Systematic search algorithm for potential thermochemical energy storage systems

Applied Energy

Volumn 183, Issue , 2016, Pages 113-120

  Deutsch, Markus ^a   Müller, Danny ^a   Aumeyr, Christian ^a   Jordan, Christian ^a   Gierl Mayer, Christian ^a   Weinberger, Peter ^a   Winter, Franz ^a   Werner, Andreas ^a  

^a VIENNA UNIVERSITY OF TECHNOLOGY   (Austria)

Author keywords

Database; Storage material; Systematic search; Thermochemical energy storage

Indexed keywords

ALGORITHMS; DATABASE SYSTEMS; ENERGY STORAGE; ENERGY UTILIZATION; GREENHOUSE GASES; LEARNING ALGORITHMS;

CHEMICAL DATABASE; ENERGY UTILIZATION EFFICIENCY; POTENTIAL REACTIONS; SEARCH ALGORITHMS; SYSTEMATIC SEARCH ALGORITHM; SYSTEMATIC SEARCHES; THERMOCHEMICAL ENERGY STORAGE; THERMOCHEMICAL STORAGE;

STORAGE (MATERIALS);

ALGORITHM; DATABASE; DECOMPOSITION; ENERGY BUDGET; GREENHOUSE GAS; TECHNOLOGICAL DEVELOPMENT; THERMOCHEMISTRY;

EID: 84985018845     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2016.08.142     Document Type: Article

References (27)

1. [1] Arce, P., Medrano, M., Gil, A., Oró, E., Cabeza, L.F., Overview of thermal energy storage (TES) potential energy savings and climate change mitigation in Spain and Europe. Appl Energy 88 (2011), 2764–2774.
2. [2] IEA. Heating without global warming: market developments and policy considerations for renewable heat; 2014. < http://www.iea.org>.
3. [3] Stitou, D., Mazet, N., Mauran, S., Experimental investigation of a solid/gas thermochemical storage process for solar air-conditioning. 23rd International conference on efficiency, cost, optimization, simulation and environmental impact of energy systems ECOS 2010, vol. 41, 2012, 261–270.
4. [4] Chan, C.W., Ling-Chin, J., Roskilly, A.P., A review of chemical heat pumps, thermodynamic cycles and thermal energy storage technologies for low grade heat utilisation. Appl Therm Eng 50 (2013), 1257–1273.
5. [5] Cot-Gores, J., Castell, A., Cabeza, L.F., Thermochemical energy storage and conversion: a-state-of-the-art review of the experimental research under practical conditions. Renew Sustain Energy Rev 16 (2012), 5207–5224.
6. [6] IEA. Co-generation and renewables: solutions for a low-carbon energy future; 2011. < http://www.iea.org>.
7. [7] Brandstätter R. Industrielle abwärmenutzung, beispiel & technologien; 2008.
8. [8] Ma, Q., Luo, L., Wang, R.Z., Sauce, G., A review on transportation of heat energy over long distance: exploratory development. Renew Sustain Energy Rev 13 (2009), 1532–1540.
9. [9] Widhalm, J., Fellner, T., Deutsch, M., Werner, A., Winter, F., Thermochemical energy storage as a way to increase the sustainability of energy generation. The international academic forum, (eds.) ACSEE2015 – official conference proceedings, 2015, 579–593.
10. [10] Kata, Y., Thermal energy storage in vehicles for fuel efficiency improvement. Proc Effstock, 2009, 14–17.
11. [11] Chemical Heat Storage for Automotive Heating and Cooling Applications. In: 3rd IAV conference: thermoelectrics goes automotive, expert Verlag; 2012.
12. [12] Romero, M., Steinfeld, A., Concentrating solar thermal power and thermochemical fuels. Energy Environ Sci 5 (2012), 9234–9245.
13. [13] Zaversky, F., García-Barberena, J., Sánchez, M., Astrain, D., Transient molten salt two-tank thermal storage modeling for CSP performance simulations. Sol Energy 93 (2013), 294–311.
14. [14] Aydin, D., Casey, S.P., Riffat, S., The latest advancements on thermochemical heat storage systems. Renew Sustain Energy Rev 41 (2015), 356–367.
15. [15] Korhammer, K., Druske, M.-M., Fopah-Lele, A., Rammelberg, H.U., Wegscheider, N., Opel, O., et al. Sorption and thermal characterization of composite materials based on chlorides for thermal energy storage. Appl Energy 162 (2016), 1462–1472.
16. [16] Fopah Lele, A., Kuznik, F., Rammelberg, H.U., Schmidt, T., Ruck, W.K.L., Thermal decomposition kinetic of salt hydrates for heat storage systems. Appl Energy 154 (2015), 447–458.
17. 4-zeolite composite for long-term thermal energy storage. Sol Energy Mater Sol Cells 95 (2011), 1831–1837.
18. 2O during dehydration in view of thermal storage. J Phys Chem C 119 (2015), 28711–28720.
19. 2/CaO reversible reaction in a fluidized bed reactor for thermochemical heat storage. Sol Energy 107 (2014), 605–616.
20. [20] Nagel, T., Shao, H., Roßkopf, C., Linder, M., Wörner, A., Kolditz, O., The influence of gas–solid reaction kinetics in models of thermochemical heat storage under monotonic and cyclic loading. Appl Energy 136 (2014), 289–302.
21. [21] Kato, Y., Harada, N., Yoshizawa, Y., Kinetic feasibility of a chemical heat pump for heat utilization of high-temperature processes. Appl Therm Eng 19 (1999), 239–254.
22. [22] Albrecht, K.J., Jackson, G.S., Braun, R.J., Thermodynamically consistent modeling of redox-stable perovskite oxides for thermochemical energy conversion and storage. Appl Energy 165 (2016), 285–296.
23. [23] Carrillo, A.J., Moya, J., Bayón, A., Jana, P., La Peña O'Shea, V.A. d., Romero, M., et al. Thermochemical energy storage at high temperature via redox cycles of Mn and Co oxides: pure oxides versus mixed ones. Sol Energy Mater Sol Cells 123 (2014), 47–57.
24. [24] N'Tsoukpoe, K.E., Schmidt, T., Rammelberg, H.U., Watts, B.A., Ruck, W.K.L., A systematic multi-step screening of numerous salt hydrates for low temperature thermochemical energy storage. Appl Energy 124 (2014), 1–16.
25. [25] Solé, A., Fontanet, X., Barreneche, C., Fernández, A.I., Martorell, I., Cabeza, L.F., Requirements to consider when choosing a thermochemical material for solar energy storage. Sol Energy 97 (2013), 398–404.
26. [26] Antti Roine. Hsc chemistry; 2007.
27. [27] Hartigan, J.A., Wong, M.A., Algorithm as 136: a k-means clustering algorithm. J R Stat Soc Ser C (Appl Stat) 28 (1979), 100–108.