Further study on thermal deformation reduction for CFRP-based improved ball screws

IF 1.7 4区材料科学 Q3 MATERIALS SCIENCE, COMPOSITES

Advanced Composites Letters Pub Date : 2020-05-29 DOI:10.1177/2633366X20917981

Xiang-sheng Gao, Yueyang Guo, Min Wang, Tao Zan

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引用次数: 2

Abstract

To determine the thermal deformation of ball screw in actual working condition, a novel method for determining thermal deformation of ball screws in complicated working condition is proposed based on G-code and finite-element (FE) method. In the complicated working condition, it is difficult to obtain and import the nut movement into FE model due to the complex nut movement. In this research, the nut movement is directly determined from G-code by MATLAB code programming. The nut location is recorded with time in a file. The thermal parameters can be determined according to the nut speed with time as well. In the implicit FE analysis, the nut location is read from the input file instead of nut location calculation before every time step. And then, the effect of factors, such as working condition and materials, on thermal deformation reduction of ball screw is studied. The thermal deformation reduction of ball screws under different rotational speed, actual working condition, and different axial elastic modulus of composites is discussed, which can provide the guidelines to evaluate the thermal deformation reduction and design the composite in improved ball screws.

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cfrp基改进滚珠丝杠的热变形减小研究

为了确定滚珠丝杠在实际工况下的热变形，提出了一种基于G-code和有限元法的复杂工况下滚珠丝杠热变形计算方法。在复杂工况下，由于螺母运动的复杂性，难以将螺母运动数据获取并导入有限元模型。在本研究中，螺母的运动是通过MATLAB代码编程直接从g代码中确定的。螺母位置随时间记录在文件中。热参数也可以根据螺母转速随时间的变化来确定。在隐式有限元分析中，从输入文件中读取螺母位置，而不是在每个时间步之前进行螺母位置计算。然后，研究了工况和材料等因素对滚珠丝杠热变形减小的影响。讨论了不同转速、实际工况和不同复合材料轴向弹性模量下滚珠丝杠的热变形减小量，为改进滚珠丝杠的热变形减小量评价和复合材料设计提供指导。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Advanced Composites Letters 工程技术-材料科学：复合

自引率

0.00%

发文量

审稿时长

4.2 months

期刊介绍： Advanced Composites Letters is a peer reviewed, open access journal publishing research which focuses on the field of science and engineering of advanced composite materials or structures.