Journal of Materials Research and Technology (Jan 2024)

Mechanical-thermal coupling structural failure and in-situ deformation mechanism of cellular high entropy alloy lattice structures

  • Shuai Tong,
  • Guoxiang Shen,
  • Zhengchen Han,
  • Zhichao Ma,
  • Yang Sun,
  • Shanyue Guan,
  • Hongwei Zhao,
  • Luquan Ren,
  • Chuliang Yan

Journal volume & issue
Vol. 28
pp. 2792 – 2799

Abstract

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To investigate the effect of temperature on the compressive strength of CoCrFeMnNi high entropy alloy with lattice structures prepared by powder bed fusion, the mechanical properties of the lattice structures at a temperature in a range from 20 °C to 900 °C were obtained through a self-developed in-situ mechanical-thermal coupling compressive system. The real-time deformation behaviors of the lattice structures were observed by an optical-infrared dual-spectrum imaging system. The experimental results indicated that the compressive strength, structural stiffness, and energy absorption of the specimens increased with the increasing temperature ranging from 20 °C to 600 °C during the load-bearing stage, accompanied by a fracture mode from cleavage step to dimple. At an elevated temperature of 900 °C, the specimens exhibited the worst compressive strength and structural stiffness but the highest densification strain. Significantly, the temperature-dependent deformation behaviors were revealed, as the gradually increased temperature promoted the deformation failure behavior transforming from “layer by layer” to “45° shear band”. The improved plasticity at elevated temperatures enhanced the deformation capacity of lattice structures, released the local concentrated load and effectively weakened the stress concentration.

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