Numerical analysis of latent heat thermal energy storage using miniature heat pipes: A potential thermal enhancement for CSP plant development

This paper presents a study, numerically and experimentally, on a new thermal enhancement method for improving the heat transfer performance of latent heat energy storage (LHTES) using miniature heat pipes (MHPs). As commonly known, heat pipes are passive heat transfer devices which are capable in transferring large amount of heat with a small temperature drop. The heat pipe used in this study is copper-water charged MHP and has physical dimensions of 2 mm diameter and 100 mm long. The phase change material (PCM) used in the LHTES is paraffin wax (RT60) which is an organic based PCM and has a melting point of 60 °C. The attractive thermal features of using PCM as thermal mass are high heat capacity, exhibit constant temperature during phase change and poor thermal response. However, the poor thermal conductivity (∼0.2 W/m·K) of the PCM has greatly limited its potential to be used as high heat storing materials for future thermal storage developments. One of the potential developments is the concentrated solar power (CSP) plant, where LHTES can play an important role for improving the power generating efficiency. Providing simple and yet effective thermal enhancement method is favourable for LHTES to be widely applicable. In this study, MHPs are randomly mixed in the PCM to provide better heat spreading and improve the effective thermal conductivity of the LHTES. The numerical method adopted is three-dimensional heat conduction and the numerical results are validated against experimental data. The results have shown that the effective thermal conductivity of MHP-PCM composition has improved exponentially with the increasing number of MHPs used.

[1]  A. B. Duncan,et al.  Experimental Investigation of Micro Heat Pipes Fabricated in Silicon Wafers , 1993 .

[2]  R. Pitchumani,et al.  Analysis and optimization of a latent thermal energy storage system with embedded heat pipes , 2011 .

[3]  Jon P. Longtin,et al.  A One-Dimensional Model of a Micro Heat Pipe During Steady-State Operation , 1994 .

[4]  Yew Mun Hung,et al.  The coupled effects of working fluid and solid wall on thermal performance of micro heat pipes , 2014 .

[5]  S. Khot Enhancement of Thermal Storage System Using Phase Change Material , 2014 .

[6]  Yiding Cao,et al.  Micro/Miniature Heat Pipes and Operating Limitations , 1994 .

[7]  Brett A. Bednarcyk,et al.  Micromechanics of Composite Materials: A Generalized Multiscale Analysis Approach , 2012 .

[8]  Abhijit Date,et al.  Performance of suspended finned heat pipes in high-temperature latent heat thermal energy storage , 2015 .

[9]  S. D. Pohekar,et al.  Performance enhancement in latent heat thermal storage system: A review , 2009 .

[10]  Y. Mai,et al.  Thermal conductivity of misaligned short-fiber-reinforced polymer composites , 2003 .

[11]  Salvatore Vasta,et al.  Thermal conductivity measurement of a PCM based storage system containing carbon fibers , 2005 .

[12]  B. R. Babin,et al.  Steady-State Modeling and Testing of a Micro Heat Pipe , 1990 .

[13]  Doerte Laing,et al.  High-Temperature Solid-Media Thermal Energy Storage for Solar Thermal Power Plants , 2012, Proceedings of the IEEE.

[14]  M. S. Naghavi,et al.  A state-of-the-art review on hybrid heat pipe latent heat storage systems , 2015 .

[15]  A. Akbarzadeh,et al.  A numerical and experimental study of solidification around axially finned heat pipes for high temperature latent heat thermal energy storage units , 2014 .

[16]  A. Sari,et al.  Thermal conductivity improvement of stearic acid using expanded graphite and carbon fiber for energy storage applications , 2007 .

[17]  Qinjun Kang,et al.  Thermal conductivity enhancement of carbon fiber composites , 2009 .

[18]  Tungyang Chen,et al.  Effect of Kapitza contact and consideration of tube-end transport on the effective conductivity in nanotube-based composites , 2005 .

[19]  T. L. Bergman,et al.  Economic evaluation of latent heat thermal energy storage using embedded thermosyphons for concentrating solar power applications , 2011 .

[20]  Claudio Feliciani,et al.  Measurement and numerical prediction of fiber-reinforced thermoplastics' thermal conductivity in injection molded parts , 2014 .

[21]  T. L. Bergman,et al.  High temperature latent heat thermal energy storage using heat pipes , 2010 .

[22]  Thomas Bauer,et al.  Approximate analytical solutions for the solidification of PCMs in fin geometries using effective thermophysical properties , 2011 .

[23]  T. Chou,et al.  Fibre orientation effects on the thermoelastic properties of short-fibre composites , 1981 .

[24]  Hugh W. Coleman,et al.  Experimentation, Validation, and Uncertainty Analysis for Engineers , 2009 .

[25]  Passive cooling of concentrated solar cells using phase change material thermal storage , 2013 .

[26]  Xu Xu,et al.  Experimental study of under-floor electric heating system with shape-stabilized PCM plates , 2005 .

[27]  T. L. Bergman,et al.  Enhancement of latent heat energy storage using embedded heat pipes , 2011 .

[28]  Minoru Taya,et al.  Effective thermal conductivity of a misoriented short fiber composite , 1985 .

[29]  Xiao Hu,et al.  The flexural modulus of misaligned short-fiber-reinforced polymers , 1999 .

[30]  Meysam Rahmat,et al.  Two-phase simulations of micro heat pipes , 2010 .