publication . Article . Other literature type . 2016

Advances in the valorization of waste and by-product materials as thermal energy storage (TES) materials

Mario Grágeda; Mario Grágeda; Svetlana Ushak; Svetlana Ushak; Andrea Gutierrez; Luisa F. Cabeza; Javier Rodríguez-Aseguinolaza; Xavier Py; Nicolas Calvet; Camila Barreneche; ...
Open Access English
  • Published: 01 Jun 2016
  • Publisher: Elsevier
Today, one of the biggest challenges our society must face is the satisfactory supply, dispatchability and management of the energy. Thermal Energy Storage (TES) has been identified as a breakthrough concept in industrial heat recovery applications and development of renewable technologies such as concentrated solar power (CSP) plants or compressed air energy storage (CAES). A wide variety of potential heat storage materials has been identified depending on the implemented TES method: sensible, latent or thermochemical. Although no ideal storage material has been identified, several materials have shown a high potential depending on the mentioned considerations....
free text keywords: Emmagatzematge d'energia tèrmica, Reciclatge de residus, Heat storage, Waste recycling, Thermal energy storage (TES), Industrial waste, Slags, Aluminium dross, Compressed air energy storage, Computer data storage, business.industry, business, Refining (metallurgy), Environmental science, Heat recovery ventilation, Concentrated solar power, Thermal energy storage, Waste management, Greenhouse gas
Funded by
  • Funder: European Commission (EC)
  • Project Code: 610692
  • Funding stream: FP7 | SP3 | PEOPLE
Energy Research
78 references, page 1 of 6

1. DOE/EIA, International Energy Outlook with projections to 2040, Report 0484, U.S., 2013.

2. CSP Today, An Overview of CSP in Europe, North Africa and the Middle East, 2008.

3. OECD/IEA, Solar Energy Perspectives, Renewable Energy Report, U.S., 2011.

4. S. Kuravi, J. Trahan, D. Y. Goswami, M. M. Rahman and E. K. Stefanakos, Prog. Energ. Comb. Sci., 2013, 29, 285.

5. Gary J, CSP & The SunShot Initiative, DOE-CSP Industry, March 2011 Solar Energy Technologies Program U.S. Department of Energy, U.S., 2011.

6. OECD/IEA, Technology Roadmap Concentrating Solar Power, U.S., 2010.

7. Renewable Energy Technologies: cost analysis series, Concentrating Solar Power, June 2012.

8. ESTELA, Solar Thermal Electricity: Strategic Research Agenda 2020-2050. Report, December, 2012.

9. Report from the commission to the European Parliament and the Council: Progress toward achievement the Kyoto and EU2020 objectives, Annex I. 2013.

10. BCS Incorporated, Waste heat recovery: Technology and opportunities in USA industry, Industrial technologies program, US Department of Energy, 2008.

11. Sieminski A, Interantional Energy Outlook, EIA - Center for Strategic and International Studies, 2013.

12. Kere A, Sadiki N, Py X, Goetz V, Applicability of thermal energy storage recycled ceramics to high temperature and compressed air operating conditions, Energ Convers Manage 2014; 88: 113-9. [OpenAIRE]

13. Gil A, Medrano M, Martorell I, Lazaro A, Dolado P, Zalba B, Cabeza LF, State of the art on high temperature thermal energy storage for power generation. Part 1-Concepts, materials and modellization, Renew Sust Energ Rev 2010; 14: 31-55.

14. Medrano M, Gil A, Martorell I, Potau X, Cabeza LF, State of the art on high-temperature thermal energy storage for power generation. Part 2-Case studies, Renew Sust Energ Rev 2010; 14: 56-72.

15. Khare S, Dell'Amico M, Knight C, McGarry S, Selection of materials for high temperature sensible energy storage, Sol Energ Mat Sol C 2013; 115: 114-22.

78 references, page 1 of 6
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