Cost effective hydrogen production of coupled photovoltaic and electrolyzer systems considering plant lifetime and geographical location
Articolo
Data di Pubblicazione:
2025
Abstract:
Advancements in electrolysis technologies, coupled with improvements in associated production processes and
public incentive programs, are progressively enabling the widespread deployment of megawatt-scale electrolyzers.
While these policies are crucial in the short term to support the adoption of emerging technologies and the
transformation of industrial processes, substantial focus must be directed toward optimizing technical solutions.
This study aims to determine the cost-optimal configuration of a grid-connected system comprising a photovoltaic
(PV) production plant and an electrolyzer. This will be accomplished using advanced simulation models
that account for the load and thermal cycles, the geographical location of production sites, and the operational
lifespan of the installations. The simulation will identify the optimal ratio between the PV array and the electrolyzer
to minimize the LCOH (Levelized Cost of Hydrogen). A sensitivity analysis of the PV capacity, considering
site-specific irradiation, will be conducted to achieve this objective. The study further delves into the
evaluation of the LCOH depending on the utilization of the stacks and alternative management control logic. The
findings from the study suggest that the optimal PV:ELE ratio ranges from 1.5:1 to 1.8:1 based on geographical
location and highlight an LCOH reduction of about 10 % while coupling the electrolyzer with a PV monoaxial
tracking installation over a fixed setup. Ultimately, the analysis of alternative stack usage strategies demonstrates
that dynamically balancing stack utilization ensures the lowest LCOH compared to all other tested alternatives.
public incentive programs, are progressively enabling the widespread deployment of megawatt-scale electrolyzers.
While these policies are crucial in the short term to support the adoption of emerging technologies and the
transformation of industrial processes, substantial focus must be directed toward optimizing technical solutions.
This study aims to determine the cost-optimal configuration of a grid-connected system comprising a photovoltaic
(PV) production plant and an electrolyzer. This will be accomplished using advanced simulation models
that account for the load and thermal cycles, the geographical location of production sites, and the operational
lifespan of the installations. The simulation will identify the optimal ratio between the PV array and the electrolyzer
to minimize the LCOH (Levelized Cost of Hydrogen). A sensitivity analysis of the PV capacity, considering
site-specific irradiation, will be conducted to achieve this objective. The study further delves into the
evaluation of the LCOH depending on the utilization of the stacks and alternative management control logic. The
findings from the study suggest that the optimal PV:ELE ratio ranges from 1.5:1 to 1.8:1 based on geographical
location and highlight an LCOH reduction of about 10 % while coupling the electrolyzer with a PV monoaxial
tracking installation over a fixed setup. Ultimately, the analysis of alternative stack usage strategies demonstrates
that dynamically balancing stack utilization ensures the lowest LCOH compared to all other tested alternatives.
Tipologia CRIS:
1.1 Articolo in rivista
Elenco autori:
Vizza, D.; Caponi, R.; Bocci, E.; Del Zotto, L.; Bassano, C.
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