n ideal gas is compressed through a compressor. At the inlet, the pressure is P1 = 100.00 kPa, and the temperature is T1 = 300.00 K. At the exit, the pressure is P2 = 400.00 kPa, and the temperature is T2 = 330.00 K. The mass flow rate is = 20.00 kg/s . The shaft power input is = 800.00 kW. There is heat loss during the process. The gas constant is R = 0.2870 kPa·m3/(kg·K), and specific heat is Cp=1.0050 kJ/kg·K. Determine the heat loss rate during the process_______(kJ/s)
n ideal gas is compressed through a compressor. At the inlet, the pressure is P1 = 100.00 kPa, and the temperature is T1 = 300.00 K. At the exit, the pressure is P2 = 400.00 kPa, and the temperature is T2 = 330.00 K. The mass flow rate is = 20.00 kg/s . The shaft power input is = 800.00 kW. There is heat loss during the process. The gas constant is R = 0.2870 kPa·m3/(kg·K), and specific heat is Cp=1.0050 kJ/kg·K. Determine the heat loss rate during the process_______(kJ/s)
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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An ideal gas is compressed through a compressor. At the inlet, the pressure is P1 = 100.00 kPa, and the temperature is T1 = 300.00 K. At the exit, the pressure is P2 = 400.00 kPa, and the temperature is T2 = 330.00 K. The mass flow rate is = 20.00 kg/s . The shaft power input is = 800.00 kW. There is heat loss during the process. The gas constant is R = 0.2870 kPa·m3/(kg·K), and specific heat is Cp=1.0050 kJ/kg·K.
Determine the heat loss rate during the process_______(kJ/s)
Transcribed Image Text:An ideal gas is compressed through a compressor. At the inlet, the pressure is P1 = 100.00 kPa, and the temperature is T1 = 300.00 K. At the exit, the
pressure is P2 = 400.00 kPa, and the temperature is T2 = 330.00 K. The mass flow rate is m = 20.00 kg/s. The shaft power input is W. = 800.00 kW.
in
There is heat loss during the process. The gas constant is R = 0.2870 kPa-m³/(kg-K), and specific heat is Cp=1.0050 kJ/kg-K.
Determine the heat loss rate Q during the process
out
_(kJ/s)
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