1. An R22 standard refrigerating cycle operates at an evaporator pressure of 367.01 kPa and a condensing pressure of 1833.45 kPa. It is desired to increase the evaporator pressure from 367.01 to 602.28 kPa. Determine For 367.01 kPa Evaporator (a) temperature and degree superheat leaving the compressor (b) mass of vapor entering evaporator (c) evaporator load (d) condenser load (e) work on the compressor (f) coefficient of performance For 602.28 kPa Evaporator (g) temperature and degree superheat leaving the compressor (h) mass of vapor entering evaporator (i) evaporator load G) condenser load (k) work on the compressor (1) coefficient of performance Show the effects of increasing evaporator pressure (m) condenser load per ton of refrigeration (n) work on compressor per ton of refrigeration (0) mass flow rate of refrigerant per ton of refrigeration (p) volume capacity of compressor per ton of refrigeration 18 answers

Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
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1. An R22 standard refrigerating cycle operates at an evaporator pressure of 367.01 kPa and a condensing pressure
of 1833.45 kPa. It is desired to increase the evaporator pressure from 367.01 to 602.28 kPa.
Determine
For 367.01 kPa Evaporator
(a) temperature and degree superheat leaving the compressor
(b) mass of vapor entering evaporator
(c) evaporator load
(d) condenser load
(e) work on the compressor
(f) coefficient of performance
For 602.28 kPa Evaporator
(g) temperature and degree superheat leaving the compressor
(h) mass of vapor entering evaporator
(i) evaporator load
G) condenser load
(k) work on the compressor
(1) coefficient of performance
Show the effects of increasing evaporator pressure
(m) condenser load per ton of refrigeration
(n) work on compressor per ton of refrigeration
(0) mass flow rate of refrigerant per ton of refrigeration
(p) volume capacity of compressor per ton of refrigeration
18 answers
Transcribed Image Text:1. An R22 standard refrigerating cycle operates at an evaporator pressure of 367.01 kPa and a condensing pressure of 1833.45 kPa. It is desired to increase the evaporator pressure from 367.01 to 602.28 kPa. Determine For 367.01 kPa Evaporator (a) temperature and degree superheat leaving the compressor (b) mass of vapor entering evaporator (c) evaporator load (d) condenser load (e) work on the compressor (f) coefficient of performance For 602.28 kPa Evaporator (g) temperature and degree superheat leaving the compressor (h) mass of vapor entering evaporator (i) evaporator load G) condenser load (k) work on the compressor (1) coefficient of performance Show the effects of increasing evaporator pressure (m) condenser load per ton of refrigeration (n) work on compressor per ton of refrigeration (0) mass flow rate of refrigerant per ton of refrigeration (p) volume capacity of compressor per ton of refrigeration 18 answers
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