Effects of microstructure on uniaxial strength asymmetry of open-cell foams 被引量：1

Effects of microstructure on uniaxial strength asymmetry of open-cell foams

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摘要 Based on the elongated Kelvin model, the effect of microstructure on the uniaxial strength asymmetry of open-cell foams is investigated. The results indicate that this asymmetry depends on the relative density, the solid material, the cell morphology, and the strut geometry of open-cell foams. Even though the solid material has the same tensile and compressive strength, the tensile and compressive strength of open-cell foams with asymmetrical sectional struts are still different. In addition, with the increasing degree of anisotropy, the uniaxial strength as well as the strength asymmetry increases in the rise direction but reduces in the transverse direction. Moreover, the plastic collapse ratio between two directions is verified to depend mainly on the cell morphology. The predicted results are compared with Gibson and Ashby＇s theoretical results as well as the experimental data reported in the literature, which validates that the elongated Kelvin model is accurate in explaining the strength asymmetry presented in realistic open-cell foams. Based on the elongated Kelvin model, the effect of microstructure on the uniaxial strength asymmetry of open-cell foams is investigated. The results indicate that this asymmetry depends on the relative density, the solid material, the cell morphology, and the strut geometry of open-cell foams. Even though the solid material has the same tensile and compressive strength, the tensile and compressive strength of open-cell foams with asymmetrical sectional struts are still different. In addition, with the increasing degree of anisotropy, the uniaxial strength as well as the strength asymmetry increases in the rise direction but reduces in the transverse direction. Moreover, the plastic collapse ratio between two directions is verified to depend mainly on the cell morphology. The predicted results are compared with Gibson and Ashby＇s theoretical results as well as the experimental data reported in the literature, which validates that the elongated Kelvin model is accurate in explaining the strength asymmetry presented in realistic open-cell foams.

作者 Zi-xing LU Ji-xiang HUANG Ze-shuai YUAN

机构地区 Institute of Solid Mechanics

出处《Applied Mathematics and Mechanics(English Edition)》 SCIE EI CSCD 2015年第1期37-46,共10页 应用数学和力学（英文版）

基金 Project supported by the National Natural Science Foundation of China(Nos.11472025 and 11272030)

关键词 open-cell foam MICROSTRUCTURE STRENGTH Kelvin model open-cell foam, microstructure, strength, Kelvin model

分类号 O341 [理学—固体力学]

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