Finite Element Simulation of Compressing an Additively Manufactured Mesostructure

Anne Schmitz
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Abstract

Abstract Numerical modeling is a useful approach for answering research questions that are either difficult or inefficient to answer experimentally. The goal of this study was to develop a validated numerical model of a stereolithography (SLA) manufactured mesostructure to predict compression behavior. A three-dimensional (3D) model was created for an 80 × 80 × 20 mm compression block. ANSYS was used to simulate compression testing of this structure. The lower plate of the structure was fixed while a vertical displacement was prescribed on the upper plate. The base material was modeled using a linearly elastic, isotropic material derived from Young's modulus (E), Poisson's ratio, and the ultimate tensile strength. The base material was varied to represent three different SLA polymers from Formlabs (i.e., three different models of the same geometrical structure). The shape of the force–displacement curves and compression force values agreed well between the model and previously collected experimental data. However, this agreement was limited to stiffer materials and only up to 10 mm of compression. This may be where the structure shifts from elastic to plastic behavior and some lattice structures fracture. This simulation tool can be used in the future to predict and optimize the behavior of this lattice structure but only while operating elastically.
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压缩增材制造细观结构的有限元模拟
数值模拟是一种有用的方法来回答研究问题,要么难以或低效的实验回答。本研究的目的是建立一个有效的立体光刻(SLA)制造的细观结构的数值模型来预测压缩行为。建立了80 × 80 × 20 mm压缩块的三维(3D)模型。利用ANSYS软件对该结构进行了模拟压缩试验。结构的下板固定,而上板规定垂直位移。基础材料采用线性弹性,各向同性材料,由杨氏模量(E),泊松比和极限抗拉强度导出。基础材料可以代表Formlabs的三种不同的SLA聚合物(即相同几何结构的三种不同模型)。模型得到的力-位移曲线形状和压缩力值与实验数据吻合较好。然而,这一协议仅限于较硬的材料,只有高达10毫米的压缩。这可能是结构从弹性行为转变为塑性行为和一些晶格结构断裂的地方。这个模拟工具可以在未来用来预测和优化这种晶格结构的行为,但只有在弹性运行时。
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