Enhancing mechanical properties of additively manufactured voronoi-based architected metamaterials via a lattice-inspired design strategy

IF 14 1区 工程技术 Q1 ENGINEERING, MANUFACTURING International Journal of Machine Tools & Manufacture Pub Date : 2024-08-16 DOI:10.1016/j.ijmachtools.2024.104199
Changjun Han , Yunhui Wang , Zaichi Wang , Zhi Dong , Kai Li , Changhui Song , Chao Cai , Xingchen Yan , Yongqiang Yang , Di Wang
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Abstract

Voronoi-based architected metamaterials have gained significant recognition as promising candidates for bone defect repair implants. However, the demanding requirements for reliable and adjustable load-bearing capacity pose challenges in applying irregular Voronoi-based architected metamaterials in implant applications. In this study, we propose a lattice-inspired design methodology for these metamaterials, enabling precise control over topologies and porosities to enhance their mechanical properties. We demonstrate the influence of unit cell topology on the printability, mechanical properties, and permeability of lattice-inspired Voronoi-based metamaterials (LIVMs) fabricated via laser powder bed fusion (LPBF) additive manufacturing. The LPBF-printed LIVMs exhibited yield strengths ranging from 3.35 to 17.59 MPa and specific energy absorption ranging from 3.81 to 14.29 J/g. Through finite element modeling and experimentation, we show that the deformation behavior of LIVMs with various topologies plays a crucial role in enhancing mechanical performance through mechanisms such as homogeneous load transfer between unit cells and multistage-contact strengthening within a unit cell. Additionally, we analyze the impact of unit cell type and porosity on the mass-transport behavior of LIVMs using computational fluid dynamics simulations. The LIVMs achieved experimental permeability values ranging from 3.88 × 10−9 to 16.83 × 10−9 m2 (consistent with trabecular bones), indicating that multiple fluid flow channels can be utilized to enhance mass transport by distributing flow pressure and increasing fluid mobility. The proposed design method effectively achieves a favorable combination of superior mechanical properties and tunable permeability in Voronoi-based architected metamaterials. These findings provide valuable theoretical guidance for the development of architected metamaterials for bone implant applications.

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通过晶格启发设计策略增强基于添加制造的 voronoi 架构超材料的机械性能
基于 Voronoi 架构的超材料作为骨缺损修复植入物的理想候选材料已获得广泛认可。然而,对可靠和可调承重能力的苛刻要求给不规则 Voronoi 架构超材料在植入应用中的应用带来了挑战。在本研究中,我们提出了一种受晶格启发的超材料设计方法,可精确控制拓扑结构和孔隙率,从而增强其机械性能。我们展示了单元拓扑结构对通过激光粉末床熔融(LPBF)快速成型制造的基于晶格启发的 Voronoi 超材料(LIVMs)的可印刷性、机械性能和渗透性的影响。LPBF 打印的 LIVMs 具有 3.35 至 17.59 兆帕的屈服强度和 3.81 至 14.29 焦耳/克的比能量吸收。通过有限元建模和实验,我们发现具有不同拓扑结构的 LIVM 的变形行为通过单元格之间的均质载荷传递和单元格内的多级接触强化等机制,在提高机械性能方面发挥着至关重要的作用。此外,我们还利用计算流体动力学模拟分析了单胞类型和孔隙率对 LIVMs 质量传输行为的影响。LIVM 的实验渗透率值从 3.88 × 10-9 到 16.83 × 10-9 m2 不等(与骨小梁一致),这表明可以利用多个流体流动通道来分散流动压力和增加流体流动性,从而提高质量传输性能。在基于 Voronoi 架构的超材料中,所提出的设计方法有效地实现了优异机械性能和可调渗透性的良好结合。这些发现为开发用于骨植入应用的结构超材料提供了宝贵的理论指导。
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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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