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The total exergy destruction occurring in a component is not only due to the component itself (endogenous exergy destruction) but is also caused by the inefficiencies of the remaining system components (exogenous exergy destruction). Hence care must be taken in using the total exergy destruction of a component for making decisions to optimize the overall energy system. In this paper, a complex industrial plant is analyzed by splitting the component’s exergy destruction into its endogenous part (the part resulting totally from the component’s irreversibilities) and its exogenous part (resulting from the irreversibilities of the other components within the system). It is observed that the steam generator has the dominant effect. From the total exergy destruction in the steam generator, 1,097.63 kW or 96.95% come from internal irreversibilities in the component, while the influence of other components on the loss of useful work in the steam generator is only 3.05%.

Exergy, Exergy Destruction, Endogenous, Exogenous, Industry

Kelly, S., Tsatsaronis, G., Morosuk, T., 2009, Advanced exergetic analysis: Approaches for splitting the exergy destruction into endogenous and exogenous parts, Energy, 34(3), pp. 384-391.

Frangopoulos, C.A., (Editor), 2009, Exergy, energy system analysis and optimization, 1, EOLSS, Oxford, United Kingdom, 292 p.

Celador, A.C., Iribarren E.P., Lizarraga J.M., Valdes L.A., 2011, The Thermoeconomic analysis of a micro-CHP installation in a tertiary sector building through transient simulation, Proc. of International Conference ECOS 2011, pp. 2958-2971, Novi Sad, Serbia.

Bejan, A., Tsatsaronis, G., Moran, M., 1996, Thermal design & optimization, John Wiley & Sons, Inc, New York, USA, 542 p.

Petrakopoulou F, Tsatsaronis G., Morosuk T., Carassai A., 2012, Conventional and advanced exergetic analyses applied to a combined cycle power plant, Energy, 41(1), pp. 146-152.

Erbay, Z., Hepbasli, A., 2014, Application of conventional and advanced exergy analyses to evaluate the performance of a ground-source heat pump (GSHP) dryer used in food drying, Energy Conversion and Management, 78, pp. 499-507.

Vučković, G., 2013, Examination of energy efficiency of a complex energy plant by applying the method of exergoeconomics, (in Serbian), PhD Thesis, University of Niš, Faculty of Mechanical Engineering, Niš, Serbia, 247 p.

Moran, M., Shapiro, H., 2006, Fundamentals of engineering thermodynamics, John Wiley & Sons, Ltd, West Sussex, England, 831 p.

Szargut J., Morris D., Steward F., 1988, Exergy Analysis of thermal, chemical, and metallurgical processes, New York: Hemisphere Publ. Corp, 332 p.

Gungor A., Tsatsaronis G., Gunerhan H., Hepbasli A., 2015, Advanced exergoeconomic analysis of gas engine heat pump (GEHP) for food drying processes, Energy Conversion and Management, 91, pp. 132-139.

Pandey A.K., Pant P.C., Sastry O.S., Kumar A, Tyagi S.K., 2013, Energy and exergy performance evaluation of a typical solar photovoltaic module, Thermal Science, doi:10.2298/TSCI130218147P.