Application of the exergy flux equation to a closed cycle

Application of the exergy flux equation to a closed cycle [Pg.20]

We next consider the application of the exergy flux equation to a closed cycle plant based on the Joule-Brayton (JB) cycle (see Fig. 1.4), but with irreversible compression and expansion processes—an irreversible Joule-Brayton (IJB) cycle. The T,.s diagram is as shown in Fig. 2.6. [Pg.20]

by addition the exergy equation for the whole cycle is fN- guT = VV uB+X [Pg.20]

The corresponding first law equations for the closed cycle gas turbine plant lead to [Pg.20]

The exergy equation (2.26) enables useful information on the irreversibilities and lost work to be obtained, in comparison with a Carnot cycle operating within the same temperature limits (T ,ax = Ey and T in = To). Note first that if the heat supplied is the same to each of the two cycles (Carnot and IJB), then the work output from the Carnot engine (Wcar) is greater than that of the IJB cycle (Wijg), and the heat rejected from the former is less than that rejected by the latter. [Pg.20]

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