Identyfikatory
Warianty tytułu
Underground thermal energy storage : methods and applications
Języki publikacji
Abstrakty
Underground Thermal Energy Storage (UTES) is a powerful set of solutions that allows efficient management of thermal energy sources, both heat and cold, the demand of which is subjected to seasonal variations. Underground can store available in excess heat or cold for periods of up to several months and use whenever needed, especially in the opposing season. Sources of thermal energy that can be stored underground are, among others: solar thermal energy, cold winter air, waste heat from ventilation and waste heat from industrial processes. Two primary methods of under ground energy storage are Aquifer Thermal Energy Storage (ATES) where water reservoir is a thermal energy accumulator and Borehole Thermal Energy Storage (BTES) where rock formation acts as a heat/cold store. UTES allows to minimizing consumption of fossil fuels and therefore reduce costs of energy purchase, limiting the amount of greenhouse gases emission into atmosphere, and increasing energy security.
Czasopismo
Rocznik
Tom
Strony
464--471
Opis fizyczny
Bibliogr. 31 poz., rys., tab.
Twórcy
autor
- Instytut Gospodarki Surowcami Mineralnymii Energii Polskiej Akademii Nauk, ul.Wybickiego7, 31-261 Kraków
Bibliografia
- 1. ANDERSSON O. 2009 - The ATES Project at the Stockholm Arlanda Airport - Technical Design and Environmental Assessment. Effstock Conference Proceedings, 14-17.06.2009, Stockholm.
- 2. ANDERSSON O. & RYDELL L. 2010 - The HT-BTES plant at Xylem in Emmaboda, Sweden - Experiences from design, construction and initial operation.
- 3. CABEZA L.F. 2015 - Advances in Thermal Energy Storage Systems: Methods and Applications. Woodhead Publishing, Cambridge.
- 4. CHUARD P. & HADORN J.C. 1983 - Heat storage systems: concepts, engineering data and compilation of projects [W]: Central solar heating plants with seasonal storage. Swiss Federal Office of Energy. Document No A24389/3.
- 5. DESMEDT J. & HOES H. 2007 - Monitoring results of aquifer thermal energy storage system in a Belgian hospital. 2nd PALENC Conference and 28th AIVC Conference on Building Low Energy Cooling and Advanced Ventilation Technologies in the 21st Century, 27-29.09.2007, Crete.
- 6. DICKINSON J.S., BUIK N., MATTHEWS M.C. & SNIJDERS A. 2009 - Aquifer thermal energy storage: theoretical and operational analysis. Geotechnique 59(3): 249-260.
- 7. EGGEN G. & VANGSNES G. 2005 - Heat pump for district cooling and heating at Oslo, Airport Gardermoen. Proceedings of 8th IEA Heat Pump Conference, 30.05-2.06.2005, Las Vegas.
- 8. GODSCHALK M. & BAKEMA G. 2009 - 20,000 ATES Systems in the Netherlands in 2020 - Major step towards a sustainable energy supply, Effstock 2009 Conference Proceedings, 14-17.06.2009, Stockholm.
- 9. HELLSTRÖM G. 2012 - UTES experiences from Sweden. REHAU seminar on Underground Thermal Energy Storage, 31.05.2012, London.
- 10. HENDRIKS M., SNIJDERS A. & BOID N. 2008 - Underground thermal energy storage for efficient heating and cooling of buildings. Proceedings of the 1st international conference on industrialised, integrated, intelligent construction (I3CON), 14-16.05.2008, Loughborough.
- 11. http://cordis.europa.eu/project/rcn/45158_en.Ptml.
- 12. http://www.dlsc.ca.
- 13. http://www.groundmed.eu.
- 14. http://www.iftecP.co.uk/aquifer_tPermal_energy_storage.cgi.
- 15. http://www.swecogroup.com/en/Sweco-group/Solutions/Bundmgs/ Effective-storage-of-energy-at-new-Akershus-University-Hospital-/.
- 16. http://www.underground-energy.com/BTES.Ptml.
- 17. IFTECH. 2012 - An Introduction to Aquifer Thermal Energy Storage (ATES). RePau Workshop, 28-31.05.2012.
- 18. KABUS F. & SEIBT P. 2000 - Aquifer Thermal Energy Storage for the Berlin Reichstag Building - New Seat of the German Parliament. Proceedings of World Geothermal Congress, 28.05-10.6.2000, KyusPu-ToPoku: 3611-3615.
- 19. KĘPIŃSKA B. 2013 - Wykorzystanie energii geotermalnej w Europie, 2012-2103. Tech. Posz. Geol. Geot. Zrów. Rozw., 52 (2): 5-16.
- 20. LEE K.S. 2013 - Underground Thermal Energy Storage. Springer, London.
- 21. MIDTT0MME K., HAUGE A., GRINI R.S., STENE J. & SKARPHAGEN H. 2009 - Underground thermal energy storage (UTES) with heat pumps in Norway. Effstock 2009 Conference Procedings,14-17.06.2009, Stockholm.
- 22. NORDELL B. 2012 - Underground Thermal Energy Storage. Innostock 2012 Conference Proceedings, 16-19.05.2012, Lleida.
- 23. SANNER B., KABUS F., SEIBT P. & BARTELS J. 2005 - Underground Thermal Energy Storage for the German Parliament in Berlin - System Concept and Operational Experiences. Proceedings of World Geothermal Congress, 24.04-29.04.2005, Antalya.
- 24. SNIJDERS A.L. & VAN AARSSEN M.M. 2003 - Big is beautiful? Application of large scale energy storage in the Netherlands. Future- stock 2003 Conference Proceedings, 1-4.09.2003, Warszawa: 83-88.
- 25. STILES L. 2011 - Geothermal installations at Richard Stockton College and NJ regulations. Northeast Region Geothermal Workshop, 29.03.2011, North Chelmsford, Massachusetts.
- 26. ŚLIWA T. & GONET A. 2011 - Otworowe wymienniki ciepła jako źródło ciepła lub chłodu na przykładzie Laboratorium Geoenergetyki WWNiG AGH. Wiertnictwo, Nafta, Gaz, 28 (1/2): 419-430.
- 27. ŚLIWA T., GONET A. & SKOWROŃSKI G. 2011 - Największa w Polsce instalacja grzewczo-chłodnicza bazująca na otworowych wymiennikach ciepła. Wiertnictwo, Nafta, Gaz, 28 (3): 587-597.
- 28. TECHNISCHE UNIVERSITEIT EIHOVEN - https://www.tue.nl/en/ university/about-the-university/sustainability/campus-and-operatio- nal-management/energy/heat-and-cold-storage-ates/.
- 29. WIGSTRAND I. 2009 - The ATES Project - a sustainable solution for Stockholm-Arlanda airport. Effstock 2009 Conference Proceedings, 14-17.06.2009, Stockholm.
- 30. WOŚ A. 1999 - Klimat Polski. PWN, Warszawa.
- 31. ZŁOTKOWSKI A., ŚLIWA T. & GONET A. 2011 - Otworowe wymienniki ciepła w instalacji grzewczo-klimatyzacyjnej ekologicznego parku edukacji i rozrywki OSSA. Wiertnictwo, Nafta, Gaz, 28(1/2): 475-482.
Uwagi
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-9071a0af-9405-48fd-9b72-e6a924fbaf28