To study the operational characteristics of inter-seasonal compressed air storage in aquifers, a coupled wellbore-reservoir 3D model of the whole subsurface system is built. The hydrodynamic and thermodynamic properties of the wellbore-reservoir system during the initial fill, energy injection, shut-in, and energy production periods are analysed. The effects
Semantic Scholar extracted view of "Techno-economic analysis of offshore isothermal compressed air energy storage in saline aquifers co-located with wind power" by J. Bennett et al. {Techno-economic analysis of offshore isothermal compressed air energy storage in saline aquifers co-located with wind power}, author={Jeffrey A. Bennett and
1 Inter-seasonal compressed air energy storage using saline aquifers Authors: Julien Mouli-Castillo*a, Mark Wilkinsona, Dimitri Mignardb, Christopher McDermotta, R. Stuart Haszeldinea, Zoe K. Shiptonc a Grant Institute, School of GeoSciences, University of Edinburgh, West Mains Road, Edinburgh, EH9 3JW, UK b Institute for Energy Systems, School of Engineering,
Meeting inter-seasonal fluctuations in electricity production or demand in a system dominated by renewable energy requires the cheap, reliable and accessible storage of energy on a scale that is currently challenging to achieve. Commercially mature compressed-air energy storage could be applied to porous rocks in sedimentary basins worldwide, where legacy data from hydrocarbon
Downloadable (with restrictions)! To study the operational characteristics of inter-seasonal compressed air storage in aquifers, a coupled wellbore-reservoir 3D model of the whole subsurface system is built. The hydrodynamic and thermodynamic properties of the wellbore-reservoir system during the initial fill, energy injection, shut-in, and energy production periods
In PM-CAES, compressed air would displace saline water within the micrometre-scale pores of the aquifers. One competing use for this resource is geological carbon storage, although some...
Inter-seasonal compressed air energy storage in aquifers (IS-CAESA) was first proposed by Mouli-Castillo et al. [7], who pointed out that safe storage of hundreds of millions of cubic meters of air is necessary if significant inter-seasonal storage is to be achieved. The IS-CAESA system is divided into a surface energy storage plant and an
Table 4-6: Parameters used for the sensitivity analysis of the PM-CAES power plant. - "Assessing the potential for Compressed Air Energy Storage using the offshore UK saline aquifer resource"
Compressed-air energy storage could be a useful inter-seasonal storage resource to support highly renewable power systems. This study presents a modelling approach to assess the potential for such storage in porous rocks and, applying it to the UK, finds availability of up to 96 TWh in offshore saline aquifers.
To study the operational characteristics of inter-seasonal compressed air storage in aquifers, a coupled wellbore-reservoir 3D model of the whole subsurface system is built.
It is well known that energy storage technologies are essential to increase the flexibility and capacity of renewable energy supply. Compressed air energy storage (CAES) [1] [2][3] technology has
When a saline aquifer is used for air storage, the air displaces the brine and creates an air plume. Another advantage of saline aquifers is that the storage duration can be increased without altering the machinery or wellbore, only by injecting more air and increasing the size of the air plume. Inter-seasonal compressed-air energy storage
Meeting inter-seasonal fluctuations in electricity production or demand in a system dominated by renewable energy requires the cheap, reliable and accessible storage of energy on a scale that is currently challenging to achieve.
Meeting inter-seasonal fluctuations in electricity production or demand in a system dominated by renewable energy requires the cheap, reliable and accessible storage of energy on a scale that is currently challenging to achieve.
Given these geographic and storage capacity constraints, there is a need to expand the search for storage. Porous media compressed air energy storage (PM-CAES), where the air is stored under
Techno-economic analysis of offshore isothermal compressed air energy storage in saline aquifers co-located with wind power. Author links open overlay panel Jeffrey A. Bennett a, Juliet G. Simpson b, Chao Qin b, Inter-seasonal compressed-air energy storage using saline aquifers. Nat Energy, 4 (2019), pp. 131-139, 10.1038/s41560-018-0311-0.
This document presents a modeling approach to estimate the potential for compressed-air energy storage (CAES) using porous rock formations called saline aquifers. The modeling approach combines three sub-models: 1) a geological porous rock store model to simulate air injection and storage, 2) an analytical well model linking the store to surface facilities, and 3) a numerical
Techno-economic analysis of offshore isothermal compressed air energy storage in saline aquifers co-located with wind power. This is the first study to quantify the efficiency of an isothermal compressed air energy storage system using a saline aquifer for air storage. The framework presented here may be applicable to any site suitable for
Inter-seasonal compressed-air energy storage using saline aquifers. Julien Mouli-Castillo (), Abstract Meeting inter-seasonal fluctuations in electricity production or demand in a system dominated by renewable energy requires the cheap, reliable and accessible storage of energy on a scale that is currently challenging to achieve
Downloadable (with restrictions)! Meeting inter-seasonal fluctuations in electricity production or demand in a system dominated by renewable energy requires the cheap, reliable and accessible storage of energy on a scale that is currently challenging to achieve. Commercially mature compressed-air energy storage could be applied to porous rocks in sedimentary basins
The promise and challenges of utility-scale compressed air energy storage in aquifers. Appl. Energy, 286 (2021), pp. 1-15. Inter-seasonal compressed-air energy storage using saline aquifers. Thermodynamic analysis of a compressed carbon dioxide energy storage system using two saline aquifers at different depths as storage reservoirs.
"Inter-seasonal compressed-air energy storage using saline aquifers," Nature Energy, Nature, vol. 4(2), pages 131-139, "Techno-economic analysis of offshore isothermal compressed air energy storage in saline aquifers co-located with wind power," Applied Energy, Elsevier, vol. 303(C). Full references (including those not matched with items
Request PDF | Assessing the potential for Compressed Air Energy Storage using the offshore UK saline aquifer resource | In the context of the development of renewable energy sources in the U.K
In the context of the development of renewable energy sources in the U.K., and of the increase in anthropogenic atmospheric CO2, it is important to develop alternative ways of providing energy to the community. The shift to renewable sources of electricity comes to a cost: variable generation. At present, an important part of the renewable electricity capacity is being
Meeting inter-seasonal fluctuations in electricity production or demand in a system dominated by renewable energy requires the cheap, reliable and accessible storage of energy on a scale that is currently challenging to achieve. Commercially mature compressed-air energy storage could be applied to porous rocks in sedimentary basins worldwide, where legacy data from hydrocarbon
Meeting inter-seasonal fluctuations in electricity production or demand in a system dominated by renewable energy requires the cheap, reliable and accessible storage of energy on a scale that is currently challenging to achieve. Commercially mature compressed-air energy storage could be applied to porous rocks in sedimentary basins worldwide, where
bon exploration are available, and if geographically close to renewable energy sources. Here we present a modelling approach to predict the potential for compressed-air energy storage in porous rocks.
The operation of aquifer compressed CO 2 storage systems was influenced by thermodynamic (T), hydraulic (H) and chemical (C) processes. Hao et al. [21] conducted thermodynamic and sensitivity analyses of a compressed transcritical CO 2 power storing system with an aquifer as the energy storage zone, and the findings showed that the heat recovery
Inter-seasonal compressed-air energy storage using saline aquifers. Nat Energy 2019; 4: 131–139. 10.1038/s41560-018-0311-0 Search in Google Scholar Kang Y, Yang F, Liu S. Method of quantified optimization selection of aquifer traps as underground natural gas storages for peak demand modulation.
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