artículo
Assessing system-level synergies between photovoltaic and proton exchange membrane electrolyzers for solar-powered hydrogen production
Date
2024Registration in:
10.1016/j.apenergy.2024.123495
1872-9118
0306-2619
Author
Arias Olivares, Ignacio Javier
G. Battisti, Felipe
Romero Ramos, J. A.
Pérez, Manuel
Valenzuela, Loreto
Cardemil Iglesias, José Miguel
Escobar Moragas, Rodrigo Alfonso
Institutions
Abstract
This study delves into the techno-economic benefits of integrating Proton Exchange Membrane electrolyzers
with photovoltaic systems for hydrogen production, with a keen focus on cost optimization strategies. A
comprehensive analysis of several system scales and cost scenarios unveils the critical roles of Proton Exchange
Membrane stack systems and the Balance of Plant components in influencing capital expenditures. Notably,
the research identifies that incorporating the grid via a complementary Power Purchase Agreement, alongside
clipped solar energy, innovatively redistributes cost elements. This approach significantly reduces the levelized
cost of hydrogen, thereby enabling the feasibility of hydrogen production in regions characterized by low solar
radiation at the cost of high grid electricity penetration. Sensitivity to energy costs, accentuated by different
integration schemes, highlights the pivotal role of the stack cost and the Balance of Plant cost reductions in
achieving economic viability for large-scale deployments. The study underscores the necessity of holistic cost
optimization, revealing that strategic grid support coupled with solar energy enhances the techno-economic
performance and broadens the scope for renewable hydrogen production in less favorable locales. These
insights offer invaluable guidance to stakeholders, advocating for advanced integration strategies that promise
both efficiency and financial sustainability in the burgeoning field of renewable hydrogen production systems.