基于激光粉末床熔融的二维和三维多层夹层晶格结构的能量吸收行为研究

IF 2.2 4区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Cibi Gabriel Goldwynsingh David Rajasingh, Kuppan Palaniyandi, Arivarasu Moganraj
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引用次数: 0

摘要

这项研究为设计、开发和分析尺寸不同的二维和三维夹层晶格结构的准静态能量吸收特性提供了宝贵的见解。研究人员设计并制造了基于激光粉末床熔融技术的 SS316L 二维蜂窝结构、三维八面体结构和三维 TPMS 陀螺结构,并从尺寸方面研究了它们在准静态载荷下的力学行为。结果发现,三维 TPMS 陀螺结构的能量吸收率最高,为 51.73 兆焦耳/立方米,且具有均匀坍塌模式。然而,二维结构在弹性和致密化区域的表现更好,具有更高的弹性模量和最高的致密化应变(0.68),同时还经历了独特的基于单元格的变形。结果表明,虽然三维结构是最好的能量吸收器;但当除了能量吸收外还需要刚度时,二维结构更受青睐,这为这些结构的设计和应用提供了实际意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Investigations on Energy Absorption Behavior of Laser Powder Bed Fusion-Based 2D and 3D Multi-layered Sandwich Lattice Structures

Investigations on Energy Absorption Behavior of Laser Powder Bed Fusion-Based 2D and 3D Multi-layered Sandwich Lattice Structures

This research provides valuable insights into the design, development, and analysis of the quasi-static energy absorption properties of dimensionally distinct 2D and 3D sandwich lattice structures. The Laser Powder Bed Fusion-based SS316L 2D Honeycomb, 3D Octet, and 3D TPMS Gyroid were designed and manufactured to study their mechanical behavior under quasi-static loading in the light of dimensional aspects. The energy absorption of the 3D TPMS Gyroid structure is found to be the highest at 51.73 MJ/m3 with a uniform collapse mode. However, the 2D structure performed better in elastic and densification regions with a superior elastic modulus and the highest densification strain of 0.68 while undergoing a unique unit cell-based deformation. The results show that while the 3D structures are the best energy absorbers; the 2D structures are preferred when stiffness is required in addition to energy absorption, providing practical implications for the design and application of these structures.

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来源期刊
Journal of Materials Engineering and Performance
Journal of Materials Engineering and Performance 工程技术-材料科学:综合
CiteScore
3.90
自引率
13.00%
发文量
1120
审稿时长
4.9 months
期刊介绍: ASM International''s Journal of Materials Engineering and Performance focuses on solving day-to-day engineering challenges, particularly those involving components for larger systems. The journal presents a clear understanding of relationships between materials selection, processing, applications and performance. The Journal of Materials Engineering covers all aspects of materials selection, design, processing, characterization and evaluation, including how to improve materials properties through processes and process control of casting, forming, heat treating, surface modification and coating, and fabrication. Testing and characterization (including mechanical and physical tests, NDE, metallography, failure analysis, corrosion resistance, chemical analysis, surface characterization, and microanalysis of surfaces, features and fractures), and industrial performance measurement are also covered
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