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Power Optimization of a Modified Closed Binary Brayton Cycle with Two Isothermal Heating Processes and Coupled to Variable-Temperature Reservoirs

Chenqi Tang, Lingen Chen, Huijun Feng, Wenhua Wang, Yanlin Ge

2020Energies18 citationsDOIOpen Access PDF

Abstract

A modified closed binary Brayton cycle model with variable isothermal pressure drop ratios is established by using finite time thermodynamics in this paper. A topping cycle, a bottoming cycle, two isothermal heating processes and variable-temperature reservoirs are included in the new model. The topping cycle is composed of a compressor, a regular combustion chamber, a converging combustion chamber, a turbine and a precooler. The bottoming cycle is composed of a compressor, an ordinary regenerator, an isothermal regenerator, a turbine and a precooler. The heat conductance distributions among the six heat exchangers are optimized with dimensionless power output as optimization objective. The results show that the double maximum dimensionless power output increases first and then tends to be unchanged while the inlet temperature ratios of the regular combustion chamber and the converging combustion chamber increase. There also exist optimal thermal capacitance rate matchings among the working fluid and heat reservoirs, leading to the optimal maximum dimensionless power output.

Topics & Concepts

Brayton cycleIsothermal processThermodynamicsRegenerative heat exchangerCombustion chamberMechanicsGas compressorTurbineMaterials scienceDimensionless quantityHeat exchangerWorking fluidCombustionNuclear engineeringChemistryEngineeringPhysicsOrganic chemistryAdvanced Thermodynamics and Statistical MechanicsThermodynamic and Exergetic Analyses of Power and Cooling SystemsAdvanced Thermodynamic Systems and Engines
Power Optimization of a Modified Closed Binary Brayton Cycle with Two Isothermal Heating Processes and Coupled to Variable-Temperature Reservoirs | Litcius