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熔融沉积成型打印的丙烯腈-丁二烯-苯乙烯(ABS)热塑性塑料激光切割质量的实验评估与基于机器学习的预测

Experimental Evaluation and Machine Learning-Based Prediction of Laser Cutting Quality in FFF-Printed ABS Thermoplastics.

作者信息

Basar Gokhan

机构信息

Department of Industrial Engineering, Faculty of Engineering and Natural Sciences, Osmaniye Korkut Ata University, 80010 Osmaniye, Türkiye.

出版信息

Polymers (Basel). 2025 Jun 20;17(13):1728. doi: 10.3390/polym17131728.

DOI:10.3390/polym17131728
PMID:40647739
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12251932/
Abstract

Additive manufacturing, particularly Fused Filament Fabrication (FFF), provides notable advantages such as design flexibility and efficient material usage. However, components produced via FFF often exhibit suboptimal surface quality and dimensional inaccuracies. Acrylonitrile Butadiene Styrene (ABS), a widely used thermoplastic in FFF applications, commonly necessitates post-processing to enhance its surface finish and dimensional precision. This study investigates the effects of CO laser cutting on FFF-printed ABS plates, focusing on surface roughness, top and bottom kerf width, and bottom heat-affected zone. Forty-five experimental trials were conducted using different combinations of plate thickness, cutting speed, and laser power. Measurements were analysed statistically, and analysis of variance was applied to determine the significance of each parameter. To enhance prediction capabilities, seven machine learning models-comprising traditional (Linear Regression and Support Vector Regression), ensemble (Extreme Gradient Boosting and Random Forest), and deep learning algorithms (Long Short-Term Memory (LSTM), LSTM-Gated Recurrent Unit (LSTM-GRU), LSTM-Extreme Gradient Boosting (LSTM-XGBoost))-were developed and compared. Among these, the LSTM-GRU model achieved the highest predictive performance across all output metrics. Results show that cutting speed is the dominant factor affecting cutting quality, followed by laser power and thickness. The proposed experimental-computational approach enables accurate prediction of laser cutting outcomes, facilitating optimisation of post-processing strategies for 3D-printed ABS parts and contributing to improved precision and efficiency in polymer-based additive manufacturing.

摘要

增材制造,尤其是熔融长丝制造(FFF),具有设计灵活性和材料使用效率高等显著优势。然而,通过FFF生产的部件往往表面质量欠佳且尺寸不准确。丙烯腈丁二烯苯乙烯(ABS)是FFF应用中广泛使用的热塑性塑料,通常需要进行后处理以提高其表面光洁度和尺寸精度。本研究调查了CO激光切割对FFF打印的ABS板材的影响,重点关注表面粗糙度、顶部和底部切口宽度以及底部热影响区。使用板材厚度、切割速度和激光功率的不同组合进行了45次实验。对测量结果进行了统计分析,并应用方差分析来确定每个参数的显著性。为了提高预测能力,开发并比较了七种机器学习模型,包括传统模型(线性回归和支持向量回归)、集成模型(极端梯度提升和随机森林)以及深度学习算法(长短期记忆(LSTM)、LSTM门控循环单元(LSTM-GRU)、LSTM-极端梯度提升(LSTM-XGBoost))。其中,LSTM-GRU模型在所有输出指标上都取得了最高的预测性能。结果表明,切割速度是影响切割质量的主导因素,其次是激光功率和厚度。所提出的实验-计算方法能够准确预测激光切割结果,有助于优化3D打印ABS零件的后处理策略,并提高基于聚合物的增材制造的精度和效率。

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