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通过轴向晶格挤压制造的碳复合材料八面体桁架结构的力学响应

Mechanical Response of Carbon Composite Octet Truss Structures Produced via Axial Lattice Extrusion.

作者信息

Poddar Pritam, Olles Mark, Cormier Denis

机构信息

Industrial and Systems Engineering, Rochester Institute of Technology, Rochester, NY 14623, USA.

出版信息

Polymers (Basel). 2022 Aug 29;14(17):3553. doi: 10.3390/polym14173553.

DOI:10.3390/polym14173553
PMID:36080632
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9459732/
Abstract

Engineered lattice structures fabricated via additive manufacturing (AM) technologies are of great interest for many applications that require high strength and/or stiffness with minimum mass. This paper studies a novel axial lattice extrusion (ALE) AM technique that greatly enhances mechanical properties of polymeric lattice structures. When the novel ALE process was used to produce 84 mm × 84 mm × 84 mm octet truss lattice samples using fiber reinforced ABS, a total of 219,520 polymer interfaces in the lattice beams were eliminated relative to the conventional 3D printing alternative. Microscopic examination revealed near perfect alignment of the chopped carbon fibers with axes of the cylindrical beams that make up the lattice structure. The greatly enhanced beam quality with fiber reinforcement resulted in excellent mechanical properties. Compression testing yielded an average relative compressive strength of 17.4 MPa and an average modulus of 162.8 MPa. These properties rate very strongly relative to other published work, and indicate that the ALE process shows great potential for fabrication of high-strength, lightweight, large-scale, carbon-fiber composite components. The paper also contributes a modeling approach to finite element analysis (FEA) that captures the highly orthotropic properties of carbon fiber lattice beams. The diagonal shear failure mode predicted via the FEA model was in good agreement with experimentally observed results.

摘要

通过增材制造(AM)技术制造的工程晶格结构,对于许多需要高强度和/或高刚度且质量最小的应用而言具有极大的吸引力。本文研究了一种新型轴向晶格挤压(ALE)增材制造技术,该技术可极大地提高聚合物晶格结构的机械性能。当使用新型ALE工艺,采用纤维增强ABS制造84毫米×84毫米×84毫米的八面体桁架晶格样品时,相对于传统的3D打印方法,晶格梁中总共消除了219,520个聚合物界面。显微镜检查显示,短切碳纤维与构成晶格结构的圆柱形梁的轴线近乎完美对齐。纤维增强极大地提高了梁的质量,从而产生了优异的机械性能。压缩测试得出平均相对抗压强度为17.4兆帕,平均模量为162.8兆帕。相对于其他已发表的研究成果,这些性能表现非常突出,表明ALE工艺在制造高强度、轻质、大规模的碳纤维复合材料部件方面具有巨大潜力。本文还提出了一种用于有限元分析(FEA)的建模方法,该方法能够捕捉碳纤维晶格梁的高度正交各向异性特性。通过FEA模型预测的对角剪切破坏模式与实验观察结果吻合良好。

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