叶序排布外圆砂轮磨削TC4的磨削力实验研究

doi:10.16731/j.cnki.1671-3133.2017.02.021

现代制造工程 ›› 2017, Vol. 437 ›› Issue (2): 105-108.doi: 10.16731/j.cnki.1671-3133.2017.02.021

叶序排布外圆砂轮磨削TC4的磨削力实验研究

刘兆博, 吕玉山, 王军, 王新争, 陈晨

沈阳理工大学机械工程学院,沈阳 110159

收稿日期:2015-11-26 出版日期:2017-02-28 发布日期:2018-01-08
作者简介:刘兆博,硕士研究生,主要研究方向为叶序排布超硬磨料砂轮磨削机理
E-mail:lzhb1990@126.com
基金资助:
国家自然科学基金项目(51175352)

Experimental investigation on the grinding force of the engineered grinding wheel in grinding TC4

Liu Zhaobo, Lü Yushan, Wang Jun, Wang Xinzheng, Chen Chen

School of Mechanical Engineering,Shenyang Ligong University,Shenyang 110159,China

Received:2015-11-26 Online:2017-02-28 Published:2018-01-08

摘要/Abstract

摘要： 为了获得有序化排布超硬磨料砂轮的磨削性能,以及实现磨削难加工材料钛合金的可行性,基于生物学中的叶序排布理论设计一种新型的有序化排布超硬磨料砂轮,即叶序排布砂轮,并利用其和错位排布砂轮及无序排布砂轮对钛合金TC4进行磨削实验,分析了它们的磨削力随着进给速度和磨削深度的变化规律。实验结果表明:在相同的磨削实验条件下,磨粒叶序排布砂轮的磨削力小于错位排布砂轮和无序排布砂轮。

关键词: 磨削, 超硬磨料砂轮, 叶序排布, 磨削力, 钛合金

Abstract: In order to obtain the grinding performance of the super-abrasive grinding wheel and realize the feasibility of grinding the Titanium alloy,a new kind of the super-abrasive grinding wheel with phyllotactic pattern was designed based on the phyllotaxis theory of biology.And the experiment of grinding the Titanium alloy TC4 was carried out with different grinding wheels.The changing rules of the grinding force with the feed speed and the grinding depth were analyzed.The results show that under the same experiment conditions,the grinding force of the grinding wheel with abrasive phyllotactic pattern is smaller than those with staggered and random pattern.

Key words: grinding, super-abrasive grinding wheel, phyllotactic pattern, grinding force, Titanium alloy

中图分类号:

TG580
TQ153

刘兆博, 吕玉山, 王军, 王新争, 陈晨. 叶序排布外圆砂轮磨削TC4的磨削力实验研究[J]. 现代制造工程, 2017, 437(2): 105-108.

Liu Zhaobo, Lü Yushan, Wang Jun, Wang Xinzheng, Chen Chen. Experimental investigation on the grinding force of the engineered grinding wheel in grinding TC4[J]. Modern Manufacturing Engineering, 2017, 437(2): 105-108.

参考文献

[1] KIM J S,LEE K M,CHO D H,et al.Fretting wear characteristics of titanium matrix composites reinforced by titanium boride and titanium carbide particulates[J].Wear,2013,301(1):562-568.
[2] RANGANATH S.A review on particulate-reinforced titanium matrix composites[J].Journal of Materials Science,1997,32(1):1-16.
[3] XU X P,YU Y Q,HUANG H.Mechanisms of abrasive wear in the grinding of titanium (TC4) and nickel (K417) alloys[J].Wear,2003,255(7):1421-1426.
[4] YU Y Q.Material removal mechanisms in grinding aeronautical alloys,part 1:Experiments and results[J].Key Engineering Materials,2004,259-260:318-323.
[5] ZHAO B,DING W F,XU J H,et al.Comparative study on cutting behavior of vitrified cubic boron nitride wheel and electroplated cubic boron nitride wheel in high-speed grinding of (TiCp+TiBw)/Ti-6Al-4V composites.Proceedings of the Institution of Mechanical Engineers,Part B:Journal of Engineering Manufacture[C].[S.l.]:[s.n.],2014.
[6] HEINAEL C,RICKENS K.Engineered wheels for grinding of optical glass[J].CIRP Annals-Manufacturing Technology,2009,58(1):315-318.
[7] KOSHY P,IWASALD A,ELBESTAWL M A.Surface generation with engineered diamond grinding wheels:insights from simulation[J].CIRP Annals-Manufacturing Technology,2003,52(1):271-274.
[8] 傅玉灿,徐鸿钧.高效磨削用砂轮地貌的优化设计研究[J].应用科学学报,2001,19(1):48-52.
[9] YEATTS F R.A growth-controlled model of the shape of a sunflower head[J].Mathematical Biosciences,2004,187(2):205-221.
[10] PRZEMYSLAW P,JAMES H,DAVID F F,et al.The Algorithmic Beauty of Plants[M].Regina Canada:Springer-Verlag,1990:23-34.
[11] LU Y S,ZHAO C Y,WANG J,et al.Design and fabrication of the super-abrasive grinding wheel with phyllotactic pattern[J].Advanced Materials Research,2012,472(1):2354-2360.
[12] 任敬心,华定安.磨削原理[M].北京:电子工业大学出版社,2011:322-324.

[1]	李东阳，谢海龙，王清辉，廖昭洋，. 基于力反馈的机器人砂带磨削虚拟示教轨迹规划方法[J]. 现代制造工程, 2022, 500(5): 30-35.
[2]	王珉，唐小聪，朱奔驰，信连甲，杨吟飞，赵国龙. 基于干冰低温冷却的大进给铣削TC4钛合金刀具磨损研究[J]. 现代制造工程, 2022, 499(4): 94-101.
[3]	华红艳，冯克明，张葵，赵金坠. 超硬磨料砂轮修整及点轮修整技术[J]. 现代制造工程, 2022, 496(1): 80-84.
[4]	徐翔宇，曹阳，王辉，吴动波. 激光熔覆修复叶片的过渡区力学性能试验研究[J]. 现代制造工程, 2021, 492(9): 118-123.
[5]	李霞. 氮化硅陶瓷磨削温度与表面裂纹扩展研究[J]. 现代制造工程, 2021, 489(6): 57-62.
[6]	李大庆，赵让乾，王振. 基于通用数控加工中心的面齿轮磨齿加工分析仿真及试验[J]. 现代制造工程, 2021, 487(4): 79-82.
[7]	贾玺章，杜龙飞，王钰. 机器人打磨铸钢件的效率与打磨力研究[J]. 现代制造工程, 2021, 487(4): 94-98.
[8]	王运，张昌明，张昱. 车削参数对难加工材料表面粗糙度的影响及参数优化[J]. 现代制造工程, 2021, 485(2): 95-101.
[9]	徐铭洲,丁凯,李奇林,王许,刘盛. 超声辅助磨削碳化硅陶瓷的工具磨损试验研究[J]. 现代制造工程, 2021, 495(12): 88-94.
[10]	蔡卫星，周伟华，张峰. 21NiCrMo5H齿轮钢超声磨削力建模研究[J]. 现代制造工程, 2020, 475(4): 113-118.
[11]	李颂华，隋阳宏，孙健，沙勇. 磨削力对HIPSN陶瓷磨削亚表面裂纹的影响[J]. 现代制造工程, 2020, 474(3): 1-6.
[12]	蓝启鑫，陈彬强，何泽，姚斌，原文，付伟. 可转位刀片周边刃磨削几何仿真系统设计[J]. 现代制造工程, 2020, 482(11): 68-72.
[13]	何高伟,陈扬枝. 砂轮位置偏差对圆柱线齿轮齿形影响的分析[J]. 现代制造工程, 2020, 481(10): 18-25.
[14]	刘智，孙桓五，侯治秀，桑媛园，段海栋，纪刚强. 液体磁性磨具光整加工TC4钛合金的试验研究[J]. 现代制造工程, 2020, 472(1): 29-34.
[15]	刘晓雯，李世杰. 民用发动机涡轮叶片砂带磨削工艺参数的设计与试验[J]. 现代制造工程, 2020, 472(1): 92-96.

叶序排布外圆砂轮磨削TC4的磨削力实验研究

Experimental investigation on the grinding force of the engineered grinding wheel in grinding TC4

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics