Abstract:
For developing a sustainable power system, the key is to maximize the use of
available resources with minimal impact on the environment. One technique of
achieving this is waste heat recovery. In this study, the combined cycles are proposed based on the concept of gas turbine waste heat recovery which comprise of
two parts: topping gas turbine and bottoming sCO2 Brayton power cycles. The
combined cycle configurations selected for thermodynamic analysis are the combined gas turbine simple regenerative sCO2 cycle (CGTSRC), the combined gas
turbine recompression sCO2 cycle (CGTREC) and the combined gas turbine preheating sCO2 cycle (CGTPHC). The energy and exergy analysis are conducted to
investigate the power production, exhaust heat recovery, energetic and exergetic
efficiencies of selected cycles for variation in mass flow rate, mass split percentage
and compression ratio. Using Engineering Equation Solver (EES) software, the
thermodynamic calculations and optimization are carried out to find the design
point which provide maximum exergetic efficiency.
In addition to determination of design point, the comparison of selected combined
cycles is performed with simple gas turbine cycle (SGT) and conventional air bottoming combined cycle (ABC) to highlight the thermodynamic and environmental
significance of sCO2 bottoming power cycles. For comparison, heat recovery, power
output of combined and bottoming cycles, mass flow rate, energetic efficiency, exergetic efficiency and environmental impact are considered as the key performance
parameters. The results and comparison indicate that optimum cycle configuration is CGTPHC which provide energy efficiency of 46.8%, exergy efficiency of
64.8% and 47.3 MW combined power output. Moreover, the energetic and exergetic performance of combined supercritical CO2 cycles are better than ABC cycle
and SGT cycle.
The turbomachinery (compressor and turbine) of optimum bottoming sCO2 power
cycle are designed which include the determination of accurate geometry and efficiency using preliminary and 1D mean line design methods. A robust design code
is developed in MATLABr coupled with REFPROP property library for retrieval
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of sCO2 properties. The compressor design code is validated with experimental
results taken from literature. The efficiency of compressor and turbine calculated
from the turbomachinery design code are 81.2% and 86.17%, respectively.