Modeling and simulation of integrated solar PV - hydrogen systems

Gutiérrez Martín, Fernando ORCID: https://orcid.org/0000-0002-8014-480X, Díaz López, José Antonio ORCID: https://orcid.org/0000-0002-8270-4508, Caravaca Huertas, Angel ORCID: https://orcid.org/0000-0003-4942-0594 and Dos Santos García, Antonio Juan ORCID: https://orcid.org/0000-0002-5660-1097 (2024). Modeling and simulation of integrated solar PV - hydrogen systems. "International Journal of Hydrogen Energy", v. 52 ; pp. 995-1006. ISSN 03603199. https://doi.org/10.1016/j.ijhydene.2023.05.179.

Descripción

Título: Modeling and simulation of integrated solar PV - hydrogen systems
Autor/es:
Tipo de Documento: Artículo
Título de Revista/Publicación: International Journal of Hydrogen Energy
Fecha: 2 Enero 2024
ISSN: 03603199
Volumen: 52
Materias:
ODS:
Palabras Clave Informales: Battery storage; hydrogen production; Solar PV energy; Water electrolysis
Escuela: E.T.S.I. Diseño Industrial (UPM)
Departamento: Ingeniería Mecánica, Química y Diseño Industrial
Licencias Creative Commons: Reconocimiento - Sin obra derivada - No comercial

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Resumen

This work provides a novel model for solar PV – hydrogen (H2) systems that uses weather data and electrical variables of the components to perform PV-H2 design for different hybrid configurations. The objectives are to size and operate the systems optimally to reach a target production (QH) and minimize cost of H2. The component sizes and hydrogen production (QH) are optimized by PV-EL direct coupling where the EL curves are determined by the number and area of EL cells connected to PV modules. The use of maximum power point (MPP) tracking increases the coupling factor (and QH), but this gain is not significant vs. optimal PV-EL coupling. Battery assisted electrolysis has the advantage of reducing the EL size, showing how convenient is also to operate it at part loads (e.g., at night) so that the PV array and EL are larger to grant H2 production, but the batteries are much more effective. The optimal configuration, design and operation will finally depend on the evolution of unit cost of the components (PV, MPPT, EL and batteries): direct coupling leads to a cost production of 5.03 Є/kgH2 with 26 (20 cm2) EL cells per PV module; this is slightly increased by MPPT use (5.20 Є/kgH2) and notably reduced with batteries (4.07 Є/kgH2), but MPPT would be optimal if cost drops to 1/5 of base prices considered in this work and batteries are not favorable if cost per m2 of EL is reduced to less than 1/3 (depending on MPPT cost).

Más información

ID de Registro: 81290
Identificador DC: https://oa.upm.es/81290/
Identificador OAI: oai:oa.upm.es:81290
URL Portal Científico: https://portalcientifico.upm.es/es/ipublic/item/10090157
Identificador DOI: 10.1016/j.ijhydene.2023.05.179
URL Oficial: https://www.sciencedirect.com/science/article/pii/...
Depositado por: Portal Científico UPM
Depositado el: 22 Abr 2024 11:28
Ultima Modificación: 10 Mar 2025 11:53