Development of Computational Models for Coiling Process with the Belt Wrapper

Abstract This study introduces coiling mechanism with the belt wrapper to understand a force equilibrium for successful coiling. By establishing a finite element (FE) model, strips were coiled 2 to 3 rotations by the belt wrapper on the sleeve without coiling tension T, then T was applied to the opp...
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Autor*in:	Park, Yonghui [verfasserIn] Park, Hyunchul

Format:	Artikel
Sprache:	Englisch

Erschienen:	2016

Schlagwörter:	Contact Pressure Radial Stress Contact Layer Radial Deformation Static Friction Force

Anmerkung:	© The Minerals, Metals & Materials Society and ASM International 2016

Übergeordnetes Werk:	Enthalten in: Metallurgical and materials transactions / B - Springer US, 1994, 47(2016), 5 vom: 06. Juli, Seite 2699-2704
Übergeordnetes Werk:	volume:47 ; year:2016 ; number:5 ; day:06 ; month:07 ; pages:2699-2704

Links:	Volltext

DOI / URN:	10.1007/s11663-016-0733-7

Katalog-ID:	OLC2059783976

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520			\|a Abstract This study introduces coiling mechanism with the belt wrapper to understand a force equilibrium for successful coiling. By establishing a finite element (FE) model, strips were coiled 2 to 3 rotations by the belt wrapper on the sleeve without coiling tension T, then T was applied to the opposite side of the strips near the pinch roller, and the belt wrapper was removed from the strip coil at the same time. Additionally, analytical model corresponding to FE model was defined by thick and thin cylinder theorems to quantize coiling mechanisms. Especially elasticity of the belt wrapper E [N/$ m^{2} $], coiling tension T [N/$ m^{2} $], and friction coefficient μ were checked on how these variables affect each other, were converted into pressure P [N/$ m^{2} $], and P were used to calculate when the strip coil come untied. For instance, the strip coil came untied when E was lower than 1 × $ 10^{9} $ N/$ m^{2} $ corresponding to $$ \left( {\frac{{{\text{Pressure}}\; {\text{on}}\; {\text{outmost}}\; {\text{of the belt wrapper}}\; P_{\text{o,belt}} }}{{{\text{Pressure}}\; {\text{on}}\; {\text{innermost}}\; {\text{of the sleeve}}\; P_{\text{i,sleeve}} }} = 0.877} \right) $$. Lastly, radial stress on the outmost of the sleeve σr,o,sleeve [N/$ m^{2} $] according to E were compared to the previous coiling method with the grooved joint to see how these methods are different. Based on these results, this paper suggests coiling criteria to avoid coiling failure of slip of the strip coil.
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allfields	10.1007/s11663-016-0733-7 doi (DE-627)OLC2059783976 (DE-He213)s11663-016-0733-7-p DE-627 ger DE-627 rakwb eng 620 660 VZ Park, Yonghui verfasserin aut Development of Computational Models for Coiling Process with the Belt Wrapper 2016 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier © The Minerals, Metals & Materials Society and ASM International 2016 Abstract This study introduces coiling mechanism with the belt wrapper to understand a force equilibrium for successful coiling. By establishing a finite element (FE) model, strips were coiled 2 to 3 rotations by the belt wrapper on the sleeve without coiling tension T, then T was applied to the opposite side of the strips near the pinch roller, and the belt wrapper was removed from the strip coil at the same time. Additionally, analytical model corresponding to FE model was defined by thick and thin cylinder theorems to quantize coiling mechanisms. Especially elasticity of the belt wrapper E [N/$ m^{2} $], coiling tension T [N/$ m^{2} $], and friction coefficient μ were checked on how these variables affect each other, were converted into pressure P [N/$ m^{2} $], and P were used to calculate when the strip coil come untied. For instance, the strip coil came untied when E was lower than 1 × $ 10^{9} $ N/$ m^{2} $ corresponding to $$ \left( {\frac{{{\text{Pressure}}\; {\text{on}}\; {\text{outmost}}\; {\text{of the belt wrapper}}\; P_{\text{o,belt}} }}{{{\text{Pressure}}\; {\text{on}}\; {\text{innermost}}\; {\text{of the sleeve}}\; P_{\text{i,sleeve}} }} = 0.877} \right) $$. Lastly, radial stress on the outmost of the sleeve σr,o,sleeve [N/$ m^{2} $] according to E were compared to the previous coiling method with the grooved joint to see how these methods are different. Based on these results, this paper suggests coiling criteria to avoid coiling failure of slip of the strip coil. Contact Pressure Radial Stress Contact Layer Radial Deformation Static Friction Force Park, Hyunchul aut Enthalten in Metallurgical and materials transactions / B Springer US, 1994 47(2016), 5 vom: 06. Juli, Seite 2699-2704 (DE-627)182203832 (DE-600)1186125-3 (DE-576)038889196 1073-5615 nnns volume:47 year:2016 number:5 day:06 month:07 pages:2699-2704 https://doi.org/10.1007/s11663-016-0733-7 lizenzpflichtig Volltext GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-TEC SSG-OLC-CHE SSG-OLC-PHA SSG-OLC-DE-84 GBV_ILN_30 GBV_ILN_70 GBV_ILN_4319 GBV_ILN_4323 AR 47 2016 5 06 07 2699-2704
spelling	10.1007/s11663-016-0733-7 doi (DE-627)OLC2059783976 (DE-He213)s11663-016-0733-7-p DE-627 ger DE-627 rakwb eng 620 660 VZ Park, Yonghui verfasserin aut Development of Computational Models for Coiling Process with the Belt Wrapper 2016 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier © The Minerals, Metals & Materials Society and ASM International 2016 Abstract This study introduces coiling mechanism with the belt wrapper to understand a force equilibrium for successful coiling. By establishing a finite element (FE) model, strips were coiled 2 to 3 rotations by the belt wrapper on the sleeve without coiling tension T, then T was applied to the opposite side of the strips near the pinch roller, and the belt wrapper was removed from the strip coil at the same time. Additionally, analytical model corresponding to FE model was defined by thick and thin cylinder theorems to quantize coiling mechanisms. Especially elasticity of the belt wrapper E [N/$ m^{2} $], coiling tension T [N/$ m^{2} $], and friction coefficient μ were checked on how these variables affect each other, were converted into pressure P [N/$ m^{2} $], and P were used to calculate when the strip coil come untied. For instance, the strip coil came untied when E was lower than 1 × $ 10^{9} $ N/$ m^{2} $ corresponding to $$ \left( {\frac{{{\text{Pressure}}\; {\text{on}}\; {\text{outmost}}\; {\text{of the belt wrapper}}\; P_{\text{o,belt}} }}{{{\text{Pressure}}\; {\text{on}}\; {\text{innermost}}\; {\text{of the sleeve}}\; P_{\text{i,sleeve}} }} = 0.877} \right) $$. Lastly, radial stress on the outmost of the sleeve σr,o,sleeve [N/$ m^{2} $] according to E were compared to the previous coiling method with the grooved joint to see how these methods are different. Based on these results, this paper suggests coiling criteria to avoid coiling failure of slip of the strip coil. Contact Pressure Radial Stress Contact Layer Radial Deformation Static Friction Force Park, Hyunchul aut Enthalten in Metallurgical and materials transactions / B Springer US, 1994 47(2016), 5 vom: 06. Juli, Seite 2699-2704 (DE-627)182203832 (DE-600)1186125-3 (DE-576)038889196 1073-5615 nnns volume:47 year:2016 number:5 day:06 month:07 pages:2699-2704 https://doi.org/10.1007/s11663-016-0733-7 lizenzpflichtig Volltext GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-TEC SSG-OLC-CHE SSG-OLC-PHA SSG-OLC-DE-84 GBV_ILN_30 GBV_ILN_70 GBV_ILN_4319 GBV_ILN_4323 AR 47 2016 5 06 07 2699-2704
allfields_unstemmed	10.1007/s11663-016-0733-7 doi (DE-627)OLC2059783976 (DE-He213)s11663-016-0733-7-p DE-627 ger DE-627 rakwb eng 620 660 VZ Park, Yonghui verfasserin aut Development of Computational Models for Coiling Process with the Belt Wrapper 2016 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier © The Minerals, Metals & Materials Society and ASM International 2016 Abstract This study introduces coiling mechanism with the belt wrapper to understand a force equilibrium for successful coiling. By establishing a finite element (FE) model, strips were coiled 2 to 3 rotations by the belt wrapper on the sleeve without coiling tension T, then T was applied to the opposite side of the strips near the pinch roller, and the belt wrapper was removed from the strip coil at the same time. Additionally, analytical model corresponding to FE model was defined by thick and thin cylinder theorems to quantize coiling mechanisms. Especially elasticity of the belt wrapper E [N/$ m^{2} $], coiling tension T [N/$ m^{2} $], and friction coefficient μ were checked on how these variables affect each other, were converted into pressure P [N/$ m^{2} $], and P were used to calculate when the strip coil come untied. For instance, the strip coil came untied when E was lower than 1 × $ 10^{9} $ N/$ m^{2} $ corresponding to $$ \left( {\frac{{{\text{Pressure}}\; {\text{on}}\; {\text{outmost}}\; {\text{of the belt wrapper}}\; P_{\text{o,belt}} }}{{{\text{Pressure}}\; {\text{on}}\; {\text{innermost}}\; {\text{of the sleeve}}\; P_{\text{i,sleeve}} }} = 0.877} \right) $$. Lastly, radial stress on the outmost of the sleeve σr,o,sleeve [N/$ m^{2} $] according to E were compared to the previous coiling method with the grooved joint to see how these methods are different. Based on these results, this paper suggests coiling criteria to avoid coiling failure of slip of the strip coil. Contact Pressure Radial Stress Contact Layer Radial Deformation Static Friction Force Park, Hyunchul aut Enthalten in Metallurgical and materials transactions / B Springer US, 1994 47(2016), 5 vom: 06. Juli, Seite 2699-2704 (DE-627)182203832 (DE-600)1186125-3 (DE-576)038889196 1073-5615 nnns volume:47 year:2016 number:5 day:06 month:07 pages:2699-2704 https://doi.org/10.1007/s11663-016-0733-7 lizenzpflichtig Volltext GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-TEC SSG-OLC-CHE SSG-OLC-PHA SSG-OLC-DE-84 GBV_ILN_30 GBV_ILN_70 GBV_ILN_4319 GBV_ILN_4323 AR 47 2016 5 06 07 2699-2704
allfieldsGer	10.1007/s11663-016-0733-7 doi (DE-627)OLC2059783976 (DE-He213)s11663-016-0733-7-p DE-627 ger DE-627 rakwb eng 620 660 VZ Park, Yonghui verfasserin aut Development of Computational Models for Coiling Process with the Belt Wrapper 2016 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier © The Minerals, Metals & Materials Society and ASM International 2016 Abstract This study introduces coiling mechanism with the belt wrapper to understand a force equilibrium for successful coiling. By establishing a finite element (FE) model, strips were coiled 2 to 3 rotations by the belt wrapper on the sleeve without coiling tension T, then T was applied to the opposite side of the strips near the pinch roller, and the belt wrapper was removed from the strip coil at the same time. Additionally, analytical model corresponding to FE model was defined by thick and thin cylinder theorems to quantize coiling mechanisms. Especially elasticity of the belt wrapper E [N/$ m^{2} $], coiling tension T [N/$ m^{2} $], and friction coefficient μ were checked on how these variables affect each other, were converted into pressure P [N/$ m^{2} $], and P were used to calculate when the strip coil come untied. For instance, the strip coil came untied when E was lower than 1 × $ 10^{9} $ N/$ m^{2} $ corresponding to $$ \left( {\frac{{{\text{Pressure}}\; {\text{on}}\; {\text{outmost}}\; {\text{of the belt wrapper}}\; P_{\text{o,belt}} }}{{{\text{Pressure}}\; {\text{on}}\; {\text{innermost}}\; {\text{of the sleeve}}\; P_{\text{i,sleeve}} }} = 0.877} \right) $$. Lastly, radial stress on the outmost of the sleeve σr,o,sleeve [N/$ m^{2} $] according to E were compared to the previous coiling method with the grooved joint to see how these methods are different. Based on these results, this paper suggests coiling criteria to avoid coiling failure of slip of the strip coil. Contact Pressure Radial Stress Contact Layer Radial Deformation Static Friction Force Park, Hyunchul aut Enthalten in Metallurgical and materials transactions / B Springer US, 1994 47(2016), 5 vom: 06. Juli, Seite 2699-2704 (DE-627)182203832 (DE-600)1186125-3 (DE-576)038889196 1073-5615 nnns volume:47 year:2016 number:5 day:06 month:07 pages:2699-2704 https://doi.org/10.1007/s11663-016-0733-7 lizenzpflichtig Volltext GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-TEC SSG-OLC-CHE SSG-OLC-PHA SSG-OLC-DE-84 GBV_ILN_30 GBV_ILN_70 GBV_ILN_4319 GBV_ILN_4323 AR 47 2016 5 06 07 2699-2704
allfieldsSound	10.1007/s11663-016-0733-7 doi (DE-627)OLC2059783976 (DE-He213)s11663-016-0733-7-p DE-627 ger DE-627 rakwb eng 620 660 VZ Park, Yonghui verfasserin aut Development of Computational Models for Coiling Process with the Belt Wrapper 2016 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier © The Minerals, Metals & Materials Society and ASM International 2016 Abstract This study introduces coiling mechanism with the belt wrapper to understand a force equilibrium for successful coiling. By establishing a finite element (FE) model, strips were coiled 2 to 3 rotations by the belt wrapper on the sleeve without coiling tension T, then T was applied to the opposite side of the strips near the pinch roller, and the belt wrapper was removed from the strip coil at the same time. Additionally, analytical model corresponding to FE model was defined by thick and thin cylinder theorems to quantize coiling mechanisms. Especially elasticity of the belt wrapper E [N/$ m^{2} $], coiling tension T [N/$ m^{2} $], and friction coefficient μ were checked on how these variables affect each other, were converted into pressure P [N/$ m^{2} $], and P were used to calculate when the strip coil come untied. For instance, the strip coil came untied when E was lower than 1 × $ 10^{9} $ N/$ m^{2} $ corresponding to $$ \left( {\frac{{{\text{Pressure}}\; {\text{on}}\; {\text{outmost}}\; {\text{of the belt wrapper}}\; P_{\text{o,belt}} }}{{{\text{Pressure}}\; {\text{on}}\; {\text{innermost}}\; {\text{of the sleeve}}\; P_{\text{i,sleeve}} }} = 0.877} \right) $$. Lastly, radial stress on the outmost of the sleeve σr,o,sleeve [N/$ m^{2} $] according to E were compared to the previous coiling method with the grooved joint to see how these methods are different. Based on these results, this paper suggests coiling criteria to avoid coiling failure of slip of the strip coil. Contact Pressure Radial Stress Contact Layer Radial Deformation Static Friction Force Park, Hyunchul aut Enthalten in Metallurgical and materials transactions / B Springer US, 1994 47(2016), 5 vom: 06. Juli, Seite 2699-2704 (DE-627)182203832 (DE-600)1186125-3 (DE-576)038889196 1073-5615 nnns volume:47 year:2016 number:5 day:06 month:07 pages:2699-2704 https://doi.org/10.1007/s11663-016-0733-7 lizenzpflichtig Volltext GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-TEC SSG-OLC-CHE SSG-OLC-PHA SSG-OLC-DE-84 GBV_ILN_30 GBV_ILN_70 GBV_ILN_4319 GBV_ILN_4323 AR 47 2016 5 06 07 2699-2704
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dewey-tens	620 - Engineering 660 - Chemical engineering
hierarchy_top_title	Metallurgical and materials transactions / B
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title	Development of Computational Models for Coiling Process with the Belt Wrapper
ctrlnum	(DE-627)OLC2059783976 (DE-He213)s11663-016-0733-7-p
title_full	Development of Computational Models for Coiling Process with the Belt Wrapper
author_sort	Park, Yonghui
journal	Metallurgical and materials transactions / B
journalStr	Metallurgical and materials transactions / B
lang_code	eng
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dewey-hundreds	600 - Technology
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container_start_page	2699
author_browse	Park, Yonghui Park, Hyunchul
container_volume	47
class	620 660 VZ
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author-letter	Park, Yonghui
doi_str_mv	10.1007/s11663-016-0733-7
dewey-full	620 660
title_sort	development of computational models for coiling process with the belt wrapper
title_auth	Development of Computational Models for Coiling Process with the Belt Wrapper
abstract	Abstract This study introduces coiling mechanism with the belt wrapper to understand a force equilibrium for successful coiling. By establishing a finite element (FE) model, strips were coiled 2 to 3 rotations by the belt wrapper on the sleeve without coiling tension T, then T was applied to the opposite side of the strips near the pinch roller, and the belt wrapper was removed from the strip coil at the same time. Additionally, analytical model corresponding to FE model was defined by thick and thin cylinder theorems to quantize coiling mechanisms. Especially elasticity of the belt wrapper E [N/$ m^{2} $], coiling tension T [N/$ m^{2} $], and friction coefficient μ were checked on how these variables affect each other, were converted into pressure P [N/$ m^{2} $], and P were used to calculate when the strip coil come untied. For instance, the strip coil came untied when E was lower than 1 × $ 10^{9} $ N/$ m^{2} $ corresponding to $$ \left( {\frac{{{\text{Pressure}}\; {\text{on}}\; {\text{outmost}}\; {\text{of the belt wrapper}}\; P_{\text{o,belt}} }}{{{\text{Pressure}}\; {\text{on}}\; {\text{innermost}}\; {\text{of the sleeve}}\; P_{\text{i,sleeve}} }} = 0.877} \right) $$. Lastly, radial stress on the outmost of the sleeve σr,o,sleeve [N/$ m^{2} $] according to E were compared to the previous coiling method with the grooved joint to see how these methods are different. Based on these results, this paper suggests coiling criteria to avoid coiling failure of slip of the strip coil. © The Minerals, Metals & Materials Society and ASM International 2016
abstractGer	Abstract This study introduces coiling mechanism with the belt wrapper to understand a force equilibrium for successful coiling. By establishing a finite element (FE) model, strips were coiled 2 to 3 rotations by the belt wrapper on the sleeve without coiling tension T, then T was applied to the opposite side of the strips near the pinch roller, and the belt wrapper was removed from the strip coil at the same time. Additionally, analytical model corresponding to FE model was defined by thick and thin cylinder theorems to quantize coiling mechanisms. Especially elasticity of the belt wrapper E [N/$ m^{2} $], coiling tension T [N/$ m^{2} $], and friction coefficient μ were checked on how these variables affect each other, were converted into pressure P [N/$ m^{2} $], and P were used to calculate when the strip coil come untied. For instance, the strip coil came untied when E was lower than 1 × $ 10^{9} $ N/$ m^{2} $ corresponding to $$ \left( {\frac{{{\text{Pressure}}\; {\text{on}}\; {\text{outmost}}\; {\text{of the belt wrapper}}\; P_{\text{o,belt}} }}{{{\text{Pressure}}\; {\text{on}}\; {\text{innermost}}\; {\text{of the sleeve}}\; P_{\text{i,sleeve}} }} = 0.877} \right) $$. Lastly, radial stress on the outmost of the sleeve σr,o,sleeve [N/$ m^{2} $] according to E were compared to the previous coiling method with the grooved joint to see how these methods are different. Based on these results, this paper suggests coiling criteria to avoid coiling failure of slip of the strip coil. © The Minerals, Metals & Materials Society and ASM International 2016
abstract_unstemmed	Abstract This study introduces coiling mechanism with the belt wrapper to understand a force equilibrium for successful coiling. By establishing a finite element (FE) model, strips were coiled 2 to 3 rotations by the belt wrapper on the sleeve without coiling tension T, then T was applied to the opposite side of the strips near the pinch roller, and the belt wrapper was removed from the strip coil at the same time. Additionally, analytical model corresponding to FE model was defined by thick and thin cylinder theorems to quantize coiling mechanisms. Especially elasticity of the belt wrapper E [N/$ m^{2} $], coiling tension T [N/$ m^{2} $], and friction coefficient μ were checked on how these variables affect each other, were converted into pressure P [N/$ m^{2} $], and P were used to calculate when the strip coil come untied. For instance, the strip coil came untied when E was lower than 1 × $ 10^{9} $ N/$ m^{2} $ corresponding to $$ \left( {\frac{{{\text{Pressure}}\; {\text{on}}\; {\text{outmost}}\; {\text{of the belt wrapper}}\; P_{\text{o,belt}} }}{{{\text{Pressure}}\; {\text{on}}\; {\text{innermost}}\; {\text{of the sleeve}}\; P_{\text{i,sleeve}} }} = 0.877} \right) $$. Lastly, radial stress on the outmost of the sleeve σr,o,sleeve [N/$ m^{2} $] according to E were compared to the previous coiling method with the grooved joint to see how these methods are different. Based on these results, this paper suggests coiling criteria to avoid coiling failure of slip of the strip coil. © The Minerals, Metals & Materials Society and ASM International 2016
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container_issue	5
title_short	Development of Computational Models for Coiling Process with the Belt Wrapper
url	https://doi.org/10.1007/s11663-016-0733-7
remote_bool	false
author2	Park, Hyunchul
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doi_str	10.1007/s11663-016-0733-7
up_date	2024-07-03T23:23:10.687Z
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