半结晶聚合物 FFF 过程的建模和表征:翘曲的形成和机理分析

Yuesheng Yu, Bingnong Jiang, Yuan Chen, Lin Ye
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摘要

熔融长丝制造(FFF)通常用于半结晶聚合物(如聚丙烯(PP))的三维打印,但打印产品经常会出现翘曲变形,表面质量和机械性能显著下降。本研究建立了计算模型,用于预测在 FFF 工艺下由不同厚度的聚丙烯制成的矩形盒子,以研究 3D 打印过程中的应力集中和翘曲机理。研究基于热传递、热弹性和结晶动力学建立了数值模型,并采用活化元素法计算聚丙烯的 FFF 过程。通过重复打印试验对数值模型进行了验证,以研究 PP 盒子在 FFF 条件下应力条件和翘曲形成的机理和关系。结果表明,厚度最薄的包装盒翘曲变形最为严重(实验和模拟结果分别为 6.8 毫米/5.9 毫米),远高于厚度最厚的包装盒(实验和模拟结果分别为 1.3 毫米/1.6 毫米)。三个盒子的平均结晶度随着盒子厚度的增加而增加,但程度较小。就残余应力而言,较薄盒子的残余应力较小(25.1 兆帕,几乎是较厚盒子的 45%)。
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Modelling and characterising FFF process of semi-crystalline polymers: Warpage formation and mechanism analysis
Fused filament fabrication (FFF) is commonly utilised for 3D printing of semi-crystalline polymers, i.e., polypropylene (PP), while warpage deformation can often be observed in the printed products, with significantly reduced surface quality and mechanical properties. This study develops computational models for predicting rectangular boxes made of PP with different thicknesses under the FFF process to study the stress concentration and warpage mechanisms during 3D printing. Numerical models were established based on heat transfer, thermoelasticity, and crystallisation kinetics, with an activating elemental approach to calculate the FFF process of PP. The numerical models were validated with repetitive printing tests to study the mechanisms and relationships of stress conditions and warpage formation in PP boxes under FFF. The results show that the boxes with the thinnest thickness exhibited mostly severe warpage deformation (6.8 mm/5.9 mm in experiment and simulation, respectively), which is much more than that of the thickest box (1.3 mm/1.6 mm in experiment and simulation, respectively). The average crystallinity of the three boxes increases as the box thickness increases, but to a lesser extent. In terms of residual stress, the thinner box has a smaller residual stress (25.1 MPa, almost 45% of the thicker box).
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