The correlation of surface roughness and tool edge condition under sustainable cryogenic machining

IF 1.1 Q4 ENGINEERING, MECHANICAL Journal of Mechanical Engineering and Sciences Pub Date : 2023-03-23 DOI:10.15282/jmes.17.1.2023.2.0736

Nurul Hayati Abdul Halim, C. H. Che Haron, J. Abdul Ghani, M. Azhar, M.Z. Zulkifli

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Abstract

This paper investigates the correlation between surface roughness of Inconel 718 and tool edge condition of ball nose inserts when milled at high speed. The cutting parameters were varied as follows; cutting speed: 120–140 m/min, feed rate: 0.15–0.25 mm/tooth, and axial depth of cut: 0.3–0.7 mm. For a sustainable machining approach, the experimental works were carried out under a smooth supply of cryogenic coolant which is a mix of liquid CO2, gas CO2, and compressed air. The experimental results revealed that the range of surface roughness obtained is from 0.114 to 0.197 µm. Along the cutting process, the tool wear patterns such as the abrasion, chipping, and the intermittent build-up-edge near the depth of cut cause the rapid increase of tool wear as well as the roughness of the machined surface with a significant correlation between them. However, the roughness was slowly reduced and became stable with the increase of notch wear. The finding could be used as a prediction reference for monitoring surface roughness and tool wear progress under cryogenic conditions. It also provides foundations for further research on machinability under this sustainable approach.

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可持续低温加工条件下表面粗糙度与刀具边缘条件的相关性

本文研究了高速铣削时铬镍铁合金718的表面粗糙度与球头镶片刃口状况之间的关系。切削参数变化如下：；切削速度：120–140 m/min，进给速度：0.15–0.25 mm/齿，轴向切削深度：0.3–0.7 mm。为了实现可持续的加工方法，实验工作是在平稳供应低温冷却剂的情况下进行的，低温冷却剂是液体CO2、气体CO2和压缩空气的混合物。实验结果表明，获得的表面粗糙度范围为0.114至0.197µm。在切削过程中，刀具磨损模式，如磨损、碎屑和切削深度附近的间歇性堆积边缘，导致刀具磨损和加工表面粗糙度迅速增加，两者之间存在显著相关性。然而，随着缺口磨损的增加，粗糙度逐渐降低并趋于稳定。这一发现可作为监测低温条件下表面粗糙度和刀具磨损过程的预测参考。它还为在这种可持续方法下进一步研究可加工性提供了基础。

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来源期刊

Journal of Mechanical Engineering and Sciences ENGINEERING, MECHANICAL-

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审稿时长

20 weeks

期刊介绍： The Journal of Mechanical Engineering & Sciences "JMES" (ISSN (Print): 2289-4659; e-ISSN: 2231-8380) is an open access peer-review journal (Indexed by Emerging Source Citation Index (ESCI), WOS; SCOPUS Index (Elsevier); EBSCOhost; Index Copernicus; Ulrichsweb, DOAJ, Google Scholar) which publishes original and review articles that advance the understanding of both the fundamentals of engineering science and its application to the solution of challenges and problems in mechanical engineering systems, machines and components. It is particularly concerned with the demonstration of engineering science solutions to specific industrial problems. Original contributions providing insight into the use of analytical, computational modeling, structural mechanics, metal forming, behavior and application of advanced materials, impact mechanics, strain localization and other effects of nonlinearity, fluid mechanics, robotics, tribology, thermodynamics, and materials processing generally from the core of the journal contents are encouraged. Only original, innovative and novel papers will be considered for publication in the JMES. The authors are required to confirm that their paper has not been submitted to any other journal in English or any other language. The JMES welcome contributions from all who wishes to report on new developments and latest findings in mechanical engineering.