Modelling and prediction of mechanical properties of FFF-printed polycarbonate parts using ML and DA hybrid approach

IF 2.2 4区 化学 Q3 CHEMISTRY, PHYSICAL Colloid and Polymer Science Pub Date : 2024-09-07 DOI:10.1007/s00396-024-05315-1
Faheem Faroze, Vineet Srivastava, Ajay Batish
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Abstract

Fused filament fabrication (FFF) is a rapidly growing additive manufacturing technique. It is widely used in various industrial applications due to its ability to efficiently produce functional parts with complex geometrical features. Estimating the mechanical properties and dimensional accuracy is essential for the functional testing of objects fabricated using the FFF process. Several process variables influence the mechanical qualities and dimensional accuracy of objects manufactured using FFF technology. Selecting the optimal set of parameters is crucial for achieving the desired properties in the final parts. This research investigated the influence of four crucial process variables, layer thickness, extrusion temperature, printing speed, and extrusion width, on the impact resistance and shear strength of polycarbonate parts printed using the fused filament fabrication (FFF) technique. A hybrid modelling approach involving dimensional analysis (DA)–based mathematical modelling and regression-based machine learning (ML) modelling was adopted to predict the two output responses and determine the correlation between the process parameters and mechanical properties. A comparison based on various error metrics and the performance of the models suggested that ML models have higher prediction performance and accuracy than DA models. The developed prediction models exhibited significant agreement with the observed values and may be used to forecast the mechanical characteristics of FFF components while manipulating the input parameters. The findings revealed that a maximum impact strength of 66.37 J/m and shear strength of 50.43 MPa were obtained when the layer height, extrusion temperature, printing speed, and extrusion width were 320 µm, 280 °C, 20 mm/s, and 0.56 mm, respectively.

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使用 ML 和 DA 混合方法对 FFF 印刷聚碳酸酯部件的机械性能进行建模和预测
熔融长丝制造(FFF)是一种快速发展的增材制造技术。由于它能够高效地制造出具有复杂几何特征的功能部件,因此被广泛应用于各种工业领域。估算机械性能和尺寸精度对于使用 FFF 工艺制造的物体的功能测试至关重要。有几个工艺变量会影响使用 FFF 技术制造的物体的机械质量和尺寸精度。选择一组最佳参数对于最终部件达到预期性能至关重要。本研究调查了四个关键工艺变量(层厚度、挤出温度、打印速度和挤出宽度)对使用熔融长丝制造(FFF)技术打印的聚碳酸酯部件的抗冲击性和剪切强度的影响。采用了一种混合建模方法,包括基于尺寸分析(DA)的数学建模和基于回归的机器学习(ML)建模,以预测两种输出响应,并确定工艺参数和机械性能之间的相关性。基于各种误差指标和模型性能的比较表明,ML 模型比 DA 模型具有更高的预测性能和准确性。所开发的预测模型与观测值具有显著的一致性,可用于在调节输入参数的同时预测 FFF 组件的机械特性。研究结果表明,当层高、挤出温度、印刷速度和挤出宽度分别为 320 µm、280 °C、20 mm/s 和 0.56 mm 时,最大冲击强度为 66.37 J/m,最大剪切强度为 50.43 MPa。
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来源期刊
Colloid and Polymer Science
Colloid and Polymer Science 化学-高分子科学
CiteScore
4.60
自引率
4.20%
发文量
111
审稿时长
2.2 months
期刊介绍: Colloid and Polymer Science - a leading international journal of longstanding tradition - is devoted to colloid and polymer science and its interdisciplinary interactions. As such, it responds to a demand which has lost none of its actuality as revealed in the trends of contemporary materials science.
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