Hybrid Hydrogen and Mechanical Distributed Energy Storage

Ubertini, Stefano; Facci, Andrea Luigi; Andreassi, Luca

doi:10.3390/en10122035

Cited by 22 publications

(10 citation statements)

References 44 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The higher the round-trip efficiency, the less energy is lost in the storage process. The AB-FB RTE is equal to 65%, which is lower than the VRFB (75%) [12], although it seems to be higher than the one reached using hydrogen as energy storage vector [24,25]. It is expected that the AB-FB RTE will reach values higher than 70% (based on preliminary and not-yet-published research studies).…”

Section: • Low Energy Efficiency and Corresponding Energy Lossesmentioning

confidence: 99%

Assessment of Potential Barriers to the Implementation of an Innovative AB-FB Energy Storage System under a Sustainable Perspective

Blecua-de-Pedro

Díaz-Ramírez

2021

Sustainability

View full text Add to dashboard Cite

The novel acid–base flow battery technology stores electrical energy using pH and salinity gradients in water and is suitable for different capacities (kWh–MWh scale) because of its scalable technology. Due to the flexibility of this system, it is predicted to provide technical, economic, and environmental benefits for supporting renewable energy integration, such as wind and solar energy, within the electricity generation system. However, its level of acceptance might be affected by additional conditioning factors in terms of policies and maintenance. To elucidate the relevance of the possible barriers to the implementation of the innovative AB-FB system, this work introduces an approach based on the analytic hierarchy process developed at three levels of hierarchy under a sustainability perspective. An exhaustive literature review as well as an assessment of experts’ evaluations were performed to identify the barriers in terms of technical, economic, environmental, policy, and maintenance aspects. Based on the results, the cost parameters (mostly attributed to the stack cost), followed by technical and environmental criteria, were deemed to be of the highest priority.

show abstract

Section: • Low Energy Efficiency and Corresponding Energy Lossesmentioning

confidence: 99%

Assessment of Potential Barriers to the Implementation of an Innovative AB-FB Energy Storage System under a Sustainable Perspective

Blecua-de-Pedro

Díaz-Ramírez

2021

Sustainability

View full text Add to dashboard Cite

show abstract

“…The exploitation of renewable energies has attracted a growing number of efforts in recent years [1], ranging from the theoretical physical aspects to the engineering implementation of novel energy systems. However, efficient and economically convenient implementations require the presence of energy buffers, due to the aleatory nature of renewable energies, especially from solar and wind sources [2,3].…”

Section: Introductionmentioning

confidence: 99%

Optimized Modeling and Design of a PCM-Enhanced H2 Storage

Facci

Lauricella²,

Succi

et al. 2021

Energies

View full text Add to dashboard Cite

Thermal and mechanical energy storage is pivotal for the effective exploitation of renewable energy sources, thus fostering the transition to a sustainable economy. Hydrogen-based systems are among the most promising solutions for electrical energy storage. However, several technical and economic barriers (e.g., high costs, low energy and power density, advanced material requirements) still hinder the diffusion of such solutions. Similarly, the realization of latent heat storages through phase change materials is particularly attractive because it provides high energy density in addition to allowing for the storage of the heat of fusion at a (nearly) constant temperature. In this paper, we posit the challenge to couple a metal hydride H2 canister with a latent heat storage, in order to improve the overall power density and realize a passive control of the system temperature. A highly flexible numerical solver based on a hybrid Lattice Boltzmann Phase-Field (LB-PF) algorithm is developed to assist the design of the hybrid PCM-MH tank by studying the melting and solidification processes of paraffin-like materials. The present approach is used to model the storage of the heat released by the hydride during the H2 loading process in a phase change material (PCM). The results in terms of Nusselt numbers are used to design an enhanced metal-hydride storage for H2-based energy systems, relevant for a reliable and cost-effective “Hydrogen Economy”. The application of the developed numerical model to the case study demonstrates the feasibility of the posited design. Specifically, the phase change material application significantly increases the heat flux at the metal hydride surface, thus improving the overall system power density.

show abstract

“…This process increases the efficiency of the system reducing the consumption of fossil fuels and, therefore, CO 2 emissions [70]. To reduce the handicaps of conventional CAES, different approaches have been considered such as reducing the target depth of the storage cavities [43] or the hybridization of energy storage technologies, such as the integration of CAES and hydrogen [63], and others [3,19,58,4].…”

Section: Introductionmentioning

confidence: 99%

Development of an efficient and sustainable energy storage system by hybridization of compressed air and biogas technologies (BIO-CAES)

Llamas

Ortega

Barthelemy

et al. 2020

Energy Conversion and Management

View full text Add to dashboard Cite

The future electricity generation model will require the integration of intermittent renewable sources. For that, the development of new efficient and sustainable energy storage technologies is mandatory. One of the most promising technologies is the utilization of compressed air energy storage (CAES). However, this technology has a limitation related with the management of the heat generated in the compression stage. In this study it is proposed the integration of a CAES system together with an anaerobic digester, which will use the generated heat, supporting the production and storage of biogas as chemical storage of energy. The latter will be used in the air expansion stage to maximize the efficiency of the overall process. In this way, a new energy storage technology by hybridization of BIOgas and CAES is achieved: BIO-CAES technology.

show abstract

Hybrid Hydrogen and Mechanical Distributed Energy Storage

Cited by 22 publications

References 44 publications

Assessment of Potential Barriers to the Implementation of an Innovative AB-FB Energy Storage System under a Sustainable Perspective

Assessment of Potential Barriers to the Implementation of an Innovative AB-FB Energy Storage System under a Sustainable Perspective

Optimized Modeling and Design of a PCM-Enhanced H2 Storage

Development of an efficient and sustainable energy storage system by hybridization of compressed air and biogas technologies (BIO-CAES)

Contact Info

Product

Resources

About