On The Applicability Of Welded J55 Line Pipe Steel For Underground Hydrogen Storage

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Standard

On The Applicability Of Welded J55 Line Pipe Steel For Underground Hydrogen Storage. / Loder, Bernd; Mori, Gregor Karl; Klarner, Jürgen et al.
AMPP Annual Conference & Expo 2023: Paper No. 19131. 2023. 19131.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Harvard

Loder, B, Mori, GK, Klarner, J, Fiedler, M & Willidal, T 2023, On The Applicability Of Welded J55 Line Pipe Steel For Underground Hydrogen Storage. in AMPP Annual Conference & Expo 2023: Paper No. 19131., 19131.

APA

Loder, B., Mori, G. K., Klarner, J., Fiedler, M., & Willidal, T. (2023). On The Applicability Of Welded J55 Line Pipe Steel For Underground Hydrogen Storage. In AMPP Annual Conference & Expo 2023: Paper No. 19131 Article 19131

Vancouver

Loder B, Mori GK, Klarner J, Fiedler M, Willidal T. On The Applicability Of Welded J55 Line Pipe Steel For Underground Hydrogen Storage. In AMPP Annual Conference & Expo 2023: Paper No. 19131. 2023. 19131

Author

Loder, Bernd ; Mori, Gregor Karl ; Klarner, Jürgen et al. / On The Applicability Of Welded J55 Line Pipe Steel For Underground Hydrogen Storage. AMPP Annual Conference & Expo 2023: Paper No. 19131. 2023.

Bibtex - Download

@inproceedings{6a072913ddf445babd96d9c7116d8294,
title = "On The Applicability Of Welded J55 Line Pipe Steel For Underground Hydrogen Storage",
abstract = "As part of the Horizon 2020 project HyStories, the possibility of hydrogen storage in old, depleted gas reservoirs and natural gas storage facilities is being investigated throughout Europe. Within the scope of this project, the work package “materials and corrosion” has the objective of testing the applicability of selected pipe materials with respect to hydrogen embrittlement. For this purpose, a welded carbon steel grade J55 with a ferritic-pearlitic microstructure was investigated by using high pressure high temperature autoclave tests, permeation tests and analysis of uptaken hydrogen. For the autoclave tests, tensile samples have been examined that were loaded by a spring at 90% of yield strength, and samples were also examined to determine the hydrogen uptake. After completion of the tests, the hydrogen uptake was analyzed by thermal desorption spectroscopy. Four main gas compositions were used for the autoclave tests: 120 bar H2, 120 bar H2 + 15 bar CO2, 120 bar H2 + 1 bar H2S, and 120 bar H2 + 15 bar CO2 + 1 bar H2S whereby the tests were carried out with and without the addition of electrolytes with a concentration of 1 and 200 g/l sodium chloride. Moreover, the experiments were conducted at room temperature and 120°C. Test duration was 720 hours. Prior to autoclave testing effective diffusion coefficient was determined to characterize diffusion behavior of hydrogen through the weld material. Results show a low hydrogen uptake even at most severe conditions. Additionally no stressed specimens failed during autoclave testing. Welded J55 is recommended as a suitable tube material for subsurface hydrogen storage.",
author = "Bernd Loder and Mori, {Gregor Karl} and J{\"u}rgen Klarner and Michael Fiedler and Thomas Willidal",
year = "2023",
month = mar,
day = "20",
language = "English",
booktitle = "AMPP Annual Conference & Expo 2023",

}

RIS (suitable for import to EndNote) - Download

TY - GEN

T1 - On The Applicability Of Welded J55 Line Pipe Steel For Underground Hydrogen Storage

AU - Loder, Bernd

AU - Mori, Gregor Karl

AU - Klarner, Jürgen

AU - Fiedler, Michael

AU - Willidal, Thomas

PY - 2023/3/20

Y1 - 2023/3/20

N2 - As part of the Horizon 2020 project HyStories, the possibility of hydrogen storage in old, depleted gas reservoirs and natural gas storage facilities is being investigated throughout Europe. Within the scope of this project, the work package “materials and corrosion” has the objective of testing the applicability of selected pipe materials with respect to hydrogen embrittlement. For this purpose, a welded carbon steel grade J55 with a ferritic-pearlitic microstructure was investigated by using high pressure high temperature autoclave tests, permeation tests and analysis of uptaken hydrogen. For the autoclave tests, tensile samples have been examined that were loaded by a spring at 90% of yield strength, and samples were also examined to determine the hydrogen uptake. After completion of the tests, the hydrogen uptake was analyzed by thermal desorption spectroscopy. Four main gas compositions were used for the autoclave tests: 120 bar H2, 120 bar H2 + 15 bar CO2, 120 bar H2 + 1 bar H2S, and 120 bar H2 + 15 bar CO2 + 1 bar H2S whereby the tests were carried out with and without the addition of electrolytes with a concentration of 1 and 200 g/l sodium chloride. Moreover, the experiments were conducted at room temperature and 120°C. Test duration was 720 hours. Prior to autoclave testing effective diffusion coefficient was determined to characterize diffusion behavior of hydrogen through the weld material. Results show a low hydrogen uptake even at most severe conditions. Additionally no stressed specimens failed during autoclave testing. Welded J55 is recommended as a suitable tube material for subsurface hydrogen storage.

AB - As part of the Horizon 2020 project HyStories, the possibility of hydrogen storage in old, depleted gas reservoirs and natural gas storage facilities is being investigated throughout Europe. Within the scope of this project, the work package “materials and corrosion” has the objective of testing the applicability of selected pipe materials with respect to hydrogen embrittlement. For this purpose, a welded carbon steel grade J55 with a ferritic-pearlitic microstructure was investigated by using high pressure high temperature autoclave tests, permeation tests and analysis of uptaken hydrogen. For the autoclave tests, tensile samples have been examined that were loaded by a spring at 90% of yield strength, and samples were also examined to determine the hydrogen uptake. After completion of the tests, the hydrogen uptake was analyzed by thermal desorption spectroscopy. Four main gas compositions were used for the autoclave tests: 120 bar H2, 120 bar H2 + 15 bar CO2, 120 bar H2 + 1 bar H2S, and 120 bar H2 + 15 bar CO2 + 1 bar H2S whereby the tests were carried out with and without the addition of electrolytes with a concentration of 1 and 200 g/l sodium chloride. Moreover, the experiments were conducted at room temperature and 120°C. Test duration was 720 hours. Prior to autoclave testing effective diffusion coefficient was determined to characterize diffusion behavior of hydrogen through the weld material. Results show a low hydrogen uptake even at most severe conditions. Additionally no stressed specimens failed during autoclave testing. Welded J55 is recommended as a suitable tube material for subsurface hydrogen storage.

M3 - Conference contribution

BT - AMPP Annual Conference & Expo 2023

ER -