011, 19(6):1213-1220. (in Chinese)巩盾, 田铁印, 王红. 离轴三反射系统的热光学分析和温控指标的制定[J]. 光学精密工程, 2011, 19(6):1213-1220.
[3]	He Yan, Wang Jihong, Peng Qi. Thermal property of large aperture light primary mirror[J]. Opto-Electronic Engineering, 2014, 41(6):63-69. (in Chinese)何宴, 王继红, 彭起. 大口径轻质主镜热特性分析[J]. 光电工程, 2014, 41(6):63-69.
[4]	Wang Fuguo, Qiao Bin, Zhang Jingxu. Flexible passive support system for 2 m SiC reflective mirror[J]. Opt Precision Eng, 2017, 25(10):2591-2598. (in Chinese)王富国, 乔兵, 张景旭. 2 m SiC反射镜柔性被动支撑系统[J]. 光学精密工程, 2017, 25(10):2591-2598.
[5]	Xu Hong, Guan Yingjun. Structural design of large aperture SiC mirror subassembly[J]. Infrared and Laser Engineering, 2014, 43(S1):83-88. (in Chinese)徐宏, 关英俊. 大口径SiC轻量化反射镜组件的结构设计[J]. 红外与激光工程, 2014, 43(S1):83-88.
[6]	Wang Kejun, Xuan Ming, Dong Jihong, et al. Design method of reflector component structure of space remote sensor[J]. Infrared and Laser Engineering, 2016, 5(11):1113001. (in Chinese)王克军, 宣明, 董吉洪, 等. 空间遥感器反射镜组件结构设计方法[J]. 红外与激光工程, 2016, 5(11):1113001.
[7]	Shao Liang, Wu Xiaoxia, Ming Ming, et al. Influence of static friction for large aperture SiC light-weight reflecting mirror with flexible strip support[J]. Opt Precision Eng, 2017, 25(9):2387-2395. (in Chinese)邵亮, 吴小霞, 明名, 等. 大口径SiC轻量化反射镜柔性带式支撑静摩擦影响[J]. 光学精密工程, 2017, 25(9):2387-2395.
[8]	Dong Deyi, Li Zhilai, Xue Donglin, et al. Integrated opto-mechanical analysis and experiments for influence of gravity on wavefront aberration of space camera[J]. Opt Precision Eng, 2016, 24(8):1917-1926. (in Chinese)董得义, 李志来, 薛栋林, 等. 重力对空间相机系统波像差影响的光机集成分析与验证[J]. 光学精密工程, 2016, 24(8):1917-1926.
[9]	Kong Lin, Yang Lin. Study and test of thermal-defocusing property in space camera[J]. Opt Precision Eng, 2017, 25(7):1825-1831. (in Chinese)孔林, 杨林. 空间相机温度-离焦特性分析与试验[J]. 光学精密工程, 2017, 25(7):1825-1831.
[10]	Pearson E, Stepp L. Response of large optical mirrors to thermal distributions[C]//Proceedings of SPIE, The International Society for Optical Engineering, 1987, 748:215-228.
[11]	Wu Qingwen, Lu E, Wang Jiaqi, et al. A study on static thermal properties of primary mirror[J]. Opt Precision Eng, 1996, 4(6):47-53. (in Chinese)吴清文, 卢锷, 王家骐,等. 主镜稳定温度场特性分析[J]. 光学精密工程, 1996, 4(6):47-53.
[12]	Wang Fuguo. Study on the influence of temperature and support style to the 1.2 m SiC primary mirror surface figure[J]. Acta Photonica Sinica, 2011, 40(6):933-936. (in Chinese)王富国. 温度和支撑方式对1.2 m SiC主镜面形的影响分析[J]. 光子学报, 2011, 40(6):933-936.
[13]	Doyle K B, Genberg V L, Michels G J. Integrated Optome Chanical Press Analysis[M]. 2nd edition, Washington:SPIE, 2012.
[14]	Genberg V L, Michels G J, Doyle K B. Making mechanical FEA results useful in optical design[C]//Proceedings of SPIE, 2002, 4769:24-33.
[15]	Olivieri O, Pieri S, Romoli A. Analysis of defocusing thermal effect on optical systems[C]//Proceedings of SPIE, 1996, 2774:283-292.
[16]	Bely P Y. The Design and Construction of Large Optical Telescopes[M]. New York:Springer, 2003.

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通讯作者: 陈斌, bchen63@163.com

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沈阳化工大学材料科学与工程学院沈阳 110142

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Influence of temperature gradient on thermal stability tolerance of large aperture reflective mirror

1. Changchun Institute of Optics,Fine Mechanics and Physics,Chinese Academy of Sciences,Changchun 130033,China

Received Date: 2019-04-05

Rev Recd Date: 2019-05-10

Publish Date: 2019-09-25

Key words:

Abstract: In order to investigate the influence of temperature on the radius of curvature and the RMS value of the large aperture SiC reflective mirror, a finite element model was established for a 2 m-aperture SiC primary mirror of a space telescope, and the effects of uniform temperature field, axial temperature gradient and radial temperature gradient on the radius of curvature and RMS of the mirror were analyzed. The accuracies of the simulation method and results were verified by experiment theoretical arithmetic. The results show that the influence of temperature gradient on the radius of curvature and the RMS value of the mirror is much greater than the effect of uniform temperature. The change of curvature radius is most sensitive to the axial temperature gradient, and the RMS value of the surface figure is most sensitive to the radial temperature gradient. The change in radius of curvature caused by the 1℃ axial temperature gradient is 48 times greater than the change in radius of curvature caused by the same uniform temperature rise. The RMS of surface figure caused by the 1℃ radial temperature gradient can be 202 times larger than that caused by the same uniform temperature rise. The influence of axial temperature gradient and radial temperature gradient on the thermal stability tolerance must be considered in determining the thermal control index of the mirror.

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Reference (16)

[1]	Ding Yanwei, You Zheng, Lu E. Influences of temperature change on dimension stability of sensor opto-structural system[J]. Journal of OptoelectronicsLaser, 2004, 15(10):1170-1173. (in Chinese)丁延卫, 尤政, 卢锷. 温度变化对遥感器光机结构尺寸稳定性的影响[J]. 光电子激光, 2004, 15(10):1170-1173.
[2]	Gong Dun, Tian Tieyin, Wang Hong. Thermal optical analysis of off-axis three-mirror system and its thermal control require-ments[J]. Opt Precision Eng, 2011, 19(6):1213-1220. (in Chinese)巩盾, 田铁印, 王红. 离轴三反射系统的热光学分析和温控指标的制定[J]. 光学精密工程, 2011, 19(6):1213-1220.
[3]	He Yan, Wang Jihong, Peng Qi. Thermal property of large aperture light primary mirror[J]. Opto-Electronic Engineering, 2014, 41(6):63-69. (in Chinese)何宴, 王继红, 彭起. 大口径轻质主镜热特性分析[J]. 光电工程, 2014, 41(6):63-69.
[4]	Wang Fuguo, Qiao Bin, Zhang Jingxu. Flexible passive support system for 2 m SiC reflective mirror[J]. Opt Precision Eng, 2017, 25(10):2591-2598. (in Chinese)王富国, 乔兵, 张景旭. 2 m SiC反射镜柔性被动支撑系统[J]. 光学精密工程, 2017, 25(10):2591-2598.
[5]	Xu Hong, Guan Yingjun. Structural design of large aperture SiC mirror subassembly[J]. Infrared and Laser Engineering, 2014, 43(S1):83-88. (in Chinese)徐宏, 关英俊. 大口径SiC轻量化反射镜组件的结构设计[J]. 红外与激光工程, 2014, 43(S1):83-88.
[6]	Wang Kejun, Xuan Ming, Dong Jihong, et al. Design method of reflector component structure of space remote sensor[J]. Infrared and Laser Engineering, 2016, 5(11):1113001. (in Chinese)王克军, 宣明, 董吉洪, 等. 空间遥感器反射镜组件结构设计方法[J]. 红外与激光工程, 2016, 5(11):1113001.
[7]	Shao Liang, Wu Xiaoxia, Ming Ming, et al. Influence of static friction for large aperture SiC light-weight reflecting mirror with flexible strip support[J]. Opt Precision Eng, 2017, 25(9):2387-2395. (in Chinese)邵亮, 吴小霞, 明名, 等. 大口径SiC轻量化反射镜柔性带式支撑静摩擦影响[J]. 光学精密工程, 2017, 25(9):2387-2395.
[8]	Dong Deyi, Li Zhilai, Xue Donglin, et al. Integrated opto-mechanical analysis and experiments for influence of gravity on wavefront aberration of space camera[J]. Opt Precision Eng, 2016, 24(8):1917-1926. (in Chinese)董得义, 李志来, 薛栋林, 等. 重力对空间相机系统波像差影响的光机集成分析与验证[J]. 光学精密工程, 2016, 24(8):1917-1926.
[9]	Kong Lin, Yang Lin. Study and test of thermal-defocusing property in space camera[J]. Opt Precision Eng, 2017, 25(7):1825-1831. (in Chinese)孔林, 杨林. 空间相机温度-离焦特性分析与试验[J]. 光学精密工程, 2017, 25(7):1825-1831.
[10]	Pearson E, Stepp L. Response of large optical mirrors to thermal distributions[C]//Proceedings of SPIE, The International Society for Optical Engineering, 1987, 748:215-228.
[11]	Wu Qingwen, Lu E, Wang Jiaqi, et al. A study on static thermal properties of primary mirror[J]. Opt Precision Eng, 1996, 4(6):47-53. (in Chinese)吴清文, 卢锷, 王家骐,等. 主镜稳定温度场特性分析[J]. 光学精密工程, 1996, 4(6):47-53.
[12]	Wang Fuguo. Study on the influence of temperature and support style to the 1.2 m SiC primary mirror surface figure[J]. Acta Photonica Sinica, 2011, 40(6):933-936. (in Chinese)王富国. 温度和支撑方式对1.2 m SiC主镜面形的影响分析[J]. 光子学报, 2011, 40(6):933-936.
[13]	Doyle K B, Genberg V L, Michels G J. Integrated Optome Chanical Press Analysis[M]. 2nd edition, Washington:SPIE, 2012.
[14]	Genberg V L, Michels G J, Doyle K B. Making mechanical FEA results useful in optical design[C]//Proceedings of SPIE, 2002, 4769:24-33.
[15]	Olivieri O, Pieri S, Romoli A. Analysis of defocusing thermal effect on optical systems[C]//Proceedings of SPIE, 1996, 2774:283-292.
[16]	Bely P Y. The Design and Construction of Large Optical Telescopes[M]. New York:Springer, 2003.

Influence of temperature gradient on thermal stability tolerance of large aperture reflective mirror

doi: 10.3788/IRLA201948.0916003

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References

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