Economic analysis of a Power-to-Gas pilot plant within the Italian energy transition framework

Today, the hydrogen is considered an essential element in speeding up the energy transition and generate important environmental benefits. Not all hydrogen is the same, though. The “green hydrogen”, which is produced using renewable energy and electrolysis to split water, is really and completely sustainable for stationary and mobile applications. This paper is focused on the techno-economic analysis of an on-site hydrogen refueling station (HRS) in which the green hydrogen production is assured by a PV plant that supplies electricity to an alkaline electrolyzer. The hydrogen is stored in low pressure tanks (200 bar) and then is compressed at 900 bar for refueling FCHVs by using the innovative technology of the ionic compressor. From technical point of view, the components of the HRS have been sized for assuring a maximum capacity of 450 kg/day. In particular, the PV plant (installed in the south of Italy) has a size of 8MWp and supplies an alkaline electrolyzer of 2.1 MW. A Li-ion battery system (size 3.5 MWh) is used to store the electricity surplus and the grid-connection of the PV plant allows to export the electricity excess that cannot be stored in the battery system. The economic analysis has been performed by estimating the levelized cost of hydrogen (LCOH) that is an important economic indicator based on the evaluation of investment, operational & maintenance and replacement costs. Results highlighted that the proposed on-site configuration in which the green hydrogen production is assured, is characterized by a LCOH of 10.71 €/kg.

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Stochastic techno-economic analysis of H2 production from power-to-gas using a high-pressure PEM water electrolyzer for a small-scale H2 fueling station

Sustainable Energy & Fuels ◽

10.1039/c9se00275h ◽

2019 ◽

Vol 3 (9) ◽

pp. 2521-2529 ◽

Cited By ~ 3

Author(s):

Boreum Lee ◽

Hyunjun Lee ◽

Juheon Heo ◽

Changhwan Moon ◽

Sangbong Moon ◽

...

Keyword(s):

High Pressure ◽

Economic Analysis ◽

H2 Production ◽

Economic Feasibility ◽

Small Scale ◽

Power To Gas ◽

Pem Water Electrolyzer ◽

Fueling Station

A stochastic techno-economic analysis is conducted to evaluate economic feasibility for power-to-gas technology using a high-pressure PEM water electrolyzer.

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A Pilot Plant for Energy Harvesting from Falling Water in Drainpipes. Technical and Economic Analysis

Computational Science and Its Applications – ICCSA 2019 - Lecture Notes in Computer Science ◽

10.1007/978-3-030-24311-1_16 ◽

2019 ◽

pp. 233-242

Author(s):

Giacomo Viccione ◽

Antonio Nesticò ◽

Federica Vernieri ◽

Maurizio Cimmino

Keyword(s):

Energy Harvesting ◽

Economic Analysis ◽

Pilot Plant ◽

Technical And Economic Analysis

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Techno-economic analysis of oxy-fuel power plant for coal and biomass combined with a power-to-gas plant

Energy for Sustainable Development ◽

10.1016/j.esd.2021.06.007 ◽

2021 ◽

Vol 64 ◽

pp. 47-58

Author(s):

Geun Sohn ◽

Ju-yeol Ryu ◽

Hyemin Park ◽

Sungho Park

Keyword(s):

Power Plant ◽

Economic Analysis ◽

Power To Gas

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Techno-economic analysis of adiabatic four-stage CO2 methanation process for optimization and evaluation of power-to-gas technology

International Journal of Hydrogen Energy ◽

10.1016/j.ijhydene.2021.04.015 ◽

2021 ◽

Author(s):

Sungho Park ◽

Kwangsoon Choi ◽

Changhyeong Lee ◽

Suhyun Kim ◽

Youngdon Yoo ◽

...

Keyword(s):

Economic Analysis ◽

Co2 Methanation ◽

Power To Gas

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The role of gases in the European energy transition

Russian Journal of Economics ◽

10.32609/j.ruje.6.55105 ◽

2020 ◽

Vol 6 (4) ◽

pp. 390-405

Author(s):

Jonathan Stern

Keyword(s):

Natural Gas ◽

Carbon Capture ◽

Large Scale ◽

Carbon Capture And Storage ◽

Energy Transition ◽

Regulatory Frameworks ◽

Gas Market ◽

Power To Gas ◽

The Eu

The role of gases in the energy transition is a different, and much more immediate, issue in the EU, compared with other global regions. Net zero targets for 2050 mean that in order to retain the gas market and the extensive network infrastructure which has been developed, zero carbon gases will need to be developed, and natural gas (methane) will need to be decarbonized. Maximum availability of biomethane and hydrogen from power to gas is estimated at 100–150 billion cubic meters by 2050 (or around 25–30% of gas demand in the late 2010s. Therefore, large scale hydrogen production from reforming methane with carbon capture and storage (CCS), or pyrolysis, will be needed to maintain anything close to current demand levels. Costs of biomethane and hydrogen options are several times higher than prices of natural gas in 2019–2020. Significant financial support for decarbonization technologies — from governments and regulators — will therefore be needed in the 2020s, if they are to be available on a large scale in the 2030s and 2040s. If the EU gas community fails to advance convincing decarbonized narratives backed by investments which allow for commercialization of renewable gas and methane decarbonization technologies; and/or governments fail to create the necessary legal/fiscal and regulatory frameworks to support these technologies, then energy markets will progressively move away from gases and towards electrification.

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Power-to-Gas and Power-to-X—The History and Results of Developing a New Storage Concept

Energies ◽

10.3390/en14206594 ◽

2021 ◽

Vol 14 (20) ◽

pp. 6594

Author(s):

Michael Sterner ◽

Michael Specht

Keyword(s):

Large Scale ◽

Energy Transition ◽

Water Electrolysis ◽

Process Engineering ◽

Green Energy ◽

Energy Problem ◽

Co2 Methanation ◽

Synthetic Natural Gas ◽

Initial Idea ◽

Power To Gas

Germany’s energy transition, known as ‘Energiewende’, was always very progressive. However, it came technically to a halt at the question of large-scale, seasonal energy storage for wind and solar, which was not available. At the end of the 2000s, we combined our knowledge of both electrical and process engineering, imitated nature by copying photosynthesis and developed Power-to-Gas by combining water electrolysis with CO2-methanation to convert water and CO2 together with wind and solar power to synthetic natural gas. Storing green energy by coupling the electricity with the gas sector using its vast TWh-scale storage facility was the solution for the biggest energy problem of our time. This was the first concept that created the term ‘sector coupling’ or ‘sectoral integration’. We first implemented demo sites, presented our work in research, industry and ministries, and applied it in many macroeconomic studies. It was an initial idea that inspired others to rethink electricity as well as eFuels as an energy source and energy carrier. We developed the concept further to include Power-to-Liquid, Power-to-Chemicals and other ways to ‘convert’ electricity into molecules and climate-neutral feedstocks, and named it ‘Power-to-X’at the beginning of the 2010s.

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