3 of 3Seatwork 1 VaporCompressionState1234<10260260>рTS(lbf/in.2) (°F) (Btu/lb) (Btu/lb.°F0.2391Determine:- / 400102.9134.7Sat. 61.0210 Sat. 61.0201:23:57(c) the coefficient of performance.:0.2391(a) the compressor power, in horsepower.(b) the rate of heat transfer, from theworking fluid passing through thecondenser, in Btu/min.0.1181 3 of 3Seatwork 1 VaporCompression<StateExpansionvalveThe figure below provides steady-stateoperating data for an ideal vapor-compression refrigeration cycle withRefrigerant 134a as the working fluid. Themass flow rate of refrigerant is 30.59lb/min.Hot regionloutCondenser- / 40Compressorm₁ = 30.59EvaporatorlinCold regionElbmin01:24:03ThSр(lbf/in.2) (°F) (Btu/lb) (Btu/lb ºf

The figure below provides steady-state operating data for an ideal vapor- compression refrigeration cycle with Refrigerant 134a as the working fluid. The mass flow rate of refrigerant is 30.59 lb/min.

The figure below provides steady-state operating data for an ideal vapor- compression refrigeration cycle with Refrigerant 134a as the working fluid. The mass flow rate of refrigerant is 30.59 lb/min.

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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3 of 3
Seatwork 1 Vapor
Compression
State
1
2
3
4
<
10
260
260
>
р
T
S
(lbf/in.2) (°F) (Btu/lb) (Btu/lb.°F
0.2391
Determine:
- / 40
0
102.9
134.7
Sat. 61.02
10 Sat. 61.02
01:23:
57
(c) the coefficient of performance.
:
0.2391
(a) the compressor power, in horsepower.
(b) the rate of heat transfer, from the
working fluid passing through the
condenser, in Btu/min.
0.1181

3 of 3
Seatwork 1 Vapor
Compression
<
State
Expansion
valve
The figure below provides steady-state
operating data for an ideal vapor-
compression refrigeration cycle with
Refrigerant 134a as the working fluid. The
mass flow rate of refrigerant is 30.59
lb/min.
Hot region
lout
Condenser
- / 40
Compressor
m₁ = 30.59
Evaporator
lin
Cold region
E
lb
min
01:24:
03
T
h
S
р
(lbf/in.2) (°F) (Btu/lb) (Btu/lb ºf

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