Exergetic analysis of energy storage using multiple phase-change materials

Journal of Energy Resources Technology, Transactions of the ASME

Volumn 118, Issue 3, 1996, Pages 242-248

  Gong, Z X ^a   Mujumdar, A S ^a  

^a MCGILL UNIVERSITY   (Canada)

Author keywords

[No Author keywords available]

Indexed keywords

ENERGY CONVERSION; HEAT TRANSFER; MATHEMATICAL MODELS; MELTING; NUMERICAL ANALYSIS; TEMPERATURE;

DISTRIBUTED MODEL; EXERGETIC ANALYSIS; HEAT TRANSFER FLUIDS; MULTIPLE PHASE CHANGE MATERIALS; THERMAL STORAGE;

ENERGY STORAGE;

EID: 0030242098     PISSN: 01950738     EISSN: 15288994     Source Type: Journal    
DOI: 10.1115/1.2793869     Document Type: Article

References (13)

1. Aceves-Saborio, S., Nakamura, H., and Reistad, G. M., 1994, “Optimum Efficiencies and Phase Change Temperatures in Latent Heat Storage Systems,” ASME JOURNAL OF ENERGY RESOURCES TECHNOLOGY, Vol. 116, pp. 79-86.
2. Adebiyi, G. A., and Russell, L. D., 1987, “A Second Law Analysis of Phase Change Thermal Energy Storage Systems,” ASME HTD-Vol. 80, pp, 9-20.
3. Adebiyi, G. A., Hodge, B. K., Steele, W. G., Jalaladeh, A., and Nsofor, E. C., 1992, “Computer Simulation of a High Temperature Thermal Energy Storage System Employing Multiple Family of Phase-Change Storage Materials,” ASME AES-Vol. 27/HTD-Vol. 228, pp. 1-11
4. Bjurstrom, R. J., and Carlsson, B., 1985, “An Exergy Analysis of Sensible and Latent Heat Storage,” Heat Recovery Systems, Vol, 5, pp. 233-250.
5. De Lucia, M., and Bejan, N., 1990, “Thermodynamics of Energy Storage by Melting due to Conduction or Natural Convection,” ASME Journal of Solar Energy Engineering, Vol, 112, pp, 110-116
6. Farid, M. M., and Kanzawa, A., 1989, “Thermal Performance of a Heat Storage Module Using PCMs With Different Melting Temperatures; Mathematical Modeling,” ASME JOURNAL OF ENERGY RESOURCES TECHNOLOGY, Vol, 111, pp, 152-157
7. Farid, M. M., Kim, Y., and Kanzawa, A., 1990, “Thermal Performance of a Heat Storage Module Using PCMs With Different Melting Temperatures; Experimental,” ASME JOURNAL OF ENERGY RESOURCES TECHNOLOGY, Vol, 112, pp. 125-131.
8. Gong, Z.-X., Zhang, Y. F., and Mujumdar, A. S., 1991, “Cyclic Phase Change Heat Conduction in Thin Composite Slabs,” Computational Modeling of Free and Moving Boundary Problems, eds., L. C. Wrobel and C. A. Brebbia, Vol, 2, Computational Mechanics Publications, pp. 105-120
9. Gong, Z.-X., and Mujumdar, A. S., 1994, “Cyclical Heat Conduction in Melting and Freezing of Composite Slabs of Different Phase Change Materials,” Proceedings of the 10th International Heat Transfer Conference, Vol, 6, pp, 343-348.
10. Gong, Z.-X., and Mujumdar, A. S., 1995, “A New Solar Receiver Thermal Store for Space-based Activities Using Multiple Composite Phase Change Materials,” ASME Journal of Solar Energy Engineering, Vol, 117, pp, 215-220
11. Gong, Z.-X., and Mujumdar, A. S., 1996, “Enhancement of Energy Charge/Discharge Rates in Composite Slabs of Different Phase Change Materials,” International Journal of Heat Mass Transfer, Vol, 39, pp, 725-733
12. Lim, J. S., Bejan, A., and Kim, J. H., 1992, “Thermodynamic Optimization of Phase-Change Energy Storage Using Two or More Materials,” ASME JOURNAL OF ENERGY RESOURCES TECHNOLOGY, Vol, 114, pp, 84-90
13. Watanabe, T., Kikuchi, H., and Kanzawa, A., 1993, “Enhancement of Charging and Discharging Rates in a Latent Heat Storage System by Use of PCM With Different Melting Temperatures,” Heat Recovery Systems & CHP, Vol, 13, pp, 57-66