Union by Co-Lamination of Aluminum and Magnetic alloy obtained by Rapid Solidification

The aim of this work is to analyze the possibility of producing a joint by lamination of an Al-1050 plate and Fe78Si9B13(%at.) soft magnetic ribbons material obtained by a rapid solidification process by using the Melt Spinning (MS) technique. The lamination conditions are studied on the characteris...

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Autores:: García Almassio, Francisco
Pagnola, Marcelo Rubén
Saporitti, Fabiana
Audebert, Fernando

Tipo de recurso:: Article of journal

Fecha de publicación:: 2022

Institución:: Universidad Tecnológica de Bolívar

Repositorio:: Repositorio Institucional UTB

Idioma:: eng

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network_acronym_str	UTB2
network_name_str	Repositorio Institucional UTB
repository_id_str
dc.title.spa.fl_str_mv	Union by Co-Lamination of Aluminum and Magnetic alloy obtained by Rapid Solidification
dc.title.translated.spa.fl_str_mv	Union by Co-Lamination of Aluminum and Magnetic alloy obtained by Rapid Solidification
title	Union by Co-Lamination of Aluminum and Magnetic alloy obtained by Rapid Solidification
spellingShingle	Union by Co-Lamination of Aluminum and Magnetic alloy obtained by Rapid Solidification COLAMINATION RAPID SOLIDIFICATION MELT SPINNING HYSTERESIS EDDY CURRENT
title_short	Union by Co-Lamination of Aluminum and Magnetic alloy obtained by Rapid Solidification
title_full	Union by Co-Lamination of Aluminum and Magnetic alloy obtained by Rapid Solidification
title_fullStr	Union by Co-Lamination of Aluminum and Magnetic alloy obtained by Rapid Solidification
title_full_unstemmed	Union by Co-Lamination of Aluminum and Magnetic alloy obtained by Rapid Solidification
title_sort	Union by Co-Lamination of Aluminum and Magnetic alloy obtained by Rapid Solidification
dc.creator.fl_str_mv	García Almassio, Francisco Pagnola, Marcelo Rubén Saporitti, Fabiana Audebert, Fernando
dc.contributor.author.eng.fl_str_mv	García Almassio, Francisco Pagnola, Marcelo Rubén Saporitti, Fabiana Audebert, Fernando
dc.subject.eng.fl_str_mv	COLAMINATION RAPID SOLIDIFICATION MELT SPINNING HYSTERESIS EDDY CURRENT
topic	COLAMINATION RAPID SOLIDIFICATION MELT SPINNING HYSTERESIS EDDY CURRENT
description	The aim of this work is to analyze the possibility of producing a joint by lamination of an Al-1050 plate and Fe78Si9B13(%at.) soft magnetic ribbons material obtained by a rapid solidification process by using the Melt Spinning (MS) technique. The lamination conditions are studied on the characteristics of the joint, the microstructure, and the magnetic properties. Mainly the surface preparation, temperature, and reduction of thickness. The material is characterized by X-Ray Diffraction, Optical, and Scanning Electron Microscopy, showing a completely amorphous structure before and after the collamination, the typical defects caused by this rapid solidification technique in ribbons (bubbles, dust particles, roughness imperfections and oxides) and the joint between materials. The microhardness Vickers has been determined in both, the ribbons as quenched and collaminated samples, to observe quantitatively the hardening suffered during colamination and find a possible cause. The Differential Scanning Calorimetry and Compositional Analysis by EDS techniques were also used to determine the crystallization temperatures and chemical exact chemical composition of the ribbons as received. The magnetic hysteresis curve of the amorphous ribbons showed a Hc and Ms around 3.8 A/m and 1.44 T correspondingly.
publishDate	2022
dc.date.accessioned.none.fl_str_mv	2022-07-28 16:45:26 2025-05-21T19:15:45Z
dc.date.available.none.fl_str_mv	2022-07-28 16:45:26
dc.date.issued.none.fl_str_mv	2022-07-28
dc.type.spa.fl_str_mv	Artículo de revista
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dc.type.driver.eng.fl_str_mv	info:eu-repo/semantics/article
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dc.type.local.eng.fl_str_mv	Journal article
dc.type.content.eng.fl_str_mv	Text
dc.type.version.eng.fl_str_mv	info:eu-repo/semantics/publishedVersion
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format	http://purl.org/coar/resource_type/c_6501
status_str	publishedVersion
dc.identifier.uri.none.fl_str_mv	https://hdl.handle.net/20.500.12585/13504
dc.identifier.url.none.fl_str_mv	https://doi.org/10.32397/tesea.vol3.n2.486
dc.identifier.doi.none.fl_str_mv	10.32397/tesea.vol3.n2.486
dc.identifier.eissn.none.fl_str_mv	2745-0120
url	https://hdl.handle.net/20.500.12585/13504 https://doi.org/10.32397/tesea.vol3.n2.486
identifier_str_mv	10.32397/tesea.vol3.n2.486 2745-0120
dc.language.iso.eng.fl_str_mv	eng
language	eng
dc.relation.references.eng.fl_str_mv	M. Pagnola and H. Sirkin. Materiales magnéticos modernos, May 2018. Avaliable at https://www.revistapetroquimica.com/materiales-magneticos-modernos/. [2] D Muraca, J Silveyra, M Pagnola, and V Cremaschi. Nanocrystals magnetic contribution to finemet-type soft magnetic materials with ge addition. Journal of Magnetism and magnetic Materials, 321(21):3640–3645, 2009. [3] Marcelo R Pagnola, Marcelo Barone, Mariano Malmoria, and Hugo Sirkin. Influence of z/w relation in chill block melt spinning (cbms) process and analysis of thickness in ribbons. Multidiscipline Modeling in Materials and Structures, 2015. [4] KH J. Buschow. J. Appl. Phys., 53:7713, 1982. [5] Giselher Herzer. Modern soft magnets: Amorphous and nanocrystalline materials. Acta Materialia, 61(3):718–734, 2013. [6] Pu Wang, Min Wei, Yannan Dong, Zhengqu Zhu, Jiaqi Liu, Jing Pang, Xiaoyu Li, and Jiaquan Zhang. Crystallization evolution behavior of amorphous fe85. 7si7. 9b3. 6cr2c0. 8 powder produced by a novel atomization process. Journal of Non-Crystalline Solids, 594:121824, 2022. [7] R. A. Serway and J. W. Jewett. Physics I, 3rd Edition. Cengage Learning Ed, 2004. [8] Marcelo R Pagnola, Mariano Malmoria, Marcelo Barone, and Hugo Sirkin. Analysis of fe78si9b13 (% at.) ribbons of noncommercial scrap materials produced by melt spinning equipment. Multidiscipline Modeling in Materials and Structures, 2014. [9] M Pagnola, M Malmoria, and M Barone. Biot number behaviour in the chill block melt spinning (cbms) process. Applied Thermal Engineering, 103:807–811, 2016. [10] Marcelo Rubén Pagnola, Jairo Useche Vivero, and Andres Guillermo Marrugo. New uses of micro and nanomaterials. IntechOpen, 2018. Avaliable at https://www.intechopen.com/books/6851. [11] A Cabral-Prieto, F García-Santibáñez, A López, R López-Castañares, and O Olea Cardoso. Vickers microhardness and hyperfine magnetic field variations of heat treated amorphous fe78si9b13 alloy ribbons. Hyperfine Interactions, 161(1):69–81, 2005. [12] NN Zhuravlev. X-ray determination of the structure of sib. Kristallografiya, 1(6):666–68, 1956. [13] J Zhang and F Guyot. Thermal equation of state of iron and fe0. 91si0. 09. Physics and Chemistry of Minerals, 26(3):206–211, 1999. [14] Sterling B Hendricks and Peter R Kosting. Xxxv. the crystal structure of fe2p, fe2n, fe3n and feb. Zeitschrift für Kristallographie-Crystalline Materials, 74(1-6):511–533, 1930. [15] Narges Amini, Július Dekan, Milan Pavúk, Safdar Habibi, and Marcel Miglierini. Influence of quenching rate on the structure, morphology, and hyperfine parameters of amorphous ribbons. Journal of Electrical Engineering, 67(5):365, 2016. [16] Aleksandr Markovich Glezer and NA Shurygina. Amorphous-nanocrystalline alloys. CRC Press, 2017. [17] JM Cadogan, SJ Campbell, J Jing, CP Foley, P Kater, and YW Mai. Annealing embrittlement of fe78si9b13 (metglas-2605s2). Hyperfine Interactions, 226(1):7–14, 2014. [18] Teruo Bitoh, Akihiro Makino, and Akihisa Inoue. Origin of low coercivity of fe-(al, ga)-(p, c, b, si, ge) bulk glassy alloys. Materials transactions, 44(10):2020–2024, 2003. [19] A Makino, T Bitoh, A Kojima, A Inoue, and T Masumoto. Low core losses of nanocrystalline fe–zr–nb–b soft magnetic alloys with high magnetic flux density. Materials Science and Engineering: A, 304:1083–1086, 2001. [20] Richard M Bozorth. Ferromagnetism. Wiley-IEEE Press, 1993. [21] F. Garcia Almassio. Unión por Co-Laminación de Aluminio y aleación Magnética obtenida por Solidificación Rápida. Universidad de Buenos Aires, 2019.
dc.relation.ispartofjournal.eng.fl_str_mv	Transactions on Energy Systems and Engineering Applications
dc.relation.citationvolume.eng.fl_str_mv	3
dc.relation.citationstartpage.none.fl_str_mv	1
dc.relation.citationendpage.none.fl_str_mv	16
dc.relation.bitstream.none.fl_str_mv	https://revistas.utb.edu.co/tesea/article/download/486/370
dc.relation.citationedition.eng.fl_str_mv	Núm. 2 , Año 2022 : Transactions on Energy Systems and Engineering Applications
dc.relation.citationissue.eng.fl_str_mv	2
dc.rights.eng.fl_str_mv	Francisco Garcia Almassio, Marcelo Ruben Pagnola, Fabiana Saporitti, Fernando Audebert - 2022
dc.rights.uri.eng.fl_str_mv	https://creativecommons.org/licenses/by/4.0
dc.rights.accessrights.eng.fl_str_mv	info:eu-repo/semantics/openAccess
dc.rights.creativecommons.eng.fl_str_mv	This work is licensed under a Creative Commons Attribution 4.0 International License.
dc.rights.coar.eng.fl_str_mv	http://purl.org/coar/access_right/c_abf2
rights_invalid_str_mv	Francisco Garcia Almassio, Marcelo Ruben Pagnola, Fabiana Saporitti, Fernando Audebert - 2022 https://creativecommons.org/licenses/by/4.0 This work is licensed under a Creative Commons Attribution 4.0 International License. http://purl.org/coar/access_right/c_abf2
eu_rights_str_mv	openAccess
dc.format.mimetype.eng.fl_str_mv	application/pdf
dc.publisher.eng.fl_str_mv	Universidad Tecnológica de Bolívar
dc.source.eng.fl_str_mv	https://revistas.utb.edu.co/tesea/article/view/486
institution	Universidad Tecnológica de Bolívar
repository.name.fl_str_mv	Repositorio Digital Universidad Tecnológica de Bolívar
repository.mail.fl_str_mv	bdigital@metabiblioteca.com
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spelling	García Almassio, FranciscoPagnola, Marcelo RubénSaporitti, FabianaAudebert, Fernando2022-07-28 16:45:262025-05-21T19:15:45Z2022-07-28 16:45:262022-07-28https://hdl.handle.net/20.500.12585/13504https://doi.org/10.32397/tesea.vol3.n2.48610.32397/tesea.vol3.n2.4862745-0120The aim of this work is to analyze the possibility of producing a joint by lamination of an Al-1050 plate and Fe78Si9B13(%at.) soft magnetic ribbons material obtained by a rapid solidification process by using the Melt Spinning (MS) technique. The lamination conditions are studied on the characteristics of the joint, the microstructure, and the magnetic properties. Mainly the surface preparation, temperature, and reduction of thickness. The material is characterized by X-Ray Diffraction, Optical, and Scanning Electron Microscopy, showing a completely amorphous structure before and after the collamination, the typical defects caused by this rapid solidification technique in ribbons (bubbles, dust particles, roughness imperfections and oxides) and the joint between materials. The microhardness Vickers has been determined in both, the ribbons as quenched and collaminated samples, to observe quantitatively the hardening suffered during colamination and find a possible cause. The Differential Scanning Calorimetry and Compositional Analysis by EDS techniques were also used to determine the crystallization temperatures and chemical exact chemical composition of the ribbons as received. The magnetic hysteresis curve of the amorphous ribbons showed a Hc and Ms around 3.8 A/m and 1.44 T correspondingly.application/pdfengUniversidad Tecnológica de BolívarFrancisco Garcia Almassio, Marcelo Ruben Pagnola, Fabiana Saporitti, Fernando Audebert - 2022https://creativecommons.org/licenses/by/4.0info:eu-repo/semantics/openAccessThis work is licensed under a Creative Commons Attribution 4.0 International License.http://purl.org/coar/access_right/c_abf2https://revistas.utb.edu.co/tesea/article/view/486COLAMINATIONRAPID SOLIDIFICATIONMELT SPINNINGHYSTERESISEDDY CURRENTUnion by Co-Lamination of Aluminum and Magnetic alloy obtained by Rapid SolidificationUnion by Co-Lamination of Aluminum and Magnetic alloy obtained by Rapid SolidificationArtículo de revistainfo:eu-repo/semantics/articlehttp://purl.org/coar/resource_type/c_6501http://purl.org/coar/resource_type/c_2df8fbb1Journal articleTextinfo:eu-repo/semantics/publishedVersionhttp://purl.org/coar/version/c_970fb48d4fbd8a85M. Pagnola and H. Sirkin. Materiales magnéticos modernos, May 2018. Avaliable at https://www.revistapetroquimica.com/materiales-magneticos-modernos/. [2] D Muraca, J Silveyra, M Pagnola, and V Cremaschi. Nanocrystals magnetic contribution to finemet-type soft magnetic materials with ge addition. Journal of Magnetism and magnetic Materials, 321(21):3640–3645, 2009. [3] Marcelo R Pagnola, Marcelo Barone, Mariano Malmoria, and Hugo Sirkin. Influence of z/w relation in chill block melt spinning (cbms) process and analysis of thickness in ribbons. Multidiscipline Modeling in Materials and Structures, 2015. [4] KH J. Buschow. J. Appl. Phys., 53:7713, 1982. [5] Giselher Herzer. Modern soft magnets: Amorphous and nanocrystalline materials. Acta Materialia, 61(3):718–734, 2013. [6] Pu Wang, Min Wei, Yannan Dong, Zhengqu Zhu, Jiaqi Liu, Jing Pang, Xiaoyu Li, and Jiaquan Zhang. Crystallization evolution behavior of amorphous fe85. 7si7. 9b3. 6cr2c0. 8 powder produced by a novel atomization process. Journal of Non-Crystalline Solids, 594:121824, 2022. [7] R. A. Serway and J. W. Jewett. Physics I, 3rd Edition. Cengage Learning Ed, 2004. [8] Marcelo R Pagnola, Mariano Malmoria, Marcelo Barone, and Hugo Sirkin. Analysis of fe78si9b13 (% at.) ribbons of noncommercial scrap materials produced by melt spinning equipment. Multidiscipline Modeling in Materials and Structures, 2014. [9] M Pagnola, M Malmoria, and M Barone. Biot number behaviour in the chill block melt spinning (cbms) process. Applied Thermal Engineering, 103:807–811, 2016. [10] Marcelo Rubén Pagnola, Jairo Useche Vivero, and Andres Guillermo Marrugo. New uses of micro and nanomaterials. IntechOpen, 2018. Avaliable at https://www.intechopen.com/books/6851. [11] A Cabral-Prieto, F García-Santibáñez, A López, R López-Castañares, and O Olea Cardoso. Vickers microhardness and hyperfine magnetic field variations of heat treated amorphous fe78si9b13 alloy ribbons. Hyperfine Interactions, 161(1):69–81, 2005. [12] NN Zhuravlev. X-ray determination of the structure of sib. Kristallografiya, 1(6):666–68, 1956. [13] J Zhang and F Guyot. Thermal equation of state of iron and fe0. 91si0. 09. Physics and Chemistry of Minerals, 26(3):206–211, 1999. [14] Sterling B Hendricks and Peter R Kosting. Xxxv. the crystal structure of fe2p, fe2n, fe3n and feb. Zeitschrift für Kristallographie-Crystalline Materials, 74(1-6):511–533, 1930. [15] Narges Amini, Július Dekan, Milan Pavúk, Safdar Habibi, and Marcel Miglierini. Influence of quenching rate on the structure, morphology, and hyperfine parameters of amorphous ribbons. Journal of Electrical Engineering, 67(5):365, 2016. [16] Aleksandr Markovich Glezer and NA Shurygina. Amorphous-nanocrystalline alloys. CRC Press, 2017. [17] JM Cadogan, SJ Campbell, J Jing, CP Foley, P Kater, and YW Mai. Annealing embrittlement of fe78si9b13 (metglas-2605s2). Hyperfine Interactions, 226(1):7–14, 2014. [18] Teruo Bitoh, Akihiro Makino, and Akihisa Inoue. Origin of low coercivity of fe-(al, ga)-(p, c, b, si, ge) bulk glassy alloys. Materials transactions, 44(10):2020–2024, 2003. [19] A Makino, T Bitoh, A Kojima, A Inoue, and T Masumoto. Low core losses of nanocrystalline fe–zr–nb–b soft magnetic alloys with high magnetic flux density. Materials Science and Engineering: A, 304:1083–1086, 2001. [20] Richard M Bozorth. Ferromagnetism. Wiley-IEEE Press, 1993. [21] F. Garcia Almassio. Unión por Co-Laminación de Aluminio y aleación Magnética obtenida por Solidificación Rápida. Universidad de Buenos Aires, 2019.Transactions on Energy Systems and Engineering Applications3116https://revistas.utb.edu.co/tesea/article/download/486/370Núm. 2 , Año 2022 : Transactions on Energy Systems and Engineering Applications220.500.12585/13504oai:repositorio.utb.edu.co:20.500.12585/135042025-06-24 14:40:47.388https://creativecommons.org/licenses/by/4.0Francisco Garcia Almassio, Marcelo Ruben Pagnola, Fabiana Saporitti, Fernando Audebert - 2022metadata.onlyhttps://repositorio.utb.edu.coRepositorio Digital Universidad Tecnológica de Bolívarbdigital@metabiblioteca.com

Union by Co-Lamination of Aluminum and Magnetic alloy obtained by Rapid Solidification

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