Improvement of power system frequency stability using alkaline electrolysis plants

“…Other electrolytic processes that have often been considered for DSM implementation are the obtaining of high‐purity aluminum or chlorine by Geres et al, 139 Kiaee et al, 134 Wang et al, 140 Otashu et al, 141 Simkoff and Baldea, 142 and Brée et al, 143 (see also Table 1 in Section 3). Aluminium and chlor‐alkali electrolysis play a major role in DSM research, due to their high production rate and specific energy consumption.…”

Section: Literature Review On Dsm Options In Biofuel Production Plantsmentioning

confidence: 99%

Options for demand side management in biofuel production: A systematic review

Röder

Gröngröft

Grünewald

et al. 2022

Intl J of Energy Research

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Summary To minimize the emissions from the production of biofuels, one aim is to reduce or completely replace the amount of fossil fuels used for internal process energy. A conceivable solution is the use of volatile renewable energy sources such as solar and wind. The fluctuation of these energy sources in their production inevitably leads to a transformation to flexible power consumption, commonly referred to as demand side management (DSM). In current research, a wide range of processes has been identified to be suitable for DSM application. Although biorefineries have not yet been tested for DSM application, it is noteworthy that many of the DSM suitable processes are employed in biofuel plants. Thus, this contribution offers a comprehensive overview of DSM options drawn from literature with a special focus on process steps, which have been analysed for operational and capacity flexibility and which are found in or are transferable to biorefinery systems. By identifying process steps in biofuel production that can be operated flexibly, this extensive literature study helps to find technical restrictions limiting the overall process flexibility. The scope of this contribution is to create an overview of which processes in biofuel production can be considered for DSM use.

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“…Majority of H 2 is currently produced from natural gas via the reforming process. However, renewable ways of obtaining H 2 are available, including water electrolysis via renewable electricity, such as solar photovoltaic (PV) and wind turbines, potentially offering grid balancing services as well [98][99][100][101]. Hydroelectric energy [102], ocean thermal [103,104] and geothermal energy [105,106] could also be utilized to produce hydrogen sustainably.…”

Section: Renewable H 2 Sourcesmentioning

confidence: 99%

A Review of The Methanol Economy: The Fuel Cell Route

et al. 2020

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This review presents methanol as a potential renewable alternative to fossil fuels in the fight against climate change. It explores the renewable ways of obtaining methanol and its use in efficient energy systems for a net zero-emission carbon cycle, with a special focus on fuel cells. It investigates the different parts of the carbon cycle from a methanol and fuel cell perspective. In recent years, the potential for a methanol economy has been shown and there has been significant technological advancement of its renewable production and utilization. Even though its full adoption will require further development, it can be produced from renewable electricity and biomass or CO2 capture and can be used in several industrial sectors, which make it an excellent liquid electrofuel for the transition to a sustainable economy. By converting CO2 into liquid fuels, the harmful effects of CO2 emissions from existing industries that still rely on fossil fuels are reduced. The methanol can then be used both in the energy sector and the chemical industry, and become an all-around substitute for petroleum. The scope of this review is to put together the different aspects of methanol as an energy carrier of the future, with particular focus on its renewable production and its use in high-temperature polymer electrolyte fuel cells (HT-PEMFCs) via methanol steam reforming.

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Improvement of power system frequency stability using alkaline electrolysis plants

Cited by 6 publications

References 18 publications

Modeling alkaline water electrolysis for power-to-x applications: A scheduling approach

Modeling alkaline water electrolysis for power-to-x applications: A scheduling approach

Options for demand side management in biofuel production: A systematic review

A Review of The Methanol Economy: The Fuel Cell Route

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