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Abstract
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To reduce the fossil fuels consumption and their environmental impact, improve the waste heat efficiency, an
enhanced transcritical CO2 ejector based combined cooling and power system is proposed using recovered waste
heat. This system can employ in vehicles and make them run more environmentally friendly. The new proposed
system includes a power generation part and a transcritical ejector based refrigeration system. A thermodynamical
model is developed to evaluate the enhanced proposed system. A comprehensive parametric investigation
and thermoeconomic analysis are presented to study the effects of key parameters on the thermoeconomic
performance of the system. The results show that back pressure of ejector (gas cooler pressure) plays
the main role to improve the system performance. A 10 bar increase in ejector back-pressure of ejector leads to
an increase of 16.4% in energy efficiency while the exergy efficiency decreases of 9.2%. From exergy analysis, it
is found that the biggest irreversibility in the system belongs to the internal heat exchanger used between pump
and turbine outflows. For the cooling capacity of 10 kW, a multi-objective optimization is carried out and the
optimal values of energy and exergy efficiencies obtained from the Pareto frontier results are 27.42% and
24.21%, respectively, while it leads to the net power output of 7.55 kW. In this case, the net present value and
the simple payback period of the proposed system are equal to 0.3419 M$ and about 4 years and 6 months,
respectively.
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