100T锻造操作机行走驱动液压系统设计
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摘要
作为现代锻造工业中重要的辅助设备,锻造操作机具有工作响应速度快、自动化程度高、定位精度高、抗干扰能力强、工作稳定和缓冲性能良好等优点,在装备制造业中得到了广泛应用。详细介绍100T/250Tm液压操作机行走驱动液压系统的设计、参数选择以及液压元件的型号确定等方面的内容,可为类似设计提供参考。
Forging manipulator is an important auxiliary equipment for modern forging industry. It has fast response speed,high automation,high precision,strong anti-interference ability,stable operation and good cushioning performance and other advantages. So it has been widely used in the equipment manufacturing industry. For 100 T/250 Tm hydraulic forging manipulator,the design,parameter selection and hydraulic components determination for the driving hydraulic system of the forging manipulator were introduced. It provides reference for similar design.
Forging manipulator is an important auxiliary equipment for modern forging industry. It has fast response speed,high automation,high precision,strong anti-interference ability,stable operation and good cushioning performance and other advantages. So it has been widely used in the equipment manufacturing industry. For 100 T/250 Tm hydraulic forging manipulator,the design,parameter selection and hydraulic components determination for the driving hydraulic system of the forging manipulator were introduced. It provides reference for similar design.
引文
[1]郭加宁,邓子龙,韦丽娃.锻造操作机大车行走液压控制系统仿真研究[J].机械与电子,2015(5):27-29.GUO J N,DENG Z L,WEI L W.Simulation Analysis on Driving Hydraulic Control System of Forging Manipulator[J].Machinery&Electronics,2015(5):27-29.
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[3]周斌,李阁强,江兵,等.20t锻造操作机大车行走液压控制系统设计[J].液压与气动,2014(6):92-94.ZHOU B,LI G Q,JIANG B,et al.Design of 20t Forging Manipulator Driving Hydraulic Control System[J].Chinese Hydraulics&Pneumatics,2014(6):92-94.
[4]成大先.机械设计手册(单行本):液压传动[M].北京:化学工业出版社,2005:20-47.
[5]李亚星.锻造操作机夹钳旋转液压控制系统的研发与分析[J].冶金设备,2013(S2):64-65.LI Y X.Design and Analysis of Hydraulic Control System of Forging Manipulator[J].Metallurgical Equipment,2013(S2):64-65.
[6]傅新,徐明,王伟,等.锻造操作机液压系统设计与仿真[J].机械工程学报,2010,46(11):49-54.FU X,XU M,WANG W,et al.Hydraulic System Design and Simulation of the Forging Manipulator[J].Journal of Mechanical Engineering,2010,46(11):49-54.
[7]郑江.锻造操作机电液比例位置控制系统研究[D].武汉:华中科技大学,2003.
[8]孔祥东,翟富刚,张杨,等.锻造操作机夹钳平行升降机构运动学特性分析[J].燕山大学学报,2010,35(3):198-202.KONG X D,ZHAI F G,ZHANG Y,et al.Research on Kinematics Characteristics of Parallel Lifting Mechanism of Forging Manipulator Tongs[J].Journal of Yanshan University,2010,35(3):198-202.
[2]翟富刚.液压锻造操作机多学科协同仿真研究[D].秦皇岛:燕山大学,2012:11.
[3]周斌,李阁强,江兵,等.20t锻造操作机大车行走液压控制系统设计[J].液压与气动,2014(6):92-94.ZHOU B,LI G Q,JIANG B,et al.Design of 20t Forging Manipulator Driving Hydraulic Control System[J].Chinese Hydraulics&Pneumatics,2014(6):92-94.
[4]成大先.机械设计手册(单行本):液压传动[M].北京:化学工业出版社,2005:20-47.
[5]李亚星.锻造操作机夹钳旋转液压控制系统的研发与分析[J].冶金设备,2013(S2):64-65.LI Y X.Design and Analysis of Hydraulic Control System of Forging Manipulator[J].Metallurgical Equipment,2013(S2):64-65.
[6]傅新,徐明,王伟,等.锻造操作机液压系统设计与仿真[J].机械工程学报,2010,46(11):49-54.FU X,XU M,WANG W,et al.Hydraulic System Design and Simulation of the Forging Manipulator[J].Journal of Mechanical Engineering,2010,46(11):49-54.
[7]郑江.锻造操作机电液比例位置控制系统研究[D].武汉:华中科技大学,2003.
[8]孔祥东,翟富刚,张杨,等.锻造操作机夹钳平行升降机构运动学特性分析[J].燕山大学学报,2010,35(3):198-202.KONG X D,ZHAI F G,ZHANG Y,et al.Research on Kinematics Characteristics of Parallel Lifting Mechanism of Forging Manipulator Tongs[J].Journal of Yanshan University,2010,35(3):198-202.