Numerical comparison between single PCM and multi-stage PCM based high temperature thermal energy storage for CSP tower plants

•Thermal behaviors of single and multi PCM thermocline storage are presented.•Temperature response and phase change process within capsules are revealed.•Energy analysis of thermocline latent heat thermal storage systems is presented.•Multi-stage PCM is a promising solution to store thermal energy f...

Full description

Saved in:
Bibliographic Details
Published in:Applied thermal engineering 2018-07, Vol.139, p.609-622
Main Authors: Elfeky, K.E., Ahmed, N., Wang, Qiuwang
Format: Article
Language:English
Subjects:
Concentrating solar power
Energy storage
Exergy
Heat storage
Heat transfer
Latent heat
Mathematical models
Melt temperature
Melting points
Melting temperature
Molten salts
Packed beds
Phase change material
Phase change materials
Physical properties
Solar energy
Spherical capsule
Temperature
Thermal energy
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Thermal behaviors of single and multi PCM thermocline storage are presented.•Temperature response and phase change process within capsules are revealed.•Energy analysis of thermocline latent heat thermal storage systems is presented.•Multi-stage PCM is a promising solution to store thermal energy for CSP plants. This paper is aimed at analyzing the behavior of a packed bed latent heat thermal energy storage system in concentrating solar power (CSP). One way of improving the performance of a latent thermal energy storage system is by implementing the multiple phase change materials (PCMs) design. The behavior of a packed bed latent heat thermal energy storage system at different cases is numerically analyzed. The molten salt is considered for the heat transfer fluid (HTF) with phase change material (PCM) capsules as the filler. In this design, spherical capsules filled with PCMs of different thermo-physical properties are used. The capsules are packed in the bed at different sections based on the PCM melting temperature. The model developed using the Concentric-Dispersion (C-D) equations. The governing equations are solved in MATLAB, and the results obtained are validated against experimental data from the literature. The performance of the systems is calculated. The results show that the three-stage PCMs system with different melting point exhibited the highest energy and exergy efficiency during a charging discharging cycle. Moreover, results show that the three-stage PCMs unit can improve the heat transfer rate greatly and shorten the heat storage time effectively.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2018.04.122