Numerical simulation and exergetic performance assessment of charging process in encapsulated ice thermal energy storage system

The solidification process in encapsulated ice thermal energy storage (EITES) system is simulated for water-filled capsules while neglecting storage tank wall effects and heat penetration. Energy and exergy efficiencies were calculated while varying capsule shape, inlet Heat Transfer Fluid (HTF) temperature as well as HTF flow rate. 105 test cases are conducted including seven geometries, five inlet HTF temperatures, and three HTF flow rates. It was found that the energy efficiencies did not accurately reflect system performance, and in all cases, were found to be above 99.96%. However, exergy efficiencies ranged from 78 to 92%, and provided better insight into system losses. The results suggest that an effective way to increase system efficiency is to increase inlet HTF temperature; considerable efficiency gains are possible by setting inlet HTF temperature slightly below solidification temperature. Varying capsule geometry had inconsistent effects on the efficiency, different geometries being optimal in different situations. Surprisingly, viscous dissipation had very little effect on the exergy efficiency and was a source of very little entropy generation. Thus, EITES designers could increase both flow rate and inlet HTF temperature in order to achieve full system charging in an acceptable amount of time.

[1]  Stuart W. Churchill,et al.  COMPREHENSIVE, THEORETICALLY BASED, CORRELATING EQUATIONS FOR FREE CONVECTION FROM ISOTHERMAL SPHERES , 1983 .

[2]  Ibrahim Dincer,et al.  Heat Transfer and Thermodynamic Analyses of Some Typical Encapsulated Ice Geometries During Discharging Process , 2009 .

[3]  Ibrahim Dincer,et al.  Thermodynamic Analysis of Freezing and Melting Processes in a Bed of Spherical PCM Capsules , 2009 .

[4]  Hisham Ettouney,et al.  Heat Transfer During Phase Change of Paraffin Wax Stored in Spherical Shells , 2005 .

[5]  A. Bejan,et al.  Thermal Energy Storage: Systems and Applications , 2002 .

[6]  Kamal Abdel Radi Ismail,et al.  A parametric study on ice formation inside a spherical capsule , 2003 .

[7]  Ibrahim Dincer,et al.  Numerical heat transfer analysis of encapsulated ice thermal energy storage system with variable heat transfer coefficient in downstream , 2009 .

[8]  Yingxin Zhu,et al.  Modeling of thermal processes for internal melt ice-on-coil tank including ice-water density difference , 2001 .

[9]  A. Saito Recent advances in research on cold thermal energy storage , 2002 .

[10]  A. Campos-Celador,et al.  Development and comparative analysis of the modeling of an innovative finned-plate latent heat thermal energy storage system , 2013 .

[11]  Amir Faghri,et al.  Exergy analysis of latent heat thermal energy storage for solar power generation accounting for constraints imposed by long-term operation and the solar day , 2013 .

[12]  Morteza M. Ardehali,et al.  Numerical simulation of water solidification phenomenon for ice-on-coil thermal energy storage application , 2003 .

[13]  Ibrahim Dincer,et al.  Thermal modeling of a packed bed thermal energy storage system during charging , 2009 .

[14]  S. Kalaiselvam,et al.  Energy efficient hybrid nanocomposite-based cool thermal storage air conditioning system for sustainable buildings , 2013 .

[15]  Tarik Kousksou,et al.  Dynamic modelling of the storage of an encapsulated ice tank , 2005 .

[16]  Jerold W. Jones,et al.  Modeling of an ice-on-coil thermal energy storage system , 1996 .

[17]  Ibrahim Dincer,et al.  On thermal energy storage systems and applications in buildings , 2002 .

[18]  V. Voller,et al.  A fixed grid numerical modelling methodology for convection-diffusion mushy region phase-change problems , 1987 .