Figure below shows a two-stage vapor-compression refrigeration system with ammonia as the working fluid. The system uses a direct-contact heat exchanger to achieve intercooling. The evaporator has a refrigerating capacity of 30 tons and produces −20°F saturated vapor at its exit. In the first compressor stage, the refrigerant is compressed adiabatically to 80 lbf/ in 2 , which is the pressure in the direct contact heat exchanger. Saturated vapor at 80 lbf/ in 2 enters the second compressor stage and is compressed adiabatically to 250 lbf/ in 2 . Each compressor stage has an isentropic efficiency of 85%. There are no significant pressure drops as the refrigerant passes through the heat exchangers. Saturated liquid enters each expansion valve. Determine a) the ratio of mass flow rates, ?̇ 3 /?̇ 1 b) the power input to each compressor stage, in horsepower. c) the coefficient of performance.
Figure below shows a two-stage vapor-compression refrigeration system with ammonia as the working fluid. The system uses a direct-contact heat exchanger to achieve intercooling. The evaporator has a refrigerating capacity of 30 tons and produces −20°F saturated vapor at its exit. In the first compressor stage, the refrigerant is compressed adiabatically to 80 lbf/ in 2 , which is the pressure in the direct contact heat exchanger. Saturated vapor at 80 lbf/ in 2 enters the second compressor stage and is compressed adiabatically to 250 lbf/ in 2 . Each compressor stage has an isentropic efficiency of 85%. There are no significant pressure drops as the refrigerant passes through the heat exchangers. Saturated liquid enters each expansion valve. Determine a) the ratio of mass flow rates, ?̇ 3 /?̇ 1 b) the power input to each compressor stage, in horsepower. c) the coefficient of performance.
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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Question
Figure below shows a two-stage vapor-compression refrigeration system with ammonia
as the working fluid. The system uses a direct-contact heat exchanger to achieve intercooling. The
evaporator has a refrigerating capacity of 30 tons and produces −20°F saturated vapor at its exit.
In the first compressor stage, the refrigerant is compressed adiabatically to 80 lbf/ in 2 , which is the
pressure in the direct contact heat exchanger. Saturated vapor at 80 lbf/ in 2 enters the second
compressor stage and is compressed adiabatically to 250 lbf/ in 2 . Each compressor stage has an
isentropic efficiency of 85%. There are no significant pressure drops as the refrigerant passes
through the heat exchangers. Saturated liquid enters each expansion valve. Determine
a) the ratio of mass flow rates, ?̇ 3 /?̇ 1
b) the power input to each compressor stage, in horsepower.
c) the coefficient of performance.
as the working fluid. The system uses a direct-contact heat exchanger to achieve intercooling. The
evaporator has a refrigerating capacity of 30 tons and produces −20°F saturated vapor at its exit.
In the first compressor stage, the refrigerant is compressed adiabatically to 80 lbf/ in 2 , which is the
pressure in the direct contact heat exchanger. Saturated vapor at 80 lbf/ in 2 enters the second
compressor stage and is compressed adiabatically to 250 lbf/ in 2 . Each compressor stage has an
isentropic efficiency of 85%. There are no significant pressure drops as the refrigerant passes
through the heat exchangers. Saturated liquid enters each expansion valve. Determine
a) the ratio of mass flow rates, ?̇ 3 /?̇ 1
b) the power input to each compressor stage, in horsepower.
c) the coefficient of performance.
Transcribed Image Text:5
Expansion
valve
6
Lout
Condenser
Expansion
valve
an
Direct contact
heat exchanger
8
4
Comp
2
3
Comp
Evaporator
2
in = 30 tons
Wc2
Wc1
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