The cost dynamics of hydrogen supply in future energy systems – A techno-economic study

[Display omitted] •The cost dynamics of hydrogen supply in future energy systems is investigated.•The cost of hydrogen influenced by several factors, in addition to electricity cost.•The hydrogen demand profile has a considerable impact on cost of hydrogen.•Flexibility in the hydrogen demand can red...

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Bibliographic Details
Published in:Applied energy Vol. 328; p. 120233
Main Authors: Öberg, Simon, Odenberger, Mikael, Johnsson, Filip
Format: Journal Article
Language:English
Published: Elsevier Ltd 15.12.2022
Subjects:
Electrolysis
Energy systems modeling
Flexible industry
Hydrogen cost
Time-shifting
Hydrogen cost
Energy systems modeling
Flexible industry
Time-shifting
Electrolysis
ISSN:0306-2619, 1872-9118, 1872-9118
Online Access:Get full text
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Summary:[Display omitted] •The cost dynamics of hydrogen supply in future energy systems is investigated.•The cost of hydrogen influenced by several factors, in addition to electricity cost.•The hydrogen demand profile has a considerable impact on cost of hydrogen.•Flexibility in the hydrogen demand can reduce the cost by more than 30%.•Time-shifting of electricity generation via hydrogen provides a system value. This work aims to investigate the time-resolved cost of electrolytic hydrogen in a future climate-neutral electricity system with high shares of variable renewable electricity generation in which hydrogen is used in the industry and transport sectors, as well as for time-shifting electricity generation. The work applies a techno-economic optimization model, which incorporates both exogenous (industry and transport) and endogenous (time-shifting of electricity generation) hydrogen demands, to elucidate the parameters that affect the cost of hydrogen. The results highlight that several parameters influence the cost of hydrogen. The strongest influential parameter is the cost of electricity. Also important are cost-optimal dimensioning of the electrolyzer and hydrogen storage capacities, as these capacities during certain periods limit hydrogen production, thereby setting the marginal cost of hydrogen. Another decisive factor is the nature of the hydrogen demand, whereby flexibility in the hydrogen demand can reduce the cost of supplying hydrogen, given that the demand can be shifted in time. In addition, the modeling shows that time-shifting electricity generation via hydrogen production, with subsequent reconversion back to electricity, plays an important in the climate-neutral electricity system investigated, decreasing the average electricity cost by 2%–16%. Furthermore, as expected, the results show that the cost of hydrogen from an off-grid, island-mode-operated industry is more expensive than the cost of hydrogen from all scenarios with a fully interconnected electricity system.
ISSN:0306-2619
1872-9118
1872-9118
DOI:10.1016/j.apenergy.2022.120233