Tool wear and life span variations in cold forming operations and their implications in microforming
The current paper aims to review tooling life span, failure modes and models in cold microforming processes. As there is nearly no information available on tool-life for microforming the starting point was conventional cold forming. In cold forming common failures are (1) over stressing of the tool;...
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sg-ntu-dr.10356-901672023-03-04T17:17:32Z Tool wear and life span variations in cold forming operations and their implications in microforming Castagne, Sylvie J. Jarfors, Anders E. W. Danno, Atsushi Zhang, Xinping School of Mechanical and Aerospace Engineering Wear DRNTU::Engineering::Mechanical engineering Fatigue The current paper aims to review tooling life span, failure modes and models in cold microforming processes. As there is nearly no information available on tool-life for microforming the starting point was conventional cold forming. In cold forming common failures are (1) over stressing of the tool; (2) abrasive wear; (3) galling or adhesive wear, and (4) fatigue failure. The large variation in tool life observed in production and how to predict this was reviewed as this is important to the viability of microforming based on that the tooling cost takes a higher portion of the part cost. Anisotropic properties of the tool materials affect tool life span and depend on both the as-received and in-service conditions. It was concluded that preconditioning of the tool surface, and coating are important to control wear and fatigue. Properly managed, the detrimental effects from surface particles can be reduced. Under high stress low-cycle fatigue conditions, fatigue failure form internal microstructures and inclusions are common. To improve abrasive wear resistance larger carbides are commonly the solution which will have a negative impact on tooling life as these tend to be the root cause of fatigue failures. This has significant impact on cold microforming. Published version 2018-12-26T04:48:59Z 2019-12-06T17:42:14Z 2018-12-26T04:48:59Z 2019-12-06T17:42:14Z 2017 Journal Article Jarfors, A. E. W., Castagne, S. J., Danno, A., & Zhang, X. (2017). Tool Wear and Life Span Variations in Cold Forming Operations and Their Implications in Microforming. Technologies, 5(1), 3-. doi:10.3390/technologies5010003 https://hdl.handle.net/10356/90167 http://hdl.handle.net/10220/47198 10.3390/technologies5010003 en Technologies © 2016 by the authors; 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 (http://creativecommons.org/licenses/by/4.0/). 29 p. application/pdf |
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Wear DRNTU::Engineering::Mechanical engineering Fatigue Castagne, Sylvie J. Jarfors, Anders E. W. Danno, Atsushi Zhang, Xinping Tool wear and life span variations in cold forming operations and their implications in microforming |
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The current paper aims to review tooling life span, failure modes and models in cold microforming processes. As there is nearly no information available on tool-life for microforming the starting point was conventional cold forming. In cold forming common failures are (1) over stressing of the tool; (2) abrasive wear; (3) galling or adhesive wear, and (4) fatigue failure. The large variation in tool life observed in production and how to predict this was reviewed as this is important to the viability of microforming based on that the tooling cost takes a higher portion of the part cost. Anisotropic properties of the tool materials affect tool life span and depend on both the as-received and in-service conditions. It was concluded that preconditioning of the tool surface, and coating are important to control wear and fatigue. Properly managed, the detrimental effects from surface particles can be reduced. Under high stress low-cycle fatigue conditions, fatigue failure form internal microstructures and inclusions are common. To improve abrasive wear resistance larger carbides are commonly the solution which will have a negative impact on tooling life as these tend to be the root cause of fatigue failures. This has significant impact on cold microforming. |
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School of Mechanical and Aerospace Engineering |
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School of Mechanical and Aerospace Engineering Castagne, Sylvie J. Jarfors, Anders E. W. Danno, Atsushi Zhang, Xinping |
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Article |
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Castagne, Sylvie J. Jarfors, Anders E. W. Danno, Atsushi Zhang, Xinping |
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Castagne, Sylvie J. |
title |
Tool wear and life span variations in cold forming operations and their implications in microforming |
title_short |
Tool wear and life span variations in cold forming operations and their implications in microforming |
title_full |
Tool wear and life span variations in cold forming operations and their implications in microforming |
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Tool wear and life span variations in cold forming operations and their implications in microforming |
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Tool wear and life span variations in cold forming operations and their implications in microforming |
title_sort |
tool wear and life span variations in cold forming operations and their implications in microforming |
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2018 |
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https://hdl.handle.net/10356/90167 http://hdl.handle.net/10220/47198 |
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