15CDV6 HSLA钢最小量和全润滑条件下高速加工参数优化

IF 2.8 3区工程技术 Q2 ENGINEERING, MANUFACTURING

Advances in Production Engineering & Management Pub Date : 2020-12-24 DOI:10.14743/apem2020.4.374

A. H. Khawaja, M. Jahanzaib, T. A. Cheema

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引用次数: 8

摘要

高速加工(HSM)一直对金属零件的最佳效果制备感兴趣，但随着高速加工的应用，可持续性问题变得重要。为了克服这一问题，在高速切削加工过程中，最小量润滑(MQL)是传统切削(铣削)过程中具有创新性和挑战性的任务之一，可以在可持续发展的前提下提高质量、生产率和强度。本研究的目的是通过同时优化MQL和全润滑条件下15CDV6 HSLA钢高速加工过程中的可持续加工驱动器，实现可持续加工。响应面方法已被应用于数学模型的开发和选择最佳的工艺参数组合，以优化响应，即表面粗糙度，材料去除率和强度。与可持续性相关的优化产生了折衷的最佳结果(最小Ra为0.131µm，最大Ra为0.131µm)。MRR 0.64 cm3/min;最高切削速度为270 m/min，最低进给速度为0.09 mm/rev，切削深度为0.15 mm。对比研究表明，MQL对材料的Ra(1.1 ~ 16.6%)和ST(1.3 ~ 2.3%)有显著的改善，有力地表明MQL是比洪水润滑更好的替代品。该方法的科学贡献是在MQL和泛流润滑下开发数学模型，这将帮助从业者在没有实验的情况下选择所需响应的输入参数。由于15CDV6 HSLA钢具有优异的力学性能，该工作将有利于航空、国防和航空领域的应用。

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High-speed machining parametric optimization of 15CDV6 HSLA steel under minimum quantity and flood lubrication

High-speed machining (HSM) maintains a high interest in the preparation of metal parts for optimum results, but with the application of HSM, the sustainability issue becomes important. To overcome the problem, minimum quantity lubrication (MQL) during HSM is one of the innovative and challenging tasks during conventional cutting (milling) to improve quality, productivity, and strength under the umbrella of sustainability. The objective of this research is to achieve sustainable machining by simultaneously optimizing sustainable machining drivers during the HSM of 15CDV6 HSLA steel under MQL and flood lubrication. The response surface methodology has been applied for the development of mathematical models and selecting the best combination of process parameters to optimized responses, i.e. surface roughness, material removal rate, and strength. Optimization associated with sustainability produced compromising optimal results (Min. Ra 0.131 µm, Max. MRR 0.64 cm3/min, and Max. ST 1132 MPa) at the highest cutting speed 270 m/min and the lowest feed rate 0.09 mm/rev and depth of cut 0.15 mm under MQL. The comparative investigation exposed that significant improvement in Ra (1.1-16.6 %) and ST (1.3-2.3 %) of the material using MQL has been witnessed and gives a strong indication that MQL is the best substitute than the flood lubrication. The scientific contribution of the approach is to develop mathematical models under MQL and flood lubrication that will aid practitioners to choose input parameters for desired responses without experimentations. The work would be beneficial in the field of aviation, defense, and aeronautical applications due to the excellent mechanical properties of 15CDV6 HSLA steel.

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来源期刊

Advances in Production Engineering & Management ENGINEERING, MANUFACTURINGMATERIALS SCIENC-MATERIALS SCIENCE, MULTIDISCIPLINARY

CiteScore

5.90

自引率

22.20%

发文量

期刊介绍： Advances in Production Engineering & Management (APEM journal) is an interdisciplinary international academic journal published quarterly. The main goal of the APEM journal is to present original, high quality, theoretical and application-oriented research developments in all areas of production engineering and production management to a broad audience of academics and practitioners. In order to bridge the gap between theory and practice, applications based on advanced theory and case studies are particularly welcome. For theoretical papers, their originality and research contributions are the main factors in the evaluation process. General approaches, formalisms, algorithms or techniques should be illustrated with significant applications that demonstrate their applicability to real-world problems. Please note the APEM journal is not intended especially for studying problems in the finance, economics, business, and bank sectors even though the methodology in the paper is quality/project management oriented. Therefore, the papers should include a substantial level of engineering issues in the field of manufacturing engineering.