Experimental characterization and modeling of the plastic behavior of a thirdgeneration advanced high strength steel sheet
| Autor(a) principal: | |
|---|---|
| Data de Publicação: | 2022 |
| Tipo de documento: | Tese |
| Idioma: | por |
| Título da fonte: | Repositório Institucional da Universidade Federal Fluminense (RIUFF) |
| Texto Completo: | http://app.uff.br/riuff/handle/1/27170 |
Resumo: | The third generation of the advanced highstrength steels (AHSS) has attracted the automotive industry attention owing to its good compromise between the formability and production cost. The current development stage of these steels so far has few products available on the market, as well as little research aimed at studying their formability. With an ultimate tensile strength greater than 1000 MPa and total elongation above 20%, the thirdgeneration AHSS with 980 MPa grade was the first sheet of this class of steel to be commercialized. In this work, several mechanical tests were performed to analyze the plastic behavior of a coldrolled Gen3 980T steel with a nominal thickness of 1.58 mm. The mechanical properties and the plastic anisotropy Lankford coefficients were obtained from uniaxial tensile tests performed in 7 angular orientations in the plane of the sheet. The workhardening of the Gen3 980T steel sheet was also assessed by means of the hydraulic bulge test, and the biaxial anisotropy coefficient was obtained using the disc compression test. The formability was investigated by means of the hole expansion, Erichsen cupping, and forming limit curve (FLC) test procedures. The limit strains were defined by ISO 120042 standard from inplane tests (uniaxial tension and plane strain in tension) and out of plane hemisphericalpunching tests (Nakajima procedure). The GursonTvergaardNeedleman (GTN) damage model was adopted to describe the fracture behavior of the Gen3 980T steel. A simple methodology for identifying the parameters of the GTN model was proposed. This calibration procedure was validated by comparing finite element predictions with the experimental measurements obtained from the mechanical tests. The Gen3 980T steel has a microstructure composed of martensite, ferrite, and retained austenite. In the asreceived condition, the Xray diffraction analysis provided 12.2% of the retained austenite volume fraction. In the sheet rolling direction, the average values of the yield stress () and ultimate tensile strength () are equal to 604 and 1040 MPa, respectively, along with a total elongation ( ) of 23.4%. In this way, Gen3 980T steel has global formability, defined by = 24.3 GPa%, a value which is consistent with that expected for the thirdgeneration of advanced highstrength steels. The Lankford coefficients determined in the angular orientations 0, 45, and 90 degrees with respect to the rolling direction are very close, which provided planar and normal anisotropy coefficients of − 0,079 and 0.917, respectively. The hole expansion ratio (HER) determined for the Gen3 980T steel sheet was equal to 10.9%, whereas the corresponding average Erichsen cupping test index (EI) was equal to 10.62 mm. The numerical simulations were able to describe the increase in formability due to the reduction of the friction coefficient and the effects inherent to the Nakajima test sample's curvature. The GTN damage model parameters, identified from the experimental uniaxial tensile data, provided a good forecast of the experimental results located on the lefthand side of the FLC. Regarding the right side of the FLC, the results obtained for the limit strains were conservative, mainly for the equal biaxial stretching. |
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Experimental characterization and modeling of the plastic behavior of a thirdgeneration advanced high strength steel sheetAdvanced high strength steels980 classMechanical testingLimit strainsDamage modelingSheet metal formingChapa de açoComportamento plásticoEngenharia MetalúrgicaProdução intelectualAços avançados de alta resistênciaClasse 980Ensaios mecânicosDeformações limitesModelamento de danoConformação de chapasThe third generation of the advanced highstrength steels (AHSS) has attracted the automotive industry attention owing to its good compromise between the formability and production cost. The current development stage of these steels so far has few products available on the market, as well as little research aimed at studying their formability. With an ultimate tensile strength greater than 1000 MPa and total elongation above 20%, the thirdgeneration AHSS with 980 MPa grade was the first sheet of this class of steel to be commercialized. In this work, several mechanical tests were performed to analyze the plastic behavior of a coldrolled Gen3 980T steel with a nominal thickness of 1.58 mm. The mechanical properties and the plastic anisotropy Lankford coefficients were obtained from uniaxial tensile tests performed in 7 angular orientations in the plane of the sheet. The workhardening of the Gen3 980T steel sheet was also assessed by means of the hydraulic bulge test, and the biaxial anisotropy coefficient was obtained using the disc compression test. The formability was investigated by means of the hole expansion, Erichsen cupping, and forming limit curve (FLC) test procedures. The limit strains were defined by ISO 120042 standard from inplane tests (uniaxial tension and plane strain in tension) and out of plane hemisphericalpunching tests (Nakajima procedure). The GursonTvergaardNeedleman (GTN) damage model was adopted to describe the fracture behavior of the Gen3 980T steel. A simple methodology for identifying the parameters of the GTN model was proposed. This calibration procedure was validated by comparing finite element predictions with the experimental measurements obtained from the mechanical tests. The Gen3 980T steel has a microstructure composed of martensite, ferrite, and retained austenite. In the asreceived condition, the Xray diffraction analysis provided 12.2% of the retained austenite volume fraction. In the sheet rolling direction, the average values of the yield stress () and ultimate tensile strength () are equal to 604 and 1040 MPa, respectively, along with a total elongation ( ) of 23.4%. In this way, Gen3 980T steel has global formability, defined by = 24.3 GPa%, a value which is consistent with that expected for the thirdgeneration of advanced highstrength steels. The Lankford coefficients determined in the angular orientations 0, 45, and 90 degrees with respect to the rolling direction are very close, which provided planar and normal anisotropy coefficients of − 0,079 and 0.917, respectively. The hole expansion ratio (HER) determined for the Gen3 980T steel sheet was equal to 10.9%, whereas the corresponding average Erichsen cupping test index (EI) was equal to 10.62 mm. The numerical simulations were able to describe the increase in formability due to the reduction of the friction coefficient and the effects inherent to the Nakajima test sample's curvature. The GTN damage model parameters, identified from the experimental uniaxial tensile data, provided a good forecast of the experimental results located on the lefthand side of the FLC. Regarding the right side of the FLC, the results obtained for the limit strains were conservative, mainly for the equal biaxial stretching.Fundação para Ciência e Tecnologia. PortugalThe third generation of the advanced highstrength steels (AHSS) has attracted the automotive industry attention owing to its good compromise between the formability and production cost. The current development stage of these steels so far has few products available on the market, as well as little research aimed at studying their formability. With an ultimate tensile strength greater than 1000 MPa and total elongation above 20%, the thirdgeneration AHSS with 980 MPa grade was the first sheet of this class of steel to be commercialized. In this work, several mechanical tests were performed to analyze the plastic behavior of a coldrolled Gen3 980T steel with a nominal thickness of 1.58 mm. The mechanical properties and the plastic anisotropy Lankford coefficients were obtained from uniaxial tensile tests performed in 7 angular orientations in the plane of the sheet. The workhardening of the Gen3 980T steel sheet was also assessed by means of the hydraulic bulge test, and the biaxial anisotropy coefficient was obtained using the disc compression test. The formability was investigated by means of the hole expansion, Erichsen cupping, and forming limit curve (FLC) test procedures. The limit strains were defined by ISO 120042 standard from inplane tests (uniaxial tension and plane strain in tension) and out of plane hemisphericalpunching tests (Nakajima procedure). The GursonTvergaardNeedleman (GTN) damage model was adopted to describe the fracture behavior of the Gen3 980T steel. A simple methodology for identifying the parameters of the GTN model was proposed. This calibration procedure was validated by comparing finite element predictions with the experimental measurements obtained from the mechanical tests. The Gen3 980T steel has a microstructure composed of martensite, ferrite, and retained austenite. In the asreceived condition, the X-ray diffraction analysis provided 12.2% of the retained austenite volume fraction. In the sheet rolling direction, the average values of the yield stress (Sᵧ) and ultimate tensile strength (Sᵤ) are equal to 604 and 1040 MPa, respectively, along with a total elongation (ₑt ) of 23.4%. In this way, Gen3 980T steel has global formability, defined by Sᵤ ₓ ₑt = 24.3 GPa%, a value which is consistent with that expected for the thirdgeneration of advanced highstrength steels. The Lankford coefficients determined in the angular orientations 0, 45, and 90 degrees with respect to the rolling direction are very close, which provided planar and normal anisotropy coefficients of − 0,079 and 0.917, respectively. The hole expansion ratio (HER) determined for the Gen3 980T steel sheet was equal to 10.9%, whereas the corresponding average Erichsen cupping test index (EI) was equal to 10.62 mm. The numerical simulations were able to describe the increase in formability due to the reduction of the friction coefficient and the effects inherent to the Nakajima test sample's curvature. The GTN damage model parameters, identified from the experimental uniaxial tensile data, provided a good forecast of the experimental results located on the lefthand side of the FLC. Regarding the right side of the FLC, the results obtained for the limit strains were conservative, mainly for the equal biaxial stretching.126 p.Butuc, Marilena CarmenMoreira, Luciano Pessanhahttp://lattes.cnpq.br/5673024226638200Pereira, António Manuel de Bastoshttp://lattes.cnpq.br/0662491008549976Vincze, Gabriela TamaraBatalha, Gilmar Ferreirahttp://lattes.cnpq.br/6266559761245923Fonseca, Gláucio Soares dahttp://lattes.cnpq.br/9663765935778795Freitas, Maria Carolina dos Santoshttp://lattes.cnpq.br/5037625890837841http://lattes.cnpq.br/1023096365327898Santos, Rafael Oliveira2022-12-05T16:12:43Z2022-12-05T16:12:43Zinfo:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/doctoralThesisapplication/pdfSANTOS, Rafael Oliveira. Experimental characterization and modeling of the plastic behavior of a thirdgeneration advanced high strength steel sheet. 2020. 126 f. Tese (Doutorado) - Curso de Engenharia Metalúrgica, Programa de Pós-Graduação em Engenharia Metalúrgica, Universidade Federal Fluminense, Volta Redonda, 2020.http://app.uff.br/riuff/handle/1/27170pt_BRporCC-BY-SAinfo:eu-repo/semantics/openAccessreponame:Repositório Institucional da Universidade Federal Fluminense (RIUFF)instname:Universidade Federal Fluminense (UFF)instacron:UFF2022-12-05T16:15:25Zoai:app.uff.br:1/27170Repositório InstitucionalPUBhttps://app.uff.br/oai/requestriuff@id.uff.bropendoar:21202022-12-05T16:15:25Repositório Institucional da Universidade Federal Fluminense (RIUFF) - Universidade Federal Fluminense (UFF)false |
| dc.title.none.fl_str_mv |
Experimental characterization and modeling of the plastic behavior of a thirdgeneration advanced high strength steel sheet |
| title |
Experimental characterization and modeling of the plastic behavior of a thirdgeneration advanced high strength steel sheet |
| spellingShingle |
Experimental characterization and modeling of the plastic behavior of a thirdgeneration advanced high strength steel sheet Santos, Rafael Oliveira Advanced high strength steels 980 class Mechanical testing Limit strains Damage modeling Sheet metal forming Chapa de aço Comportamento plástico Engenharia Metalúrgica Produção intelectual Aços avançados de alta resistência Classe 980 Ensaios mecânicos Deformações limites Modelamento de dano Conformação de chapas |
| title_short |
Experimental characterization and modeling of the plastic behavior of a thirdgeneration advanced high strength steel sheet |
| title_full |
Experimental characterization and modeling of the plastic behavior of a thirdgeneration advanced high strength steel sheet |
| title_fullStr |
Experimental characterization and modeling of the plastic behavior of a thirdgeneration advanced high strength steel sheet |
| title_full_unstemmed |
Experimental characterization and modeling of the plastic behavior of a thirdgeneration advanced high strength steel sheet |
| title_sort |
Experimental characterization and modeling of the plastic behavior of a thirdgeneration advanced high strength steel sheet |
| author |
Santos, Rafael Oliveira |
| author_facet |
Santos, Rafael Oliveira |
| author_role |
author |
| dc.contributor.none.fl_str_mv |
Butuc, Marilena Carmen Moreira, Luciano Pessanha http://lattes.cnpq.br/5673024226638200 Pereira, António Manuel de Bastos http://lattes.cnpq.br/0662491008549976 Vincze, Gabriela Tamara Batalha, Gilmar Ferreira http://lattes.cnpq.br/6266559761245923 Fonseca, Gláucio Soares da http://lattes.cnpq.br/9663765935778795 Freitas, Maria Carolina dos Santos http://lattes.cnpq.br/5037625890837841 http://lattes.cnpq.br/1023096365327898 |
| dc.contributor.author.fl_str_mv |
Santos, Rafael Oliveira |
| dc.subject.por.fl_str_mv |
Advanced high strength steels 980 class Mechanical testing Limit strains Damage modeling Sheet metal forming Chapa de aço Comportamento plástico Engenharia Metalúrgica Produção intelectual Aços avançados de alta resistência Classe 980 Ensaios mecânicos Deformações limites Modelamento de dano Conformação de chapas |
| topic |
Advanced high strength steels 980 class Mechanical testing Limit strains Damage modeling Sheet metal forming Chapa de aço Comportamento plástico Engenharia Metalúrgica Produção intelectual Aços avançados de alta resistência Classe 980 Ensaios mecânicos Deformações limites Modelamento de dano Conformação de chapas |
| description |
The third generation of the advanced highstrength steels (AHSS) has attracted the automotive industry attention owing to its good compromise between the formability and production cost. The current development stage of these steels so far has few products available on the market, as well as little research aimed at studying their formability. With an ultimate tensile strength greater than 1000 MPa and total elongation above 20%, the thirdgeneration AHSS with 980 MPa grade was the first sheet of this class of steel to be commercialized. In this work, several mechanical tests were performed to analyze the plastic behavior of a coldrolled Gen3 980T steel with a nominal thickness of 1.58 mm. The mechanical properties and the plastic anisotropy Lankford coefficients were obtained from uniaxial tensile tests performed in 7 angular orientations in the plane of the sheet. The workhardening of the Gen3 980T steel sheet was also assessed by means of the hydraulic bulge test, and the biaxial anisotropy coefficient was obtained using the disc compression test. The formability was investigated by means of the hole expansion, Erichsen cupping, and forming limit curve (FLC) test procedures. The limit strains were defined by ISO 120042 standard from inplane tests (uniaxial tension and plane strain in tension) and out of plane hemisphericalpunching tests (Nakajima procedure). The GursonTvergaardNeedleman (GTN) damage model was adopted to describe the fracture behavior of the Gen3 980T steel. A simple methodology for identifying the parameters of the GTN model was proposed. This calibration procedure was validated by comparing finite element predictions with the experimental measurements obtained from the mechanical tests. The Gen3 980T steel has a microstructure composed of martensite, ferrite, and retained austenite. In the asreceived condition, the Xray diffraction analysis provided 12.2% of the retained austenite volume fraction. In the sheet rolling direction, the average values of the yield stress () and ultimate tensile strength () are equal to 604 and 1040 MPa, respectively, along with a total elongation ( ) of 23.4%. In this way, Gen3 980T steel has global formability, defined by = 24.3 GPa%, a value which is consistent with that expected for the thirdgeneration of advanced highstrength steels. The Lankford coefficients determined in the angular orientations 0, 45, and 90 degrees with respect to the rolling direction are very close, which provided planar and normal anisotropy coefficients of − 0,079 and 0.917, respectively. The hole expansion ratio (HER) determined for the Gen3 980T steel sheet was equal to 10.9%, whereas the corresponding average Erichsen cupping test index (EI) was equal to 10.62 mm. The numerical simulations were able to describe the increase in formability due to the reduction of the friction coefficient and the effects inherent to the Nakajima test sample's curvature. The GTN damage model parameters, identified from the experimental uniaxial tensile data, provided a good forecast of the experimental results located on the lefthand side of the FLC. Regarding the right side of the FLC, the results obtained for the limit strains were conservative, mainly for the equal biaxial stretching. |
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2022 |
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2022-12-05T16:12:43Z 2022-12-05T16:12:43Z |
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info:eu-repo/semantics/doctoralThesis |
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SANTOS, Rafael Oliveira. Experimental characterization and modeling of the plastic behavior of a thirdgeneration advanced high strength steel sheet. 2020. 126 f. Tese (Doutorado) - Curso de Engenharia Metalúrgica, Programa de Pós-Graduação em Engenharia Metalúrgica, Universidade Federal Fluminense, Volta Redonda, 2020. http://app.uff.br/riuff/handle/1/27170 |
| identifier_str_mv |
SANTOS, Rafael Oliveira. Experimental characterization and modeling of the plastic behavior of a thirdgeneration advanced high strength steel sheet. 2020. 126 f. Tese (Doutorado) - Curso de Engenharia Metalúrgica, Programa de Pós-Graduação em Engenharia Metalúrgica, Universidade Federal Fluminense, Volta Redonda, 2020. |
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