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机器学习驱动的3D打印生物聚合物复合材料抗压强度优化

Machine learning driven optimization of compressive strength of 3D printed bio polymer composite material.

作者信息

Jayaram R S, Saravanamuthukumar P, Abdullah Ahmad Baharuddin, Krishnamoorthy Ramalingam, Kunar Sandip, Yong Xu, Prabhakar S

机构信息

Department of Mechanical Engineering, Amrita Vishwa Vidyapeetham, Nagercoil, Tamil Nadu, India.

School of Mechanical Engineering, Engineering campus, Universiti Sains Malaysia, Nibong Tebal, Penang, Malaysia.

出版信息

PLoS One. 2025 Aug 28;20(8):e0330625. doi: 10.1371/journal.pone.0330625. eCollection 2025.

DOI:10.1371/journal.pone.0330625
PMID:40875778
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12393749/
Abstract

3D printing has brought significant changes to manufacturing sectors, making it possible to produce intricate, multi-layered designs with greater ease. This study focuses on optimizing the compressive strength (CS) of functionally graded multi-material (PLA/Almond Shell Reinforced PLA) which is fabricated with the aid of the FFF process, a widely used additive manufacturing technique. Six different machine learning models (ML) were utilized to estimate CS using key process parameters, namely print speed (PS), layer height (LH), and printing temperature (PT). Among six ML models, Polynomial Regression (PR) performed best, with an R2 of 0.88 and the lowest error metrics (MAE = 1.38, RMSE = 1.9, MSE = 3.6). SHAP analysis indicated that PS is the most influential parameter, followed by LH. PR predicted optimal parameters (PS = 19 mm/s, LH = 0.1 mm, PT = 216°C) and yielded a predicted CS of 36 MPa, which was experimentally validated as 34.8 MPa with a low error of 3.44%. Also, the PR outperformed the traditional Taguchi method, which predicted a CS of 33.74 MPa, showing a 7.5% improvement and lower error. This demonstrates that PR-based ML optimization offers better accuracy and improved mechanical performance, making these FGMs suitable for various consumer applications.

摘要

3D打印给制造业带来了重大变革,使生产复杂的多层设计变得更加容易。本研究聚焦于优化功能梯度多材料(聚乳酸/杏仁壳增强聚乳酸)的抗压强度,该材料借助熔融沉积成型工艺制造,这是一种广泛使用的增材制造技术。使用六种不同的机器学习模型来利用关键工艺参数估计抗压强度,这些参数分别是打印速度、层高和打印温度。在六种机器学习模型中,多项式回归表现最佳,决定系数R2为0.88,误差指标最低(平均绝对误差MAE = 1.38,均方根误差RMSE = 1.9,均方误差MSE = 3.6)。SHAP分析表明,打印速度是最具影响力的参数,其次是层高。多项式回归预测了最佳参数(打印速度 = 19毫米/秒,层高 = 0.1毫米,打印温度 = 216°C),并得出预测抗压强度为36兆帕,经实验验证为34.8兆帕,误差低至3.44%。此外,多项式回归优于传统田口方法,传统方法预测的抗压强度为33.74兆帕,显示出7.5%的提升且误差更低。这表明基于多项式回归的机器学习优化提供了更高的准确性和更好的机械性能,使这些功能梯度材料适用于各种消费应用。

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