Abstract
The latest developments in solar technologies demonstrated that the solar central receiver configuration is the most promising application among concentrated solar power (CSP) plants. In CSPs solar-heated air can be used as the working fluid in a Brayton thermal cycle and as the heat transfer fluid for a Rankine thermal cycle as an alternative to more traditional working fluids thereby reducing maintenance operations and providing the power section with a higher degree of flexibility To supply thermal needs when the solar source is unavailable, an auxiliary burner is requested. This configuration is adopted in the Julich CSP (J-CSP) plant, operating in Germany and characterized by a nominal power of 1.5 MW, the heat transfer fluid (HTF) is air which is heated in the solar tower and used to produce steam for the bottoming Rankine cycle. In this paper, the J-CSP plant with thermal energy storage has been compared with a hybrid CSP plant (H-CSP) using air as the working fluid. Thermodynamic and economic performances of all the simulated plants have been evaluated by applying both exergy analysis and thermoeconomic analysis (TA) to determine the yearly average operation at nominal conditions. The exergy destructions and structure as well as the exergoeconomic costs of products have been derived for all the components of the plants. Based on the obtained results, the thermoeconomic design evaluation and optimization of the plants has been performed, allowing for improvement of the thermodynamic and economic efficiency of the systems as well as decreasing the exergy and exergoeconomic cost of their products.
Highlights
This is composed of a gas (GT), a CMP, an an heat recovery steam generator (HRSG), a steam turbine (ST), and plant is composed of a turbine gas turbine (GT), a CMP, HRSG, a ST, anda awater-cooled water-cooledsurface surface condenser
Results provided by the thermoeconomic analysis (TA) allow for the optimization of the selected systems in terms of exergy and exergoeconomic costs
The two configurations have been compared with a conventional cycle power plant (CCPP) in order to quantify benefits and drawbacks of Concentrated solar power (CSP)
Summary
The second half of the 20th century underwent a rapid and worldwide increase of atmospheric pollution levels, which has forced many countries to invest in eco-friendly energy conversion processes. Energy analysis and performance evaluations of solar central receiver thermal power systems and components can be found in the literature [10,11,12,13,14]. The thermodynamic and economic performance of a combined-cycle solar tower power plant with thermal energy storage for a variety of operating conditions and superstructure layouts are presented in [16]. They concluded that, when properly designed, solar thermal power plants based on combined-cycles are both economically and thermodynamically promising, with levelized energy costs competitive with those for other solar thermal power plant configurations. The present study proposes a possible benchmark as an exergy based method for future analysis about the thermodynamic and economic performances of alternative CSP plant configurations
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