HERREJÓN-ESCUTIA, Martin ;SOLORIO-DÍAZ, Gildardo ;VERGARA-HERNÁNDEZ, Héctor Javier;LÓPEZ-MARTÍNEZ, Edgar ;CHÁVEZ-CAMPOS, Gerardo Marx;VÁZQUEZ-GÓMEZ, Octavio . Electric-Thermo-Mechanical Analysis of Joule Heating in Dilatometric Specimens. Strojniški vestnik - Journal of Mechanical Engineering, [S.l.], v. 63, n.9, p. 537-547, june 2018. ISSN 0039-2480. Available at: <https://www.sv-jme.eu/sl/article/electric-thermo-mechanical-analysis-of-joule-heating-in-dilatometric-specimens/>. Date accessed: 10 dec. 2024. doi:http://dx.doi.org/10.5545/sv-jme.2017.4320.
Herrejón-Escutia, M., Solorio-Díaz, G., Vergara-Hernández, H., López-Martínez, E., Chávez-Campos, G., & Vázquez-Gómez, O. (2017). Electric-Thermo-Mechanical Analysis of Joule Heating in Dilatometric Specimens. Strojniški vestnik - Journal of Mechanical Engineering, 63(9), 537-547. doi:http://dx.doi.org/10.5545/sv-jme.2017.4320
@article{sv-jmesv-jme.2017.4320, author = {Martin Herrejón-Escutia and Gildardo Solorio-Díaz and Héctor Javier Vergara-Hernández and Edgar López-Martínez and Gerardo Marx Chávez-Campos and Octavio Vázquez-Gómez}, title = {Electric-Thermo-Mechanical Analysis of Joule Heating in Dilatometric Specimens}, journal = {Strojniški vestnik - Journal of Mechanical Engineering}, volume = {63}, number = {9}, year = {2017}, keywords = {mathematical model; continuous heating; Joule effect; dilatometry; AISI 304 stainless steel}, abstract = {A mathematical model of Joule heating was developed for an AISI 304 stainless steel in a hollow cylinder dilatometric specimen. The model was developed by means of creating a balance of energy by coupling the generation term due to the Joule heating and the thermal expansion of the specimen. A Newtonian heating system was assumed for a volume element, and it was resolved by means of the finite differences method, generating its own computer code in the Scilab free-license software. The model considers the thermophysical and electrical properties of steel, depending on the temperature. Thermal interactions at the boundary and the linear thermal expansion coefficient were determined by solving the inverse heat conduction problem (IHCP) using the thermal profile and thermal expansion measured experimentally by means of a direct heating device. The model was validated by comparing the thermal response and experimental thermal expansion with simulated responses for different heating rates.}, issn = {0039-2480}, pages = {537-547}, doi = {10.5545/sv-jme.2017.4320}, url = {https://www.sv-jme.eu/sl/article/electric-thermo-mechanical-analysis-of-joule-heating-in-dilatometric-specimens/} }
Herrejón-Escutia, M.,Solorio-Díaz, G.,Vergara-Hernández, H.,López-Martínez, E.,Chávez-Campos, G.,Vázquez-Gómez, O. 2017 June 63. Electric-Thermo-Mechanical Analysis of Joule Heating in Dilatometric Specimens. Strojniški vestnik - Journal of Mechanical Engineering. [Online] 63:9
%A Herrejón-Escutia, Martin %A Solorio-Díaz, Gildardo %A Vergara-Hernández, Héctor Javier %A López-Martínez, Edgar %A Chávez-Campos, Gerardo Marx %A Vázquez-Gómez, Octavio %D 2017 %T Electric-Thermo-Mechanical Analysis of Joule Heating in Dilatometric Specimens %B 2017 %9 mathematical model; continuous heating; Joule effect; dilatometry; AISI 304 stainless steel %! Electric-Thermo-Mechanical Analysis of Joule Heating in Dilatometric Specimens %K mathematical model; continuous heating; Joule effect; dilatometry; AISI 304 stainless steel %X A mathematical model of Joule heating was developed for an AISI 304 stainless steel in a hollow cylinder dilatometric specimen. The model was developed by means of creating a balance of energy by coupling the generation term due to the Joule heating and the thermal expansion of the specimen. A Newtonian heating system was assumed for a volume element, and it was resolved by means of the finite differences method, generating its own computer code in the Scilab free-license software. The model considers the thermophysical and electrical properties of steel, depending on the temperature. Thermal interactions at the boundary and the linear thermal expansion coefficient were determined by solving the inverse heat conduction problem (IHCP) using the thermal profile and thermal expansion measured experimentally by means of a direct heating device. The model was validated by comparing the thermal response and experimental thermal expansion with simulated responses for different heating rates. %U https://www.sv-jme.eu/sl/article/electric-thermo-mechanical-analysis-of-joule-heating-in-dilatometric-specimens/ %0 Journal Article %R 10.5545/sv-jme.2017.4320 %& 537 %P 11 %J Strojniški vestnik - Journal of Mechanical Engineering %V 63 %N 9 %@ 0039-2480 %8 2018-06-27 %7 2018-06-27
Herrejón-Escutia, Martin, Gildardo Solorio-Díaz, Héctor Javier Vergara-Hernández, Edgar López-Martínez, Gerardo Marx Chávez-Campos, & Octavio Vázquez-Gómez. "Electric-Thermo-Mechanical Analysis of Joule Heating in Dilatometric Specimens." Strojniški vestnik - Journal of Mechanical Engineering [Online], 63.9 (2017): 537-547. Web. 10 Dec. 2024
TY - JOUR AU - Herrejón-Escutia, Martin AU - Solorio-Díaz, Gildardo AU - Vergara-Hernández, Héctor Javier AU - López-Martínez, Edgar AU - Chávez-Campos, Gerardo Marx AU - Vázquez-Gómez, Octavio PY - 2017 TI - Electric-Thermo-Mechanical Analysis of Joule Heating in Dilatometric Specimens JF - Strojniški vestnik - Journal of Mechanical Engineering DO - 10.5545/sv-jme.2017.4320 KW - mathematical model; continuous heating; Joule effect; dilatometry; AISI 304 stainless steel N2 - A mathematical model of Joule heating was developed for an AISI 304 stainless steel in a hollow cylinder dilatometric specimen. The model was developed by means of creating a balance of energy by coupling the generation term due to the Joule heating and the thermal expansion of the specimen. A Newtonian heating system was assumed for a volume element, and it was resolved by means of the finite differences method, generating its own computer code in the Scilab free-license software. The model considers the thermophysical and electrical properties of steel, depending on the temperature. Thermal interactions at the boundary and the linear thermal expansion coefficient were determined by solving the inverse heat conduction problem (IHCP) using the thermal profile and thermal expansion measured experimentally by means of a direct heating device. The model was validated by comparing the thermal response and experimental thermal expansion with simulated responses for different heating rates. UR - https://www.sv-jme.eu/sl/article/electric-thermo-mechanical-analysis-of-joule-heating-in-dilatometric-specimens/
@article{{sv-jme}{sv-jme.2017.4320}, author = {Herrejón-Escutia, M., Solorio-Díaz, G., Vergara-Hernández, H., López-Martínez, E., Chávez-Campos, G., Vázquez-Gómez, O.}, title = {Electric-Thermo-Mechanical Analysis of Joule Heating in Dilatometric Specimens}, journal = {Strojniški vestnik - Journal of Mechanical Engineering}, volume = {63}, number = {9}, year = {2017}, doi = {10.5545/sv-jme.2017.4320}, url = {https://www.sv-jme.eu/sl/article/electric-thermo-mechanical-analysis-of-joule-heating-in-dilatometric-specimens/} }
TY - JOUR AU - Herrejón-Escutia, Martin AU - Solorio-Díaz, Gildardo AU - Vergara-Hernández, Héctor Javier AU - López-Martínez, Edgar AU - Chávez-Campos, Gerardo Marx AU - Vázquez-Gómez, Octavio PY - 2018/06/27 TI - Electric-Thermo-Mechanical Analysis of Joule Heating in Dilatometric Specimens JF - Strojniški vestnik - Journal of Mechanical Engineering; Vol 63, No 9 (2017): Strojniški vestnik - Journal of Mechanical Engineering DO - 10.5545/sv-jme.2017.4320 KW - mathematical model, continuous heating, Joule effect, dilatometry, AISI 304 stainless steel N2 - A mathematical model of Joule heating was developed for an AISI 304 stainless steel in a hollow cylinder dilatometric specimen. The model was developed by means of creating a balance of energy by coupling the generation term due to the Joule heating and the thermal expansion of the specimen. A Newtonian heating system was assumed for a volume element, and it was resolved by means of the finite differences method, generating its own computer code in the Scilab free-license software. The model considers the thermophysical and electrical properties of steel, depending on the temperature. Thermal interactions at the boundary and the linear thermal expansion coefficient were determined by solving the inverse heat conduction problem (IHCP) using the thermal profile and thermal expansion measured experimentally by means of a direct heating device. The model was validated by comparing the thermal response and experimental thermal expansion with simulated responses for different heating rates. UR - https://www.sv-jme.eu/sl/article/electric-thermo-mechanical-analysis-of-joule-heating-in-dilatometric-specimens/
Herrejón-Escutia, Martin, Solorio-Díaz, Gildardo, Vergara-Hernández, Héctor, López-Martínez, Edgar, Chávez-Campos, Gerardo, AND Vázquez-Gómez, Octavio. "Electric-Thermo-Mechanical Analysis of Joule Heating in Dilatometric Specimens" Strojniški vestnik - Journal of Mechanical Engineering [Online], Volume 63 Number 9 (27 June 2018)
Strojniški vestnik - Journal of Mechanical Engineering 63(2017)9, 537-547
© The Authors, CC-BY 4.0 Int. Change in copyright policy from 2022, Jan 1st.
A mathematical model of Joule heating was developed for an AISI 304 stainless steel in a hollow cylinder dilatometric specimen. The model was developed by means of creating a balance of energy by coupling the generation term due to the Joule heating and the thermal expansion of the specimen. A Newtonian heating system was assumed for a volume element, and it was resolved by means of the finite differences method, generating its own computer code in the Scilab free-license software. The model considers the thermophysical and electrical properties of steel, depending on the temperature. Thermal interactions at the boundary and the linear thermal expansion coefficient were determined by solving the inverse heat conduction problem (IHCP) using the thermal profile and thermal expansion measured experimentally by means of a direct heating device. The model was validated by comparing the thermal response and experimental thermal expansion with simulated responses for different heating rates.