Development of a hatch system for the determination of diffusible hydrogen in underwater welding

The design and implementation of hatch mechanism aims to optimize the development of welding simulations performed in the Robotic, Welding and Simulation Laboratory. The project is part of the upgrade technologies applied to sciences of the sea, and make it possible to evaluate the influence of weld...

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Published in:Respuestas
Main Authors: Fernandes-Lara, Rodrigo, Moreno-Uribe, Andrés M., Bracarense, Alexandre Q.
Format: Article in Journal/Newspaper
Language:English
Spanish
Published: Universidad Francisco de Paula Santander 2020
Subjects:
Underwater welding
diffusible hydrogen
FCAW
SMAW
inspection hatch
Soldadura submarina
hidrógeno difusible
escotilla de inspección
Arctic
Online Access:https://revistas.ufps.edu.co/index.php/respuestas/article/view/2433
https://doi.org/10.22463/0122820X.2433
id ftunivfpsojs:oai:revistas.ufps.edu.co:article/2433
record_format openpolar
institution Open Polar
collection Portal de Revistas Institucionales UFPS (Universidad Francisco de Paula Santander)
op_collection_id ftunivfpsojs
language English
Spanish
topic Underwater welding
diffusible hydrogen
FCAW
SMAW
inspection hatch
Soldadura submarina
hidrógeno difusible
escotilla de inspección
spellingShingle Underwater welding
diffusible hydrogen
FCAW
SMAW
inspection hatch
Soldadura submarina
hidrógeno difusible
escotilla de inspección
Fernandes-Lara, Rodrigo
Moreno-Uribe, Andrés M.
Bracarense, Alexandre Q.
Development of a hatch system for the determination of diffusible hydrogen in underwater welding
topic_facet Underwater welding
diffusible hydrogen
FCAW
SMAW
inspection hatch
Soldadura submarina
hidrógeno difusible
escotilla de inspección
description The design and implementation of hatch mechanism aims to optimize the development of welding simulations performed in the Robotic, Welding and Simulation Laboratory. The project is part of the upgrade technologies applied to sciences of the sea, and make it possible to evaluate the influence of welding parameters on SMAW and FCAW processes, especially as regards the content of diffusible hydrogen specimen welding in different depths. Due to the specifications imposed by the gas chromatography standards applied to welding, tests must be carried out at short intervals, which requires a fast process. This research will promote the evaluation of commercial electrodes and promote the development of new consumables. El diseño e implementación del mecanismo de escotilla, tiene como finalidad optimizar el desarrollo de simulaciones de soldadura ejecutadas en el Laboratorio de Robótica, Soldadura y Simulación. El proyecto hace parte de la actualización de tecnologías aplicadas a ciencias del mar, y posibilitará evaluar la influencia de los parámetros de soldadura en los procesos SMAW y FCAW, especialmente en lo que se refiere al contenido de hidrógeno difusible en cuerpos de prueba soldados en diferentes profundidades. Debido a las especificaciones impuestas por las normas de cromatografía de gases aplicadas a la soldadura, las pruebas deben desarrollarse en intervalos cortos, lo cual exige un proceso rápido. Esta investigación fomentará la evaluación de electrodos comerciales y promoverá el desarrollo de nuevos consumibles.
format Article in Journal/Newspaper
author Fernandes-Lara, Rodrigo
Moreno-Uribe, Andrés M.
Bracarense, Alexandre Q.
author_facet Fernandes-Lara, Rodrigo
Moreno-Uribe, Andrés M.
Bracarense, Alexandre Q.
author_sort Fernandes-Lara, Rodrigo
title Development of a hatch system for the determination of diffusible hydrogen in underwater welding
title_short Development of a hatch system for the determination of diffusible hydrogen in underwater welding
title_full Development of a hatch system for the determination of diffusible hydrogen in underwater welding
title_fullStr Development of a hatch system for the determination of diffusible hydrogen in underwater welding
title_full_unstemmed Development of a hatch system for the determination of diffusible hydrogen in underwater welding
title_sort development of a hatch system for the determination of diffusible hydrogen in underwater welding
publisher Universidad Francisco de Paula Santander
publishDate 2020
url https://revistas.ufps.edu.co/index.php/respuestas/article/view/2433
https://doi.org/10.22463/0122820X.2433
genre Arctic
genre_facet Arctic
op_source Revista Respuestas; ##issue.vol## 25 ##issue.no## 1 (2020); 168-177
Respuestas; Vol. 25 Núm. 1 (2020); 168-177
2422-5053
0122-820X
op_relation https://revistas.ufps.edu.co/index.php/respuestas/article/view/2433/2815
https://revistas.ufps.edu.co/index.php/respuestas/article/view/2433/3020
R. R. Marinho, M. T. P. Paes, E. C. P. Pessoa, et. al., “Perspectivas e Desafios para Aplicação da Soldagem Subaquática Molhada na PETROBRAS”, Rio Welding, 2014. [En línea]. Disponible en: https://docplayer.com.br/30687506-Perspectivas-e-desafios-para-aplicacao-da-soldagem-subaquatica-molhada-na-petrobras-trabalho-a-ser-apresentado-durante-a-rio-welding-2014.html.
B. D. Silvestre and PRT Dalcol, “Geographical proximity and innovation: Evidences from the Campos Basin oil & gas industrial agglomeration-Brazil”, Technovation, vol. 29, no. 8, pp. 546-561, 2009.
M. C. Joshi, D. S. Rautela, R. Chauhan and S. Suyal, “Scrutinize Research on Underwater Welding Process: A Review”, IOSR Journal of Mechanical and Civil Engineering., vol. 13, no. 5, pp. 74-78, 2016.
C. E. Grubbs, A. E. Bertelmann, S. Ibarra, et. al., Welding Handbook Material and Applications-Part 1. Estados Unidos: AWS, 1996.
K. Verma and H. K. Garg, “Underwater Welding-Recent Trends and Future Scope”, International Journal on Emerging Technologies, vol. 3, no. 2, pp. 115-120, 2012.
C. E. Grubbs and O. W. Seth, Underwater Wet Welding With Manual Arc Electrodes, ASCE National Water Resources and Ocean Engineering Convention, San Diego, Estados Unidos, 1976.
A. M. M. Uribe, A. Q. Bracarense, E. C. P. Pessoa and V. R. Santos, “Influência da Polaridade Sobre a Estabilidade do Processo de Soldagem Subaquática Molhada com Eletrodo Revestido”, Soldagem & Inspeção, vol. 22, no. 4, pp. 429-441, 2017.
A. M. Pope, S. Liu, J.C.G. Teixeira, et. al., “Use of Nickel to Improve the Mechanical Properties of High Oxygen Underwater Wet Welds”, 3th OMAE/ International conference on offshore mechanics and arctic engineering, Copenhagen, Denmark, 1995.
W. C. D. Silva, A. Q. Bracarense and E. C. P. Pessoa, “Efeito da profundidade de soldagem no hidrogênio difusível de soldas molhadas”, Soldagem & Inspeção, vol. 17, no. 4, pp. 298-305, 2012.
M. Rowe and S. Liu, “Recent developments in underwater wet welding”, Science and Technology of Welding and Joining, vol. 6, no. 6, pp. 387-396, 2013.
W. C. D. Silva, L. F. Ribeiro, A.Q. Bracarense and E. C. P. Pessoa, “Effect of the Hydrostatic Pressure in the Diffusible Hydrogen at the Underwater Wet Welding”, 31st Internacional Conference on Ocean, Offshore and Artic Engineering, volume 6: Materials Technology, Polar and Arctic Sciences and Technology, Petroleum Technology Symposium, Rio de Janeiro, Brazil, 2012.
A. M. M. Uribe, A. Q. Bracarense, E. C. P. Pessoa, et. al., “Metodología de Diseño de una Escotilla de Inspección para Recipientes a Presión”, Investigación e Innovación en Ingenierías, vol. 5, no. 1, pp. 8-23, 2017.
https://revistas.ufps.edu.co/index.php/respuestas/article/view/2433
doi:10.22463/0122820X.2433
op_rights Derechos de autor 2020 Universidad Francisco de Paula Santander
https://creativecommons.org/licenses/by-nc/4.0
op_doi https://doi.org/10.22463/0122820X.2433
container_title Respuestas
container_volume 25
container_issue 1
container_start_page 168
op_container_end_page 177
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spelling ftunivfpsojs:oai:revistas.ufps.edu.co:article/2433 2024-09-15T17:52:01+00:00 Development of a hatch system for the determination of diffusible hydrogen in underwater welding Desarrollo de un sistema de escotilla para la determinación de hidrógeno difusible en soldadura submarina Fernandes-Lara, Rodrigo Moreno-Uribe, Andrés M. Bracarense, Alexandre Q. 2020-01-01 application/pdf text/html https://revistas.ufps.edu.co/index.php/respuestas/article/view/2433 https://doi.org/10.22463/0122820X.2433 eng spa eng spa Universidad Francisco de Paula Santander https://revistas.ufps.edu.co/index.php/respuestas/article/view/2433/2815 https://revistas.ufps.edu.co/index.php/respuestas/article/view/2433/3020 R. R. Marinho, M. T. P. Paes, E. C. P. Pessoa, et. al., “Perspectivas e Desafios para Aplicação da Soldagem Subaquática Molhada na PETROBRAS”, Rio Welding, 2014. [En línea]. Disponible en: https://docplayer.com.br/30687506-Perspectivas-e-desafios-para-aplicacao-da-soldagem-subaquatica-molhada-na-petrobras-trabalho-a-ser-apresentado-durante-a-rio-welding-2014.html. B. D. Silvestre and PRT Dalcol, “Geographical proximity and innovation: Evidences from the Campos Basin oil & gas industrial agglomeration-Brazil”, Technovation, vol. 29, no. 8, pp. 546-561, 2009. M. C. Joshi, D. S. Rautela, R. Chauhan and S. Suyal, “Scrutinize Research on Underwater Welding Process: A Review”, IOSR Journal of Mechanical and Civil Engineering., vol. 13, no. 5, pp. 74-78, 2016. C. E. Grubbs, A. E. Bertelmann, S. Ibarra, et. al., Welding Handbook Material and Applications-Part 1. Estados Unidos: AWS, 1996. K. Verma and H. K. Garg, “Underwater Welding-Recent Trends and Future Scope”, International Journal on Emerging Technologies, vol. 3, no. 2, pp. 115-120, 2012. C. E. Grubbs and O. W. Seth, Underwater Wet Welding With Manual Arc Electrodes, ASCE National Water Resources and Ocean Engineering Convention, San Diego, Estados Unidos, 1976. A. M. M. Uribe, A. Q. Bracarense, E. C. P. Pessoa and V. R. Santos, “Influência da Polaridade Sobre a Estabilidade do Processo de Soldagem Subaquática Molhada com Eletrodo Revestido”, Soldagem & Inspeção, vol. 22, no. 4, pp. 429-441, 2017. A. M. Pope, S. Liu, J.C.G. Teixeira, et. al., “Use of Nickel to Improve the Mechanical Properties of High Oxygen Underwater Wet Welds”, 3th OMAE/ International conference on offshore mechanics and arctic engineering, Copenhagen, Denmark, 1995. W. C. D. Silva, A. Q. Bracarense and E. C. P. Pessoa, “Efeito da profundidade de soldagem no hidrogênio difusível de soldas molhadas”, Soldagem & Inspeção, vol. 17, no. 4, pp. 298-305, 2012. M. Rowe and S. Liu, “Recent developments in underwater wet welding”, Science and Technology of Welding and Joining, vol. 6, no. 6, pp. 387-396, 2013. W. C. D. Silva, L. F. Ribeiro, A.Q. Bracarense and E. C. P. Pessoa, “Effect of the Hydrostatic Pressure in the Diffusible Hydrogen at the Underwater Wet Welding”, 31st Internacional Conference on Ocean, Offshore and Artic Engineering, volume 6: Materials Technology, Polar and Arctic Sciences and Technology, Petroleum Technology Symposium, Rio de Janeiro, Brazil, 2012. A. M. M. Uribe, A. Q. Bracarense, E. C. P. Pessoa, et. al., “Metodología de Diseño de una Escotilla de Inspección para Recipientes a Presión”, Investigación e Innovación en Ingenierías, vol. 5, no. 1, pp. 8-23, 2017. https://revistas.ufps.edu.co/index.php/respuestas/article/view/2433 doi:10.22463/0122820X.2433 Derechos de autor 2020 Universidad Francisco de Paula Santander https://creativecommons.org/licenses/by-nc/4.0 Revista Respuestas; ##issue.vol## 25 ##issue.no## 1 (2020); 168-177 Respuestas; Vol. 25 Núm. 1 (2020); 168-177 2422-5053 0122-820X Underwater welding diffusible hydrogen FCAW SMAW inspection hatch Soldadura submarina hidrógeno difusible escotilla de inspección info:eu-repo/semantics/article info:eu-repo/semantics/publishedVersion 2020 ftunivfpsojs https://doi.org/10.22463/0122820X.2433 2024-06-27T03:03:41Z The design and implementation of hatch mechanism aims to optimize the development of welding simulations performed in the Robotic, Welding and Simulation Laboratory. The project is part of the upgrade technologies applied to sciences of the sea, and make it possible to evaluate the influence of welding parameters on SMAW and FCAW processes, especially as regards the content of diffusible hydrogen specimen welding in different depths. Due to the specifications imposed by the gas chromatography standards applied to welding, tests must be carried out at short intervals, which requires a fast process. This research will promote the evaluation of commercial electrodes and promote the development of new consumables. El diseño e implementación del mecanismo de escotilla, tiene como finalidad optimizar el desarrollo de simulaciones de soldadura ejecutadas en el Laboratorio de Robótica, Soldadura y Simulación. El proyecto hace parte de la actualización de tecnologías aplicadas a ciencias del mar, y posibilitará evaluar la influencia de los parámetros de soldadura en los procesos SMAW y FCAW, especialmente en lo que se refiere al contenido de hidrógeno difusible en cuerpos de prueba soldados en diferentes profundidades. Debido a las especificaciones impuestas por las normas de cromatografía de gases aplicadas a la soldadura, las pruebas deben desarrollarse en intervalos cortos, lo cual exige un proceso rápido. Esta investigación fomentará la evaluación de electrodos comerciales y promoverá el desarrollo de nuevos consumibles. Article in Journal/Newspaper Arctic Portal de Revistas Institucionales UFPS (Universidad Francisco de Paula Santander) Respuestas 25 1 168 177

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