Energy storage using underground mining caverns

Łukasz Szabłowski; Piotr Krawczyk; Krzysztof Badyda

doi:10.1051/e3sconf/201910801004

All issues

Volume 108 (2019)

E3S Web Conf., 108 (2019) 01004

References

Open Access

Issue		E3S Web Conf. Volume 108, 2019 Energy and Fuels 2018


Article Number		01004
Number of page(s)		10
Section		Energy
DOI		https://doi.org/10.1051/e3sconf/201910801004
Published online		05 July 2019

K. Badyda, J. Milewski, Compressed air storage systems as a peak looping power station in Polish conditions, Proceeding of International Conference on Power Engineering, ICOPE 2009 (2009) [Google Scholar]
K. Badyda, J. Milewski, Magazynowanie energii z wykorzystaniem układów CAES. Współczesne problemy energetyki gazowej i gazownictwa. IV Konferencja Energetyka Gazowa [Energy storage using CAES systems. Contemporary problems of gas energy and gas industry. The 4th Gas Power Engineering Conference]. Wydawnictwo Instytutu Techniki Cieplnej Politechniki Śląskiej, Gliwice (pp. 371–388) (2009) [Google Scholar]
K. Badyda, J. Milewski, Thermodynamic analysis of compressed air energy storage working conditions, Archives of Energetics, 42 (1), 53–68 (2012) [Google Scholar]
F. Crotogino, K.-U. Mohmeyer, R. Scharf, Huntorf CAES: More than 20 years of successful operation, Orlando, Florida, USA. (2001) [Google Scholar]
A. Gajewski, A. Wójcicki, Międzynarodowy projekt CASTOR a problematyka sekwestracji, czyli ujmowania i magazynowania CO2 w Polsce [International Project CASTOR and the problem of sequestration, or capture and storage of CO2 in Poland], Przegląd Geologiczny, 54 (4), 270–272 (2005) [Google Scholar]
J. E. Mason, C. L. Archer, Baseload electricity from wind via compressed air energy storage (CAES), Renewable and Sustainable Energy Reviews, 16 (2), 1099–1109 (2012) [CrossRef] [Google Scholar]
H. Lund, G. Salgi, B. Elmegaard, A. N. Andersen, Optimal operation strategies of compressed air energy storage (CAES) on electricity spot markets with fluctuating prices, Applied Thermal Engineering, 29 (5), 799–806 (2009) [Google Scholar]
X. Luo, J. Wang, M. Dooner, J. Clarke, C. Krupke, Overview of current development in compressed air energy storage technology, Energy Procedia, 62, 603–611 (2014) [Google Scholar]
M. Satkin, Y. Noorollahi, M. Abbaspour, H. Yousefi, Multi criteria site selection model for wind-compressed air energy storage power plants in Iran, Renewable and Sustainable Energy Reviews, 32, 579–590 (2014) [CrossRef] [Google Scholar]
A. Yucekaya, The operational economics of compressed air energy storage systems under uncertainty, Renewable and Sustainable Energy Reviews, 22, 298–305 (2013) [CrossRef] [Google Scholar]
J. Kotowicz, M. Jurczyk, Wyznaczenie sprawności diabatycznych instalacji CAES [Efficiency of diabatic CAES instalation], Rynek Energii, 119 (4), 49–56 (2015) [Google Scholar]
W. Liu, L. Liu, L. Zhou, J. Huang, Y. Zhang, G. Xu, Y. Yang, Analysis and optimization of a compressed air energy storage-combined cycle system. Entropy, 16 (6), 3103–3120 (2014) [CrossRef] [Google Scholar]
P. Zhao, J. Wang, Y. Dai, Thermodynamic analysis of an integrated energy system based on compressed air energy storage (CAES) system and Kalina cycle, Energy Conversion and Management, 98, 161–172 (2015) [Google Scholar]
N. M. Jubeh, Y. S. H. Najjar, Green solution for power generation by adoption of adiabatic CAES system, Applied Thermal Engineering, 44, 85–89 (2012) [Google Scholar]
E. Barbour, D. Mignard, Y. Ding, Y. Li, Adiabatic Compressed Air Energy Storage with packed bed thermal energy storage, Applied Energy, 155, 804–815 (2015) [Google Scholar]
D. Wolf, M. Budt, LTA-CAES-a low-temperature approach to adiabatic compressed air energy storage, Applied Energy, 125, 158–164 (2014) [Google Scholar]
F. De Bosio, V. Verda, Thermoeconomic analysis of a Compressed Air Energy Storage (CAES) system integrated with a wind power plant in the framework of the IPEX Market, Applied Energy, 152, 173–182 (2015) [Google Scholar]
E. Jannelli, M. Minutillo, A. L. Lavadera, G. Falcucci, A small-scale CAES (compressed air energy storage) system for stand-alone renewable energy power plant for a radio base station: A sizing-design methodology, Energy, 78, 313–322 (2014) [CrossRef] [Google Scholar]
B. Kantharaj, S. Garvey, A. Pimm, Thermodynamic analysis of a hybrid energy storage system based on compressed air and liquid air. Sustainable Energy Technologies and Assessments, 11, 159–164 (2014) [CrossRef] [Google Scholar]
B. Kantharaj, S. Garvey, A. Pimm, Compressed air energy storage with liquid air capacity extension, Applied Energy, 157, 152–164 (2015) [Google Scholar]
P. Krawczyk, Ł. Szabłowski, K. Badyda, S. Karellas, E. Kakaras, Impact of selected parameters on performance of the Adiabatic Liquid Air Energy Storage system, Journal of Power Technologies, 96 (4), 238–244 (2016) [Google Scholar]
P. Krawczyk, Ł. Szabłowski, S. Karellas, E. Kakaras, K. Badyda, Comparative thermodynamic analysis of compressed air and liquid air energy storage systems, Energy, 142, 46–54 (2018) [CrossRef] [Google Scholar]
L. Szablowski, P. Krawczyk, K. Badyda, S. Karellas, E. Kakaras, W. Bujalski, Energy and exergy analysis of adiabatic compressed air energy storage system, Energy, 138, 1218 (2017) [CrossRef] [Google Scholar]
J. Milewski, K. Badyda, Ł. Szabłowski, Compressed Air Energy Storage Systems, Journal of Power Technologies, 96 (4), 245–260 (2016) [Google Scholar]
HYSYS 3.2 Dynamic Modeling. Hyprotech (2003) [Google Scholar]
HYSYS 3.2 Operations Guide (2003) [Google Scholar]
Ł. Szabłowski, J. Milewski, Dynamic analysis of compressed air energy storage in the car. Journal of Power Technologies, 91 (1), 23–36 (2011) [Google Scholar]
P. Denholm, G. L. Kulcinski, Life cycle energy requirements and greenhouse gas emissions from large scale energy storage systems, Energy Conversion and Management, 45 (13), 2153–2172 (2004) [Google Scholar]

Current usage metrics show cumulative count of Article Views (full-text article views including HTML views, PDF and ePub downloads, according to the available data) and Abstracts Views on Vision4Press platform.

Data correspond to usage on the plateform after 2015. The current usage metrics is available 48-96 hours after online publication and is updated daily on week days.

Initial download of the metrics may take a while.

[1] K. Badyda, J. Milewski, Compressed air storage systems as a peak looping power station in Polish conditions, Proceeding of International Conference on Power Engineering, ICOPE 2009 (2009) [Google Scholar]

[2] K. Badyda, J. Milewski, Magazynowanie energii z wykorzystaniem układów CAES. Współczesne problemy energetyki gazowej i gazownictwa. IV Konferencja Energetyka Gazowa [Energy storage using CAES systems. Contemporary problems of gas energy and gas industry. The 4th Gas Power Engineering Conference]. Wydawnictwo Instytutu Techniki Cieplnej Politechniki Śląskiej, Gliwice (pp. 371–388) (2009) [Google Scholar]

[3] K. Badyda, J. Milewski, Thermodynamic analysis of compressed air energy storage working conditions, Archives of Energetics, 42 (1), 53–68 (2012) [Google Scholar]

[4] F. Crotogino, K.-U. Mohmeyer, R. Scharf, Huntorf CAES: More than 20 years of successful operation, Orlando, Florida, USA. (2001) [Google Scholar]

[5] A. Gajewski, A. Wójcicki, Międzynarodowy projekt CASTOR a problematyka sekwestracji, czyli ujmowania i magazynowania CO2 w Polsce [International Project CASTOR and the problem of sequestration, or capture and storage of CO2 in Poland], Przegląd Geologiczny, 54 (4), 270–272 (2005) [Google Scholar]

[6] J. E. Mason, C. L. Archer, Baseload electricity from wind via compressed air energy storage (CAES), Renewable and Sustainable Energy Reviews, 16 (2), 1099–1109 (2012) [CrossRef] [Google Scholar]

[7] H. Lund, G. Salgi, B. Elmegaard, A. N. Andersen, Optimal operation strategies of compressed air energy storage (CAES) on electricity spot markets with fluctuating prices, Applied Thermal Engineering, 29 (5), 799–806 (2009) [Google Scholar]

[8] X. Luo, J. Wang, M. Dooner, J. Clarke, C. Krupke, Overview of current development in compressed air energy storage technology, Energy Procedia, 62, 603–611 (2014) [Google Scholar]

[9] M. Satkin, Y. Noorollahi, M. Abbaspour, H. Yousefi, Multi criteria site selection model for wind-compressed air energy storage power plants in Iran, Renewable and Sustainable Energy Reviews, 32, 579–590 (2014) [CrossRef] [Google Scholar]

[10] A. Yucekaya, The operational economics of compressed air energy storage systems under uncertainty, Renewable and Sustainable Energy Reviews, 22, 298–305 (2013) [CrossRef] [Google Scholar]

[11] J. Kotowicz, M. Jurczyk, Wyznaczenie sprawności diabatycznych instalacji CAES [Efficiency of diabatic CAES instalation], Rynek Energii, 119 (4), 49–56 (2015) [Google Scholar]

[12] W. Liu, L. Liu, L. Zhou, J. Huang, Y. Zhang, G. Xu, Y. Yang, Analysis and optimization of a compressed air energy storage-combined cycle system. Entropy, 16 (6), 3103–3120 (2014) [CrossRef] [Google Scholar]

[13] P. Zhao, J. Wang, Y. Dai, Thermodynamic analysis of an integrated energy system based on compressed air energy storage (CAES) system and Kalina cycle, Energy Conversion and Management, 98, 161–172 (2015) [Google Scholar]

[14] N. M. Jubeh, Y. S. H. Najjar, Green solution for power generation by adoption of adiabatic CAES system, Applied Thermal Engineering, 44, 85–89 (2012) [Google Scholar]

[15] E. Barbour, D. Mignard, Y. Ding, Y. Li, Adiabatic Compressed Air Energy Storage with packed bed thermal energy storage, Applied Energy, 155, 804–815 (2015) [Google Scholar]

[16] D. Wolf, M. Budt, LTA-CAES-a low-temperature approach to adiabatic compressed air energy storage, Applied Energy, 125, 158–164 (2014) [Google Scholar]

[17] F. De Bosio, V. Verda, Thermoeconomic analysis of a Compressed Air Energy Storage (CAES) system integrated with a wind power plant in the framework of the IPEX Market, Applied Energy, 152, 173–182 (2015) [Google Scholar]

[18] E. Jannelli, M. Minutillo, A. L. Lavadera, G. Falcucci, A small-scale CAES (compressed air energy storage) system for stand-alone renewable energy power plant for a radio base station: A sizing-design methodology, Energy, 78, 313–322 (2014) [CrossRef] [Google Scholar]

[19] B. Kantharaj, S. Garvey, A. Pimm, Thermodynamic analysis of a hybrid energy storage system based on compressed air and liquid air. Sustainable Energy Technologies and Assessments, 11, 159–164 (2014) [CrossRef] [Google Scholar]

[20] B. Kantharaj, S. Garvey, A. Pimm, Compressed air energy storage with liquid air capacity extension, Applied Energy, 157, 152–164 (2015) [Google Scholar]

[21] P. Krawczyk, Ł. Szabłowski, K. Badyda, S. Karellas, E. Kakaras, Impact of selected parameters on performance of the Adiabatic Liquid Air Energy Storage system, Journal of Power Technologies, 96 (4), 238–244 (2016) [Google Scholar]

[22] P. Krawczyk, Ł. Szabłowski, S. Karellas, E. Kakaras, K. Badyda, Comparative thermodynamic analysis of compressed air and liquid air energy storage systems, Energy, 142, 46–54 (2018) [CrossRef] [Google Scholar]

[23] L. Szablowski, P. Krawczyk, K. Badyda, S. Karellas, E. Kakaras, W. Bujalski, Energy and exergy analysis of adiabatic compressed air energy storage system, Energy, 138, 1218 (2017) [CrossRef] [Google Scholar]

[24] J. Milewski, K. Badyda, Ł. Szabłowski, Compressed Air Energy Storage Systems, Journal of Power Technologies, 96 (4), 245–260 (2016) [Google Scholar]

[25] HYSYS 3.2 Dynamic Modeling. Hyprotech (2003) [Google Scholar]

[26] HYSYS 3.2 Operations Guide (2003) [Google Scholar]

[27] Ł. Szabłowski, J. Milewski, Dynamic analysis of compressed air energy storage in the car. Journal of Power Technologies, 91 (1), 23–36 (2011) [Google Scholar]

[28] P. Denholm, G. L. Kulcinski, Life cycle energy requirements and greenhouse gas emissions from large scale energy storage systems, Energy Conversion and Management, 45 (13), 2153–2172 (2004) [Google Scholar]