Effects of Size Reduction on the Failure Mechanism of 3D Printed PLA+ Parts

Zane Decker, Mason Makulinski, Suprita Vispute, M. Sundaram
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引用次数: 1

Abstract

Fused Deposition Modeling (FDM) with Poly(lactic Acid) plus (PLA+) is frequently used in rapid prototyping and 3D printing of complex shapes. Owing to their light weight, manufacturability and cost effectiveness, thermoplastic parts made by FDM are increasingly used in several applications ranging from tissue engineering to consumer goods industry. Understanding the size effects on the strength of these parts is essential to extend their use in the microsystem applications. This paper studies the effect of scale on the mechanical properties and failure mechanisms of a 3D printed parts made by FDM. Process parameter such as extrusion temperature, infill density, infill pattern, print speed, layer thickness and nozzle diameter were kept consistent for this experiment. Five samples each with a square cross-sectional area of side lengths of 2mm, 4mm, 6mm, and 10mm were subjected to a tensile test. It was observed that parts with a smaller cross-sectional area experienced ductile failure as opposed to brittle fracture in larger cross-sectional area. Failure is shown to occur at sections where the geometry changes for brittle fractures while it occurs at the center of the parts displaying ductile failure. Results of the tensile test show a non-uniform ultimate yield strength across the four sizes. Crystallization of the material due to nozzle temperature at extrusion could be a contributing factor to failure discrepancies. Increase in the cycle time is theorized to improve the layer to layer adhesion of the part thereby affecting its mode of failure.
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尺寸减小对3D打印PLA+零件失效机理的影响
使用聚乳酸+ (PLA+)的熔融沉积建模(FDM)经常用于复杂形状的快速原型制作和3D打印。由于其重量轻,可制造性和成本效益,FDM制造的热塑性部件越来越多地用于从组织工程到消费品工业的几个应用领域。了解尺寸对这些部件强度的影响对于扩展其在微系统应用中的使用至关重要。研究了水垢对FDM 3D打印零件力学性能和失效机理的影响。挤压温度、填充密度、填充图案、打印速度、层厚、喷嘴直径等工艺参数保持一致。对5个边长分别为2mm、4mm、6mm和10mm的方形截面积试样进行拉伸试验。观察到,与大截面积的脆性断裂相比,小截面积的零件经历了延性破坏。破坏发生在脆性断裂的几何形状发生变化的部分,而发生在显示韧性破坏的部分的中心。拉伸试验结果表明,四种尺寸的极限屈服强度不均匀。由于挤出时喷嘴温度导致的材料结晶可能是导致失效差异的一个因素。理论上,增加循环时间可以改善零件的层间附着力,从而影响其失效模式。
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