Microhardness and wear resistance in materials manufactured by laser powder bed fusion: Machine learning approach for property pbkp_rediction


Abstract:

Laser-based powder bed fusion (LPBF) technology is one of the most applied additive manufacturing processes owing to, among others, its capacity of producing parts with mechanical properties superior to conventionally processed counterparts. Whereas to obtain full-dense components, the proper selection of processing parameters is mandatory and well explored, there is a gap in comprehending the influence of processing parameters on the resulting surface hardness and wear resistance. In this work, the effect of laser power, scanning speed, layer thickness, hatch distance, and material density on these properties is evaluated for materials commercially employed in LPBF. A machine learning-aided interpretable model is developed, featuring gradient boosting techniques (gradient boosting regressor (GBR), extreme gradient boosting regressor (XGBR), and AdaBoost) trained and evaluated by 5-fold cross-validation for the pbkp_rediction of microhardness analyzed for literature data specific to selective laser melting of a variety of alloys and metal-based composites. Gaussian process regression is used to evaluate the wear rate, employing the testing parameters to learn the wear behavior, and interpreted in the context of an analytical model. Feature importance analysis has been carried out to understand the complex interactions during the pin-on-disc test. The trained models achieved high pbkp_redictive performance (R2> 0.96) for wear rate pbkp_rediction, consistent with mechanistic understanding, posing machine learning as a powerful tool for LPBF process design with minimum experimental effort in calibration.

Año de publicación:

2023

Keywords:

  • Wear
  • pbkp_rediction
  • Microhardness
  • Processing parameters
  • Laser powder-bed-fusion
  • Machine learning

Fuente:

googlegoogle
scopusscopus

Tipo de documento:

Article

Estado:

Acceso restringido

Áreas de conocimiento:

  • Ciencia de materiales
  • Aprendizaje automático

Áreas temáticas:

  • Ingeniería y operaciones afines
  • Instrumentos de precisión y otros dispositivos
  • Métodos informáticos especiales