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Erschienen in:
Recent Developments in the Research on Pressure-Gain Combustion Devices Kapitel lesen Erstes Kapitel lesen

2020 | OriginalPaper | Buchkapitel

Hydrogen and Hydrogen-Rich Fuels: Production and Conversion to Electricity

verfasst von : Jens Klingmann, Martin Andersson

Erschienen in: Innovations in Sustainable Energy and Cleaner Environment

Verlag: Springer Singapore

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Abstract

Hydrogen has been proposed as an energy carrier in storage systems, fueled by excess electricity from volatile power production and re-electrified in times of electricity shortage. Unfortunately, these storage systems suffer from fairly poor return efficiencies. There is however a multitude of other production methods and usages that not seldom are intermixed with storage, creating possibilities for hydrogen as an attractive energy carrier. In many cases, hydrogen is mixed with other species. A brief introduction of possible hydrogen production methods and ways to convert hydrogen into electricity are presented. Emphases are put on comparing electrochemical methods (fuel cells and electrolyzers) to more traditional methods, mainly turbine-based power production.

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Vorheriges Kapitel Laminar Burning Speed Study of Alternative Fuel Air Diluent Mixtures at High Pressures and Temperatures
Nächstes Kapitel On Soot Reduction Using Oxygenated Combustion in Counterflow Diffusion Flames
Fußnoten
1
Gas turbines may have considerably higher temperatures because they are internally fired engines and thus, the heat does not have to be transferred into the cycle through a heat exchange process. This makes it possible to cool the most endangered parts.
 
Literatur
1.
Khan MA (2011) Multiphysics modelling of PEFCs-with reacting transport phenomena at micro and macroscales. Doctoral dissertation, Lund University
2.
Andersson M, Nakajima H, Kitahara T, Shimizu A, Koshiyama T, Paradis H, Yuan J, Bengt S (2014) Comparison of humidified hydrogen and partly pre-reformed natural gas as fuel for solid oxide fuel cells applying computational fluid dynamics. Int J Heat Mass Transf 77:1008–1022CrossRef
3.
Butler A, Spliethoff H (2018) Current status of water electrolysis for energy storage, grid balancing and sector coupling via power-to-gas and power-to-liquids: a review. Renew Sustain Energy Rev 82(3):2440–2454CrossRef
4.
Götz M, Lefebvre J, Mörs F, Koch AM, Graf F, Bajohr S, Reimert R, Kolb T (2016) Renewable power-to-gas: a technological and economic review. Renew Energy 85:1371–1390CrossRef
5.
Navasa M (2016) Three dimensional multiphysics modeling of reversible solid oxide electrochemical cells for degradation studies. Doctoral dissertation, Lund University
6.
Andersson M (2011) Solid oxide fuel cell modeling at the cell scale—focusing on species heat, charge and momentum transport as well as the reaction kinetics and effects. Doctoral dissertation, Lund University
7.
Andersson M, Beale S, Espinoza M, Wu Z, Lehnert W (2016) A review of cell-scale multiphase flow modeling, including water management, in polymer electrolyte fuel cells. Appl Energy 180:757–778CrossRef
8.
Andersson M, Sundén B (2017) Technology review—solid oxide fuel cell. Energiforsk AB
9.
Andersson M, Yuan J, Sundén B (2010) Review on modeling development for multiscale chemical reactions coupled transport phenomena in SOFCs. J Appl Energy 87:1461–1476CrossRef
10.
Andersson M, Beale S, Reimer U, Lehnert W, Stolten D (2018) Interface resolving two-phase flow simulations in gas channels relevant for polymer electrolyte fuel cells using the volume of fluid approach. J Hydrog Energy 43:1961–2976CrossRef
11.
Tang CL, Huang ZH, Law CK (2011) Determination, correlation, and mechanistic interpretation of effects of hydrogen addition on laminar flame speeds of hydro-carbon-air mixtures. Proc Combust Inst 33:921–928CrossRef
12.
Schönborn A, Sayad P, Konnov A, Klingmann J (2014) OH*-chemiluminescence during autoignition of hydrogen with air in a pressurised turbulent flow reactor. Int J Hydrog Energy 39(23):12166–12181CrossRef
13.
14.
Sebastian S, Stathopoulos S, Tom T, Oliver PC (2015) Blue combustion: stoichiometric hydrogen-oxygen combustion under humidified conditions, pp GT2015-43149
15.
Milewski J (2015) Hydrogen utilization by steam turbine cycles. J Power Technol 95:258–264
16.
Ito H, Miyazaki N, Ishida M, Nakano A (2016) Efficiency of unitized reversible fuel cell systems. Int J Hydrog Energy 41:5803–5815CrossRef
17.
Kobayashi Y et al (2015) Mitsubishi heavy industries technical review, vol 52, no. 2
18.
FCE wraps up world’s largest fuel cell park in Korea, new Seoul one. Fuel Cell Bull, pp 6 (2014)
19.
van Biert L, Woudstra T, Godjevac M, Visser K, Aravind P (2018) A thermodynamic comparison of solid oxide fuel cell-combined cycles. J Power Sour 397, 382–396
Metadaten
Titel
Hydrogen and Hydrogen-Rich Fuels: Production and Conversion to Electricity
verfasst von
Jens Klingmann
Martin Andersson
Copyright-Jahr
2020
Verlag
Springer Singapore
Buch
Innovations in Sustainable Energy and Cleaner Environment

Print ISBN: 978-981-13-9011-1

Electronic ISBN: 978-981-13-9012-8

Copyright-Jahr: 2020

DOI
https://doi.org/10.1007/978-981-13-9012-8_10