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Optimal Operation Conditions for a Methane Fuelled SOFC and Microturbine Hybrid System
Joint Authors
De Marco, Vincenzo
Florio, Gaetano
Fragiacomo, Petronilla
Source
Issue
Vol. 2015, Issue 2015 (31 Dec. 2015), pp.1-13, 13 p.
Publisher
Hindawi Publishing Corporation
Publication Date
2015-11-10
Country of Publication
Egypt
No. of Pages
13
Main Subjects
Abstract EN
The study of a hybrid system obtained coupling a methane fuelled gas microturbine (MTG) and a solid oxide fuel cell (SOFC) was performed.
The objective of this study is to evaluate the operation conditions as a function of the independent variables of the system, which are the current density and fuel utilization factor.
Numerical simulations were carried out in developing a C++ computer code, in order to identify the preferable plant configuration and both the optimal methane flow and the current density.
Operation conditions are able to ensure elasticity and the most suitable fuel utilization factor.
To confirm the reliability of the models, results of the simulations were compared with reference results found in literature.
American Psychological Association (APA)
De Marco, Vincenzo& Florio, Gaetano& Fragiacomo, Petronilla. 2015. Optimal Operation Conditions for a Methane Fuelled SOFC and Microturbine Hybrid System. Journal of Renewable Energy،Vol. 2015, no. 2015, pp.1-13.
https://search.emarefa.net/detail/BIM-1070052
Modern Language Association (MLA)
De Marco, Vincenzo…[et al.]. Optimal Operation Conditions for a Methane Fuelled SOFC and Microturbine Hybrid System. Journal of Renewable Energy No. 2015 (2015), pp.1-13.
https://search.emarefa.net/detail/BIM-1070052
American Medical Association (AMA)
De Marco, Vincenzo& Florio, Gaetano& Fragiacomo, Petronilla. Optimal Operation Conditions for a Methane Fuelled SOFC and Microturbine Hybrid System. Journal of Renewable Energy. 2015. Vol. 2015, no. 2015, pp.1-13.
https://search.emarefa.net/detail/BIM-1070052
Data Type
Journal Articles
Language
English
Notes
Includes bibliographical references
Record ID
BIM-1070052