Magnetic and ultrasonic vibration dual-field assisted ultra-precision diamond cutting of high-entropy alloys

IF 14 1区 工程技术 Q1 ENGINEERING, MANUFACTURING International Journal of Machine Tools & Manufacture Pub Date : 2024-09-03 DOI:10.1016/j.ijmachtools.2024.104208
Yintian Xing , Yue Liu , Tengfei Yin , Denghui Li , Zhanwen Sun , Changxi Xue , Wai Sze Yip , Suet To
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Abstract

Despite the remarkable achievements in single-energy field-assisted diamond cutting technology, its performance remains unsatisfactory for processing high-entropy alloys (HEAs), targeted for next-generation large-scale industrial applications due to their exceptional properties. The challenge lies in overcoming the limitations of current single-energy field-assisted processing to achieve ultra-precision manufacturing of these advanced materials. This study proposes a multi-energy field-assisted ultra-precision machining technology, the magnetic and ultrasonic vibration dual-field assisted diamond cutting (MUVFDC), to address the current challenges. The phenomenological aspects of the dual-field coupling effect on HEAs are explored and investigated through comprehensive characterization of the workpiece material, ranging from macroscopic surface morphology to microscopic structural features. These analyses are performed based on experimental results from four different processing technologies: non-energy field, magnetic field, ultrasonic vibration field, and dual-field assisted machining. Research results demonstrate that MUVFDC technology effectively combines the advantages of a vibration field, which enhances cutting stability, and a magnetic field, which improves the machinability of materials. Additionally, this coupling technology addresses the challenges associated with single-energy field machining: it mitigates the difficulty of controlling surface scratches caused by tiny hard particles in a vibration field and suppresses the rapid tool wear encountered in a magnetic field. Furthermore, the gradient evolution of the subsurface microstructure reveals that the vibration field suppresses the severe matrix deformation induced by magnetic excitation. Simultaneously, the magnetic field reduces the size inhomogeneity of recrystallized grains caused by intermittent cutting. Overall, MUVFDC technology enhances surface quality, suppresses tool wear, smooths chip morphology, and reduces subsurface damage compared to single-energy field or non-energy-assisted machining. This work breaks through the performance limitations of traditional single-energy field-assisted processing and advances the understanding of the dual-field coupling effects in HEAs machining. It also presents a promising processing technology for the future ultra-precision manufacturing of advanced materials.

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磁场和超声波振动双场辅助超精密金刚石切割高熵合金
尽管单能场辅助金刚石切割技术取得了令人瞩目的成就,但在加工高熵合金(HEAs)时,其性能仍不尽如人意。如何克服当前单能量场辅助加工的局限性,实现这些先进材料的超精密制造,是一项挑战。本研究提出了一种多能量场辅助超精密加工技术--磁场和超声波振动双场辅助金刚石切割(MUVFDC),以应对当前的挑战。通过对工件材料从宏观表面形态到微观结构特征的全面表征,探索和研究了双场耦合效应对 HEA 的现象学影响。这些分析基于四种不同加工技术的实验结果:非能量场、磁场、超声振动场和双场辅助加工。研究结果表明,MUVFDC 技术有效地结合了振动场和磁场的优势,前者可提高切削稳定性,后者可改善材料的可加工性。此外,这种耦合技术还解决了与单能场加工相关的难题:它减轻了控制振动场中微小硬质颗粒造成的表面划痕的难度,并抑制了磁场中刀具的快速磨损。此外,表面下微观结构的梯度演变表明,振动场抑制了磁激励引起的严重基体变形。同时,磁场减少了间歇切削造成的再结晶晶粒尺寸不均匀性。总体而言,与单能量场或非能量辅助加工相比,MUVFDC 技术可提高表面质量、抑制刀具磨损、平滑切屑形态并减少表面下损伤。这项工作突破了传统单能量场辅助加工的性能限制,加深了人们对 HEAs 加工中双场耦合效应的理解。它还为未来先进材料的超精密制造提供了一种前景广阔的加工技术。
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来源期刊
CiteScore
25.70
自引率
10.00%
发文量
66
审稿时长
18 days
期刊介绍: The International Journal of Machine Tools and Manufacture is dedicated to advancing scientific comprehension of the fundamental mechanics involved in processes and machines utilized in the manufacturing of engineering components. While the primary focus is on metals, the journal also explores applications in composites, ceramics, and other structural or functional materials. The coverage includes a diverse range of topics: - Essential mechanics of processes involving material removal, accretion, and deformation, encompassing solid, semi-solid, or particulate forms. - Significant scientific advancements in existing or new processes and machines. - In-depth characterization of workpiece materials (structure/surfaces) through advanced techniques (e.g., SEM, EDS, TEM, EBSD, AES, Raman spectroscopy) to unveil new phenomenological aspects governing manufacturing processes. - Tool design, utilization, and comprehensive studies of failure mechanisms. - Innovative concepts of machine tools, fixtures, and tool holders supported by modeling and demonstrations relevant to manufacturing processes within the journal's scope. - Novel scientific contributions exploring interactions between the machine tool, control system, software design, and processes. - Studies elucidating specific mechanisms governing niche processes (e.g., ultra-high precision, nano/atomic level manufacturing with either mechanical or non-mechanical "tools"). - Innovative approaches, underpinned by thorough scientific analysis, addressing emerging or breakthrough processes (e.g., bio-inspired manufacturing) and/or applications (e.g., ultra-high precision optics).
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