Estudio del área afectada por el calor en los aceros al carbono, por efecto de precalentamiento y soldadura

Nelver J. Escalante-Espinoza; Johnny F. Fernández-Urbano; Serapio A. Quillos-Ruiz; Ruben A. Figueroa-León; Johnny Nahui-Ortiz

doi:10.18687/LACCEI2021.1.1.238

Estudio del área afectada por el calor en los aceros al carbono, por efecto de precalentamiento y soldadura

Nelver J. Escalante-Espinoza, Johnny F. Fernández-Urbano, Serapio A. Quillos-Ruiz, Ruben A. Figueroa-León, Johnny Nahui-Ortiz

Departamento Académico de Energía, Física y Mecánica

Producción científica: Capítulo del libro/informe/acta de congreso › Contribución a la conferencia › revisión exhaustiva

Resumen

The affected area by heat was studied in ASTM A36 carbon steels, with thicknesses of 12 mm, analyzing the effect of preheating on their properties. The welding process used was SMAW, then tensile, hardness, metallography and numerical calculations were carried out, for which a temperature range of 100 ° C was established; 120 ° C; 145 ° C; 160 ° C, concluding that the optimum preheating temperature is 145 ° C, with which the following results of the tensile test (515.82 Mpa) and hardness (232 HV) were obtained; according to recommendations of the percentage of carbon equivalent and hardness ratios, the material will not present fissures when it will get cold. On the other hand, the results of stress (424.15-500.36 MPa) and hardness (209-250 HV) due to preheating effect show that both are inversely proportional. In addition, the effect of preheating decreases the cooling rate in order to avoid brittleness of the material and the maximum martensite formation, in addition, the width of the heat-affected area increases as the heat input increases. Then it was determined that the influence of preheating on the microstructure is essential to reduce the amount of martensite through a slow cooling and do not cause hardening levels in the affected area caused by heat; avoiding so risks of cold cracking. Finally, it was possible to understand the microstructural variations (tensile and hardness), of the affected area by heat, in order to avoid the appearance of fissures in the weld seam.

Título traducido de la contribución	Study of the affected area by heat in carbon steels, due to the effect of preheating and welding
Idioma original	Español
Título de la publicación alojada	19th LACCEI International Multi-Conference for Engineering, Education Caribbean Conference for Engineering and Technology
Subtítulo de la publicación alojada	"Prospective and Trends in Technology and Skills for Sustainable Social Development" and "Leveraging Emerging Technologies to Construct the Future", LACCEI 2021 - Proceedings
Editores	Maria M. Larrondo Petrie, Luis Felipe Zapata Rivera, Catalina Aranzazu-Suescun
Editorial	Latin American and Caribbean Consortium of Engineering Institutions
ISBN (versión digital)	9789585207189
DOI	https://doi.org/10.18687/LACCEI2021.1.1.238
Estado	Publicada - 2021
Evento	19th LACCEI International Multi-Conference for Engineering, Education Caribbean Conference for Engineering and Technology: "Prospective and Trends in Technology and Skills for Sustainable Social Development" and "Leveraging Emerging Technologies to Construct the Future", LACCEI 2021 - Virtual, Online Duración: 19 jul. 2021 → 23 jul. 2021

Serie de la publicación

Nombre	Proceedings of the LACCEI international Multi-conference for Engineering, Education and Technology
Volumen	2021-July
ISSN (versión digital)	2414-6390

Conferencia

Conferencia	19th LACCEI International Multi-Conference for Engineering, Education Caribbean Conference for Engineering and Technology: "Prospective and Trends in Technology and Skills for Sustainable Social Development" and "Leveraging Emerging Technologies to Construct the Future", LACCEI 2021
Ciudad	Virtual, Online
Período	19/07/21 → 23/07/21

Nota bibliográfica

Publisher Copyright:
© 2021 Latin American and Caribbean Consortium of Engineering Institutions. All rights reserved.

Palabras clave

Cooling speed
Cracking
Hardness
Microstructure
Preheating

Acceder al documento

10.18687/LACCEI2021.1.1.238

Otros archivos y enlaces

Enlace a la publicación en Scopus

Citar esto

Escalante-Espinoza, N. J., Fernández-Urbano, J. F., Quillos-Ruiz, S. A., Figueroa-León, R. A., & Nahui-Ortiz, J. (2021). Estudio del área afectada por el calor en los aceros al carbono, por efecto de precalentamiento y soldadura. En M. M. Larrondo Petrie, L. F. Zapata Rivera, & C. Aranzazu-Suescun (Eds.), 19th LACCEI International Multi-Conference for Engineering, Education Caribbean Conference for Engineering and Technology: "Prospective and Trends in Technology and Skills for Sustainable Social Development" and "Leveraging Emerging Technologies to Construct the Future", LACCEI 2021 - Proceedings (Proceedings of the LACCEI international Multi-conference for Engineering, Education and Technology; Vol. 2021-July). Latin American and Caribbean Consortium of Engineering Institutions. https://doi.org/10.18687/LACCEI2021.1.1.238

Escalante-Espinoza, Nelver J. ; Fernández-Urbano, Johnny F. ; Quillos-Ruiz, Serapio A. et al. / Estudio del área afectada por el calor en los aceros al carbono, por efecto de precalentamiento y soldadura. 19th LACCEI International Multi-Conference for Engineering, Education Caribbean Conference for Engineering and Technology: "Prospective and Trends in Technology and Skills for Sustainable Social Development" and "Leveraging Emerging Technologies to Construct the Future", LACCEI 2021 - Proceedings. editor / Maria M. Larrondo Petrie ; Luis Felipe Zapata Rivera ; Catalina Aranzazu-Suescun. Latin American and Caribbean Consortium of Engineering Institutions, 2021. (Proceedings of the LACCEI international Multi-conference for Engineering, Education and Technology).

@inproceedings{0e5bb557809741b78917e24fc58c9569,

title = "Estudio del {\'a}rea afectada por el calor en los aceros al carbono, por efecto de precalentamiento y soldadura",

abstract = "The affected area by heat was studied in ASTM A36 carbon steels, with thicknesses of 12 mm, analyzing the effect of preheating on their properties. The welding process used was SMAW, then tensile, hardness, metallography and numerical calculations were carried out, for which a temperature range of 100 ° C was established; 120 ° C; 145 ° C; 160 ° C, concluding that the optimum preheating temperature is 145 ° C, with which the following results of the tensile test (515.82 Mpa) and hardness (232 HV) were obtained; according to recommendations of the percentage of carbon equivalent and hardness ratios, the material will not present fissures when it will get cold. On the other hand, the results of stress (424.15-500.36 MPa) and hardness (209-250 HV) due to preheating effect show that both are inversely proportional. In addition, the effect of preheating decreases the cooling rate in order to avoid brittleness of the material and the maximum martensite formation, in addition, the width of the heat-affected area increases as the heat input increases. Then it was determined that the influence of preheating on the microstructure is essential to reduce the amount of martensite through a slow cooling and do not cause hardening levels in the affected area caused by heat; avoiding so risks of cold cracking. Finally, it was possible to understand the microstructural variations (tensile and hardness), of the affected area by heat, in order to avoid the appearance of fissures in the weld seam.",

keywords = "Cooling speed, Cracking, Hardness, Microstructure, Preheating",

author = "Escalante-Espinoza, {Nelver J.} and Fern{\'a}ndez-Urbano, {Johnny F.} and Quillos-Ruiz, {Serapio A.} and Figueroa-Le{\'o}n, {Ruben A.} and Johnny Nahui-Ortiz",

note = "Publisher Copyright: {\textcopyright} 2021 Latin American and Caribbean Consortium of Engineering Institutions. All rights reserved.; 19th LACCEI International Multi-Conference for Engineering, Education Caribbean Conference for Engineering and Technology: {"}Prospective and Trends in Technology and Skills for Sustainable Social Development{"} and {"}Leveraging Emerging Technologies to Construct the Future{"}, LACCEI 2021 ; Conference date: 19-07-2021 Through 23-07-2021",

year = "2021",

doi = "10.18687/LACCEI2021.1.1.238",

language = "Espa{\~n}ol",

series = "Proceedings of the LACCEI international Multi-conference for Engineering, Education and Technology",

publisher = "Latin American and Caribbean Consortium of Engineering Institutions",

editor = "{Larrondo Petrie}, {Maria M.} and {Zapata Rivera}, {Luis Felipe} and Catalina Aranzazu-Suescun",

booktitle = "19th LACCEI International Multi-Conference for Engineering, Education Caribbean Conference for Engineering and Technology",

}

Escalante-Espinoza, NJ, Fernández-Urbano, JF, Quillos-Ruiz, SA, Figueroa-León, RA & Nahui-Ortiz, J 2021, Estudio del área afectada por el calor en los aceros al carbono, por efecto de precalentamiento y soldadura. En MM Larrondo Petrie, LF Zapata Rivera & C Aranzazu-Suescun (eds.), 19th LACCEI International Multi-Conference for Engineering, Education Caribbean Conference for Engineering and Technology: "Prospective and Trends in Technology and Skills for Sustainable Social Development" and "Leveraging Emerging Technologies to Construct the Future", LACCEI 2021 - Proceedings. Proceedings of the LACCEI international Multi-conference for Engineering, Education and Technology, vol. 2021-July, Latin American and Caribbean Consortium of Engineering Institutions, 19th LACCEI International Multi-Conference for Engineering, Education Caribbean Conference for Engineering and Technology: "Prospective and Trends in Technology and Skills for Sustainable Social Development" and "Leveraging Emerging Technologies to Construct the Future", LACCEI 2021, Virtual, Online, 19/07/21. https://doi.org/10.18687/LACCEI2021.1.1.238

Estudio del área afectada por el calor en los aceros al carbono, por efecto de precalentamiento y soldadura. / Escalante-Espinoza, Nelver J.; Fernández-Urbano, Johnny F.; Quillos-Ruiz, Serapio A. et al.
19th LACCEI International Multi-Conference for Engineering, Education Caribbean Conference for Engineering and Technology: "Prospective and Trends in Technology and Skills for Sustainable Social Development" and "Leveraging Emerging Technologies to Construct the Future", LACCEI 2021 - Proceedings. ed. / Maria M. Larrondo Petrie; Luis Felipe Zapata Rivera; Catalina Aranzazu-Suescun. Latin American and Caribbean Consortium of Engineering Institutions, 2021. (Proceedings of the LACCEI international Multi-conference for Engineering, Education and Technology; Vol. 2021-July).

Producción científica: Capítulo del libro/informe/acta de congreso › Contribución a la conferencia › revisión exhaustiva

TY - GEN

T1 - Estudio del área afectada por el calor en los aceros al carbono, por efecto de precalentamiento y soldadura

AU - Escalante-Espinoza, Nelver J.

AU - Fernández-Urbano, Johnny F.

AU - Quillos-Ruiz, Serapio A.

AU - Figueroa-León, Ruben A.

AU - Nahui-Ortiz, Johnny

PY - 2021

Y1 - 2021

N2 - The affected area by heat was studied in ASTM A36 carbon steels, with thicknesses of 12 mm, analyzing the effect of preheating on their properties. The welding process used was SMAW, then tensile, hardness, metallography and numerical calculations were carried out, for which a temperature range of 100 ° C was established; 120 ° C; 145 ° C; 160 ° C, concluding that the optimum preheating temperature is 145 ° C, with which the following results of the tensile test (515.82 Mpa) and hardness (232 HV) were obtained; according to recommendations of the percentage of carbon equivalent and hardness ratios, the material will not present fissures when it will get cold. On the other hand, the results of stress (424.15-500.36 MPa) and hardness (209-250 HV) due to preheating effect show that both are inversely proportional. In addition, the effect of preheating decreases the cooling rate in order to avoid brittleness of the material and the maximum martensite formation, in addition, the width of the heat-affected area increases as the heat input increases. Then it was determined that the influence of preheating on the microstructure is essential to reduce the amount of martensite through a slow cooling and do not cause hardening levels in the affected area caused by heat; avoiding so risks of cold cracking. Finally, it was possible to understand the microstructural variations (tensile and hardness), of the affected area by heat, in order to avoid the appearance of fissures in the weld seam.

AB - The affected area by heat was studied in ASTM A36 carbon steels, with thicknesses of 12 mm, analyzing the effect of preheating on their properties. The welding process used was SMAW, then tensile, hardness, metallography and numerical calculations were carried out, for which a temperature range of 100 ° C was established; 120 ° C; 145 ° C; 160 ° C, concluding that the optimum preheating temperature is 145 ° C, with which the following results of the tensile test (515.82 Mpa) and hardness (232 HV) were obtained; according to recommendations of the percentage of carbon equivalent and hardness ratios, the material will not present fissures when it will get cold. On the other hand, the results of stress (424.15-500.36 MPa) and hardness (209-250 HV) due to preheating effect show that both are inversely proportional. In addition, the effect of preheating decreases the cooling rate in order to avoid brittleness of the material and the maximum martensite formation, in addition, the width of the heat-affected area increases as the heat input increases. Then it was determined that the influence of preheating on the microstructure is essential to reduce the amount of martensite through a slow cooling and do not cause hardening levels in the affected area caused by heat; avoiding so risks of cold cracking. Finally, it was possible to understand the microstructural variations (tensile and hardness), of the affected area by heat, in order to avoid the appearance of fissures in the weld seam.

KW - Cooling speed

KW - Cracking

KW - Hardness

KW - Microstructure

KW - Preheating

UR - http://www.scopus.com/inward/record.url?scp=85122026928&partnerID=8YFLogxK

U2 - 10.18687/LACCEI2021.1.1.238

DO - 10.18687/LACCEI2021.1.1.238

M3 - Contribución a la conferencia

AN - SCOPUS:85122026928

T3 - Proceedings of the LACCEI international Multi-conference for Engineering, Education and Technology

BT - 19th LACCEI International Multi-Conference for Engineering, Education Caribbean Conference for Engineering and Technology

A2 - Larrondo Petrie, Maria M.

A2 - Zapata Rivera, Luis Felipe

A2 - Aranzazu-Suescun, Catalina

PB - Latin American and Caribbean Consortium of Engineering Institutions

T2 - 19th LACCEI International Multi-Conference for Engineering, Education Caribbean Conference for Engineering and Technology: "Prospective and Trends in Technology and Skills for Sustainable Social Development" and "Leveraging Emerging Technologies to Construct the Future", LACCEI 2021

Y2 - 19 July 2021 through 23 July 2021

ER -

Escalante-Espinoza NJ, Fernández-Urbano JF, Quillos-Ruiz SA, Figueroa-León RA, Nahui-Ortiz J. Estudio del área afectada por el calor en los aceros al carbono, por efecto de precalentamiento y soldadura. En Larrondo Petrie MM, Zapata Rivera LF, Aranzazu-Suescun C, editores, 19th LACCEI International Multi-Conference for Engineering, Education Caribbean Conference for Engineering and Technology: "Prospective and Trends in Technology and Skills for Sustainable Social Development" and "Leveraging Emerging Technologies to Construct the Future", LACCEI 2021 - Proceedings. Latin American and Caribbean Consortium of Engineering Institutions. 2021. (Proceedings of the LACCEI international Multi-conference for Engineering, Education and Technology). doi: 10.18687/LACCEI2021.1.1.238

Estudio del área afectada por el calor en los aceros al carbono, por efecto de precalentamiento y soldadura

Resumen

Serie de la publicación

Conferencia

Nota bibliográfica

Palabras clave

Acceder al documento

Otros archivos y enlaces

Huella

Citar esto