Given: = 10 MPa T= 600°C = 0.2 MPa 2 21 A. For the turbine, for mass flow rate of 3,000 kg/hr, caiculate: 1. Ideal work, WE, in KW 2. Turbine, isentropic efficiency, n 3. Ideal engine thermal efficiency, e B. For the cycle, calculate: 4. Network, Wat in KW 5. Cycle thermal efficiency, e
Given: = 10 MPa T= 600°C = 0.2 MPa 2 21 A. For the turbine, for mass flow rate of 3,000 kg/hr, caiculate: 1. Ideal work, WE, in KW 2. Turbine, isentropic efficiency, n 3. Ideal engine thermal efficiency, e B. For the cycle, calculate: 4. Network, Wat in KW 5. Cycle thermal efficiency, e
Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
ChapterMA: Math Assessment
Section: Chapter Questions
Problem 1.1MA
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RANKINE CYCLE
![Given:
P = 10 MPa
T= 600°C
2=0.2 MPa
A. For the turbine, for mass flow rate of 3,000 kg/hr, caiculate:
1. Ideal work, WE, in KW
2. Turbine, isentropic efficiency, n
3. Ideal engine thermal efficiency, e
B. For the cycle, calculate:
4. Network, Wnet in KW
5. Cycle thermal efficiency, e.
C. For the actual turbine; mechanical efficiency,n = 84% and generator efficiency,
ng= 93%, calculate:
6. Combined steam rate, w
7. Combined heat rate, kHR
8. Brake engine thermal efficiency, e
9. Brake engine efficiency, n
21
3.](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F3a90d7c3-671c-4e22-940c-f0984fbeeb1f%2Feeeb369e-20cc-42e5-b2db-043119924e9e%2Fbne0q8_processed.png&w=3840&q=75)
Transcribed Image Text:Given:
P = 10 MPa
T= 600°C
2=0.2 MPa
A. For the turbine, for mass flow rate of 3,000 kg/hr, caiculate:
1. Ideal work, WE, in KW
2. Turbine, isentropic efficiency, n
3. Ideal engine thermal efficiency, e
B. For the cycle, calculate:
4. Network, Wnet in KW
5. Cycle thermal efficiency, e.
C. For the actual turbine; mechanical efficiency,n = 84% and generator efficiency,
ng= 93%, calculate:
6. Combined steam rate, w
7. Combined heat rate, kHR
8. Brake engine thermal efficiency, e
9. Brake engine efficiency, n
21
3.
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COMPLETE AND CLEAR SOLUTION PLEASE.
![Given:
P₁ = 10 MPa
•T₁ = 600°C
2 21
1₂ = 0.2 MPa
S](https://content.bartleby.com/qna-images/question/108f8719-3ad1-4b7b-b6fa-8f44fe8c42a2/6affd8d6-74fb-4fdd-86da-03a696cc4a62/9ybskpb_thumbnail.png)
Transcribed Image Text:Given:
P₁ = 10 MPa
•T₁ = 600°C
2 21
1₂ = 0.2 MPa
S
![C. For the actual turbine; mechanical efficiency, n= 84% and generator efficiency.
ng 93%, calculate:
6. Combined steam rate, w
7. Combined heat rate, kHR
8. Brake engine thermal efficiency,
9. Brake engine efficiency, no](https://content.bartleby.com/qna-images/question/108f8719-3ad1-4b7b-b6fa-8f44fe8c42a2/6affd8d6-74fb-4fdd-86da-03a696cc4a62/skcde4t_thumbnail.png)
Transcribed Image Text:C. For the actual turbine; mechanical efficiency, n= 84% and generator efficiency.
ng 93%, calculate:
6. Combined steam rate, w
7. Combined heat rate, kHR
8. Brake engine thermal efficiency,
9. Brake engine efficiency, no
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