Abstract
This work presents an innovative indirect supercritical CO2 – air driven concentrated solar power plant with a packed bed thermal energy storage. High supercritical CO2 turbine inlet temperature can be achieved, avoiding the temperature limitations set by the use of solar molten salts as primary heat transfer fluid. The packed bed thermal energy storage enables the decoupling between solar irradiation collection and electricity production, and it grants operational flexibility while enhancing the plant capacity factor. A quasi steady state thermo-economic model of the integrated concentrating solar power plant has been developed. The thermo-economic performance of the proposed plant design has been evaluated via multi-objective optimizations and sensitivity analyses. Results show that a Levelized Cost of Electricity of 100 $/MWhe and a capacity factor higher than 50% can be achieved already at a 10 MWe nominal size. Such limited plant size bounds the capital investment and leads to more bankable and easily installable plants. Results also show that larger plants benefit from economy of scale, with a 65 $/MWhe cost identified for a 50 MWe plant. The receiver efficiency is found to be the most influential assumption. A 20% decrease of receiver efficiency would lead to an increase of more than 15% of the Levelized Cost of Electricity. These results show the potential of indirect supercritical CO2 – air driven concentrated solar power plant and highlight the importance of further air receiver development. More validations and verification tests are needed to ensure the system operation during long lifetime.
Highlights
Due to rising electricity needs and worsening climatic changes, solar energy has become a major player in the renewable energy market
A first of a kind indirect supercritical CO2 – air driven concentrated solar plant design integrated with a packed bed thermal energy storage has been introduced and studied
A quasisteady state thermodynamic model coupled with a comprehensive economic description of the integrated concentrating solar plant has been developed and discussed for two plant sizes of 10 and 50 MWe
Summary
Due to rising electricity needs and worsening climatic changes, solar energy has become a major player in the renewable energy market. In this field, concentrated solar power (CSP) plants account for an increasing share of the market (IRENA, 2020). In order to further reduce the costs and enhance the economic viability of CSP plants, the focus of researchers has been placed in increasing the oper ating temperature of the system looking at both new heat transfer fluids (HTF) and power cycles. Particles and gas based receivers have been introduced, they have the potential to reach heat transfer media temperature higher than 1000 ◦C (Ho and Iverson, 2013). Sodium has been identified as a promising HTF for liquid metal based systems (Wood and Drewes, 2019)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
