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The present study investigates the advanced exergy assessment in a solar absorption power cycle to reveal the inefficiency of the system. Unlike simple exergy assessment, which only assesses exergy destruction, advanced exergy evaluates avoidable, unavoidable, exogenous, and endogenous exergy destructions. EES software is employed to model the proposed absorption power cycle, in which the power is generated using a low-temperature heat source driven by solar energy. The novelties of the present study are the use of solar energy in absorption power and applying the advanced exergy assessment. According to the results, the total energy and exergy efficiencies are 6.655% and 7.011% in the real state, 8.517% and 8.973% in the unavoidable state, and 9.433% and 9.938% in the ideal state, respectively. In other words, both efficiencies improve by 41.7% and 10.75% under ideal and unavoidable conditions compared to the real state, respectively. The outcomes reveal that the unavoidable exergy destruction is greater than the avoidable exergy destruction in the constituents, implying that no structural refinement can be effective in the system. Among the components, 73.69 kW exergy destruction occurs in the solar collector, of which 67.47 kW is endogenous destruction. Also, the unavoidable and avoidable exergy destructions equal 73.03 kW and 0.66 kW in the solar collector, respectively. Moreover, the unavoidable endogenous part accounts for the highest proportion of exergy destruction in the solar collector, while the avoidable exogenous destruction is less than zero. It means that by improving the component itself, it is possible to reduce the exergy destruction. |
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