Part and process monitoring for 3D printing technologies

For Direct Energy Deposition (DED) technologies, process monitoring is essential for consistently achieving high quality parts and stabilization of processes. Hence, the appropriate process parameters must be selected for evaluation to enable effective process monitoring. The key contributions of th...

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Main Author: Ong, Benjamin Jin Rui
Other Authors: Moon Seung Ki
Format: Final Year Project
Language:English
Published: Nanyang Technological University 2022
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Online Access:https://hdl.handle.net/10356/157383
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1573832023-03-04T20:17:43Z Part and process monitoring for 3D printing technologies Ong, Benjamin Jin Rui Moon Seung Ki School of Mechanical and Aerospace Engineering Singapore Institute of Manufacturing Technologies skmoon@ntu.edu.sg Engineering::Manufacturing Engineering::Aeronautical engineering For Direct Energy Deposition (DED) technologies, process monitoring is essential for consistently achieving high quality parts and stabilization of processes. Hence, the appropriate process parameters must be selected for evaluation to enable effective process monitoring. The key contributions of this FYP project are: (1) The development of an in-situ monitoring system to capture optical images of the L-DED process, (2) The implementation of OpenCV image processing pipelines, (3) Provision of 3D and 2D data visualization of the melt pool features. Firstly, a robust and efficient in-situ process monitoring strategy was proposed. A Charged Couple Device (CCD) camera was integrated into a Computer Numerically Controlled (CNC) laser aided additive manufacturing (LAAM) system to identify significant melt pool characteristics. Image processing techniques via various OpenCV libraries were then developed to extract in-situ melt pool features. These libraries include image binarization (Simple Thresholding), image masking (Bitwise functions), image noise removal (morphological transformations) and melt pool shape fitting (Contour generation). The python software infrastructure was tested on pyrometer and Infrared (IR) images from an open-sourced database. Raw pixel data was extracted from the Comma Separated Values (CSV) files and subsequently reorganized and normalized to lie within the OpenCV pixel value limits. Next, data cleaning was carried out to remove irrelevant (laser transition images) before storing the remaining data into a big list as Portable Graphics Format (PNG) files to retain all the image information. Following that, the PNG images were passed through the OpenCV image processing pipelines to extract various melt pool parameters. Some of these parameters include the Heat Affect Zone (HAZ) area, inner melt pool length, width, area, maximum and average temperature. Finally, these parameters were plotted against time and layer number to provide a 2D and 3D visualization of the melt pool. As such, the relative standard deviation, and the coefficient of determination of the melt pool parameters were derived to identify the most reliable parameter to be used for future data-driven control models. Bachelor of Engineering (Aerospace Engineering) 2022-05-14T11:32:57Z 2022-05-14T11:32:57Z 2022 Final Year Project (FYP) Ong, B. J. R. (2022). Part and process monitoring for 3D printing technologies. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/157383 https://hdl.handle.net/10356/157383 en 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::Manufacturing
Engineering::Aeronautical engineering
spellingShingle Engineering::Manufacturing
Engineering::Aeronautical engineering
Ong, Benjamin Jin Rui
Part and process monitoring for 3D printing technologies
description For Direct Energy Deposition (DED) technologies, process monitoring is essential for consistently achieving high quality parts and stabilization of processes. Hence, the appropriate process parameters must be selected for evaluation to enable effective process monitoring. The key contributions of this FYP project are: (1) The development of an in-situ monitoring system to capture optical images of the L-DED process, (2) The implementation of OpenCV image processing pipelines, (3) Provision of 3D and 2D data visualization of the melt pool features. Firstly, a robust and efficient in-situ process monitoring strategy was proposed. A Charged Couple Device (CCD) camera was integrated into a Computer Numerically Controlled (CNC) laser aided additive manufacturing (LAAM) system to identify significant melt pool characteristics. Image processing techniques via various OpenCV libraries were then developed to extract in-situ melt pool features. These libraries include image binarization (Simple Thresholding), image masking (Bitwise functions), image noise removal (morphological transformations) and melt pool shape fitting (Contour generation). The python software infrastructure was tested on pyrometer and Infrared (IR) images from an open-sourced database. Raw pixel data was extracted from the Comma Separated Values (CSV) files and subsequently reorganized and normalized to lie within the OpenCV pixel value limits. Next, data cleaning was carried out to remove irrelevant (laser transition images) before storing the remaining data into a big list as Portable Graphics Format (PNG) files to retain all the image information. Following that, the PNG images were passed through the OpenCV image processing pipelines to extract various melt pool parameters. Some of these parameters include the Heat Affect Zone (HAZ) area, inner melt pool length, width, area, maximum and average temperature. Finally, these parameters were plotted against time and layer number to provide a 2D and 3D visualization of the melt pool. As such, the relative standard deviation, and the coefficient of determination of the melt pool parameters were derived to identify the most reliable parameter to be used for future data-driven control models.
author2 Moon Seung Ki
author_facet Moon Seung Ki
Ong, Benjamin Jin Rui
format Final Year Project
author Ong, Benjamin Jin Rui
author_sort Ong, Benjamin Jin Rui
title Part and process monitoring for 3D printing technologies
title_short Part and process monitoring for 3D printing technologies
title_full Part and process monitoring for 3D printing technologies
title_fullStr Part and process monitoring for 3D printing technologies
title_full_unstemmed Part and process monitoring for 3D printing technologies
title_sort part and process monitoring for 3d printing technologies
publisher Nanyang Technological University
publishDate 2022
url https://hdl.handle.net/10356/157383
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