Review of technology: Thermochemical energy storage for concentrated solar power plants

Renewable and Sustainable Energy Reviews

Volumn 60, Issue , 2016, Pages 909-929

  Prieto, Cristina ^a   Cooper, Patrick ^a   Fernández, A Inés ^b   Cabeza, Luisa F ^c  

^a ABENGOA RESEARCH   (Spain)

^b UNIVERSITY OF BARCELONA   (Spain)

^c UNIVERSITY OF LLEIDA   (Spain)

Author keywords

Metal oxide cycles; Perovskite; Redox reactions; Sulfur based cycles; Thermal energy storage; Thermochemical energy storage

Indexed keywords

CALCIUM CARBONATE; CONCENTRATED SOLAR POWER; HEAT STORAGE; MANGANESE OXIDE; METALS; PEROVSKITE; SOLAR ENERGY; THERMAL ENERGY;

BROAD SPECTRUM; CONCENTRATED SOLAR POWER; METAL OXIDE CYCLE; METAL-OXIDE; REVIEW OF TECHNOLOGIES; STORAGE TECHNOLOGY; SULPHUR-BASED CYCLE; THERMAL ENERGY STORAGE; THERMOCHEMICAL ENERGY STORAGE; THERMOCHEMICAL STORAGE;

REDOX REACTIONS;

EID: 84959018446     PISSN: 13640321     EISSN: 18790690     Source Type: Journal    
DOI: 10.1016/j.rser.2015.12.364     Document Type: Review

References (48)

1. P.W. Parfomak Energy storage for power grids and electric transporation: a technology assessment 2012 Congressional Research Service
2. A. Gil, M. Medrano, I. Martorell, A. Lázaro, P. Dolado, B. Zalba, and L.F. Cabeza State of the art on high temperature thermal storage for power generation. Part 1 - concepts, materials and modelization Renew Sustain Energy Rev 14 2010 31 55
3. "www.abengoasolar.com". Accessed last time July 2014.
4. A.I. Fernandez, M. Martinez, M. Segarra, I. Martorell, and L.F. Cabeza Selection of materials with potential in sensible thermal energy storage Sol Energy Mater Sol Cells 94 2010 1723 1729
5. Tamme R. IEA ECES Annex 19: Optimised industrial process heat and power generation with thermal energy storage. Final report; 2010.
6. IEA-ETSAP, IRENA. Thermal energy storage- technology brief; 2013.
7. J. Cot-Gores, A. Castell, and L.F. Cabeza Thermochemical energy storage and conversion: a-state-of -the art review of the experimental research under practical conditions Renew Sustian Rev 16 2012 5207 5224
8. A. Wörner, German Aerospace Center- 7th Framwork Programme, 2014. Available at: "http://www.tcs-power.eu/reports-publications/conferences.html". Accessed last time July 2014.
9. R. Project, Seventh Framework Programme, 2014. Available at: "http://www.restructure-project.org/". Accessed last time July 2014.
10. Sattler C, Wörner A. «Thermochemical Energy Storage: Overview on German, and European R&D Programs and the work carried out at the German Aerospace Center DLR. Deutschen Zentrum für Luft-und Raumfahrt (DLR); 2013.
11. U.S. Department of Energy, SunShot Initiative, 20 June 2013. Available at: "http://www1.eere.energy.gov/solar/sunshot/about.html". Accessed last time July 2014.
12. General Atomics, DLR. Sulfur Based Thermochemical Heat Storage for Base load Concentrating Power; 2011.
13. M. Roeb Sulfur and ferrite-based thermochemical cycles for water splitting 2011 SFERA Winter School. Solar Fuels & Materials Zurich, Switzerland
14. Sattler C. Solar fuels: overview of the work carried out at the German Aerospace Center. Solar Fuels, Niigata University: Japan; 2012.
15. Wong B, Brown L, Buckingham R, Thomey D, Roeb M, Sattler C. Sulfur based thermochemical energy storage for concentrated solar power. SolarPACES, Marrakech, Morocco; 2012.
16. Thomey D, Lennartz F, Schöllgen D, de Oliveira L, Säck J.-P., Roeb M, Sattler C. Development and test of a solar decomposer of sulphuric acid for thermochemical hydrogen production. In: Proceedings of the ICPH2-11th international conference on hydrogen production: Thessaloniki, Greece; 2011.
17. General Atomics. Thermochemical heat storage for concentrated solar power based on multivalent metal oxides. CSP Program Review. Award Number: DE-FG-36-08GO18145; 2011.
18. Air Liquide. Air Liquide Gas Encyclopedia. Available at: "http://encyclopedia.airliquide.com/Encyclopedia.asp?GasID=27". Accessed last time July 2014. Accessed last time July 2014.
19. DKL Engineering, Inc. Sulphuric Acid on the Web. Available at: "http://www.sulphuric-acid.com/techmanual/Properties/properties-sulphur.htm". Accessed last time July 2014.
20. M. Smitkova, and F. Janicek Comparison of thermo-chemical water splitting cycles Power Syst Oper Control, ATP J PLUS2 2008 41 43
21. IEA/HIA Task 25. Hybrid Sulfur Cycle. Available at: "http://ieahia.org/pdfs/Task25/Hybrid-Sulfur-Cycle.pdf". Accessed last time July 2014.
22. N. AuYeung Hydrogen production via a sulfur-sulfur thermochemical water-splitting cycle PhD. Thesis 2011 Oregon State University USA
23. A. Le Duigou, J.M. Borgard, B. Larousse, D. Doizi, R. Allen, B.C. Ewan, and et al. HYTHEC: an EC funded search for a long term massive hydrogen production route using solar and nuclear technologies Int J Hydrog Energy 32 2007 1516 1529
24. Möller S, Roeb M, Sattler C. Solar thermal hydrogen production via reforming and thermo-chemical-cycles. ForschungsVerbund Sonnenenergie Workshop 2007, Ulm, Germany; 2007.
25. United States Department of Energy. Nuclear Hydrogen R&D Plan; 2004.
26. EXTOXNET-Extension Toxicology Network. Cornell University, USA, 1994. Available at: "http://pmep.cce.cornell.edu/profiles/extoxnet/pyrethrins-ziram/sulfur-ext.html". Accessed last time July 2014.
27. United States Department of Energy Project Staff Thermochemical heat storage for concentrated solar power: thermochemical system reactor design for thermal energy storage 2011 U.S. Department of Energy USA
28. S.E. Edwards, and V. Materić Calcium looping in solar power generation plants Sol Energy 86 2012 2494 2503
29. A. Meier, E. Bonaldi, G.M. Cella, W. Lipinski, and D. Wuillemin Solar chemical reactor technology for industrial production of lime Sol Energy 80 2006 1355 1362
30. M. Neises, S. Tescari, L. de Oliveira, M. Roeb, C. Sattler, and B. Wong Solar-heated rotary kiln for thermochemical energy storage Sol Energy 86 2012 3040 3048
31. C. Wieckert A 300 kW solar chemical pilot plant for the carbothermic production of zinc J Sol Energy Eng 129 2007 190 197
32. Wörner A, Linder M. Thermochemical Storage of Heat. Achema 2012: Frankfurt, Germany; 2012.
33. Schaube F, Wörner A, Müller-Steinhagen H. High temperature heat storage using gas-solid reactions. Effstock 2009, Stockholm, Sweden; 2009.
34. Arpa-e Energy. Thermochemical Storage Breakout. United States Department of Energy: USA.
35. M. Felderhoff, R. Urbanczyk, and S. Peil Thermochemical heat storage for high temperature applications-a review Green 3 2013 113 123
36. G. Bauerle, D. Chung, G Ervin, and J. Guon Storage of solar energy be inorganic oxide/hydroxides 1976 Springer
37. Wong B. Lessons learned: developing thermochemical cycles for solar heat storage applications. IFT/P2013-001 Workshop on TES for CSP; 2013.
38. M. Borowski Perovskite: structure, properties and use 2011 Nova Science Publisher New York
39. A. Navrostky Energetics and crystal chemical systematics among ilmenite, lithium niobate, and perovskite structures Chem Mater 10 1998 2787 2793
40. M.A. Peña, and J.L. Fierro Chemical structures and performance of perovskite oxides Chem Rev 101 2001 1981 2017
41. 2 and CO production Energy Environ Sci 6 2013 2424 2428
42. A. Evdou, L. Nalbandian, and V.T. Zaspalis Perovskite membrane reactor for continuous and isothermal redox hydrogen production from the dissociation of water J Membr Sci 325 2008 704 711
43. 2 generation using sol-gel derived Mn-ferrite in a packed bed reactor Int J Hydrog Energy 37 2012 2924 2934
44. McDaniel A, Ermanoski I. Solar hydrogen production with a metal oxide based thermochemical cycle. Project ID: PD081, DOE Annual Merit Review; 2013.
45. Ermanoski I, McDaniel A, Siegel N. Solar hydrogen production with a metal oxide based thermochemical cycle. Project ID: PD081, DOE Annual Merit Review; 2012.
46. Z. Zeng, F. Calle-Vallejo, M.B. Mogensen, and J. Rossmeisl Generalized trends in the formation energies of perovskite oxides Phys Chem Chem Phys 20 2013 7526 7533
47. 2N oxynitrides for solar water splitting: influence of the synthesis conditions Energy Procedia 22 2012 61 66
48. (3-δ) perovskites as redox materials for the production of high purity hydrogen Int J Hydrog Energy 33 2008 5554 5562