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Moldflow Simulation and Characterization of Pure Copper Fabricated via Metal Injection Molding

Metal injection molding (MIM) is a representative near-net-shape manufacturing process that fabricates advanced geometrical components for automobile and device industries. As the mechanical performance of an MIM product is affected by green-part characteristics, this work investigated the green par...

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Autores principales: Bahanan, Warda, Fatimah, Siti, Song, Hyunseok, Lee, Eun Hye, Kim, Dong-Ju, Yang, Hae Woong, Woo, Chang Hoon, Ryu, Jungho, Widiantara, I Putu, Ko, Young Gun
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2023
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10419387/
https://www.ncbi.nlm.nih.gov/pubmed/37569963
http://dx.doi.org/10.3390/ma16155252
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author Bahanan, Warda
Fatimah, Siti
Song, Hyunseok
Lee, Eun Hye
Kim, Dong-Ju
Yang, Hae Woong
Woo, Chang Hoon
Ryu, Jungho
Widiantara, I Putu
Ko, Young Gun
author_facet Bahanan, Warda
Fatimah, Siti
Song, Hyunseok
Lee, Eun Hye
Kim, Dong-Ju
Yang, Hae Woong
Woo, Chang Hoon
Ryu, Jungho
Widiantara, I Putu
Ko, Young Gun
author_sort Bahanan, Warda
collection PubMed
description Metal injection molding (MIM) is a representative near-net-shape manufacturing process that fabricates advanced geometrical components for automobile and device industries. As the mechanical performance of an MIM product is affected by green-part characteristics, this work investigated the green part of pure copper processed with MIM using the injection temperature of ~180 °C and injection pressure of ~5 MPa. A computational analysis based on the Moldflow program was proposed to simulate the effectivity of the process by evaluating the confidence of fill, quality prediction, and pressure drop of three distinctive regions in the green part. The results showed that the ring and edge regions of the green parts showed localized behavior, which was related to processing parameters including the position of the gate. A microstructural observation using scanning electron microscopy and a 3D X-ray revealed that both the surface and body matrix consisted of pores with some agglomeration of micro-pores on the edges and ring part, while any critical defects, such as a crack, were not found. A microhardness analysis showed that the three regions exhibited a reasonable uniformity with a slight difference in one specific part mainly due to the localized pore agglomeration. The simulation results showed a good agreement with the microstructures and microhardness data. Thus, the present results are useful for providing guidelines for the sound condition of MIM-treated pure copper with a complex shape.
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spelling pubmed-104193872023-08-12 Moldflow Simulation and Characterization of Pure Copper Fabricated via Metal Injection Molding Bahanan, Warda Fatimah, Siti Song, Hyunseok Lee, Eun Hye Kim, Dong-Ju Yang, Hae Woong Woo, Chang Hoon Ryu, Jungho Widiantara, I Putu Ko, Young Gun Materials (Basel) Article Metal injection molding (MIM) is a representative near-net-shape manufacturing process that fabricates advanced geometrical components for automobile and device industries. As the mechanical performance of an MIM product is affected by green-part characteristics, this work investigated the green part of pure copper processed with MIM using the injection temperature of ~180 °C and injection pressure of ~5 MPa. A computational analysis based on the Moldflow program was proposed to simulate the effectivity of the process by evaluating the confidence of fill, quality prediction, and pressure drop of three distinctive regions in the green part. The results showed that the ring and edge regions of the green parts showed localized behavior, which was related to processing parameters including the position of the gate. A microstructural observation using scanning electron microscopy and a 3D X-ray revealed that both the surface and body matrix consisted of pores with some agglomeration of micro-pores on the edges and ring part, while any critical defects, such as a crack, were not found. A microhardness analysis showed that the three regions exhibited a reasonable uniformity with a slight difference in one specific part mainly due to the localized pore agglomeration. The simulation results showed a good agreement with the microstructures and microhardness data. Thus, the present results are useful for providing guidelines for the sound condition of MIM-treated pure copper with a complex shape. MDPI 2023-07-26 /pmc/articles/PMC10419387/ /pubmed/37569963 http://dx.doi.org/10.3390/ma16155252 Text en © 2023 by the authors. https://creativecommons.org/licenses/by/4.0/Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Bahanan, Warda
Fatimah, Siti
Song, Hyunseok
Lee, Eun Hye
Kim, Dong-Ju
Yang, Hae Woong
Woo, Chang Hoon
Ryu, Jungho
Widiantara, I Putu
Ko, Young Gun
Moldflow Simulation and Characterization of Pure Copper Fabricated via Metal Injection Molding
title Moldflow Simulation and Characterization of Pure Copper Fabricated via Metal Injection Molding
title_full Moldflow Simulation and Characterization of Pure Copper Fabricated via Metal Injection Molding
title_fullStr Moldflow Simulation and Characterization of Pure Copper Fabricated via Metal Injection Molding
title_full_unstemmed Moldflow Simulation and Characterization of Pure Copper Fabricated via Metal Injection Molding
title_short Moldflow Simulation and Characterization of Pure Copper Fabricated via Metal Injection Molding
title_sort moldflow simulation and characterization of pure copper fabricated via metal injection molding
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10419387/
https://www.ncbi.nlm.nih.gov/pubmed/37569963
http://dx.doi.org/10.3390/ma16155252
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