Performance optimization and entropy-TOPSIS evaluation of a thermochemical solar thermal power generation system based on packed bed reactor exothermic characteristics
Journal article
Chen, J., Yang, X., Cui, J., Huo, Y. and Xie, J. 2025. Performance optimization and entropy-TOPSIS evaluation of a thermochemical solar thermal power generation system based on packed bed reactor exothermic characteristics. Energy Conversion and Management. 336. https://doi.org/10.1016/j.enconman.2025.119891
| Authors | Chen, J., Yang, X., Cui, J., Huo, Y. and Xie, J. |
|---|---|
| Abstract | Solar thermal power generation technology has enormous potential in global low-carbon energy transition, but its large-scale development is still constrained by solar intermittency and system stability issues. This study focuses on diatomite-modified calcium-based materials, revealing that diatomite modification transforms the exothermic reaction mechanism from an A3 model to a D2 model, significantly reducing activation energy by 8.69% and increasing the pre-exponential factor by 18.19%. The exothermic process in packed bed reactors was thoroughly investigated, illustrating the evolution patterns of temperature field, reaction extent, and pressure field. An innovative design incorporating intermediate air pathways was proposed, reducing reaction time by 28.57%. A novel thermochemical solar thermal power generation (TSTPG) system was established to systematically examine its performance from the perspective of reactor heat release characteristics. Through a comprehensive 4E (energy, exergy, economy, and environment) analysis framework, the mechanism of reactor parameter optimization on system energy efficiency improvement, exergy loss reduction, CO2 emission reduction, and economic benefits was systematically investigated. A multi-dimensional evaluation methodology based on entropy-TOPSIS (Technique for Order Preference by Similarity to Ideal Solution) was proposed, incorporating power generation capacity, energy efficiency, exergy efficiency, annual total cost, and carbon emission reduction. Results demonstrate that the newly established system achieved impressive energy and exergy efficiencies of 56.86% and 49.06% respectively under optimal conditions (650 K), along with power generation of 48.31 MWh and a total annual cost of 4.11 m$/year, showing promising prospects for engineering applications. |
| Keywords | Thermochemical energy storage; Packed bed reactor; Solar thermal power generation system; 4E analysis; Entropy-TOPSIS method |
| Year | 2025 |
| Journal | Energy Conversion and Management |
| Journal citation | 336 |
| Publisher | Elsevier |
| ISSN | 1879-2227 |
| Digital Object Identifier (DOI) | https://doi.org/10.1016/j.enconman.2025.119891 |
| Web address (URL) | https://www.sciencedirect.com/science/article/pii/S0196890425004157 |
| Accepted author manuscript | License File Access Level Open |
| Output status | Published |
| Publication dates | 01 Jun 2025 |
| Online | 08 May 2025 |
| Publication process dates | |
| Accepted | 01 May 2025 |
| Deposited | 13 May 2025 |
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