This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Strielkowski W., Civín L., Tarkhanova E., Tvaronavičienė M., Petrenko Y. (2021). Renewable Energy in the Sustainable Development of Electrical Power Sector: A Review. Energies 14(24).StrielkowskiW.CivínL.TarkhanovaE.TvaronavičienėM.PetrenkoY.2021Renewable Energy in the Sustainable Development of Electrical Power Sector: A Review142410.3390/en14248240Search in Google Scholar
REN21. 2021. Renewables 2021 Global Status Report (Paris: REN21 Secretariat). ISBN 978-3-948393-03-8. Available online: www.ren21.net (accessed on 14 February 2022).REN212021ParisREN21 SecretariatISBN 978-3-948393-03-8. Available online: www.ren21.net (accessed on 14 February 2022).Search in Google Scholar
National Energy System reports. Available online: https://www.pse.pl/dane-systemowe/funkcjonowaniekse/raporty-roczne-z-funkcjonowania-kse-zarok/raporty-za-rok-2020 (accessed on 14 February 2022).Available online: https://www.pse.pl/dane-systemowe/funkcjonowaniekse/raporty-roczne-z-funkcjonowania-kse-zarok/raporty-za-rok-2020 (accessed on 14 February 2022).Search in Google Scholar
Jurczyk M., Węcel D., Uchman W., Skorek-Osikowska A. (2022). Assessment of operational performance for an integrated “power to synthetic natural gas” system. Energies 15(1).JurczykM.WęcelD.UchmanW.Skorek-OsikowskaA.2022Assessment of operational performance for an integrated “power to synthetic natural gas” system15110.3390/en15010074Search in Google Scholar
Kotowicz J., Jurczyk M., Węcel D. (2021). The possibilities of cooperation between a hydrogen generator and a wind farm. International Journal of Hydrogen Energy 46(10).KotowiczJ.JurczykM.WęcelD.2021The possibilities of cooperation between a hydrogen generator and a wind farm461010.1016/j.ijhydene.2020.11.246Search in Google Scholar
Kotowicz J., Jurczyk M (2019). Economic analysis of an installation producing hydrogen through water electrolysis. Journal of Power Technologies 99(3), 170–175.KotowiczJ.JurczykM2019Economic analysis of an installation producing hydrogen through water electrolysis993170175Search in Google Scholar
Bartela Ł. (2020). A hybrid energy storage system using compressed air and hydrogen as the energy carrier. Energy 196.BartelaŁ.2020A hybrid energy storage system using compressed air and hydrogen as the energy carrier19610.1016/j.energy.2020.117088Search in Google Scholar
Koceman A.S., Modi V. (2017). Value of pumped hydro storage in a hybrid energy generation allocation system. Applied Energy 205, 1202–1215.KocemanA.S.ModiV.2017Value of pumped hydro storage in a hybrid energy generation allocation system2051202121510.1016/j.apenergy.2017.08.129Search in Google Scholar
Uchman W., Skorek-Osikowska A., Jurczyk M., Węcel D. (2020). The analysis of dynamic operation of power-to-SNG system with hydrogen generator powered with renewable energy, hydrogen storage and methanation unit. Energy 213.UchmanW.Skorek-OsikowskaA.JurczykM.WęcelD.2020The analysis of dynamic operation of power-to-SNG system with hydrogen generator powered with renewable energy, hydrogen storage and methanation unit21310.1016/j.energy.2020.118802Search in Google Scholar
Węcel D., Jurczyk M., Uchman W., Skorek-Osikowska A. (2020). Investigation on system for renewable electricity storage in small scale integrating photovoltaics, batteries, and hydrogen generator. Energies 13(22), 1–19.WęcelD.JurczykM.UchmanW.Skorek-OsikowskaA.2020Investigation on system for renewable electricity storage in small scale integrating photovoltaics, batteries, and hydrogen generator132211910.3390/en13226039Search in Google Scholar
Pfeiffer W. T., Witte F., Tuschy I., Bauer S. (2021). Coupled power plant and geostorage simulations of porous media compressed air energy storage (PMCAES). Energy Conversion and Management, 249.PfeifferW. T.WitteF.TuschyI.BauerS.2021Coupled power plant and geostorage simulations of porous media compressed air energy storage (PMCAES)24910.1016/j.enconman.2021.114849Search in Google Scholar
Chaychizadeh F., Dehghandorost H., Aliabadi A., Taklifi A. (2018). Stochastic dynamic simulation of a novel hybrid thermal-compressed carbon dioxide energy storage system (T-CCES) integrated with a wind farm. Energy Conversion and Management, 166, 500–511.ChaychizadehF.DehghandorostH.AliabadiA.TaklifiA.2018Stochastic dynamic simulation of a novel hybrid thermal-compressed carbon dioxide energy storage system (T-CCES) integrated with a wind farm16650051110.1016/j.enconman.2018.04.050Search in Google Scholar
Tola V., Meloni V., Spadaccini F., Cau G. (2017). Performance assessment of Adiabatic Compressed Air Energy Storage (A-CAES) power plants integrated with packed-bed thermocline storage systems. Energy Conversion and Management, 151, 342–356.TolaV.MeloniV.SpadacciniF.CauG.2017Performance assessment of Adiabatic Compressed Air Energy Storage (A-CAES) power plants integrated with packed-bed thermocline storage systems15134235610.1016/j.enconman.2017.08.051Search in Google Scholar
Mehla N., Kumar A. (2021). Experimental evaluation of used engine oil based thermal energy storage coupled with novel evacuated tube solar air collector (NETAC). Journal of Energy Storage 2021.MehlaN.KumarA.2021Experimental evaluation of used engine oil based thermal energy storage coupled with novel evacuated tube solar air collector (NETAC)2021.10.1016/j.est.2021.102656Search in Google Scholar
Liu X., Chen M., Xu Q., Gao K., Dang C., Li P., Luo Q., Zheng H., Song C., Tian Y., Yao H., Jin Y., Xuan Y., Ding Y. (2022). Bamboo derived SiC ceramics-phase change composites for efficient, rapid, and compact solar thermal energy storage. Applied Energy 240.LiuX.ChenM.XuQ.GaoK.DangC.LiP.LuoQ.ZhengH.SongC.TianY.YaoH.JinY.XuanY.DingY.2022Bamboo derived SiC ceramics-phase change composites for efficient, rapid, and compact solar thermal energy storage24010.1016/j.solmat.2022.111726Search in Google Scholar
Muthukumaran J., Senthil R. (2022). Experimental performance of a solar air heater using straight and spiral absorber tubes with thermal energy storage. Journal of Energy Storage, 45.MuthukumaranJ.SenthilR.2022Experimental performance of a solar air heater using straight and spiral absorber tubes with thermal energy storage4510.1016/j.est.2021.103796Search in Google Scholar
Praveen R.P., Chandra Mouli K.V.V. (2022). Performance enhancement of parabolic trough collector solar thermal power plants with thermal energy storage capability. Ain Shams Engineering Journal, 13.PraveenR.P.Chandra MouliK.V.V.2022Performance enhancement of parabolic trough collector solar thermal power plants with thermal energy storage capability1310.1016/j.asej.2022.101716Search in Google Scholar
Pachori H., Choudhary T., Sheorey T. (2022). Significance of thermal energy storage material in solar air heaters. Materials Today: Proceedings. In Press, Corrected Proof, Available online 6 January 2022.PachoriH.ChoudharyT.SheoreyT.2022Materials Today: Proceedings. In Press, Corrected Proof, Available online 6 January 2022.10.1016/j.matpr.2021.12.516Search in Google Scholar
Rathore P., Gupta N., Yadav D., Shukla S., Kaul S. (2022). Thermal performance of the building envelope integrated with phase change material for thermal energy storage: an updated review. Sustainable Cities and Society 79.RathoreP.GuptaN.YadavD.ShuklaS.KaulS.2022Thermal performance of the building envelope integrated with phase change material for thermal energy storage: an updated review7910.1016/j.scs.2022.103690Search in Google Scholar
Andersen T., Vinkovic K., de Vries M., Kers B., Necki J., Swolkien J., Roiger A., Peters W., Chen H. (2021). Quantifying methane emissions from coal mining ventilation shafts using an unmanned aerial vehicle (UAV)-based active AirCore system. Atmospheric Environment: X 12.AndersenT.VinkovicK.de VriesM.KersB.NeckiJ.SwolkienJ.RoigerA.PetersW.ChenH.2021Atmospheric Environment: X 12.10.1016/j.aeaoa.2021.100135Search in Google Scholar
Zheng C., Jiang B., Xue S., Chen Z., Li H. (2019). Coalbed methane emissions and drainage methods in underground mining for mining safety and environmental benefits: A review. Process Safety and Environmental Protection 127, 103–124.ZhengC.JiangB.XueS.ChenZ.LiH.2019Coalbed methane emissions and drainage methods in underground mining for mining safety and environmental benefits: A review12710312410.1016/j.psep.2019.05.010Search in Google Scholar
Barbour E., Mignard E., Ding Y., Li Y. (2015). Adiabatic Compressed Air Energy Storage with packed bed thermal energy storage. Applied Energy 155, 804–815.BarbourE.MignardE.DingY.LiY.2015Adiabatic Compressed Air Energy Storage with packed bed thermal energy storage15580481510.1016/j.apenergy.2015.06.019Search in Google Scholar
Bashiri Mousavi S., Adib M., Soltani M., Razmi A.R., Nathwani J. (2021). Transient thermodynamic modeling and economic analysis of an adiabatic compressed air energy storage (A-CAES) based on cascade packed bed thermal energy storage with encapsulated phase change materials. Energy Conversion and Management 243.Bashiri MousaviS.AdibM.SoltaniM.RazmiA.R.NathwaniJ.2021Transient thermodynamic modeling and economic analysis of an adiabatic compressed air energy storage (A-CAES) based on cascade packed bed thermal energy storage with encapsulated phase change materials24310.1016/j.enconman.2021.114379Search in Google Scholar
Bartela Ł., Lutyński M., Smolnik G., Waniczek S. Underground Compressed Air Storage Installation. European Patent Application, No. 20000302.8.BartelaŁ.LutyńskiM.SmolnikG.WaniczekS.European Patent Application, No. 20000302.8.Search in Google Scholar
Lee K-C., Baek W-K., Kwon H., S W-S., Yoh J.J. (2013). Analysis of melt-through process of 1.07 μm continuous wave high power laser irradiation on metal. Journal of Mechanical Science and Technology 27, 1745–1752.LeeK-C.BaekW-K.KwonH.SW-S.YohJ.J.2013Analysis of melt-through process of 1.07 μm continuous wave high power laser irradiation on metal271745175210.1007/s12206-013-0425-zSearch in Google Scholar
Jurczyk M., Rulik S., Bartela Ł. (2020). Thermal energy storage in rock bed – CFD analysis. Journal od Power Technologies, Vol. 100.JurczykM.RulikS.BartelaŁ.2020Thermal energy storage in rock bed – CFD analysis100Search in Google Scholar
Ochmann J., Rusin K., Rulik S., Bartela Ł. (2022). Identyfikacja współczynnika wnikania ciepła w procesie ładowania zasobnika Thermal Energy Storage na potrzeby adiabatycznego systemu CAES (Identification of the heat transfer coefficient in the Thermal Energy Storage charging process for the adiabatic CAES system). Współczesne problemy ochrony środowiska i energetyki, 147–157.OchmannJ.RusinK.RulikS.BartelaŁ.2022Identyfikacja współczynnika wnikania ciepła w procesie ładowania zasobnika Thermal Energy Storage na potrzeby adiabatycznego systemu CAES (Identification of the heat transfer coefficient in the Thermal Energy Storage charging process for the adiabatic CAES system)147157Search in Google Scholar
Waniczek S., Ochmann J., Bartela Ł., Rulik S., Lutyński M., Brzuszkiewicz M., Kołodziej K., Smolnik G., Jurczyk M., Lipka M. (2022) Design and Construction Challenges for a Hybrid Air and Thermal Energy Storage System Built in the Post-Mining Shaft. Journal of Thermal Science.WaniczekS.OchmannJ.BartelaŁ.RulikS.LutyńskiM.BrzuszkiewiczM.KołodziejK.SmolnikG.JurczykM.LipkaM.2022Design and Construction Challenges for a Hybrid Air and Thermal Energy Storage System Built in the Post-Mining Shaft10.52202/062738-0166Search in Google Scholar
Labus M., Labus K. (2018). Thermal conductivity and diffusivity of fine-grained sedimentary rocks. Journal of Thermal Analysis and Calorimetry, 132, 1669–1676.LabusM.LabusK.2018Thermal conductivity and diffusivity of fine-grained sedimentary rocks1321669167610.1007/s10973-018-7090-5Search in Google Scholar
Hartlieb P., Toifl M., Kuchar F., Meisels R., Antretter T. (2016). Thermo-physical properties of selected hard rocks and their relationto microwave-assisted comminution. Minerals Engineering, 91.HartliebP.ToiflM.KucharF.MeiselsR.AntretterT.2016Thermo-physical properties of selected hard rocks and their relationto microwave-assisted comminution9110.1016/j.mineng.2015.11.008Search in Google Scholar
Bindra H., Bueno P., Morris J.F., Shinnar R. (2013). Thermal analysis and exergy evaluation of packed bed thermal storage systems. Applied Thermal Engineering 52(2), 255–263.BindraH.BuenoP.MorrisJ.F.ShinnarR.2013Thermal analysis and exergy evaluation of packed bed thermal storage systems52225526310.1016/j.applthermaleng.2012.12.007Search in Google Scholar
Bouvry B., Carrion A., Andujar J., Veron E., Ory S., Brassamin S., Echegut P., Escape C., Nahhas T., Py X., Bessada C. (2017). Mediterranean basin basalts as potential materials for thermal energy storage in concentrated solar plants, Solar Energy Materials and Solar Cells, 171, 50–59.BouvryB.CarrionA.AndujarJ.VeronE.OryS.BrassaminS.EchegutP.EscapeC.NahhasT.PyX.BessadaC.2017Mediterranean basin basalts as potential materials for thermal energy storage in concentrated solar plants171505910.1016/j.solmat.2017.06.030Search in Google Scholar
Churchill S. W., Chu H. (1975). Correlating equations for laminar and turbulent free convection from a vertical plate. International Journal of Heat Mass Transfer 18, 1323–1329.ChurchillS. W.ChuH.1975Correlating equations for laminar and turbulent free convection from a vertical plate181323132910.1016/0017-9310(75)90243-4Search in Google Scholar