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Abstract
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In this study, a novel geothermal-driven combined power and dual ejector refrigeration (CPDER) system using
the zeotropic mixture as the working fluid with composition adjustable is presented, investigated, and assessed
from an exergoeconomic viewpoint. The proposed system includes two ejector refrigeration subsystems connected
in parallel mode. The zeotropic mixture is distributed into these subsystems through a vapor-liquid
separator with various compositions. To represent the superiority of the proposed CPDER system compared to
the conventional ones, a comprehensive parametric perusal is conducted. The results reveal that the mixture
composition and outlet pressure of the turbine have the biggest impact on the total exergy destruction and the net
power output, while the outlet temperature of the evaporator has the biggest effect on the refrigeration capacity.
Furthermore, optimal operating condition is found through a tri-objective optimization process where energy
efficiency, exergy efficiency, and overall unit cost of products are chosen as objective functions. The optimization
results detect that for the proposed CPDER system, the energy efficiency and exergy efficiency improve by 6.0%
and 11.9%, respectively. In this case, a decrement of 1.18 $/GJ (10.7%) is obtained in the overall unit cost of
products compared to the conventional CPER system.
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