The Effect of High-Pressure Jet Cooling on Surface Roughness, Cutting Force and Chip Formation of Ti-6Al-4V ELI in High-Speed Turning

IF 2.7 4区 工程技术 Q2 ENGINEERING, MANUFACTURING
F. Taylan, Tolgahan Ermergen
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Abstract

Abstract In the machining of difficult-to-machine metals, such as titanium-based alloys, the delivery of coolant with high pressure can increase machining efficiency and improve process stability through more efficient chip breaking and better cooling. Proper selection of machining conditions can also increase the productivity of the process by reducing cutting forces and tool wear rate. To investigate the effect of high-pressure jet cooling (HPJC) on cutting force, surface roughness, and chip formation of Ti-6Al-4V ELI in high-speed turning, Grade 5 Ti ELI turning tests were carried out under coolant pressure of 200 bar. A lower pressure of 6 bar was also used in this study to compare the results of the pressure change. In general, surface roughness increased as the feed rate increased at constant cutting speeds in experiments with both 6 bar and 200 bar coolant pressures. Even though 200 bar pressure provided a better cooling thus reduced cutting force, and tool wear rate; the surface roughness values obtained from the experiments with 200 bar were relatively worse than the experiments with 6 bar pressure. It was also seen that 200 bar coolant pressure may result in instabilities in the turning process in terms of chip geometries and formations.
高压射流冷却对高速车削Ti-6Al-4V ELI表面粗糙度、切削力和切屑形成的影响
在钛基合金等难加工金属的加工中,高压冷却液的输送可以通过更高效的断屑和更好的冷却来提高加工效率和工艺稳定性。适当选择加工条件还可以通过降低切削力和刀具磨损率来提高加工的生产率。为了研究高压射流冷却(HPJC)对高速车削Ti- 6al - 4v ELI切削力、表面粗糙度和切屑形成的影响,在冷却液压力为200 bar的条件下进行了5级Ti ELI车削试验。在本研究中还使用了较低的6 bar压力来比较压力变化的结果。在6 bar和200 bar冷却液压力下,在恒定切削速度下,表面粗糙度随着进给量的增加而增加。尽管200 bar的压力提供了更好的冷却,从而降低了切削力和刀具磨损率;在200 bar压力下得到的表面粗糙度值相对差于6 bar压力下得到的表面粗糙度值。研究还发现,200 bar的冷却液压力可能导致车削过程中切屑几何形状和形状的不稳定。
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来源期刊
Machining Science and Technology
Machining Science and Technology 工程技术-材料科学:综合
CiteScore
5.70
自引率
3.70%
发文量
18
审稿时长
6 months
期刊介绍: Machining Science and Technology publishes original scientific and technical papers and review articles on topics related to traditional and nontraditional machining processes performed on all materials—metals and advanced alloys, polymers, ceramics, composites, and biomaterials. Topics covered include: -machining performance of all materials, including lightweight materials- coated and special cutting tools: design and machining performance evaluation- predictive models for machining performance and optimization, including machining dynamics- measurement and analysis of machined surfaces- sustainable machining: dry, near-dry, or Minimum Quantity Lubrication (MQL) and cryogenic machining processes precision and micro/nano machining- design and implementation of in-process sensors for monitoring and control of machining performance- surface integrity in machining processes, including detection and characterization of machining damage- new and advanced abrasive machining processes: design and performance analysis- cutting fluids and special coolants/lubricants- nontraditional and hybrid machining processes, including EDM, ECM, laser and plasma-assisted machining, waterjet and abrasive waterjet machining
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