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Finite element simulation and experimental research on rotary ultrasonic grinding of titanium alloy |
LIU Fan, QIN Na, NIU Jian-di, ZHENG Liang |
School of Mechanical Engineering, Southwest Jiaotong University, Chengdu 610031, China |
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Abstract In order to study the effects of the abrasive grain size of core tool on grinding force in rotary ultrasonic grinding titanium alloy, abrasive grain in the shape of irregular polyhedron was modeled by cutting regular hexahedron with random interception plane on a hexahedron. Based on virtual grid method, a simulation model of core drill with multi abrasive grains randomly distributing on the end face of tool was built. A 3D finite element model of rotary ultrasonic grinding of titanium alloy was developed by using Deform-3D. The simulation value of grinding force in rotary ultrasonic grinding of titanium alloy Ti6Al4V with multi abrasive grains was obtained by Lagrangian incremental algorithm, and the effects of the abrasive grain size on grinding force was investigated. A series of experiments were conducted to validate the grinding force in rotary ultrasonic grinding of titanium alloy. The result proved that rotary ultrasonic grinding force decreased as abrasive grain size increased and the experimental result agreed well with the simulation result. The result shows that the multi abrasive grain tool model and the finite element model of rotary ultrasonic grinding have certain accuracy. A new way for multi abrasive grain tool relational investigation in rotary ultrasonic grinding has been provided.
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Received: 04 August 2016
Published: 28 April 2017
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旋转超声磨削钛合金有限元仿真与试验研究
为了研究固结磨粒磨具的磨料粒度对旋转超声磨削钛合金磨削力的影响,采用随机空间平面切割正六面体的方法构建了具有实际磨粒几何特征的不规则多面体磨粒,并基于虚拟格子法建立了磨粒在磨具端面随机分布的多颗磨粒磨具模型。使用Deform-3D软件构建了三维旋转超声磨削钛合金有限元模型,采用拉格朗日增量算法获得了多颗磨粒磨具旋转超声磨削钛合金Ti6Al4V的磨削力仿真值,得到了磨料粒度对磨削力的影响规律,并通过试验进行了验证。结果表明,旋转超声磨削钛合金磨削力随着磨料粒度的增大而减小,且试验结果和仿真结果具有一致性,说明了多颗磨粒磨具模型、旋转超声磨削有限元模型具有一定的准确性,为多颗磨粒磨具旋转超声磨削的相关研究提供了新的方法。
关键词:
多颗磨粒,
虚拟格子法,
旋转超声磨削,
钛合金,
有限元分析
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