Achieving fine tailoring of elastocaloric properties of laser powder bed-fused NiTi alloy via laser beam manipulation

IF 14 1区工程技术 Q1 ENGINEERING, MANUFACTURING

International Journal of Machine Tools & Manufacture Pub Date : 2024-09-10 DOI:10.1016/j.ijmachtools.2024.104210

Jianbin Zhan , Kun Li , Ruijin Ma , Liang Zhu , Jiahui Fang , Huajun Cao , David Z. Zhang , Lawrence E. Murr

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Abstract

Laser powder bed fusion (LPBF) technology enables the development of NiTi alloys with complex geometries and tunable phase-transformation temperatures (PTTs). This technology is increasingly acknowledged as promising in the field of elastocaloric (eC) refrigeration. However, the mechanisms governing the manner in which this technology tunes the eC performance remain ambiguous. This study evaluated the fine-tuning of the eC properties by regulating Ni evaporation through laser manipulation. Our results demonstrate that although adjusting Ni loss via laser heat input can effectively control the PTTs, inappropriate combinations of laser parameters may result in lower than anticipated cooling capacity (ΔT_ad) and coefficient of performance (COP_mat) of produced samples. An excessive heat input results in Ni evaporation and in grain coarsening through the remelting and combination of fine grains owing to overlapping molten pools. Lower Ni enhances the phase-transformation enthalpy (ΔH_tr). However, larger grains increase the energy dissipation and thereby, counteracting ΔT_ad improvements. Theoretical analysis and experiments revealed that finer grains increase the misorientation angles. This hinders the dislocation motion and thereby, enhances the mechanical properties. Meanwhile, coarser grains can more conveniently promote PT and thereby, increase ΔH_tr. Thus, based on the naturally controllable grain size heterogeneity in LPBF-manufactured NiTi alloys, we propose optimizing the eC properties by controlling the morphology of the molten pool. Thermal-history simulations could balance this relationship. Ultimately, we developed two NiTi alloys for both high-temperature (70 °C) and room-temperature (25 °C) refrigeration. This study has provided effective insights for customizing high-performance eC components such as multistage caloric cascade regenerators, using additive manufacturing.

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通过激光束操纵实现激光粉末床熔融镍钛合金弹性特性的微调

激光粉末床熔融（LPBF）技术能够开发出具有复杂几何形状和可调相变温度（PTT）的镍钛合金。这项技术在弹性制冷（eC）领域的前景日益广阔。然而，该技术调整 eC 性能的机制仍不明确。本研究评估了通过激光操作调节镍蒸发来微调 eC 性能的情况。我们的结果表明，虽然通过激光热输入调节镍损耗可以有效控制 PTT，但激光参数组合不当可能会导致生产的样品冷却能力（）和性能系数（）低于预期。过多的热量输入会导致镍蒸发，并由于熔池重叠导致细小晶粒的重熔和组合而使晶粒变粗。镍含量越低，相变焓（）越高。然而，较大的晶粒会增加能量耗散，从而抵消改善作用。理论分析和实验表明，晶粒越细，错向角越大。这阻碍了位错运动，从而提高了机械性能。同时，较粗的晶粒可以更方便地促进位错运动，从而提高机械性能。因此，基于 LPBF 制造的镍钛合金中自然可控的晶粒尺寸异质性，我们建议通过控制熔池的形态来优化 eC 性能。热历史模拟可以平衡这种关系。最终，我们开发出了两种适用于高温（70 °C）和室温（25 °C）制冷的镍钛合金。这项研究为利用增材制造技术定制高性能 eC 组件（如多级热量级联再生器）提供了有效的启示。

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来源期刊

International Journal of Machine Tools & Manufacture 工程技术-工程：机械

CiteScore

25.70

自引率

10.00%

发文量

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).