电梯液压缓冲器缓冲特性研究
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摘要
为了获取电梯用液压缓冲器复位弹簧刚度、缓冲质量、下落速度对缓冲特性的影响规律,应用质量守恒方程和能量守恒方程建立了缓冲器液压阻力数学模型,采用数值分析的方法对不同复位弹簧刚度、不同缓冲质量、不同下落速度工况下的缓冲特性进行了分析。结果表明:复位弹簧刚度对缓冲性能有一定影响但优化的空间并不大;在重载工况下,该液压缓冲器满足性能要求,在轻载工况下,缓冲行程较短但缓冲减速度较大;随着下落速度的增大,缓冲过程平均减速度、最大减速度、缓冲行程均随之增大。
In order to obtain the influence law of the spring stiffness of the elevator hydraulic buffer,the buffer mass and the falling speed of the hydraulic buffer on the cushioning characteristics,the buffer hydraulic resistance mathematic model is established with mass conservation equation and energy conservation equation. The cushion characteristics under conditions of different reset spring stiffness,different buffer quality,different falling speed were analyzed with the method of numerical analysis. The results show that the reset spring stiffness has certain effect on the cushion characteristics but the optimization space is small; the hydraulic bumper can meet the performance requirements under heavy load condition and buffer stroke is shorter but buffer deceleration is larger under light load condition; in the buffering process average deceleration,maximum deceleration,buffer stroke increased with falling speed increasing.
In order to obtain the influence law of the spring stiffness of the elevator hydraulic buffer,the buffer mass and the falling speed of the hydraulic buffer on the cushioning characteristics,the buffer hydraulic resistance mathematic model is established with mass conservation equation and energy conservation equation. The cushion characteristics under conditions of different reset spring stiffness,different buffer quality,different falling speed were analyzed with the method of numerical analysis. The results show that the reset spring stiffness has certain effect on the cushion characteristics but the optimization space is small; the hydraulic bumper can meet the performance requirements under heavy load condition and buffer stroke is shorter but buffer deceleration is larger under light load condition; in the buffering process average deceleration,maximum deceleration,buffer stroke increased with falling speed increasing.
引文
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[8]黄景峰,董楠,刘圣杰.基于Simulink的液压缓冲器动态特性分析[J].机床与液压,2015,43(13):145-148.HUANG J F,DONG N,LIU S J.Study on Dynamic Characteristics of Hydraulic Bumper Based on Simulink[J].Machine Tool&Hydraulics,2015,43(13):145-148.
[9]李海文,王永良,胡月萍,等.碟簧液压操动机构缓冲特性仿真与优化[J].高压电器,2015,51(1):110-114.LI H W,WANG Y L,HU Y P,et al.Simulation and Optimization on Buffering Characteristics of the Disc Spring Hydraulic Operating Mechanisms[J].High Voltage Apparatus,2015,51(1):110-114.
[10]李庆扬,王能超,易大义.数值分析[M].武汉:华中工学院出版社,1982.
[2]马星国,吴琼,尤小梅,等.渐变节流液压缓冲器特性分析与结构优化[J].机床与液压,2015,43(19):100-104.MA X G,WU Q,YOU X M,et al.Performance Analysis and Structural Optimization of Gradual Throttling Hydraulic Buffer[J].Machine Tool&Hydraulics,2015,43(19):100-104.
[3]焦素娟,刘成良,苗中华,等.并联阻尼结构液压缓冲器冲击波形仿真[J].振动与冲击,2007,26(9):27-29.JIAO S J,LIU C L,MIAO Z H,et al.Shock Wave Characteristics of A Hydraulic Damper with Parallel Passages[J].Journal of Vibration and Shock,2007,26(9):27-29.
[4]张文斌,周晓军.液压缓冲器特性计算与仿真分析[J].农业机械学报,2008,39(7):164-168.ZHANG W B,ZHOU X J.Simulation and Characteristic Analysis of Hydraulic Buffer[J].Transactions of the Chinese Society for Agricultural Machinery,2008,39(7):164-168.
[5]马星国,顾婷婷,尤小梅.车用液压缓冲器动态特性研究[J].机床与液压,2013,41(17):56-59.MA X G,GU T T,YOU X M.Research on Dynamic Characteristics of the Hydraulic Buffer for Vehicles[J].Machine Tool&Hydraulics,2013,41(17):56-59.
[6]史华成,高彩云,沈亮.一种力值可调式液压缓冲器的仿真与分析[J].液压与气动,2013(5):69-71.SHI H C,GAO C Y,SHEN L.Simulation and Analysis of New Adjustable Hydraulic Buffer[J].Chinese Hydraulics&Pneumatics,2013(5):69-71.
[7]耿晓光,马飞,李叶林.液压凿岩机双缓冲系统的特性分析与动态仿真[J].机床与液压,2015,43(19):180-183.GENG X G,MA F,LI Y L.Characteristic Analysis and Dynamic Simulation of Double Damper System for Hydraulic Rock Drill[J].Machine Tool&Hydraulics,2015,43(19):180-183.
[8]黄景峰,董楠,刘圣杰.基于Simulink的液压缓冲器动态特性分析[J].机床与液压,2015,43(13):145-148.HUANG J F,DONG N,LIU S J.Study on Dynamic Characteristics of Hydraulic Bumper Based on Simulink[J].Machine Tool&Hydraulics,2015,43(13):145-148.
[9]李海文,王永良,胡月萍,等.碟簧液压操动机构缓冲特性仿真与优化[J].高压电器,2015,51(1):110-114.LI H W,WANG Y L,HU Y P,et al.Simulation and Optimization on Buffering Characteristics of the Disc Spring Hydraulic Operating Mechanisms[J].High Voltage Apparatus,2015,51(1):110-114.
[10]李庆扬,王能超,易大义.数值分析[M].武汉:华中工学院出版社,1982.
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