The role of hydrogen‐based power systems in the energy transition of the residential sector

Maestre, V.M.; Ortiz, Alfredo; Ortíz, Inmaculada

doi:10.1002/jctb.6938

Cited by 24 publications

(9 citation statements)

References 50 publications

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“…Alternatively, green hydrogen, which is being highly promoted, comes from routes such as water electrolysis using energy from renewable sources. A greenhouse gas emissions-free, hydrogen-based economy places hydrogen as a key element with different purposes: i) to balance the grid when needed using a fuel cell (FC) system (power-to-power), ii) to be blended in the natural gas grid or used as feedstock for synthetic natural gas production (power-to-gas), , iii) to be used as fuel in the transport sector (power-to-fuel), , or iv) to be employed as a valuable commodity to produce chemical compounds or synthetic fuels (power-to-feedstock). , The technological research is being supported by the development of hydrogen policies (30 countries have released hydrogen roadmaps in 2021) in many regions such as Asia, Europe, or Canada. − The total investment in hydrogen spending will exceed $300 billion through 2030, and as a result, the hydrogen economy will continue its expansion with a 5.7% growth forecasted for the period 2021–2030 . The future development of hydrogen relies on the reduction of the production costs.…”

Section: Introductionmentioning

confidence: 99%

Hydrogen Recovery from Coke Oven Gas. Comparative Analysis of Technical Alternatives

Moral

Ortiz-Imedio

Ortiz

et al. 2022

Ind. Eng. Chem. Res.

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The recovery of energy and valuable compounds from exhaust gases in the iron and steel industry deserves special attention due to the large power consumption and CO 2 emissions of the sector. In this sense, the hydrogen content of coke oven gas (COG) has positioned it as a promising source toward a hydrogen-based economy which could lead to economic and environmental benefits in the iron and steel industry. COG is presently used for heating purposes in coke batteries or furnaces, while in high production rate periods, surplus COG is burnt in flares and discharged into the atmosphere. Thus, the recovery of the valuable compounds of surplus COG, with a special focus on hydrogen, will increase the efficiency in the iron and steel industry compared to the conventional thermal use of COG. Different routes have been explored for the recovery of hydrogen from COG so far: i) separation/purification processes with pressure swing adsorption or membrane technology, ii) conversion routes that provide additional hydrogen from the chemical transformation of the methane contained in COG, and iii) direct use of COG as fuel for internal combustion engines or gas turbines with the aim of power generation. In this study, the strengths and bottlenecks of the main hydrogen recovery routes from COG are reviewed and discussed.

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Section: Introductionmentioning

confidence: 99%

Hydrogen Recovery from Coke Oven Gas. Comparative Analysis of Technical Alternatives

Moral

Ortiz-Imedio

Ortiz

et al. 2022

Ind. Eng. Chem. Res.

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“…Moreover, 28% of the studies focused on the use of hydrogen in the residential sector. This minimal attention from researchers may be due to significant costs, including a levelized energy price that is higher than ordinary grid rates Maestre et al (2022). Yet, a variety of specifically designed residential buildings can be supplied with heat and power in both gridconnected and off-grid locations.…”

Section: Hydrogen Supply Chain Downstream (Hscd) Dimensionmentioning

confidence: 99%

A Comprehensive Systematic Overview of Canadian Hydrogen Supply Chains Downstream

Farahmand,

King,

Ghahremanlou

et al. 2023

JSD

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This paper investigates Canada’s endeavor for carbon neutrality by 2050 and its strategic response to the European energy crisis resulting from the Russia-Ukraine war. With a significant potential for hydrogen production, Canada’s hydrogen exports to Europe are poised to reshape its hydrogen supply chains downstream (HSCD). Through a systematic review of 39 papers published before October 2023, our examination explores HSCD components, decision levels, and sustainability perspectives. Consequently, we offer recommendations for scientific, legislative, and industrial sectors for forward horizons. Additionally, this study proposes future research avenues for similar systematic review papers.

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“…To meet the residential energy demand and, at the same time, ensure the decarbonisation of the energy infrastructure, hydrogen-based cogeneration systems might represent a viable solution; indeed, hydrogen produced with renewable sources, known as "green hydrogen", can be used as energy vector to store energy for medium-long term periods as well as solve the variability issue of renewable sources that leads to grid instability. Maestre et al [4] provided an analysis of standalone Renewable Hydrogen-based Systems (RHSs) focusing on both the residential and building sectors. The analysed pilot plants reflected the possibility of achieving 100% energy self-sufficiency; however, the system is still not costcompetitive with current electricity grid prices, and economic incentives are needed to deploy this technology further.…”

Section: Introductionmentioning

confidence: 99%

Energy analysis of a hydrogen integrated system in the residential sector

Mennilli,

Jin,

Rossi

et al. 2023

J. Phys.: Conf. Ser.

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Nowadays, buildings are responsible for almost 40% of global energy consumption, which is addressed by thermal (e.g., heating, cooling, and hot water) and electric (e.g., lighting and household appliances) loads. To meet the residential energy demand and, at the same time, ensure the decarbonisation of the energy infrastructure, hydrogen-based cogeneration systems might represent a viable solution. This work aims at evaluating the performance of a green hydrogen integrated system consisting of a Proton Exchange Membrane (PEM) electrolyser, hydrogen storage tanks, and a PEM fuel cell to meet both the electricity and, partially, the thermal energy demands of a condominium located in the center of Italy. The analysis considers a single energy scenario in which a Photovoltaic (PV) plant installed on the roof is directly connected with the hydrogen integrated system without any withdrawal from the national grid (e.g., off-grid operation mode). Results showed that, during the year, the user is completely self-sufficient from the electricity demand point of view. Furthermore, 22% of the thermal need can be satisfied through the fuel cell cogeneration system.

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The role of hydrogen‐based power systems in the energy transition of the residential sector

Cited by 24 publications

References 50 publications

Hydrogen Recovery from Coke Oven Gas. Comparative Analysis of Technical Alternatives

Hydrogen Recovery from Coke Oven Gas. Comparative Analysis of Technical Alternatives

A Comprehensive Systematic Overview of Canadian Hydrogen Supply Chains Downstream

Energy analysis of a hydrogen integrated system in the residential sector

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