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Garvey, S. D.; Eames, P. C.; Wang, J. H.; Pimm, A. J.; Waterson, M.; MacKay, Robert S.; Giulietti, M.; Flatley, Lisa; Thomson, M.; Barton, J.; Evans, David; Busby, J.; Garvey, J. E. (2015)
Publisher: Elsevier Ltd.
Journal: Energy Policy
Languages: English
Types: Article
Subjects: Energy(all), Management, Monitoring, Policy and Law, TJ, HD
Generation-integrated energy storage (GIES) systems store energy at some point along the transformation between the primary energy form and electricity. Instances exist already in natural hydro power, biomass generation, wave power, and concentrated solar power. GIES systems have been proposed for wind, nuclear power and they arise naturally in photocatalysis systems that are in development. GIES systems can compare very favourably in both performance and total cost against equivalent non-integrated systems comprising both generation and storage. Despite this, they have not hitherto been recognised as a discrete class of systems. Consequently policy decisions affecting development or demonstration projects and policy approaches concerning low-carbon generation are not fully informed. This paper highlights that policy structures exist militating against the development and introduction of GIES systems-probably to the detriment of overall system good.\ud
  • The results below are discovered through our pilot algorithms. Let us know how we are doing!

    • Barnacle, M., Robertson, E., Galloway, S., Barton, J., Ault, G., 2013. Modelling generation and infrastructure requirements for transition pathways. Energy Policy 52, 60-75.
    • Barton, J., Huang, S., Infield, D., Leach, M., Ogunkunle, D., Torriti, J., Thomson, M., 2013. The evolution of electricity demand and the role for demand side participation, in buildings and transport. Energy Policy 52, 85-102.
    • Bergan, P.G., Greiner, C.J., 2014. A new type of large scale energy storage. Energy Procedia 58, 152-159.
    • Denholm, P., Hand, M., 2011. Grid flexibility and storage required to achieve very high penetration of variable renewable electricity. Energy Policy 39, 1817-1830.
    • Denholm, P., King, J.C., Kutcher, C.F., Wilson, P.P.H., 2012. Decarbonising the electric sector: combining renewable energy and nuclear energy using thermal storage. Energy Policy 44, 301-311.
    • Dunn, R., 2010. A Global Review of Concentrated Solar Power. Solar2010 Conference, Canberra.
    • Garvey, S.D., 2010. Structural capacity and the 20 MW wind turbine. Proc. IMechE Pt. A J. Power Energy 224 (224), 1027-1043.
    • Garvey, S.D., 2014. An energy-storing wind turbine would provide power 24/7. IEEE Spectrum Online Magazine. 〈http://spectrum.ieee.org/energywise/energy/re newables/an-energystoring-wind-turbine-would-provide-power-247〉.
    • Garvey, S.D., Pimm, A.J., Buck, J.A., Woolhead, S., Liew, K.W., Kantharaj, B., Garvey, J.E., Brewster, B., 2015. Analysis of a wind turbine power transmission system with intrinsic energy storage capability. Wind Eng. 39 (2), 149-174. http://dx.doi.org/ 10.1260/0309-524X.39.2.149 (Open access paper).
    • Ingersoll, E., 2008. Wind Turbine System. Patent Application US20080050234-A1.
    • Ismail, A.A., Bahnemann, D.W., 2014. Photochemical splitting of water for hydrogen production by photocatalysis: a review. Sol. Energy Mater. Sol. Cells 128, 85-101.
    • Krohn, S., Morthorst, P.E., Awerbuch, S., 2009. The economics of wind energy. A report by the EWEA.
    • Lee, J.E., 2012. On-Demand Generation of Electricity from Stored Wind Energy. Patent Application, US2012326445-A1.
    • McKenna, E., Thomson, M., 2014. Impact of wind curtailment and storage on the Irish Power System in 2020 renewable electricity targets: a free open-source Electricity System Balancing and Market (ESBM) Model. In: Proceedings of the 3rd IET Renewable Power Generation Conference, Naples.
    • Newbery, D., 2010. Market design for a large share of wind power. Energy Policy 38, 3131-3134.
    • Nicolosi, M., 2010. Wind power integration and power system flexibility - an empirical analysis of extreme events in Germany under the new negative price regime. Energy Policy 38 (11), 7257-7268.
    • Paraschiv, F., Erni, D., Pietsch, R., 2014. The impact of renewable energies on EEX day-ahead electricity prices. Energy Policy 73, 196-210.
    • Ren, Z., Wang, H., Chen, G., Li, X., Esfarjani, K., 2014. High-temperature thermal energy storage module for use in nuclear power plants, Patent Application: US2014109895.
    • Salter, S.H., Rea, M., 1984 Hydraulics for Wind. European Wind Energy Conference, Hamburg, 534-541, October 1984.
    • Strbac, G., Aunedi, M., Pudjianto, D., Djapic, P., Teng, F., Sturt, A., Jackravut, D., Sansom, R., Yufit, V., Brandon, N., 2012. Strategic Assessment of the Role and Value of Energy Storage Systems in the UK Low Carbon Energy Future, Report for Carbon Trust.
    • Taylor, P.G., Bolton, R., Stone, D., Upham, P., 2013. Developing pathways for energy storage in the UK using a co-evolutionary framework. Energy Policy 63, 230-243.
    • Toke, D., 2011. UK Electricity Market Reform - revolution or much ado about nothing? Energy Policy 39 (12), 7609-7611.
    • Wagner, M., 2012. Banking on Energy - Investing in Energy Storage Presentation given at IMechE Seminar on Energy Storage, March 13, 2012.
    • Whittaker, T., Folley, M., 2012. Nearshore oscillating wave surge converters and development of oyster. Philos. Trans. R. Soc. A 370, 345-364.
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