随机与区间混合不确定情形下动力总成悬置系统的固有特性分析

摘要
图/表
参考文献(15)
相关文章 (15)

全文: PDF (928 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要工程实际中，汽车动力总成悬置系统(powertrain mount system, PMS)不可避免地存在着各种不确定因素。针对PMS一部分参数信息充足而另一部分参数信息匮乏的情形，本文首先将样本信息充足的参数视为随机变量，而将信息匮乏的参数处理为区间变量；随后，提出了一种求解PMS固有特性混合响应的混合蒙特卡洛法；进一步，结合泰勒展开、随机矩法和中心差分法提出了一种快速求解PMS固有特性混合响应的混合摄动-中心差分法；最后，通过算例验证了方法的有效性，并分析了混合不确定性对PMS固有特性的影响。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	吕辉1
	杨坤1
	区霆钧1
	上官文斌1
	于德介2

关键词 ：动力总成悬置系统, 随机变量, 区间变量, 固有频率, 解耦率

Abstract：In engineering practice, various uncertainties inevitably exist in powertrain mount system (PMS) of vehicles.Here, aiming at cases of parts of PMS parameters’ information being sufficient while other parts of PMS parameters’ being deficient, firstly, PMS parameters with sufficient information were taken as random variables, while PMS parameters with deficient information were treated as interval variables.Then, the hybrid Monte-Carlo method (HMCM) was proposed to solve natural characteristics hybrid response of a PMS.Furthermore, the hybrid perturbation-central difference method (HPCDM) was proposed to quickly solve natural characteristics hybrid response of a PMS through combining Taylor expansion, random moment method and central difference one.Finally, the effectiveness of the proposed methods was verified with a numerical example, and effects of hybrid uncertainties on natural characteristics of PMS were analyzed.

Key words： powertrain mount system random variable interval variable natural frequency decoupling rate

收稿日期: 2019-08-06 出版日期: 2020-11-28

引用本文:

吕辉1，杨坤1，区霆钧1，上官文斌1，于德介2. 随机与区间混合不确定情形下动力总成悬置系统的固有特性分析[J]. 振动与冲击, 2020, 39(23): 58-63.
L Hui1, YANG Kun1, OU Tingjun1, SHANGGUAN Wenbin1, YU Dejie2. Natural characteristics of PMS with random and interval hybrid uncertainties. JOURNAL OF VIBRATION AND SHOCK, 2020, 39(23): 58-63.

链接本文:

http://jvs.sjtu.edu.cn/CN/ 或 http://jvs.sjtu.edu.cn/CN/Y2020/V39/I23/58

[1] Lü H, Shangguan WB, Yu D. An imprecise probability approach for squeal instability analysis based on evidence theory. Journal of Sound and Vibration, 2017, 387(20): 96-113.
[2] Lü H, Shangguan WB, Yu D. A unified approach for squeal instability analysis of disc brakes with two types of random-fuzzy uncertainties. Mechanical Systems and Signal Processing, 2017, 93: 281-298.
[3] 时培成, 陈无畏, 高立新. 基于蒙特卡罗法的动力总成悬置系统稳健性设计[J]. 汽车工程, 2010, 32(08): 707-711.
Shi Pei-cheng, Chen Wu-wei, Gao Li-xin. Robustness Design of Powertrain Mount System Based on Monte Carlo Method. Automotive Engineering, 2010, 32(8):707-711.
[4] 谢展, 于德介, 李蓉. 汽车发动机悬置系统的多目标稳健优化设计[J]. 汽车工程, 2013, 35(10):893-897.
Xie Zhan, Yu De-jie, Li Rong. Multi-objective Robust Optimization Design of Vehicle Engine Mount Systems. Automotive Engineering, 2013, 35(10):893-897.
[5] Wu J. A robust optimization for the frequency and decoupling ratio of a powertrain mounting system based on interval analysis. International Journal of Automotive Technology, 2012, 13(3):409-422.
[6] Xie Y, Zhang W, Feng X, et al. Powertrain mounting system with uncertainty using Chebyshev interval method. 2015, SAE2015-01-0609.
[7] 吕辉, 于德介, 陈宁, 夏百战. 基于可靠性的混合不确定参数汽车盘式制动器振动稳定性分析[J]. 机械工程学报, 2014,50(06):112-119.
Lü Hui, Yu De-jie, Chen Ning, Xia Bai-zhan. Reliability Analysis for Vibration Stability of Automotive Disc Brake System with Hybrid Uncertain Parameters. Journal of Mechanical Engineering, 2014, 50(06): 112-119.
[8] Lü H, Shangguan W B, Yu D. A new hybrid uncertainty analysis method and its application to squeal analysis with random and interval variables. Probabilistic Engineering Mechanics, 2018, 51:1-10.
[9] 周冠南, 蒋伟康, 吴海军. 基于总传递力最小的发动机悬置系统优化设计[J]. 振动与冲击, 2008(8):56-58.
Zhou Guan-nan, Jiang Wei-kang, Wu Hai-jun. Optimal Design of Engine Mount System by Minimizing the Total Force Transmission. Journal of Vibration and Shock. 2008(8):56-58.
[10] 阎红玉, 徐石安. 发动机-悬置系统的能量法解耦及优化设计[J]. 汽车工程, 1993(6):321-328.
Yan Hong-yu, Xu Shi-an. Energy Method of Decoupling and Computer Optimization of Engine Mounting Systems. Automotive Engineering, 1993(6):321-328.
[11] Xia B, Yu D. Modified sub-interval perturbation finite element method for 2D acoustic field prediction with large uncertain-but-bounded parameters. Journal of Sound and Vibration, 2012, 331(16): 3774-3790.
[12] Wang X, Li Y, Ma Z, et al. Robust optimization of structural–acoustic coupled system with random parameters. Aerospace Science and Technology, 2017, 60: 48-57.
[13] Gao W, Song C, Tin-Loi F. Probabilistic interval analysis for structures with Uncertainty. Structural Safety, 2010, 32(3):191-199．
[14] 谢展. 基于不确定性分析的汽车发动机悬置系统设计研究[D]. 长沙：湖南大学, 2013.
Xie zhan. The Research on the Design of Vehicle Mounting Systems Based on Uncertainty Analysis. Changsha: Hunan University, 2013.
[15] Wang L, Cai Y, Liu D. Multiscale reliability-based topology optimization methodology for truss-like microstructures with unknown-but-bounded uncertainties. Computer Methods in Applied Mechanics and Engineering, 2018, 339: 358-388.