Heat transfer performance of thermal energy storage components containing composite phase change materials

IET Renewable Power Generation

Volumn 10, Issue 10, 2016, Pages 1515-1522

  Zhao, Bo ^a   Li, Chuan ^b   Jin, Yi ^a   Yang, Cenyu ^a   Leng, Guanghui ^b   Cao, Hui ^b   Li, Yongliang ^b   DIng, Yulong ^b  

^a STATE GRID CORPORATION OF CHINA   (China)

^b UNIVERSITY OF BIRMINGHAM   (United Kingdom)

Author keywords

[No Author keywords available]

Indexed keywords

DIGITAL STORAGE; ENERGY STORAGE; HEAT STORAGE; HEAT TRANSFER; STORAGE (MATERIALS); SURFACE ROUGHNESS; THERMAL CONDUCTIVITY; THERMAL ENERGY;

COMPOSITE PHASE CHANGE MATERIALS; CONCENTRIC TUBE; HEAT TRANSFER PERFORMANCE; MASS FRACTION; MODELLING STUDIES; SINGLE TUBES; THERMAL CONDUCTIVITY ENHANCEMENT; THERMAL CONTACT RESISTANCE;

PHASE CHANGE MATERIALS;

EID: 85017436863     PISSN: 17521416     EISSN: 17521424     Source Type: Journal    
DOI: 10.1049/iet-rpg.2016.0026     Document Type: Conference Paper

References (22)

1. Farid, M.M., Khudhair, A.M., Razack, S.A.K., et al.: 'A review on phasechange energy storage: Materials and applications', Energy Convers.Manage., 2007, 45, pp. 1597-1615
2. Verma, P., Varun, Singal, S.K.: 'Review of mathematical modeling on latentheat thermal energy storage systems using phase-change material', Renew.Sustain. Energy. Rev., 2008, 12, (4), pp. 999-1031
3. Cardenas, B., Leon, N.: 'High temperature latent heat thermal energy storage:phase change materials, design considerations and performance enhancementtechniques', Renew. Sustain. Energy Rev., 2013, 27, pp. 724-737
4. Ge, Z.W., Li, Y.L., Li, D.C., et al.: 'Thermal energy storage: Challenges andthe role of particle technology', Particuology, 2004, 15, pp. 2-8
5. Felix Regin, A., Solanki, S.C., Saini, J.S.: 'Heat transfer characteristics ofthermal energy storage system using PCM capsules: A review', Renew.Sustain. Energy Rev., 2008, 12, (9), pp. 2438-2458
6. Khodadadi, J.M., Fan, L.W., Babaei, H.: 'Thermal conductivity enhancementof nanostructure-based colloidal suspensions utilized as phase changematerials for thermal energy storage: A review', Renew. Sustain. Energy Rev., 2013, 24, pp. 418-444
7. Dutil, Y., Rousse, D.R., Salah, N.B., et al.: 'A review on phase-changematerials: Mathematical modelling and simulations', Renew. Sustain. EnergyRev., 2011, 15, (1), pp. 112-130
8. Li, M., Wu, Z.S., Tan, J.M.: 'Heat storage properties of the cement mortarincorporate with composite phase change materials', Appl. Energy, 2013, 103, pp. 393-399
9. Karaman, S., Karaipekli, A., Sari, A., et al.: 'Polyethylene glycol (PEG)/diatomite composite as a novel form-stable phase change material for thermalenergy storage', Sol. Energy Mater. Sol. Cells, 2011, 95, pp. 1647-1653
10. Wang, W.L., Yang, X.X., Fang, Y.T., et al.: 'Preparation and performance ofform-stable polyethylene glycol/silicon dioxide composites as solid-liquidphase change materials', Appl. Energy, 2009, 86, (2), pp. 170-174
11. Ye, F., Ge, Z.W., Ding, Y.L.: 'Multi-walled carbon nanotubes added toNa2CO3/MgO composites for thermal energy storage', Particuology, 2013, 15, pp. 56-60
12. Ge, Z.W., Ye, F., Cao, H., et al.: 'Carbonate-salt-based composite materialsfor medium and high temperature thermal energy storage', Particuology, 2014, 15, pp. 77-81
13. Ge, Z.W., Ye, F., Ding, Y.L.: 'Composite materials for thermal energy storage:enhancing performance through microstructures', ChemSusChem, 2014, 7, (5), pp. 1318-1325
14. Oro, E., Chiu, J., Martin, V., et al.: 'Comparative study of different numericalmodels of packed bed thermal energy storage systems', Appl. Therm. Eng., 2013, 50, (1), pp. 384-392
15. Ismail, K.A.R., Abugderah, M.M.: 'Performance of a thermal storage systemof the vertical tube type', Energy Convers. Manage., 2000, 41, pp. 1165-1190
16. Wang, M., Pan, N.: 'Predictions of effective physical properties of complexmultiphase materials', Mater. Sci. Eng. R, 2008, 63, (1), pp. 1-30
17. Chan, K.C., Chao, C.Y.H.: 'A theoretical model on the effective stagnantthermal conductivity of an adsorbent embedded with a highly thermalconductive material', Int. J. Heat Mass Transf., 2013, 65, pp. 863-872
18. Dhaidan, N.S., Khodadadi, J.M., Al-Hattab, T.A., et al.: 'Experimental andnumerical investigation of melting of phase change material/nanoparticlesuspensions in a square container subjected to a constant heat flux', Int. J.Heat Mass Transf., 2013, 66, pp. 672-683
19. Abyzov, A.M., Goryunov, A.V., Shakhov, F.M.: 'Effective thermalconductivity of disperse materials. I. Compliance of common models withexperimental data', Int. J. Heat Mass Transf., 2013, 67, pp. 752-767
20. Bahrami, M., Yovanovich, M.M., Culham, J.R.: 'Effective thermalconductivity of rough spherical packed beds', Int. J. Heat Mass Transf., 2006, 49, pp. 3691-3701
21. Bahrami, M., Yovanovich, M.M., Culham, J.R.: 'Thermal joint resistances ofnonconforming rough surfaces with gas-filled gaps', J. Thermophys. HeatTransf., 2004, 18, (3), pp. 326-332
22. Bahrami, M., Yovanovich, M.M., Culham, J.R.: 'Thermal joint resistances ofconforming rough surfaces with gas-filled gaps', J. Thermophys. Heat Transf., 2004, 18, (3), pp. 318-325