Corrosion of metals and salt hydrates used for thermochemical energy storage

Renewable Energy

Volumn 75, Issue , 2015, Pages 519-523

  Solé, Aran ^a   Miró, Laia ^a   Barreneche, Camila ^a,b   Martorell, Ingrid ^a   Cabeza, Luisa F ^a  

^a UNIVERSITY OF LLEIDA   (Spain)

^b UNIVERSITY OF BARCELONA   (Spain)

Author keywords

Building applications; Corrosion tests; Metals; Salt hydrates; Thermal energy storage (TES); Thermochemical materials (TCM)

Indexed keywords

ALUMINUM COATED STEEL; ATMOSPHERIC CORROSION; AUSTENITIC STAINLESS STEEL; CALCIUM OXIDE; COOLING SYSTEMS; COPPER CORROSION; HEAT STORAGE; HYDRATES; HYDRATION; MAGNESIUM COMPOUNDS; METALS; SODIUM SULFIDE; SOLAR ENERGY; STORAGE (MATERIALS); THERMAL ENERGY;

BUILDING APPLICATIONS; CORROSION TESTS; HUMIDITY AND TEMPERATURES; IMMERSION CORROSION TESTS; SALT HYDRATES; THERMAL ENERGY STORAGE SYSTEMS; THERMOCHEMICAL ENERGY STORAGE; THERMOCHEMICAL MATERIALS (TCM);

ALUMINUM CORROSION;

ALUMINUM; COOLING; COPPER; CORROSION; DESIGN METHOD; ENERGY CONSERVATION; ENERGY USE; HEATING; REACTION KINETICS; SALT; SIMULATION; SOLAR POWER; STEEL; STORAGE STRUCTURE; THERMOCHEMISTRY;

EID: 84908638658     PISSN: 09601481     EISSN: 18790682     Source Type: Journal    
DOI: 10.1016/j.renene.2014.09.059     Document Type: Article

References (25)

1. Pomianowski M., Heiselberg P., Zhang Y. Review of thermal energy storage technologies based on PCM application in buildings. Energy Build 2013, 67:56-69.
2. Zhou D., Zhao C.Y., Tian Y. Review on thermal energy storage with phase change materials (PCMs) in building applications. Appl Energy 2012, 92:593-605.
3. Pinel P., Cruickshank C.A., Beausoleil-Morrison I., Wills A. Areview of available methods for seasonal storage of solar thermal energy in residential applications. Renew Sustain Energy Rev 2011, 15(7):3341.
4. Perry R.H., Green D. Perry's chemical engineers' handbook 1984, 23-16-23-33. McGraw-Hill, New York, USA. 6th ed.
5. Oró E., Miró L., Barreneche C., Martorell I., Farid M.M., Cabeza L.F. Corrosion of metal and polymer containers for use in PCM cold storage. Appl Energy 2013, 109:449-453.
6. Porisini F.C. Salt hydrates used for latent heat storage: corrosion of metals and reliability of thermal performance. Sol Energy 1988, 41(2):193-197.
7. Cabeza L.F., Illa J., Roca J., Badia F., Mehling H., Hiebler S., et al. Immersion corrosion tests on metal-salt hydrate pairs used for latent heat storage in the 32 to 36°C temperature range. Mater Corros 2001, 52:140-146.
8. Farrel A.J., Norton B., Kennedy D.M. Corrosive effects of salt hydrate phase change materials used with aluminum and copper. JMater Process Tech 2006, 175:198-205.
9. Guillot S., Faik A., Rakhmatullin A., Lambert J., Veron E., Echegut P., et al. Corrosion effects between molten salts and thermal storage material for concentrated solar power plants. Appl Energy 2012, 94:174-181.
10. Hauer A. Sorption theory for thermal energy storage. Thermal energy storage for sustainable energy consumption 2007, 393-408. Springer, Dordrecht, The Netherlands. H. Paksoy (Ed.).
11. Visscher K. Simulation of thermo chemical seasonal storage of solar heat-material selection and optimum performance simulation. In: Proceedings of 2nd workshop Matlab/Simulink for building simulation, CSTB, Paris, France, 14-15 October, 2004.
12. Masruroh N.A., Li B., Klemes J. Life cycle analysis of a solar thermal system with thermochemical storage process. Renew Energy 2006, 31:537-548.
13. Solé A., Fontanet X., Barreneche C., Fernández I.A., Martorell I., Cabeza L.F. Requirements to consider when choosing a thermochemical material for solar energy storage. Sol Energy 2013, 97:398.
14. de Boer R, Haije WG, Veldhuis JBJ, Smeding SF. Solid-sorption cooling with integrated thermal storage: the SWEAT prototype. In: Proceedings of Heat Powered Cycles, HPC, Larnaca, Cyprus, 11-13 October, 2004.
15. Cuypers R., Maraz N., Eversdijk J., Finck C., Henquet E., Oversloot H., et al. Development of a seasonal thermochemical storage system. Energy Procedia 2012, 30:207-214.
16. Schmidt M., Szczukowski C., Robkopf C., Linder M., Wörner A. Experimental results of a 10kW high temperature thermochemical storage reactor based on calcium hydroxide. Appl Therm Eng 2014, 62:553-559.
17. Abedin A.H., Rosen M.A. Acritical review of thermochemical energy storage systems. Open Renew Energy J 2011, 4:42-46.
18. ASTM G1-03. Standard for preparing, cleaning, and evaluating corrosion test specimens.
19. Davis J.R. Heat resistant materials 1997, ASM International, USA, [accessed 16.07.14]. http://users.encs.concordia.ca/%7Emmedraj/tmg-books/edit/Metals%20Handbook%20Desk%20Edition/Metals_Handbook_Desk_Edition.pdf.
20. Bagdasarian A., Feather J., Hull B., Stephenson R., Strong R. Crude unit corrosion and corrosion control 2010, GE Power & Water. Water & Process Technologies.
21. SWEAT Project RTB internal report for MERITS partners 2013.
22. Garverick L. Corrosion in the petrochemical industry 1994, ASM International, USA.
23. George E. King Consulting. [accessed 08.05.14]. http://gekengineering.com/Downloads/Free_Downloads/Corrosion_Overview.pdf.
24. Ma H., Cheng X., Li G., Chen S., Quan Z., Zhao S., et al. The influence of hydrogen sulfide on corrosion of iron under different conditions. Corr Sci 2000, 42:1669.
25. Sastri V.S., Ghali E., Elboujdaini M. Corrosion, prevention and protection. Practical solutions 2007, John Wiley & Sons, Chichester, UK.