Modelling of geometry for directed energy deposition via machine learning

Predicting the geometry of bead in multi-track and multi-layer Directed Energy Deposition (DED) presents a challenge due to variations in process parameters, resulting in changes in geometry from one layer or track to another. To address this issue, a Long Short-Term Memory (LSTM) model is applied t...

Full description

Saved in:
Bibliographic Details
Main Author: Hong, Weidong
Other Authors: Li Hua
Format: Final Year Project
Language:English
Published: Nanyang Technological University 2023
Subjects:
Online Access:https://hdl.handle.net/10356/167105
Tags: Add Tag
No Tags, Be the first to tag this record!
Institution: Nanyang Technological University
Language: English
id sg-ntu-dr.10356-167105
record_format dspace
spelling sg-ntu-dr.10356-1671052023-05-27T16:51:49Z Modelling of geometry for directed energy deposition via machine learning Hong, Weidong Li Hua School of Mechanical and Aerospace Engineering Chen Chengxi LiHua@ntu.edu.sg Engineering::Mechanical engineering Predicting the geometry of bead in multi-track and multi-layer Directed Energy Deposition (DED) presents a challenge due to variations in process parameters, resulting in changes in geometry from one layer or track to another. To address this issue, a Long Short-Term Memory (LSTM) model is applied to model and predict the bead geometry in multi-track and multi-layer deposition, specifically height and waviness by predicting the 2nd order polynomial coefficients. The LSTM model is designed to capture long-term dependencies in the dataset containing process parameters and corresponding bead geometries. The process parameters used in this study include laser power, scanning speed, powder mass flow rate, hatch spacing value and z-incremental value. The applied model is trained, validated and tested using process parameters and the corresponding coefficients of unique sample name and layer number combination. The LSTM model achieved a considerable good 2 score of 0.81 for the coefficients, and 0.77 for height, but a poor score of -0.79 for waviness. The model’s performance in predicting the detailed waviness variations between the curves requires further improvement. Despite the limitations in waviness prediction, the model demonstrated its usefulness in capturing general trend of bead geometry changes under varying process parameters, particularly laser power and powder mass flow rate. To further assess the model, standard deviation of the curve heights are also analysed through which it revealed that adjusting the aforementioned parameters has the potential to decrease the variability in the curves height. This study highlights the potential of using a many to many LSTM model in bead geometry modelling and parameter selection in the field of additive manufacturing. Bachelor of Engineering (Mechanical Engineering) 2023-05-23T04:55:44Z 2023-05-23T04:55:44Z 2023 Final Year Project (FYP) Hong, W. (2023). Modelling of geometry for directed energy deposition via machine learning. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/167105 https://hdl.handle.net/10356/167105 en B123 School of Mechanical and Aerospace Engineering application/pdf Nanyang Technological University
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering::Mechanical engineering
spellingShingle Engineering::Mechanical engineering
Hong, Weidong
Modelling of geometry for directed energy deposition via machine learning
description Predicting the geometry of bead in multi-track and multi-layer Directed Energy Deposition (DED) presents a challenge due to variations in process parameters, resulting in changes in geometry from one layer or track to another. To address this issue, a Long Short-Term Memory (LSTM) model is applied to model and predict the bead geometry in multi-track and multi-layer deposition, specifically height and waviness by predicting the 2nd order polynomial coefficients. The LSTM model is designed to capture long-term dependencies in the dataset containing process parameters and corresponding bead geometries. The process parameters used in this study include laser power, scanning speed, powder mass flow rate, hatch spacing value and z-incremental value. The applied model is trained, validated and tested using process parameters and the corresponding coefficients of unique sample name and layer number combination. The LSTM model achieved a considerable good 2 score of 0.81 for the coefficients, and 0.77 for height, but a poor score of -0.79 for waviness. The model’s performance in predicting the detailed waviness variations between the curves requires further improvement. Despite the limitations in waviness prediction, the model demonstrated its usefulness in capturing general trend of bead geometry changes under varying process parameters, particularly laser power and powder mass flow rate. To further assess the model, standard deviation of the curve heights are also analysed through which it revealed that adjusting the aforementioned parameters has the potential to decrease the variability in the curves height. This study highlights the potential of using a many to many LSTM model in bead geometry modelling and parameter selection in the field of additive manufacturing.
author2 Li Hua
author_facet Li Hua
Hong, Weidong
format Final Year Project
author Hong, Weidong
author_sort Hong, Weidong
title Modelling of geometry for directed energy deposition via machine learning
title_short Modelling of geometry for directed energy deposition via machine learning
title_full Modelling of geometry for directed energy deposition via machine learning
title_fullStr Modelling of geometry for directed energy deposition via machine learning
title_full_unstemmed Modelling of geometry for directed energy deposition via machine learning
title_sort modelling of geometry for directed energy deposition via machine learning
publisher Nanyang Technological University
publishDate 2023
url https://hdl.handle.net/10356/167105
_version_ 1772827558838009856