Measured and simulated mechanical properties of additively manufactured matrix-inclusion multimaterials fabricated by material jetting.

IF 3.2 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Erik Kornfellner, Markus Königshofer, Lisa Krainz, Arno Krause, Ewald Unger, Francesco Moscato
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Abstract

Modern additive manufacturing enables the simultaneous processing of different materials during the printing process. While multimaterial 3D printing allows greater freedom in part design, the prediction of the mix-material properties becomes challenging. One type of multimaterials are matrix-inclusion composites, where one material contains inclusions of another material. Aim of this study was to develop a method to predict the uniaxial Young's modulus and Poisson's ratio of material jetted matrix-inclusion composites by a combination of simulations and experimental data.Fifty samples from commercially available materials in their pure and matrix-inclusion mixed forms, with cubic inclusions, have been fabricated using material jetting and mechanically characterized by uniaxial tensile tests. Multiple simulation approaches have been assessed and compared to the measurement results in order to find and validate a method to predict the multimaterials' properties. Optical coherence tomography and microscopy was used to characterize the size and structure of the multimaterials, compared to the design.The materials exhibited Young's moduli in the range of 1.4 GPa to 2.5 GPa. The multimaterial mixtures were never as stiff as the weighted volume average of the primary materials (up to [Formula: see text] softer for 45% RGD8530-DM inclusions in VeroClear matrix). Experimental data could be predicted by finite element simulations by considering a non-ideal contact stiffness between matrix and inclusion ([Formula: see text] for RGD8530-DM, [Formula: see text] for RGD8430-DM), and geometries of the printed inclusions that deviated from the design (rounded edge radii of [Formula: see text]m). Not considering this would lead to a difference of the estimation result of up to [Formula: see text]MPa (44%), simulating an inclusion volume fraction of 45% RGD8530-DM.Prediction of matrix-inclusion composites fabricated by multimaterial jetting printing, is possible, however, requires a priori knowledge or additional measurements to characterize non-ideal contact stiffness between the components and effective printed geometries, precluding therefore a simple multimaterial modelling.

通过材料喷射法制造的添加剂制造基体-夹杂物多材料的测量和模拟机械性能。
现代增材制造技术可在打印过程中同时加工不同的材料。虽然多材料三维打印技术为零件设计提供了更大的自由度,但对混合材料特性的预测也变得极具挑战性。多材料的一种类型是基体-夹杂复合材料,其中一种材料包含另一种材料的夹杂物。这项研究的目的是开发一种方法,通过模拟和实验数据相结合的方式预测材料喷射基体-夹杂复合材料的单轴杨氏模量和泊松比。我们利用材料喷射技术制作了 50 个样品,这些样品来自纯材料和基体-夹杂混合材料,其中包含立方体夹杂物,并通过单轴拉伸试验对其进行了机械表征。对多种模拟方法进行了评估,并将其与测量结果进行了比较,以找到并验证预测多种材料特性的方法。与设计相比,光学相干断层扫描和显微镜用于表征多元材料的尺寸和结构。多材料混合物的刚度从未达到主材料的加权体积平均值(VeroClear 基体中 45% 的 RGD8530-DM 杂质的刚度可达[公式:见正文]更软)。考虑到基体和夹杂物之间的非理想接触刚度(RGD8530-DM 为[式:见正文],RGD8430-DM 为[式:见正文]),以及印刷夹杂物的几何形状偏离设计(圆边半径为[式:见正文]m),可以通过有限元模拟预测实验数据。如果不考虑这一点,在模拟夹杂物体积分数为 45% 的 RGD8530-DM 时,估算结果将相差高达 [式中:见正文] MPa(44%)。通过多材料喷射打印制造的基体-夹杂物复合材料的预测是可能的,但需要先验知识或额外的测量,以确定组件和有效打印几何形状之间的非理想接触刚度,因此无法进行简单的多材料建模。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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