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基于机器学习的丝材电弧增材制造焊缝几何形状精确预测新模型

A novel machine learning-based model for accurate prediction of weld bead geometry in wire arc additive manufacturing

  • 摘要: 由于多工艺参数相互作用的复杂性,准确预测电弧熔丝增材制造(wire arc additive manufacturing, WAAM)成形焊缝的几何形状仍然是一个挑战.传统的单一参数模型或经验公式往往难以全面捕捉这种非线性、高耦合的工艺-形貌关系,限制了工艺优化与质量控制的效果.针对这一问题,文中提出了一种基于曲率特征的通用焊缝几何预测模型,能够适应不同的工艺参数组合,实现对沉积层横截面形状的准确描述.文中通过系统试验获取了包括焊缝曲率、焊缝接触角和关键工艺参数在内的综合数据集,并在此基础上构建了多种机器学习预测模型,包括XGBoost模型和支持向量机(support vector machine, SVM)模型.文中通过提供一种普遍适用的预测沉积几何形状和进一步优化工艺参数的策略,为WAAM后续工艺参数优化与智能控制策略的制定提供了理论和数据参考.

     

    Abstract: Due to the complexity of interactions among multiple process parameters, accurately predicting the geometric shape of formed weld beads in wire arc additive manufacturing (WAAM) remains a challenge. Traditional single-parameter models or empirical formulas often fail to fully capture this nonlinear, highly coupled process-morphology relationship, which limits the effectiveness of process optimization and quality control. To address this issue, a universal weld bead geometry prediction model based on curvature features was proposed, which could adapt to different combinations of process parameters and achieve an accurate description of the cross-sectional shape of deposited layers. Through systematic experiments, a comprehensive dataset including the weld curvature, the weld contact angle, and key process parameters was obtained. On this basis, multiple machine learning prediction models, including the XGBoost model and the support vector machine (SVM) model, were developed. By providing a universally applicable strategy for predicting the deposition geometry and further optimizing the process parameters, theoretical and data references are provided for the subsequent process parameter optimization and intelligent control strategy formulation of WAAM.

     

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