基于自适应遗传算法的碳纤维复合材料汽车防撞梁优化设计研究
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摘要
目前汽车防撞梁主要采用高碳钢或者铝合金材料,但在设计强度与汽车轻量化方面,碳纤维复合材料(CFRP)有着明显的优势,所以对CFRP汽车防撞梁层合板的性能研究十分重要。将考虑层合板铺层的广义海明距离与遗传算法相结合,提出了能够以汽车防撞梁为模型的优化设计新方法。该算法采用自适应的思想,与传统遗传算法不同,每次重组算子保留最优个体,这有效避免了交叉、变异操作对最优解取值的干扰,解决遗传算法过早收敛的现象。
Currently,high carbon steel or aluminum alloy is applied for automobile collision-resistant beam,but carbon-fiber reinforced polymer(CFRP) has obvious advantages in design intensity and light weight. Therefore,it is very important to study the performance of CFRP automobile collision-resistant beam laminate. In this paper,with the combination of the laminate layer's generalized Hamming distance and the genetic algorithm,a new method of optimization design,which can be used as model of automobile collision-resistant beam,is proposed. This algorithm,based on the adaptive principles,is different from traditional genetic algorithm. Each recombination operator keeps the best individual,which effectively avoids the interference of crossover and mutation operations exerted on the optimal solution,and addresses the premature convergence of the genetic algorithm.
Currently,high carbon steel or aluminum alloy is applied for automobile collision-resistant beam,but carbon-fiber reinforced polymer(CFRP) has obvious advantages in design intensity and light weight. Therefore,it is very important to study the performance of CFRP automobile collision-resistant beam laminate. In this paper,with the combination of the laminate layer's generalized Hamming distance and the genetic algorithm,a new method of optimization design,which can be used as model of automobile collision-resistant beam,is proposed. This algorithm,based on the adaptive principles,is different from traditional genetic algorithm. Each recombination operator keeps the best individual,which effectively avoids the interference of crossover and mutation operations exerted on the optimal solution,and addresses the premature convergence of the genetic algorithm.
引文
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[2]苏尚彬.汽车前防撞梁耐撞性分析及其轻量化研究[D].山东:山东理工大学,2015.
[3]张海洋,莫富灏,肖志,等.纤维增强复合材料汽车保险杠防撞梁的轻量化研究[J].玻璃钢/复合材料,2017(10):34-40.
[4]徐轶,周光明,刘伟先.基于遗传算法的垂直轴风机复合材料叶片铺层优化设计[J].江苏航空,2012(增刊):114-116.
[5]冯雁,郑锡涛,吴淑一,等.轻型复合材料机翼铺层优化设计与分析[J].航空学报,2015,36(6):1858-1866.
[6]程超,汪久根.复合材料力学[M].2版.北京:清华大学出版社,2013:62-69.
[7]沈观林,胡更开,刘彬.基于遗传算法的双列角接触球轴承优化设计[J].机械设计,2015,32(2):46-50.
[8]Srinivas M,Patnaik L M.Adaptive probabilities of crossover and mutation in genetic algorithms[J].IEEE Transactions on System,Man and Cybernetics,1994,24(4):656-667.
[9]任子武,伞冶.自适应遗传算法的改进及在系统辨识中的应用研究[J].系统仿真学报,2006,18(1):41-66.
[10]徐中明,徐小飞,万鑫铭,等.铝合金保险杠防撞梁结构优化设计[J].机械工程学报,2013,49(8):136-142.
[11]许玉荣.复合材料层合板基于可靠性的优化设计与遗传算法[D].武汉:华中科技大学,2005.
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