叶片式液压摆动油缸的动态特性仿真研究
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摘要
为了得到更准确的叶片式液压摆动油缸(摆动油缸)动态特性数学模型,并提高现有摆动油缸的动态性能,对摆动油缸动态特性数学模型力矩平衡方程中由粘性阻尼产生的力矩项进行了改进,运用MATLAB/Simulink对摆动油缸进行仿真,对比数学模型改进前后的角速度响应曲线和高压腔压力曲线,发现数学模型中粘性阻尼产生的力矩对分析摆动油缸的动态特性影响较大,验证了数学模型改进的必要性。对摆动油缸响应快速性和运动平稳性分析,指出影响摆动油缸响应速度和稳定性的主要因素。通过减小摆动油缸油腔与输油管油液总体积对摆动油缸动态性能进行优化,结果表明优化后摆动油缸动态性能得到较大提升。
To obtain a more accurate mathematical model of Rotary Vane Actuator(RVA) dynamic characteristics and improve the dynamic performance of RVA, a more accurate mathematical model of RVA dynamic characteristics is established. The MATLAB/Simulink is used to simulate RVA,comparing the angular velocity response curve and the high pressure cavity pressure curve before and after the improvement of the mathematical model, it is found that the moment generated by the viscous damping in the mathematical model has a great influence on the analysis of the dynamic characteristics of the oscillating cylinder, which verifies the necessity of the improvement of the mathematical model. Analysis of the response speed and motion stability of RVA, pointing out the main factors affecting the response speed and stability of RVA. The dynamic performance of RVA is optimized by reducing the oil volume of RVA and the total volume of the oil pipe. The results show that the dynamic performance of RVA is greatly improved.
To obtain a more accurate mathematical model of Rotary Vane Actuator(RVA) dynamic characteristics and improve the dynamic performance of RVA, a more accurate mathematical model of RVA dynamic characteristics is established. The MATLAB/Simulink is used to simulate RVA,comparing the angular velocity response curve and the high pressure cavity pressure curve before and after the improvement of the mathematical model, it is found that the moment generated by the viscous damping in the mathematical model has a great influence on the analysis of the dynamic characteristics of the oscillating cylinder, which verifies the necessity of the improvement of the mathematical model. Analysis of the response speed and motion stability of RVA, pointing out the main factors affecting the response speed and stability of RVA. The dynamic performance of RVA is optimized by reducing the oil volume of RVA and the total volume of the oil pipe. The results show that the dynamic performance of RVA is greatly improved.
引文
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[3] 杨国来,王淏泽,郭龙,等.阀控液压马达动态特性控制的仿真研究[J].液压气动与密封,2017(1):27-30.
[4] 徐海军,潘存云,谢海斌,等.水下仿生推进器阀控液压摆动关节建模与动态特性分析[J].国防科技大学学报,2010,32(6):116-121.
[5] 王大伟,李新平,纪鹏礼,等.泵控液压马达系统的动态特性分析与仿真[J].煤矿机械,2013,34(12):70-72.
[6] 谢良喜,孔建益,万晓红.矩形截面叶片密封可靠性和机械效率的数值研究[J].润滑与密封,2009(7):54-57.
[7] 王春行.液压控制系统[M].北京:机械工业出版社,1999.
[8] 朱术林,康学超.管片拼装机比例阀控液压马达系统特性研究[J].机床与液压,2016,44(20):86-90.
[9] 陈芷,丁求启,刘明波.基于Simulink的气动同步阀静动态性能研究[J].液压与气动,2015(8):67-72.
[10] 夏磊.基于液压驱动的跳跃机器人关键技术研究[D].南京:东南大学,2015.
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