Measuring thermal curing induced shrinkage of material extrusion based additive manufacturing silicone elastomer lattices by X-ray computed tomography

Tomography of Materials and Structures Pub Date : 2025-04-11 DOI:10.1016/j.tmater.2025.100064

Massimiliano Ferrucci , Anne-Françoise Obaton , Robert Cerda , Brian Au , Nicholas Rodriguez , Ziad Ammar , Gabriel Balensiefer , Chuck Divin , Jeremy Lenhardt , Brian Giera

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Abstract

Thermal curing induces shrinkage in material extrusion based additive manufacturing silicone elastomer samples, resulting in discrepancies between as printed and final geometries. Knowing the extent to which the samples change in shape and size allows us to make appropriate modifications to the printing design to better control the geometry of the samples. We present an X-ray computed tomography (CT) based approach to determine filament-level shrinkage due to thermal curing of silicone elastomer samples printed with direct ink writing (DIW). The approach relies on custom-designed build plates that are resistant to the elevated curing temperatures and that have sufficiently distinct X-ray absorption characteristics from the silicone elastomer to ensure adequate segmentation of the latter in X-ray imaging data. We implement the approach to evaluate shrinkage in DIW ‘log pile’ samples with three distinct strand arrangements and demonstrate of how filament-level information can be extracted from the X-ray CT data.

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用x射线计算机断层扫描测量基于增材制造硅弹性体晶格的材料挤压热固化诱导收缩

热固化诱导收缩材料挤压为基础的增材制造硅弹性体样品，导致打印和最终几何形状之间的差异。了解样品在形状和尺寸上的变化程度，使我们能够对印刷设计进行适当的修改，以更好地控制样品的几何形状。我们提出了一种基于x射线计算机断层扫描（CT）的方法来确定用直接墨水书写（DIW）打印的硅弹性体样品的热固化引起的长丝级收缩。该方法依赖于定制设计的构建板，这些构建板可以抵抗较高的固化温度，并且与有机硅弹性体具有足够不同的x射线吸收特性，以确保在x射线成像数据中对后者进行充分的分割。我们采用该方法来评估具有三种不同链排列的DIW“原木桩”样品的收缩率，并演示如何从x射线CT数据中提取长丝级信息。

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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Tomography of Materials and Structures

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