10–82 The gas-turbine portion of a combined gas-steam power plant has a pressure ratio of 16. Air enters the compressor at 300 K at a rate of 14 kg/s and is heated to 1500 K in the combustion chamber. The combustion gases leaving the gas turbine are used to heat the steam to 400°C at 10 MPa in a heat exchanger. The combustion gases leave the heat exchanger at 420 K. The steam leaving the turbine is condensed at 15 kPa. Assuming all the compression and expansion processes to be isentropic, determine (a) the mass flow rate of the steam, (b) the net power output, and (c) the thermal efficiency of the combined cycle. For air, assume constant specific heats at room temperature. Answers: (a) 1.275 kg/s, (b) 7819 kW, (c) 66.4 percent
10–82 The gas-turbine portion of a combined gas-steam power plant has a pressure ratio of 16. Air enters the compressor at 300 K at a rate of 14 kg/s and is heated to 1500 K in the combustion chamber. The combustion gases leaving the gas turbine are used to heat the steam to 400°C at 10 MPa in a heat exchanger. The combustion gases leave the heat exchanger at 420 K. The steam leaving the turbine is condensed at 15 kPa. Assuming all the compression and expansion processes to be isentropic, determine (a) the mass flow rate of the steam, (b) the net power output, and (c) the thermal efficiency of the combined cycle. For air, assume constant specific heats at room temperature. Answers: (a) 1.275 kg/s, (b) 7819 kW, (c) 66.4 percent
Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
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See the following pic:
![10–82 The gas-turbine portion of a combined gas–steam power plant has a pressure ratio of 16. Air enters the compressor at
300 K at a rate of 14 kg/s and is heated to 1500 K in the combustion chamber. The combustion gases leaving the gas turbine are
used to heat the steam to 400°C at 10 MPa in a heat exchanger. The combustion gases leave the heat exchanger at 420 K. The
steam leaving the turbine is condensed at 15 kPa. Assuming all the compression and expansion processes to be isentropic,
determine (a) the mass flow rate of the steam, (b) the net power output, and (c) the thermal efficiency of the combined cycle. For
air, assume constant specific heats at room temperature. Answers: (a) 1.275 kg/s, (b) 7819 kW, (c) 66.4 percent](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F80f7c260-381e-459c-a1c9-46e439766b69%2F0ee49f7c-9a52-4613-87f2-181775c12fa4%2Fteg7dp_processed.png&w=3840&q=75)
Transcribed Image Text:10–82 The gas-turbine portion of a combined gas–steam power plant has a pressure ratio of 16. Air enters the compressor at
300 K at a rate of 14 kg/s and is heated to 1500 K in the combustion chamber. The combustion gases leaving the gas turbine are
used to heat the steam to 400°C at 10 MPa in a heat exchanger. The combustion gases leave the heat exchanger at 420 K. The
steam leaving the turbine is condensed at 15 kPa. Assuming all the compression and expansion processes to be isentropic,
determine (a) the mass flow rate of the steam, (b) the net power output, and (c) the thermal efficiency of the combined cycle. For
air, assume constant specific heats at room temperature. Answers: (a) 1.275 kg/s, (b) 7819 kW, (c) 66.4 percent
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