A Rankine cycle with superheat uses water as its working fluid. Superheated steam exits the steam generator at 1,800 psia and 1,100°F and exits the condenser as a saturated liquid at 4 psia. The mass flow rate of the water is 205 lbm/s. (a) Determine the exit state of the water from the turbine, the net power produced, and the thermal efficiency of the cycle if the turbine and pump are isentropic. exit state of the water net power produced thermal efficiency MW (b) Determine the exit state of the water from the turbine, the net power produced, and the thermal efficiency of the cycle if the turbine isentropic efficiency is 76% and the pump isentropic efficiency is 68%. exit state of the water net power produced thermal efficiency MW

Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
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A Rankine cycle with superheat uses water as its working fluid. Superheated steam exits the steam generator at 1,800 psia and 1,100°F and exits the
condenser as a saturated liquid at 4 psia. The mass flow rate of the water is 205 lbm/s.
(a) Determine the exit state of the water from the turbine, the net power produced, and the thermal efficiency of the cycle if the turbine and pump are
isentropic.
exit state of the water
net power produced
thermal efficiency
MW
(b) Determine the exit state of the water from the turbine, the net power produced, and the thermal efficiency of the cycle if the turbine isentropic efficiency
is 76% and the pump isentropic efficiency is 68%.
exit state of the water
net power produced
thermal efficiency
MW
Transcribed Image Text:A Rankine cycle with superheat uses water as its working fluid. Superheated steam exits the steam generator at 1,800 psia and 1,100°F and exits the condenser as a saturated liquid at 4 psia. The mass flow rate of the water is 205 lbm/s. (a) Determine the exit state of the water from the turbine, the net power produced, and the thermal efficiency of the cycle if the turbine and pump are isentropic. exit state of the water net power produced thermal efficiency MW (b) Determine the exit state of the water from the turbine, the net power produced, and the thermal efficiency of the cycle if the turbine isentropic efficiency is 76% and the pump isentropic efficiency is 68%. exit state of the water net power produced thermal efficiency MW
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