)A compressor is to compress 300 mol/min of methane gas at 27°C from 150 kPa to 750 Problem 2. - kPa. The ratio of constant pressure to constant volume heat capacity is 1.31 for methane: (a), . Please use the molecule weight M = 16 g/mol for methane gas for the calculation. , Calculate the power required if the mechanical efficiency is 80% in an adiabatic compressor.

Introduction to Chemical Engineering Thermodynamics
8th Edition
ISBN:9781259696527
Author:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Publisher:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
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Problem 2. -
)A compressor is to compress 300 mol/min of methane gas at 27°C from 150 kPa to 750
kPa. The ratio of constant pressure to constant volume heat capacity is 1.31 for methane:
Calculate the power required if the mechanical efficiency is 80% in an adiabatic compressor.
Please use the molecule weight M = 16 g/mol for methane gas for the calculation.
(a) .
If the ideal gas law can apply to this adiabatic compression process, what is the temperature
(b)
of the methane gas discharged from the compressor?
4
Transcribed Image Text:Problem 2. - )A compressor is to compress 300 mol/min of methane gas at 27°C from 150 kPa to 750 kPa. The ratio of constant pressure to constant volume heat capacity is 1.31 for methane: Calculate the power required if the mechanical efficiency is 80% in an adiabatic compressor. Please use the molecule weight M = 16 g/mol for methane gas for the calculation. (a) . If the ideal gas law can apply to this adiabatic compression process, what is the temperature (b) of the methane gas discharged from the compressor? 4
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