基于实车传动系统动力学特性的变刚度扭转吸振器减振控制

doi:10.12382/bgxb.2021.0475

兵工学报 ›› 2022, Vol. 43 ›› Issue (10): 2443-2450.doi: 10.12382/bgxb.2021.0475

• 论文 • 上一篇

基于实车传动系统动力学特性的变刚度扭转吸振器减振控制

高普^1，2，3，项昌乐^1，2，刘辉^1，2

(1.北京理工大学机械与车辆学院，北京 100081； 2.北京理工大学前沿技术研究院，山东济南 250307；3.北京理工大学重庆创新中心，重庆 401147)

上线日期:2022-05-30
通讯作者: 刘辉(1975—)，女，教授，博士生导师 E-mail:lh@bit.edu.cn
作者简介:高普(1989—)，男，副研究员。 E-mail: gaopu1989@126.com
基金资助:
国家自然科学基金项目(52205086、52130512)；基础研究项目(20195208003)；重庆市自然科学基金面上项目(cstc2020jcyj-msxmX1081)

Vibration Reduction Control of Variable Stiffness Torsional Vibration Absorber Based on Real Vehicle Transmission SystemDynamic Characteristics

GAO Pu^1，2，3， XIANG Changle^1，2， LIU Hui^1，2

(1.School of Mechanical Engineering, Beijing Institute of Technology, Beijing 100081, China; 2.Beijing Institute of Technology Advanced Technology Research Institute (Jinan), Jinan 250307, Shandong, China; 3.Chongqing Innovation Center, Beijing Institute of Technology, Chongqing 401147, China)

Online:2022-05-30

摘要/Abstract

摘要： 频率自适应变刚度扭转吸振器的半主动控制研究是实现动力传动系统扭转减振的关键。针对某履带车辆动力传动系统，建立含变刚度扭转减振器的系统动力学模型，基于系统模型提出瞬态查表和稳态寻优结合的控制策略，有效地消除系统外部激励主导频率识别偏差，使变刚度扭转吸振器能够快速跟随外部激励主频，实现扭转吸振器的半主动控制。仿真和试验的研究结果表明，所提综合控制方案能有效提升减振性能10%。

关键词: 变刚度扭转吸振器, 车辆动力传动系统, 控制策略, 主导频率

Abstract: The semi-control of the frequency adaptive magnetorheological elastomer(MRE) torsional vibration absorber is a key step to reduce torsional vibration in the powertrain system. In this paper, aiming at the powertrain system of a tracked vehicle, a dynamic system model with a MRE variable stiffness torsional vibration absorber is established. Based on the model, a control strategy combining transient look-up table and steady-state optimization is proposed to significantly reduce the deviation of the identified external excitation dominant frequency, allowing the absorber to be capable of quickly following the dominant external excitation frequency, thereby achieving semi-active control of the vibration absorber. The simulation and experimental results indicate that the proposed integrated control scheme can improve damping performance by 10%.

Key words: variablestiffnesstorsionalvibrationabsorber, powertrainsystem, controlstrategy, externalexcitationdominantfrequency

中图分类号:

U463.212

高普，项昌乐，刘辉. 基于实车传动系统动力学特性的变刚度扭转吸振器减振控制[J]. 兵工学报, 2022, 43(10): 2443-2450.

GAO Pu， XIANG Changle， LIU Hui. Vibration Reduction Control of Variable Stiffness Torsional Vibration Absorber Based on Real Vehicle Transmission SystemDynamic Characteristics[J]. Acta Armamentarii, 2022, 43(10): 2443-2450.

参考文献

［1］ LONDHE A，YADAV V H.Design and optimization of crankshaft torsional vibration damper for a 4-cylinder 4-stroke engine［R］.New York,NY,US：SAE International，2008.
［2］ NAGAR A，CHOKKALINGAM V，UMASHANKAR N，et al.Improvement in crank train torsional vibration(TV) performance of multi-cylinder diesel engine［R］.New York,NY,US：SAE International，2013.
［3］ SHANGGUAN W B，GUO Y，WEI Y M，et al. Experimental characterizations and estimation of the natural frequency of nonlinear rubber-damped torsional vibration absorbers［J］.Journal of Vibration and Acoustics，2016，138(5): 051006.
［4］ WAGAJ P，KAHRAMAN A.Influence of tooth profile modification on helical gear durability［J］.Journal of Mechanical Design，2002，124: 501-510.
［5］ LI S T. Effects of machining errors，assembly errors and tooth modifications on loading capacity，load-sharing ratio and transmission error of a pair of spur gears［J］.Mechanism and Machine Theory，2007，42: 698-726.
［6］ TESFAHUNEGN Y A，ROSA F，GORLA C.The effects of the shape of tooth profile modifications on the transmission error，bending，and contact stress of spur gears［J］.Proceedings of the Institution of Mechanical Engineers Part C Journal of Mechanical Engineering Science，2010，224(8):1749-1758.
［7］陈家瑞.汽车构造［M］.北京:机械工业出版社，2005.
CHEN J R.Automobile construction［J］.Beijing：China Machine Press，2005.(in Chinese)
［8］项昌乐，耿冲.盖斯林格联轴器动态特性的分析与计算［J］.机械设计，2004，21(8):24-26.
XIANG C L，GENG C.Analysis and calculation on dynamic characteristics of Geis linger coupling［J］.Journal of Machine Design，2004，21(8):24-26. (in Chinese)
［9］史文库，龙岩，卢玉.多级非线性双质量飞轮参数设计与优化［J］.振动与冲击，2009，28(5):92-96.
SHI W K，LONG Y，LU Y. The study of multistage non-linear dual mass flywheel damper［J］.Journal of Vibration and Shock，2009，28(5):92-96.(in Chinese)
［10］ LIU H，WANG X J，LIU F，et al.Stiffness and vibration isolation characteristics of a torsional isolator with negative stiffness structure［J］.Journal of Vibroengineering，2018，20(1): 401-416.
［11］ SARKAR S，FITZGERALD B.Vibration control of spar-type floating offshore wind turbine towers using a tuned mass-damper-inerter［J］.Structural Control and Health Monitoring，2020，27(2): e2471.
［12］ DONG X M，LI W F，YU J Q，et al.Magneto-rheological variable stiffness and damping torsional vibration control of powertrain system［J］.Frontiers in Materials，2020，7:121.
［13］ LI W F，DONG X M，XI J，et al. Semi-active vibration control of a transmission system using a magneto-rheological variable stiffness and damping torsional vibration absorber［J］.Proceedings of the Institution of Mechanical Engineers Part D Journal of Automobile Engineering，2021(2):095440702199949.
［14］ NAGAYA K，KURUSU A，IKAI S，et al. Vibration control of a structure by using a tunable absorber and an optimal vibration absorber under auto-tuning control［J］.Journal of Sound and Vibration，1999，228(4): 773-792.
［15］ BUHR C，FRANCHEK M A，BERNHARD R J. Non-collocated adaptive-passive vibration control［J］. Journal of Sound and Vibration，1997，206(3): 371-398.
［16］ KIDNER M R F，BRENNAN M J.Varying the stiffness of a beam-like neutralizer under fuzzy logic control［J］.Journal of Vibration and Acoustics，2002，124(1): 90-99.
［17］ ZHANG X Z，LI W H.Adaptive tuned dynamic vibration absorbers working with MR elastomers［J］.Smart Structures and Systems，2009，5(5): 517-529.
［18］ LIAO G J，GONG X L，KANG C J，et al.The design of an active-adaptive tuned vibration absorber based on magnetorheological elastomer and its vibration attenuation performance［J］.Smart Materials and Structures，2011，20(7): 075015.
［19］ KIM Y K，KOO J H，KIM K S，et al. Developing a real time controlled adaptive MRE-based tunable vibration absorber system for a linear cryogenic cooler［C］∥Proceedings of IEEE/ASME International Conference on Advanced Intelligent Mechatronics.Budapest，Hungary：IEEE，2011: 287-290.
［20］ QIAN L J，XIN F L，BAI X X，et al.State observation-based control algorithm for dynamic vibration absorbing systems featuring magnetorheological elastomers: Principle and analysis［J］.Journal of Intelligent Material Systems and Structures，2017，28(18):2539-2556.
［21］ FU J，LIAO G Y，YU M，et al.NARX neural network modeling and robustness analysis of magnetorheological elastomer isolator［J］.Smart Materials and Structures，2016，25(12): 125019.
［22］ HE W，XIANG C L，LIU H，et al. Analysis and simulations of the dynamic behaviour of an automotive powertrain during gearshifts［J］.Proceedings of the Institution of Mechanical Engineers，Part D: Journal of Automobile Engineering，2016，230(13):1791-1807.
［23］项昌乐，何韡，刘辉，等.履带车辆传动系统换挡工况瞬态动力学分析［J］.农业机械学报，2016，47(4): 288-293.
XIANG C L，HE W，LIU H,et al.Transient dynamic analysis of tracked vehicle transmission during gear shift process［J］. Transactions of the Chinese Society for Agricultural Machinery，2016，47(4): 288-293. (in Chinese)
［24］王钦.汽车动力总成磁流变弹性体悬置隔振性能及控制策略研究［D］.合肥：合肥工业大学，2015.
WANG Q.Research on vibration isolation performance and control strategy of vehicle powertrain mount with magnetorheological elastomer［D］.Hefei:Hefei University of Technology,2015.(in Chinese)
［25］辛付龙.动力总成磁流变弹性体悬置力学形成机制及控制方法研究［D］.合肥:合肥工业大学，2017.
XIN F L.Study on mechanical formation mechanism and control method of mount of powertrain magnetorheological elastomer［D］.Hefei:Hefei University of Technology,2017.(in Chinese)

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基于实车传动系统动力学特性的变刚度扭转吸振器减振控制

Vibration Reduction Control of Variable Stiffness Torsional Vibration Absorber Based on Real Vehicle Transmission SystemDynamic Characteristics

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