Towards Non-Mechanical Hybrid Hydrogen Compression for Decentralized Hydrogen Facilities

Sdanghi, Giuseppe; Maranzana, Gaël; Celzard, Alain; Fierro, Vanessa

doi:10.3390/en13123145

Cited by 64 publications

(38 citation statements)

References 112 publications

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“…The ×10 scale-up in installed capacity case assumes that the BOP costs can be improved by 60 $/kW; Symbiosis and heat recovery: Additionally, as low-grade heat is the principle waste product, opportunities for heat recovery and utilisation can also be exploited [39]. Hydrogen compression via sorption technology also represents an opportunity for direct recovery and utilisation of heat from the PEM system [40]. The ×100 scale-up in installed capacity case assumes that the installation of symbiotic technology costs can be improved by 20 $/kW.…”

Section: Comparison Of Current and Future System Capital Costsmentioning

confidence: 99%

The Key Techno-Economic and Manufacturing Drivers for Reducing the Cost of Power-to-Gas and a Hydrogen-Enabled Energy System

Bristowe

Smallbone

2021

Hydrogen

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Water electrolysis is a process which converts electricity into hydrogen and is seen as a key technology in enabling a net-zero compatible energy system. It will enable the scale-up of renewable electricity as a primary energy source for heating, transport, and industry. However, displacing the role currently met by fossil fuels might require a price of hydrogen as low as 1 $/kg, whereas renewable hydrogen produced using electrolysis is currently 10 $/kg. This article explores how mass manufacturing of proton exchange membrane (PEM) electrolysers can reduce the capital cost and, thus, make the production of renewable power to hydrogen gas (PtG) more economically viable. A bottom up direct manufacturing model was developed to determine how economies of scale can reduce the capital cost of electrolysis. The results demonstrated that (assuming an annual production rate of 5000 units of 200 kW PEM electrolysis systems) the capital cost of a PEM electrolysis system can reduce from 1990 $/kW to 590 $/kW based on current technology and then on to 431 $/kW and 300 $/kW based on the an installed capacity scale-up of ten- and one-hundred-fold, respectively. A life-cycle costing analysis was then completed to determine the importance of the capital cost of an electrolysis system to the price of hydrogen. It was observed that, based on current technology, mass manufacturing has a large impact on the price of hydrogen, reducing it from 6.40 $/kg (at 10 units units per year) to 4.16 $/kg (at 5000 units per year). Further analysis was undertaken to determine the cost at different installed capacities and found that the cost could reduce further to 2.63 $/kg and 1.37 $/kg, based on technology scale-up by ten- and one hundred-fold, respectively. Based on the 2030 (and beyond) baseline assumptions, it is expected that hydrogen production from PEM electrolysis could be used as an industrial process feed stock, provide power and heat to buildings and as a fuel for heavy good vehicles (HGVs). In the cases of retrofitted gas networks for residential or industrial heating solutions, or for long distance transport, it represents a more economically attractive and mass-scale compatible solution when compared to electrified heating or transport solutions.

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Section: Comparison Of Current and Future System Capital Costsmentioning

confidence: 99%

The Key Techno-Economic and Manufacturing Drivers for Reducing the Cost of Power-to-Gas and a Hydrogen-Enabled Energy System

Bristowe

Smallbone

2021

Hydrogen

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“…Type IV tanks, which are made of carbon fibers and a polymer inner lining, are most commonly used for storing hydrogen at high pressures. 16 The cost of a Type IV tank has been estimated at approximately $ 633 kg -1 . 6 Nevertheless, high-pressure systems require safety measures that may alarm public opinion.…”

Section: Introductionmentioning

confidence: 99%

“…High-pressure hydrogen storage requires heavy and bulky tanks. Type IV tanks, which are made of carbon fibers and a polymer inner lining, are most commonly used for storing hydrogen at high pressures . The cost of a Type IV tank has been estimated at approximately $ 633 kg ‑1 .…”

Section: Introductionmentioning

confidence: 99%

A Step Forward in Understanding the Hydrogen Adsorption and Compression on Activated Carbons

Ramírez-Vidal

Canevesi

Sdanghi

et al. 2021

ACS Appl. Mater. Interfaces

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HAL is a multi-disciplinary open access archive for the deposit and dissemination of scientific research documents, whether they are published or not. The documents may come from teaching and research institutions in France or abroad, or from public or private research centers. L'archive ouverte pluridisciplinaire HAL, est destinée au dépôt et à la diffusion de documents scientifiques de niveau recherche, publiés ou non, émanant des établissements d'enseignement et de recherche français ou étrangers, des laboratoires publics ou privés.

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“…An emerging technology for hydrogen compression is based on thermally driven, cyclic, adsorption-desorption on porous materials [140]. In addition to carbon materials [141], thoroughly reviewed in the present paper, other candidates for this purpose are: (i) MOFs, with their exceptional A BET sometimes higher than 6000 m 2 g −1 , thereby allowing excess uptakes of around 10 wt.% at 77 K and 6 MPa [142] (however, the main drawback of MOF for a wide application is their high price and the degradation of their properties with ageing [143]); (ii) organic polymers, which ensure hydrogen uptakes of about 4 wt.% at 77 K and approximately 1 MPa [144,145]; and (iii) silicas, aluminas, and zeolites, but giving amounts of adsorbed hydrogen lower than carbons of similar A BET [146].…”

Section: Carbon Materials For Hydrogen Compressionmentioning

confidence: 99%

Characterization of Carbon Materials for Hydrogen Storage and Compression

Sdanghi

Canevesi

Celzard

et al. 2020

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Carbon materials have proven to be a suitable choice for hydrogen storage and, recently, for hydrogen compression. Their developed textural properties, such as large surface area and high microporosity, are essential features for hydrogen adsorption. In this work, we first review recent advances in the physisorption characterization of nanoporous carbon materials. Among them, approaches based on the density functional theory are considered now standard methods for obtaining a reliable assessment of the pore size distribution (PSD) over the whole range from narrow micropores to mesopores. Both a high surface area and ultramicropores (pore width < 0.7 nm) are needed to achieve significant hydrogen adsorption at pressures below 1 MPa and 77 K. However, due to the wide PSD typical of activated carbons, it follows from an extensive literature review that pressures above 3 MP are needed to reach maximum excess uptakes in the range of ca. 7 wt.%. Finally, we present the adsorption–desorption compression technology, allowing hydrogen to be compressed at 70 MPa by cooling/heating cycles between 77 and 298 K, and being an alternative to mechanical compressors. The cyclic, thermally driven hydrogen compression might open a new scenario within the vast field of hydrogen applications.

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Towards Non-Mechanical Hybrid Hydrogen Compression for Decentralized Hydrogen Facilities

Cited by 64 publications

References 112 publications

The Key Techno-Economic and Manufacturing Drivers for Reducing the Cost of Power-to-Gas and a Hydrogen-Enabled Energy System

The Key Techno-Economic and Manufacturing Drivers for Reducing the Cost of Power-to-Gas and a Hydrogen-Enabled Energy System

A Step Forward in Understanding the Hydrogen Adsorption and Compression on Activated Carbons

Characterization of Carbon Materials for Hydrogen Storage and Compression

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