大客车空调压缩机悬置机构优化仿真
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摘要
改进大客车常用曲轴连杆式空调压缩机悬置机构,基于与汽车动力总成悬置系统的相似性,考虑发动机振动和带传动对压缩机振动影响,建立压缩机总成—发动机集总参数模型。以系统能量解耦率为优化目标,系统固有频率和悬置刚度约束作为约束条件,悬置的三向刚度值为设计变量进行优化设计。基于ADAMS建立压缩机总成—发动机动力学模型,仿真结果表明悬置机构改进后压缩机振动减弱,优化后悬置支反力、压缩机质心纵向位移和绕转动轴角加速度明显下降,证明改进悬置机构和优化方法对压缩机隔振的可行性和有效性。
Crankshaft-link type suspension mechanism is commonly used in air-conditioning compressors of improved buses. In this paper, based on the similarity of the automotive powertrain mounting system, a compressor- assembly and engine-lumped parameter model was built to study the engine and belt vibrations. Taking the system energy decoupling rate as the optimization target, the system natural frequency and suspension stiffness as the constraint condition, and the stiffness values in the three special directions as the design variables, optimal design of the suspension mechanism was done. The compressor-assembly and engine-lumped dynamic model was established by means of ADAMS code. Results of simulation show that the vibration of the compressor suspension mechanism is reduced after the improvement. The suspension reaction forces, longitudinal displacement of the mass centroid axis of the compressor, and the angular acceleration about the vertical axis are effectively decreased. The results have proved the feasibility and effectiveness of the optimized model in compressor's vibration isolation.
Crankshaft-link type suspension mechanism is commonly used in air-conditioning compressors of improved buses. In this paper, based on the similarity of the automotive powertrain mounting system, a compressor- assembly and engine-lumped parameter model was built to study the engine and belt vibrations. Taking the system energy decoupling rate as the optimization target, the system natural frequency and suspension stiffness as the constraint condition, and the stiffness values in the three special directions as the design variables, optimal design of the suspension mechanism was done. The compressor-assembly and engine-lumped dynamic model was established by means of ADAMS code. Results of simulation show that the vibration of the compressor suspension mechanism is reduced after the improvement. The suspension reaction forces, longitudinal displacement of the mass centroid axis of the compressor, and the angular acceleration about the vertical axis are effectively decreased. The results have proved the feasibility and effectiveness of the optimized model in compressor's vibration isolation.
引文
[1]王久生.大客车空调的现状及发展趋势[J].汽车空调技术,2003,5:45-46.
[2]董自强.关于客车空调压缩机减振问题的思考[J].制冷与空调,2011,11(3):69-71.
[3]武圆,刘仁喜.空车空调压缩机的振动现象分析[J].城市车辆,2003(1):41-42.
[4]刘志奇,刘之江.客车空调压缩机减振机构的改进[J].机电工程技术,2002,31(1):158-159.
[5]陈助碧,范兴标.基于皮带约束的客车动力总成悬置系统的动力学建模分析及其应用[J].客车技术与研究,2011,33(1):9-12.
[6]王小莉,上官文斌,张少飞,等.发动机前端附件驱动系统—曲轴扭振系统耦合建模与曲轴扭振分析[J].振动工程学报,2011,24(5):505-511.
[7]范让林,吕振华.汽车动力总成三点式悬置系统的设计方法探讨[J].汽车工程,2005,27(3):304-308.
[8]吕振华,范让林.动力总成—悬置系统振动解耦设计方法[J].机械工程学报,2005,41(4):49-52.
[9]吴飞,胡朝辉,成艾国,等.综合考虑解耦率和隔振率的发动机悬置系统多目标优化[J].汽车工程,2013,35(1):18-22.
[10]刘元冬,王文林,罗明军.基于Adams发动机前端附件带传动的动态特性研究[J].机械传动,2013,37(6):28-32.
[11]王红云.单根多楔带附件驱动系统动态特性建模与仿真技术的研究[D].广州:华南理工大学,2010.
[2]董自强.关于客车空调压缩机减振问题的思考[J].制冷与空调,2011,11(3):69-71.
[3]武圆,刘仁喜.空车空调压缩机的振动现象分析[J].城市车辆,2003(1):41-42.
[4]刘志奇,刘之江.客车空调压缩机减振机构的改进[J].机电工程技术,2002,31(1):158-159.
[5]陈助碧,范兴标.基于皮带约束的客车动力总成悬置系统的动力学建模分析及其应用[J].客车技术与研究,2011,33(1):9-12.
[6]王小莉,上官文斌,张少飞,等.发动机前端附件驱动系统—曲轴扭振系统耦合建模与曲轴扭振分析[J].振动工程学报,2011,24(5):505-511.
[7]范让林,吕振华.汽车动力总成三点式悬置系统的设计方法探讨[J].汽车工程,2005,27(3):304-308.
[8]吕振华,范让林.动力总成—悬置系统振动解耦设计方法[J].机械工程学报,2005,41(4):49-52.
[9]吴飞,胡朝辉,成艾国,等.综合考虑解耦率和隔振率的发动机悬置系统多目标优化[J].汽车工程,2013,35(1):18-22.
[10]刘元冬,王文林,罗明军.基于Adams发动机前端附件带传动的动态特性研究[J].机械传动,2013,37(6):28-32.
[11]王红云.单根多楔带附件驱动系统动态特性建模与仿真技术的研究[D].广州:华南理工大学,2010.
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