哈尔滨工程大学学报
哈爾濱工程大學學報
합이빈공정대학학보
Journal of Harbin Engineering University
2015年
9期
1246-1251
,共6页
马闻宇%王宝雨%周靖%黄鸣东%唐学峰%陈晓莉
馬聞宇%王寶雨%週靖%黃鳴東%唐學峰%陳曉莉
마문우%왕보우%주정%황명동%당학봉%진효리
铝合金%热冲压%回弹和减薄%响应面法%多目标优化
鋁閤金%熱遲壓%迴彈和減薄%響應麵法%多目標優化
려합금%열충압%회탄화감박%향응면법%다목표우화
aluminum alloy%hot stamping%thinning and springback%response surface method%multi-objective opti-mization
为解决铝合金热冲压板件存在的减薄和回弹等缺陷,采用响应面法分析了板料初始成形温度和压边力对最大减薄率和最大回弹量的影响规律. 结果表明:成形件的最大减薄率随着板料初始成形温度和压边力的增大而增加;最大回弹量随着板料初始成形温度和压边力的增大而下降. 最大减薄率和最大回弹量之间具有一定的冲突性. 为解决这种冲突,采用多目标遗传算法NSGA-Ⅱ进行多目标优化,得到Pareto最优解. 进而在保证最大减薄率和最大回弹量都相对较小的情况下,确定合理的铝合金热冲压板件的工艺参数范围:板料初始成形温度为470.86~520℃;压边力为110~131.78 kN. 试验结果表明,合理的工艺参数可以避免破裂和减少回弹. 仿真结果与试验具有较好的一致性.
為解決鋁閤金熱遲壓闆件存在的減薄和迴彈等缺陷,採用響應麵法分析瞭闆料初始成形溫度和壓邊力對最大減薄率和最大迴彈量的影響規律. 結果錶明:成形件的最大減薄率隨著闆料初始成形溫度和壓邊力的增大而增加;最大迴彈量隨著闆料初始成形溫度和壓邊力的增大而下降. 最大減薄率和最大迴彈量之間具有一定的遲突性. 為解決這種遲突,採用多目標遺傳算法NSGA-Ⅱ進行多目標優化,得到Pareto最優解. 進而在保證最大減薄率和最大迴彈量都相對較小的情況下,確定閤理的鋁閤金熱遲壓闆件的工藝參數範圍:闆料初始成形溫度為470.86~520℃;壓邊力為110~131.78 kN. 試驗結果錶明,閤理的工藝參數可以避免破裂和減少迴彈. 倣真結果與試驗具有較好的一緻性.
위해결려합금열충압판건존재적감박화회탄등결함,채용향응면법분석료판료초시성형온도화압변력대최대감박솔화최대회탄량적영향규률. 결과표명:성형건적최대감박솔수착판료초시성형온도화압변력적증대이증가;최대회탄량수착판료초시성형온도화압변력적증대이하강. 최대감박솔화최대회탄량지간구유일정적충돌성. 위해결저충충돌,채용다목표유전산법NSGA-Ⅱ진행다목표우화,득도Pareto최우해. 진이재보증최대감박솔화최대회탄량도상대교소적정황하,학정합리적려합금열충압판건적공예삼수범위:판료초시성형온도위470.86~520℃;압변력위110~131.78 kN. 시험결과표명,합리적공예삼수가이피면파렬화감소회탄. 방진결과여시험구유교호적일치성.
To overcome the defects of thinning and springback in aluminum alloy hot stamping, the response surface method was employed to analyze the effects of initial blank temperature and blank holder force ( BHF) on the re-sponse values, namely, the maximum thinning rate and maximum springback value. The results show that the maxi-mum thinning rate increases and the maximum springback value decreases with increasing initial blank temperature and BHF. Conflict exists between the maximum thinning rate and maximum springback value. In order to resolve such conflict, multi-objective optimization was conducted by genetic algorithm ( NSGA-Ⅱ) to reach a Pareto opti-mal solution. To keep both the maximum thinning rate and the maximum springback value at a relatively lower lev-el, the optimal ranges of process parameters were determined: initial blank temperature: 470. 86~520℃; BHF:110~131.78 kN. The results show that reasonable process parameters can avoid cracks and decrease springback. The simulation results agree well with the experimental results.
