热力耦合结构的弹性支撑分析与拓扑优化设计被引量：7

ANALYSIS AND TOPOLOGY OPTIMIZATION OF ELASTIC SUPPORTS FOR STRUCTURES UNDER THERMO-MECHANICAL LOADS

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摘要弹性支撑是保证热力耦合载荷作用下结构有效承载的一种支撑设计方案,可以在满足结构刚度设计要求的同时有效降低结构内的应力集中,保证结构的热变形协调.从理论分析与数值计算两个方面,研究了热力耦合载荷作用下结构的弹性支撑优化设计.首先以弹性支撑梁模型为例,通过给出热力耦合载荷下应力计算的解析表达式,从理论上说明弹性支撑对结构应力峰值的影响,阐述了弹性支撑的承载与热变形协调的双重效果.在此基础上,提出了解决该类问题的弹性支撑通用优化数学模型和拓扑构型优化方法,通过数值算例与优化结果展示了方法的有效性. Elastic supports are recognized as an efficient means for structural designs under thermo-mechanical loads. Their introduction is beneficial not only for the achievement of the specific structure stiffness but also for the reduction of stress intensities to match the thermal deformation of the structure. In this paper, both theoretical and numerical studies are carried out to optimize the elastic support under thermo-mechanical loads. First, the analytical expression of the maximal thermo-mechanical stress is derived for a beam model with elastic support to illustrate the effects of the load-bearing and thermal deformation coordination of the elastic support. On this basis, a general topology optimization model and related topology optimization methods are proposed. Numerical examples and results are presented to demonstrate the validity of the proposed approach.

作者杨军刚张卫红王丹蔡守宇

机构地区西北工业大学机电学院

出处《力学学报》 EI CSCD 北大核心 2012年第3期537-545,共9页 Chinese Journal of Theoretical and Applied Mechanics

基金国家重点基础研究发展计划(2011CB610304) 国家自然科学基金(10925212) 111计划(B07050)资助项目~~

关键词弹性支撑拓扑优化热应力热变形协调支撑刚度 elastic support, topology optimization, thermal stress, coordination of thermal deformation, support stiffness

分类号 TB303 [一般工业技术—材料科学与工程]

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参考文献13

1Noda N, Hetnarski RB, Tanigawa Y. Thermal Stress. 2nd edn. New York: Taylor and Francis, 2003.
2Friswell MI, Wang D. The minimum support stiffness required to raise the fundamental natural frequency of plate structures. Journal of Sound and Vibration, 2007, 301:665-677.
3Wang CY. Minimum stiffness of an internal elastic support to maximize the fundamental frequency of a vibrating beam. Journal of Sound and Vibration, 2003, 259:229-232.
4Pedersen P, Pedersen NL. Strength optimized designs of ther- moelastic structures. Structural and Multidisciplinary Opti- mization, 2010, 42:681-691.
5Gao T, Zhang WH. Topology optimization involving thermo- elastic stress loads. Structural and Multidisciplinary Opti- mization, 2010, 42:725-738.
6Yan J, Cheng GD, Liu L. A uniform optimum material based model for concurrent optimization of thermoelastic structures and materials. International Journal for Simulation and Multidisciplinary Design Optimization, 2008, 2:259-266.
7Chen B, Tong L. Thermo-mechanically coupled sensitivity analysis and design optimization of functionally graded ma- terials. Computer Methods in Applied Mechanics and Engi- neering, 2005, 194:1891-1911.
8Rodrigues H, Fernandes P. A material based model for topology optimization of thermoelastic structures. International Jour- nal fdr Numerical Methods in Engineering, 1995, 38: 1951- 1965.
9孙士平,张卫红.热弹性结构的拓扑优化设计[J].力学学报,2009,41(6):878-887. 被引量：9
10Rozvany GIN. On design-dependent constraints and singular topologies. Structural and Multidisciplinary Optimization, 2001, 21:164-172.

二级参考文献9

1Rodrigues H, Fernandes P. A material based model for topology optimization of thermoelastic structures. Int J Numerical Methods in Engineering, 1995, 38:1951-1965.
2Li Q, Steven GP, Xie YM. Displacement minimization of themoelastic structures by evolutionary thickness design. Computer Methods in Applied Mechanics Engineering, 1999, 179:361-378.
3Cho S, Choi JY. Efficient topology optimization of thermo-elasticity problems using coupled field adjoint sensitivity analysis method. Finite Elements in Analysis and Design, 2005, 41:1481-1495.
4Rozvany GIN. Basic geometrical properties of exact optimal composite plates. Computers and Structures, 2000, 76: 263-275.
5Rozvany GIN. Exact analytical solutions for some popular benchmark problem in topology optimization. Structural Optimization, 1998, 15:42-48.
6Zhang WH, Fleury C. A modification of convex approximations methods for structural optimization. Computers and Structures, 1997, 64:89-95.
7Stolpe M, Svanberg K. An alternative interpolation scheme for minimum compliance topology optimization. Structural and Multidisciplinary Optimization, 2001, 22:116-124.
8Bendsoe MP, Sigmund O. Material interpolation schemes in topology optimization. Archive of Applied Mechanics, 1999, 69:635-654.
9Stolpe M, Svanberg K. On the trajectories of penalization methods for topology optimization. Structural and Multidisciplinary Optimization, 2001, 21:140-151.

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1徐胜利,牛斌,程耿东.材料设计的晶核法[J].固体力学学报,2010,31(4):369-378. 被引量：1
2LIU XinJun,WANG Chao,ZHOU YanHua.Topology optimization of thermoelastic structures using the guide-weight method[J].Science China(Technological Sciences),2014,57(5):968-979. 被引量：4
3倪晓琴,程耿东.热荷载作用下薄板的优化设计[J].应用数学和力学,2015,36(3):233-241. 被引量：3
4赵清海,陈潇凯,林逸.基于有限体积法的稳态热传导结构拓扑优化[J].北京理工大学学报,2016,36(11):1117-1121. 被引量：5
5赵清海,张洪信,华青松,蒋荣超,袁林.基于Ordered-RAMP模型的热固耦合结构多材料拓扑优化方法[J].计算机辅助设计与图形学学报,2019,31(2):340-348. 被引量：3
6郭伟超,李辉,李丙震,孔令飞,刘永,苏力争.热力耦合情况下的导弹导引头多尺度并行拓扑优化设计方法[J].航空动力学报,2024,39(5):181-189. 被引量：1
7王琪,武龙,刘振,刘建霞,夏凉.热弹性多构型梯度点阵结构拓扑优化设计[J].航空学报,2024,45(23):202-211. 被引量：1
8兰鹏伟,张业伟,梁缘,刘宏亮.热机械载荷下多孔结构的填充拓扑优化[J].力学学报,2025,57(7):1660-1670.

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1张磊,郑建平,付跃刚,刘智颖.大口径反射光学系统的支撑结构设计[J].仪器仪表学报,2005,26(z1):461-463. 被引量：5
2唐羽烨,薛明德.蜂窝夹芯板的热学与力学特性分析[J].复合材料学报,2005,22(2):130-136. 被引量：33
3荣见华,唐国金,杨振兴,傅建林.一种三维结构拓扑优化设计方法[J].固体力学学报,2005,26(3):289-296. 被引量：38
4左孔天,钱勤,赵雨东,陈立平.热固耦合结构的拓扑优化设计研究[J].固体力学学报,2005,26(4):447-452. 被引量：18
5张文君,顾行发,陈良富,余涛,许华.基于均值-标准差的K均值初始聚类中心选取算法[J].遥感学报,2006,10(5):715-721. 被引量：61
60 Sigmund. M P Bendsce. Topology Optimization: Theory, Meth- ods, and Application[ M]. Springer, 2003.
7T Gao, W H Zhang. Topology optimization involving thermo - elas- tic stress loads [ J ]. Structural and Multidisciplinary Optimization, 2010,42(5) :725 -738.
8B Wang, J Yan, G D Cheng. Optimal structure design with low thermal directional expansion and high stiffness [ J ]. Engineering Optimization, 2011,43 (6) : 581 - 595.
9M P Bendsce. Optimal shape design as a material distribution problem[ J]. Structural Optimization, 1989,1 (4) : 193 - 202.
10M Stolpe, K Svanberg. An alternative interpolation scheme for minimum compliance topology optimization [ J ]. Structural and Multidisciplinary Optimization, 2001,22 ( 2 ) : 116 - 124.

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2李湘勤,谢军,刘永明,刘震宇.热力耦合作用下支撑平台的拓扑优化[J].计算机仿真,2014,31(4):227-231. 被引量：4
3何彬,李响.冷镦机床身热力分析与结构优化[J].锻压技术,2014,39(9):92-96. 被引量：1
4刘萍.汽车内部拓扑设计优化设计与仿真分析[J].计算机仿真,2014,31(9):178-181.
5何彬,李响.一种新型组合蜂窝夹芯的热性能分析与尺寸改进方法[J].现代制造工程,2016(2):12-15.
6唐其琴,李伯阳,石运国,王国力.热力复合作用下的典型弹箭结构优化设计[J].机械强度,2016,38(6):1229-1236. 被引量：5
7徐妍彦,谢斌,陈明祥.基于二维密度法的电—热耦合拓扑优化分析[J].微处理机,2024,45(6):31-36.

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2周连生,于新峰,吴志会,芮大为,张巍.基于小物镜系统的热像差影响因素分析[J].激光与光电子学进展,2014,51(9):197-204. 被引量：6
3刘旭堂,高云国.大口径激光发射窗口拼接方法研究[J].光学学报,2014,34(10):243-248. 被引量：4
4许尧,黄一帆,常军.挠性压圈在被动式热分析中的应用研究[J].中国激光,2015,42(1):342-349. 被引量：3
5李雄魁,徐珊珊,闫路,耿文涛,王斌,张晓晖.运载火箭惯组基座设计与优化[J].强度与环境,2015,42(1):46-53. 被引量：5
6韩琪,蔡勇.基于GPU的大规模拓扑优化问题并行计算方法[J].计算机仿真,2015,32(4):221-226. 被引量：5
7姚劲刚,张金平,郑列华,郝沛明.干涉零位补偿检验研究[J].光学学报,2015,35(6):248-254. 被引量：11
8孙毅,高云国,邵帅.多波段激光合束镜温度适应性分析[J].长春理工大学学报（自然科学版）,2015,38(3):1-5. 被引量：1
9胡海飞,罗霄,戚二辉,胡海翔,郑立功.超大口径光学制造的静压支撑系统集成与控制[J].光学学报,2015,35(8):246-254. 被引量：4
10孙毅,高云国,邵帅.高功率激光热效应对合束系统的影响[J].光学精密工程,2015,23(11):3097-3106. 被引量：8

17款热销数码单反实拍测试[J].数码摄影,2007(11):66-79.
2杜大翔,杜义贤,尹艺峰,周鹏,田启华.网格数及体积比对微结构拓扑构型的影响分析[J].三峡大学学报（自然科学版）,2017,39(2):89-92.
3马骏,戴俊,孙炳南,寇西平,荆建平.轴承支撑特性及其对轴系动特性的影响[J].噪声与振动控制,2011,31(5):22-26. 被引量：7
4胡卫强,王敏庆.迟滞相频特性方法测量方程的一种改进[J].船舶工程,2014,36(4):61-64.
5徐敬勃,刘高锋.某磁浮飞轮转子系统有限元分析[J].计算机辅助工程,2011,20(2):86-89.
6闫锋,马文坚.齿式压缩机振动速度缓升故障溯源与处置[J].工业技术创新,2017,4(1):113-114.
7赵厚继,刘厚根,王宇奇,朱晓东.基于ANSYS机械增压器主动轴的动态特性分析[J].机械传动,2009,33(3):1-3. 被引量：3
8范华林,方岱宁.胞元材料拓扑构型与力学性能的相关性[J].清华大学学报（自然科学版）,2007,47(11):2072-2075. 被引量：8
9胡涵,米永振,郑辉.面向高效推进的硬岩隧道掘进机前支撑刚度优化设计[J].噪声与振动控制,2017,37(1):108-112. 被引量：2
10苏勋文,刘晋浩,王少萍.旋翼试验台传动系统振动分析与实验[J].振动与冲击,2014,33(16):177-182. 被引量：1

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热力耦合结构的弹性支撑分析与拓扑优化设计被引量：7

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热力耦合结构的弹性支撑分析与拓扑优化设计 被引量：7

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热力耦合结构的弹性支撑分析与拓扑优化设计被引量：7