A numerical method for electromagnetic and chemical coupling in liquid metal flow optimization for carbon dioxide free production of hydrogen

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OriginalspracheEnglisch
Titel des Sammelwerks11th PAMIR international conference
UntertitelFundamental and Applied MHD
Seiten292-296
PublikationsstatusVeröffentlicht - 2019
Veranstaltung11th PAMIR International Conference: Fundamentals and Applied MHD - Reims, Frankreich
Dauer: 1 Juli 20195 Juli 2019

Abstract

The usage of hydrogen as alternative energy offers many applications, they can be found in in vehicle technology for fuel cells or as a reducing agent. Classical production methods like steam reforming generate carbon dioxide as a byproduct. In the discovered method, hydrogen is produced CO2 free by thermal decomposition of methane. To realize the production, methane is injected into a reactor that is filled with liquid tin. Inside the melt, methane bubbles will react to carbon and hydrogen. To optimize the reaction, different parameters for influencing the bubble flow will be discussed. The focus is set on the electromagnetic stirring of bubbles. A solving method is developed to simulate this effect, and will be demonstrated in parameter studies. To get a detailed view on the produced hydrogen, also a chemical calculation method is developed, that can be coupled with the electromagnetic solver and allow a validation of the model, that is presented in this article.

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A numerical method for electromagnetic and chemical coupling in liquid metal flow optimization for carbon dioxide free production of hydrogen. / Fehling, Tristan; Baake, Egbert.
11th PAMIR international conference: Fundamental and Applied MHD. 2019. S. 292-296.

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschung

Fehling T, Baake E. A numerical method for electromagnetic and chemical coupling in liquid metal flow optimization for carbon dioxide free production of hydrogen. in 11th PAMIR international conference: Fundamental and Applied MHD. 2019. S. 292-296
Fehling, Tristan ; Baake, Egbert. / A numerical method for electromagnetic and chemical coupling in liquid metal flow optimization for carbon dioxide free production of hydrogen. 11th PAMIR international conference: Fundamental and Applied MHD. 2019. S. 292-296
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title = "A numerical method for electromagnetic and chemical coupling in liquid metal flow optimization for carbon dioxide free production of hydrogen",
abstract = "The usage of hydrogen as alternative energy offers many applications, they can be found in in vehicle technology for fuel cells or as a reducing agent. Classical production methods like steam reforming generate carbon dioxide as a byproduct. In the discovered method, hydrogen is produced CO2 free by thermal decomposition of methane. To realize the production, methane is injected into a reactor that is filled with liquid tin. Inside the melt, methane bubbles will react to carbon and hydrogen. To optimize the reaction, different parameters for influencing the bubble flow will be discussed. The focus is set on the electromagnetic stirring of bubbles. A solving method is developed to simulate this effect, and will be demonstrated in parameter studies. To get a detailed view on the produced hydrogen, also a chemical calculation method is developed, that can be coupled with the electromagnetic solver and allow a validation of the model, that is presented in this article.",
author = "Tristan Fehling and Egbert Baake",
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T1 - A numerical method for electromagnetic and chemical coupling in liquid metal flow optimization for carbon dioxide free production of hydrogen

AU - Fehling, Tristan

AU - Baake, Egbert

N1 - Funding Information: This work was supported by Helmholtz Association of German Research Centers in frame of Helmholtz Alliance LIMTECH.

PY - 2019

Y1 - 2019

N2 - The usage of hydrogen as alternative energy offers many applications, they can be found in in vehicle technology for fuel cells or as a reducing agent. Classical production methods like steam reforming generate carbon dioxide as a byproduct. In the discovered method, hydrogen is produced CO2 free by thermal decomposition of methane. To realize the production, methane is injected into a reactor that is filled with liquid tin. Inside the melt, methane bubbles will react to carbon and hydrogen. To optimize the reaction, different parameters for influencing the bubble flow will be discussed. The focus is set on the electromagnetic stirring of bubbles. A solving method is developed to simulate this effect, and will be demonstrated in parameter studies. To get a detailed view on the produced hydrogen, also a chemical calculation method is developed, that can be coupled with the electromagnetic solver and allow a validation of the model, that is presented in this article.

AB - The usage of hydrogen as alternative energy offers many applications, they can be found in in vehicle technology for fuel cells or as a reducing agent. Classical production methods like steam reforming generate carbon dioxide as a byproduct. In the discovered method, hydrogen is produced CO2 free by thermal decomposition of methane. To realize the production, methane is injected into a reactor that is filled with liquid tin. Inside the melt, methane bubbles will react to carbon and hydrogen. To optimize the reaction, different parameters for influencing the bubble flow will be discussed. The focus is set on the electromagnetic stirring of bubbles. A solving method is developed to simulate this effect, and will be demonstrated in parameter studies. To get a detailed view on the produced hydrogen, also a chemical calculation method is developed, that can be coupled with the electromagnetic solver and allow a validation of the model, that is presented in this article.

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EP - 296

BT - 11th PAMIR international conference

T2 - 11th PAMIR International Conference

Y2 - 1 July 2019 through 5 July 2019

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