Multidisciplinary and multi-objective optimization design method was applied in the researches of collimator mirror lightweight of wide field spectrometer of extremely large telescope. Lightweight design was operated independently on the basis of collaborative optimization which is one of the best feasible multidisciplinary design optimization approaches combined with multi-objective genetic algorithm to carry out the optimization, and the Pareto optimal set was obtained. The lightweight performance with different lightweight holes and the thermal stability of light-weighting collimator mirrors were comparatively studied. With triangle lightweight hole of collimation mirror, the light weighting rate is about 70% and the peak-valley (PV) value is 82.696 nm. With rectangle lightweight hole of collimation mirror, the light weighting rate is about 75.3% and the PV value is 107.03 nm. When the temperature of the collimator mirror changes about 10 K, the deformation of the collimator mirror is added doubled. The results indicate that the comprehensive evaluation of triangle lightweight hole is better than rectangle holes; the coupling and interdisciplinary relationships among the lightweight, the lightweight hole shape parameter and the deformation of mirror are comprehensively considered during the multi-objective optimization of collimator mirror lightweight structure. Thus the designers can choose the satisfactory optimization results according to their demands, so as to significantly reduce the product development cycle and costs.
Key words
wide field spectrometer /
extremely large telescope /
collimating mirror /
lightweight /
multi-objective genetic algorithm
{{custom_keyword}} /
{{custom_sec.title}}
{{custom_sec.title}}
{{custom_sec.content}}
References
黄欣, 沈湘衡, 叶露, 等.多光轴光学系统光轴间平行性检测仪的研制[J].应用光学, 2015, 36(1):19-23.
姜海波, 赵宏超, 杨飞. TMT三镜缩比系统cradle组件结构设计与分析[J].长春理工大学学报:自然科学版, 2017, 40 (4):7-9, 13.
傅家. TMT三镜被动支撑技术研究[D].北京: 中国科学院研究生院, 2012.
张景旭.大口径地基光电望远镜结构总体研究[D].北京: 中国科学院研究生院, 2007.
苏定强, 中国12 m光学红外望远镜[C].武汉: 中国天文学会摘要集, 2016.
王富国, 杨洪波, 赵文兴, 等. 1.2m Sic主镜轻量化设计与分析[J].光学?精密工程, 2009, 17(1):85-91.
范磊, 张景旭, 吴小霞, 等.大口径轻量化主镜边缘侧向支撑的优化设计[J].光学?精密工程, 2012, 20(10):2207-2213.
李全超, 李蕾, 谭淞年, 等.大口径铝合金主反射镜设计与分析[J].应用光学, 2016, 37(3):337-341.
王平, 郑松林, 吴光强.基于协同优化和多
HUANG Xin, SHEN Xiangheng, YE Lu, et al. Development of testing instrument of optical-axial parallelism for multi-axial systems[J]. Journal of Applied Optics, 2015, 36(1):19-23.
JIANG Haibo, ZHAO Hongchao, YANG Fei. Structure design and analysis for cradle of GSSMP[J]. Journal of Changchun University of Science and Technology:Natural Science edition, 2017, 40 (4): 7-9, 13.
FU Jia. Study on the passive support of TMT tertiary mirror[D]. Beijin: University of Chinese Academy of Sciences, 2012.
ZHANG Jingxu. Study on macro-structure of large ground-based electro-optical telescope[D]. Beijing: University of Chinese Academy of Sciences, 2007.
SU Dingqiang. 12 meter optical infrared telescope of China[C]. Wuhan: Chinese Astronomical Society, 2016.
WANG Fuqiang, YANG Hongbo, ZHAO Wenxing, et al. Lightweight design and analysis of 1.2 m SiC primary mirror[J]. Optics and Precision Engineering, 2009, 17(1):85-91.
FAN Lei, ZHANG Jingxu, WU Xiaoxia, et al. Optimum design of edge-lateral support fo
{{custom_fnGroup.title_en}}
Footnotes
{{custom_fn.content}}
