A compressor takes in water at 100. kPa and 235.0 ◦C and discharges it at 1.52...

Q#1 An adiabatic compressor receives air from the ambient at 95 kPa, 20°C, with a low...

Q#1 An adiabatic compressor receives air from the ambient at 95 kPa, 20°C, with a low velocity. At the compressor discharge, air exits at 1.52 MPa, 430°C. The power input to the compressor is 5000 kW. Determine the mass flow rate of air through the compressor.

Air enters the compressor of a gas-turbine plant at ambient conditions of 100 kPa and 25°C...

Air enters the compressor of a gas-turbine plant at ambient conditions of 100 kPa and 25°C with a low velocity and exits at 1 MPa and 347°C with a velocity of 90 m/s. The compressor is cooled at a rate of 1500 kJ/min, and the power input to the compressor is 250 kW. Determine (a) temperature at the compressor exit Investigate the effect of cooling rate from 1300 kJ/min to 1600 kJ/min in steps of 50 kJ/min on the mass...

Mixture of saturated liquid-vapor water enters a compressor with mass flow rate of 2 kg/s, velocity...

Mixture of saturated liquid-vapor water enters a compressor with mass flow rate of 2 kg/s, velocity of 150 m/s, pressure of 10 kpa and quality of 0.85. The substance leaves the compressor with the velocity of 40 m/s at 7 MPa and 450°C. The heat loss from the compressor is 200 kW. Neglecting the changes in potential energy, determine the compressor required power.

air pressure of 103 kPa., entering the compressor at a temperature of 15 degrees Celsius and...

air pressure of 103 kPa., entering the compressor at a temperature of 15 degrees Celsius and a low speed. 1 mPa pressure, 336 degrees Celsius temperature and 106 m / s speed is coming out of the compressor. The compressor is cooled by air at a temperature of 15 degrees Celsius and 26 kW. The power input to the compressor is 298 kW. (cp= 1.005kj/kgK , R=0.287 kj/kgK) a) Find the mass flow of air b) calculate the irreversibility in...

An isentropic compressor that takes in air from the atmosphere at 100 kPa and 300 K...

An isentropic compressor that takes in air from the atmosphere at 100 kPa and 300 K compresses it to 1 MPa. The compressor feeds into a rigid tank that is initially filled with 5 kg of air at a pressure of 500 kPa and a temperature of 500 K. Once the mass in the tank reaches 8 kg, the compressor will stop to prevent the tank from rupturing, which will occur if the pressure exceeds 1000 kPa. a) Determine the...

Air at 100 kPa and 10°C enters a compressor and is brought to 1000 kPa and...

Air at 100 kPa and 10°C enters a compressor and is brought to 1000 kPa and 50°C. The constant pressure heat capacity of air is 1.01 kJ/kg K. If 15 kg/min of air are to be compressed, determine the power require- ment of the compressor. State your assumptions. (12.625 kW)

3. Air with 100 kPa, 300 K flows into the insulating compressor with a flow rate...

3. Air with 100 kPa, 300 K flows into the insulating compressor with a flow rate of 2 kg/s, compressed to 1000 kPa and then discharged to the exit. The back entropy efficiency of the compressor is 82%. The gas constant of the ideal gas is the air, and the meanness of the air is , The mean ratio is k=1.4. Ignore kinetic energy and position energy. 1) Draw a schematic diagram and a T-s plot of the compressor. 2)...

Air enters the compressor of an ideal gas refrigeration cycle at 7oC and 40 kPa and...

Air enters the compressor of an ideal gas refrigeration cycle at 7oC and 40 kPa and the turbine at 37oC and 170 kPa. The mass flow rate of air through the cycle is 0.3 kg/sec. Assuming variable specific heats for air, determine (a) the rate of refrigeration, (b) the net power input, and (c) the coefficient of performance. Also, draw the T-s diagram of the gas refrigeration cycle.   

Consider an ideal gas refrigeration cycle using helium as the working fluid. Helium enters the compressor...

Consider an ideal gas refrigeration cycle using helium as the working fluid. Helium enters the compressor at 105 kPa and 18°C and compressed to 410 kPa. Helium is then cooled to 19°C before it enters the turbine. Assume constant heat capacity of helium. For a mass flow rate of 0.21 kg/s, the net power input required is a. 96.1652 kW b. 63.0826 kW c. 48.0826 kW d. 81.1652 kW

Air at a pressure of 101 kPa and temperature of 288 K enters an axial compressor...

Air at a pressure of 101 kPa and temperature of 288 K enters an axial compressor stage with a velocity of 170 m/s. There are no guide vanes, so the air enters in the axial direction only. When traveling through the rotor, the air turns 15 degrees. This means the angle of the relative velocity with respect to the axis is 15 degrees greater when entering the rotor than when it leaves. The rotor spins at 8000 rpm and has...