材料科学
熔融沉积模型
各向同性
各向异性
有限元法
复合材料
3D打印
极限抗拉强度
材料性能
弹性(物理)
横观各向同性
本构方程
结构工程
工程类
量子力学
物理
作者
Francesco Bandinelli,Lorenzo Peroni,Alberto Morena
出处
期刊:Polymers
[Multidisciplinary Digital Publishing Institute]
日期:2023-01-02
卷期号:15 (1): 234-234
被引量:40
标识
DOI:10.3390/polym15010234
摘要
Fused deposition modeling (FDM) is one of the most common 3D printing technologies and is becoming a well-established production method. Short fiber-reinforced polymers represent a new class of printing materials that enhance the mechanical properties of final components, thus informing an interesting subject of analysis for this study. FDM-printed parts are characterized by a strong anisotropy, so their behavior should be analyzed accordingly. The authors proposed a modeling strategy based on a transversely isotropic behavior hypothesis, representing material behaviors associated with an elasticity matrix in relation to the elastic field and a combination of Hill's yield criterion and Voce's isotropic hardening law for the plastic field. Material properties of materials were experimentally identified through tensile tests on dog bone specimens printed with different orientations in space. The numerical model was then calibrated using the finite element software LS-DYNA and the optimization software LS-OPT. An agreement between numerical and experimental results showed the robustness of the modeling strategy proposed to describe the stress behaviors of printed materials until a maximum load is reached, while strain behaviors have yet to be correctly defined due to the difficulties associated with evaluating an equivalent deformation.
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