Traditional manufacturing of large parts requires a costly process of developing, certifying, storing, and maintaining physical casts and molds. Wire Arc Directed Energy Deposition (Wire Arc DED), which uses an electric arc to 3D print metal layers, offers a potential improvement to this process by replacing physical molds with digital CAD models. Additionally, Wire Arc DED has a higher deposition rate, increased material utilization, and improved energy efficiency over traditional manufacturing techniques. As a new technology, it could benefit from an optimized parameter selection process, enabling quicker and more efficient manufacturing. We propose to use a data-driven machine learning approach to train a model capable of predicting the bead shape (width and height) of a printed layer using Wire Arc DED. Specifically, through a novel design of experiment (DOE) approach, expansive data collection, feature engineering, and extensive evaluation of distinct model architectures, we aim to advance the state-of-the-art performance and generalizability in predicting the bead shape of printed layers using Wire Arc DED.

Creator

• Price, Stephen

Contributeurs

• Neamtu, Rodica
• Beck, Joseph
• Cote, Danielle

Degree

• MS

Unit

• Computer Science

Publisher

• Worcester Polytechnic Institute

Identifier

• etd-115018

Mot-clé

• Design of Experiemnt
• Feature Engineering
• Regression
• Predictive Modeling
• Machine Learning
• Wire Arc DED

Advisor

• Cote, Danielle
• Neamtu, Rodica

Orcid

• https://orcid.org/0000-0001-9368-1789

Defense date

• 2023-12-04

Year

• 2023

Date created

• 2023-12-12

Resource type

• Thesis

Source

• etd-115018

Rights statement

• In Copyright

License

• Creative Commons BY-NC Attribution-NonCommercial 4.0 International

Dernière modification

• 2024-01-25