Increasing market opportunities for renewable energy technologies with innovations in aquifer thermal energy storage

Increasing market opportunities for renewable energy technologies with innovations in aquifer thermal energy storage

Heating and cooling using aquifer thermal energy storage (ATES) has hardly been applied outside the Netherlands, even though it could make a valuable contribution to the energy transition. The Climate-KIC project “Europe-wide Use of Energy from aquifers” – E-USE(aq) – aimed to pave the way for Europ...

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Veröffentlicht in:The Science of the total environment 2020-03, Vol.709, p.136142-136142, Article 136142
Hauptverfasser: Hoekstra, N., Pellegrini, M., Bloemendal, M., Spaak, G., Andreu Gallego, A., Rodriguez Comins, J., Grotenhuis, T., Picone, S., Murrell, A.J., Steeman, H.J., Verrone, A., Doornenbal, P., Christophersen, M., Bennedsen, L., Henssen, M., Moinier, S., Saccani, C.
Format: Artikel
Sprache:eng
Schlagworte:
Aquifer thermal energy storage
District heating and cooling
Geothermal energy
Heating and cooling
Photovoltaic-thermal module
Pilot plant
Remediation
Technological innovation
Water scarcity
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container_end_page 136142
container_issue
container_start_page 136142
container_title The Science of the total environment
container_volume 709
creator Hoekstra, N.
Pellegrini, M.
Bloemendal, M.
Spaak, G.
Andreu Gallego, A.
Rodriguez Comins, J.
Grotenhuis, T.
Picone, S.
Murrell, A.J.
Steeman, H.J.
Verrone, A.
Doornenbal, P.
Christophersen, M.
Bennedsen, L.
Henssen, M.
Moinier, S.
Saccani, C.
description Heating and cooling using aquifer thermal energy storage (ATES) has hardly been applied outside the Netherlands, even though it could make a valuable contribution to the energy transition. The Climate-KIC project “Europe-wide Use of Energy from aquifers” – E-USE(aq) – aimed to pave the way for Europe-wide application of ATES, through the realization and monitoring of six ATES pilot plants across five different EU countries. In a preceding paper, based on preliminary results of E-USE(aq), conclusions were already drawn, demonstrating how the barriers for this form of shallow geothermal energy can be overcome, and sometimes even leveraged as opportunities. Based on final pilot project results, key economic and environmental outcomes are now presented. This paper starts with the analysis of specific technological barriers: unfamiliarity with the subsurface, presumed limited compatibility with existing energy provision systems (especially district heating), energy imbalances and groundwater contamination. The paper then shows how these barriers have been tackled, using improved site investigation and monitoring technologies to map heterogeneous subsoils. In this way ATES can cost-efficiently be included in smart grids and combined with other sources of renewable (especially solar) energy, while at the same time achieving groundwater remediation. A comparative assessment of economic and environmental impacts of the pilots is included, to demonstrate the sustainability of ATES system with different renewables and renewable-based technologies. The paper concludes with an assessment of the market application potential of ATES, including in areas with water scarcity, and a review of climate beneficial impact. [Display omitted] •Aquifer Thermal Energy Storage can play an important role in the energy transition.•Barriers for ATES application can be overcome and turned into opportunities.•Cost-efficient green technology combinations make ATES much wider applicable.
doi_str_mv 10.1016/j.scitotenv.2019.136142
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The Climate-KIC project “Europe-wide Use of Energy from aquifers” – E-USE(aq) – aimed to pave the way for Europe-wide application of ATES, through the realization and monitoring of six ATES pilot plants across five different EU countries. In a preceding paper, based on preliminary results of E-USE(aq), conclusions were already drawn, demonstrating how the barriers for this form of shallow geothermal energy can be overcome, and sometimes even leveraged as opportunities. Based on final pilot project results, key economic and environmental outcomes are now presented. This paper starts with the analysis of specific technological barriers: unfamiliarity with the subsurface, presumed limited compatibility with existing energy provision systems (especially district heating), energy imbalances and groundwater contamination. The paper then shows how these barriers have been tackled, using improved site investigation and monitoring technologies to map heterogeneous subsoils. In this way ATES can cost-efficiently be included in smart grids and combined with other sources of renewable (especially solar) energy, while at the same time achieving groundwater remediation. A comparative assessment of economic and environmental impacts of the pilots is included, to demonstrate the sustainability of ATES system with different renewables and renewable-based technologies. The paper concludes with an assessment of the market application potential of ATES, including in areas with water scarcity, and a review of climate beneficial impact. 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In this way ATES can cost-efficiently be included in smart grids and combined with other sources of renewable (especially solar) energy, while at the same time achieving groundwater remediation. A comparative assessment of economic and environmental impacts of the pilots is included, to demonstrate the sustainability of ATES system with different renewables and renewable-based technologies. The paper concludes with an assessment of the market application potential of ATES, including in areas with water scarcity, and a review of climate beneficial impact. 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subjects Aquifer thermal energy storage
District heating and cooling
Geothermal energy
Heating and cooling
Photovoltaic-thermal module
Pilot plant
Remediation
Technological innovation
Water scarcity
title Increasing market opportunities for renewable energy technologies with innovations in aquifer thermal energy storage
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