梁式称重传感器弹性体的固有频率的提高及结构参数优化
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摘要
合理的结构参数组合能够提高悬臂梁式称重传感器弹性体的固有频率,并且能够改善传感器的响应特性。先通过Solidworks参数化建模软件建立悬臂梁式称重传感器的参数化三维模型。为实现参数传递不丢失,再建立Solidworks与ANSYS Workbench的无缝连接。在对悬臂梁式称重传感器进行模态分析的基础上,基于ANSYS Workbench的优化设计功能模块,对其进行优化计算分析,通过计算、分析相关参数对优化目标的敏感性和输入参数对优化目标的响应,来确定最佳的优化方案,并与原方案比较,结果表明:优化后的传感器固有频率提高了2. 47%,达到了优化目的。
A reasonable combination of structural parameters can improve the natural frequency of the cantilever beam weighing sensor elastomer and can improve the response characteristics of the sensor. The parameterized 3 D model for the cantilever beam load cell is established through the Solidworks parameterized modeling software. In order to achieve parameter transmission without lossing,a seamless connection between the Solidworks and the ANSYS Workbench is established. On the basis of modal analysis on the cantilever load cell,based on the optimized design function module of ANSYS Workbench,optimized calculation and analysis are carried out,by calculating and analying on sensitivity of the relevant parameters to the optimization target and the input parameters to the optimization target to determine the best optimization plan. Through the comparison with the original plan,the result shows that the natural frequency of the optimized sensor is increased by 2. 47 %,achieve the goal of optimization.
A reasonable combination of structural parameters can improve the natural frequency of the cantilever beam weighing sensor elastomer and can improve the response characteristics of the sensor. The parameterized 3 D model for the cantilever beam load cell is established through the Solidworks parameterized modeling software. In order to achieve parameter transmission without lossing,a seamless connection between the Solidworks and the ANSYS Workbench is established. On the basis of modal analysis on the cantilever load cell,based on the optimized design function module of ANSYS Workbench,optimized calculation and analysis are carried out,by calculating and analying on sensitivity of the relevant parameters to the optimization target and the input parameters to the optimization target to determine the best optimization plan. Through the comparison with the original plan,the result shows that the natural frequency of the optimized sensor is increased by 2. 47 %,achieve the goal of optimization.
引文
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[2]路峻岭,田文杰,张伟,等.压电谐振式力传感器响应时间的研究[J].仪表技术与传感器,2005(12):49-51.
[3]杨一柳,佘东生,魏泽飞.一种双桥臂微悬臂梁谐振频率的影响因素研究[J].渤海大学学报:自然科学版,2015,36(2):183-187.
[4]杨帅,王太勇.竖直方向弹性约束悬臂梁的固有频率分析[J].天津大学学报,2011,44(1):18-22.
[5]褚雷阳,于德润,刘宝伟,等.加速度传感器壳体结构参数优化[J].传感器与微系统,2014,33(12):13-16.
[6]崔宏敏,陈宝成,丁钟凯,等.压力传感器结构参数识别及优化方法[J].仪器仪表学报,2016,37(12):2805-2812.
[7]姚道壮,杨建国,吕志军.基于ANSYS Workbench的货架立柱截面优化设计[J].东华大学学报:自然科学版,2011,37(4):438-441,475.
[8]张国锋,王卫荣.基于ANSYS Workbench的吊座尺寸多目标优化设计[J].机械工程与自动化,2014(1):69-70,73.
[9]张付英,陈建垒,王宏浩,等.基于响应曲面法的油封结构参数优化设计[J].润滑与密封,2017,42(9):86-91.
[10]冯强,仲梁维,李磊. ANSYS Workbench仿真平台在支架优化设计中的应用[J].软件导刊,2017,16(11):172-175.
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