Question 1 Refrigerant 134a enters an insulated diffuser as a saturated vapor at 80°F with a...
Refrigerant-134a enters a diffuser as saturated vapor at 800kpa with a velocity of 120m/s, and leaves the device at 900kpa and 40^C. The R-134a is gaining energy by heat transfer at a rate of 2kW as it passes through the diffuser. If the exit area is 80% greater than the inlet area, determine the exit velocity m/s, and the mass flow rate kg/s.
Problem 4.041 SI Refrigerant 134a enters an insulated compressor operating at steady state as saturated vapor at -26°C with a volumetric flow rate of 0.18 m3/s. Refrigerant exits at 9 bar, 70°C. Changes in kinetic and potential energy from inlet to exit can be ignored. Determine the volumetric flow rate at the exit, in m3/s, and the compressor power, in kW.
Problem 4.021 Your answer is partially correct. Try again. Refrigerant 134a enters a well-insulated nozzle at 200 Ibf/in.2, 170°F, with a velocity of 120 ft/s and exits at 10 Ibf/in.2 with a velocity of 1500 ft/s For steady-state operation, and neglecting potential energy effects, determine the temperature, in °F, and the quality of the refrigerant at the exit. T2 -29.52 x2872284 OF Problem 4.021 Your answer is partially correct. Try again. Refrigerant 134a enters a well-insulated nozzle at 200 Ibf/in.2,...
Refrigerant 134a enters a compressor with a mass flow rate of 15 kg/s with a velocity of 10 m/s. The refrigerant enters the compressor as a saturated vapor at 10°C and leaves the compressor at 1400 kPa with an enthalpy of 281.39 kJ/kg with a negligible velocity. The rate of work done on the refrigerant is measured to be 380 kW. If the elevation change between the compressor inlet and exit is negligible, determine the rate of heat transfer associated...
2. Saturated vapor of refrigerant 134a enters a well-insulated compressor at 140 kPa and leaves at 800 kPa and 50°C at a flowrate of 0.04 kg/s. Estimate the work done by the compressor.
Refrigerant 134a enters a well-insulated nozzle at 14 bar, 60°C, with a velocity of 40 m/s and exits at 1.2 bar with a velocity of 460 m/s. For steady-state operation, and neglecting potential energy effects, determine: (a) the exit temperature, in K.
Refrigerant 134a enters a turbine with a mass flow rate of 12 kg/s at 54°C, 3 MPa, while the velocity is negligible. The refrigerant expands in the turbine to a saturated vapor at 400 kPa where 10 percent of the steam is removed for some other use. The remainder of the refrigerant continues to expand to the turbine exit where the pressure is 5 kPa and quality is 75 percent. If the turbine is adiabatic, determine the rate of work...
4. Refrigerant- 134a enters an adiahaticpressor as saturated vapor at 240°C and leaves at 09 MIPa and 60°C. The mass flow rate of the refrigerant is 1.2 kg/s. Determine (a) the power input to the compressor and (b) the volume flow rate of the refrigerant at the compressor inlet
6-17 Refrigerant-134a enters the compressor of a refrig- cration system as saturated vapor at 0.14 MPa and leaves as superheated vapor at 0.8 MPa and 60°C at a rate of 0.06 kg/s. Determine the rates of energy transfers by mass into and out of the compressor. Assume the kinetic and potential cncrgics to be negligible.
Refrigerant 134a is the working fluid in an ideal vapor-compression refrigeration cycle. Saturated vapor enters the compressor at h = 400 J/kg and saturated liquid leaves the condenser at h= 242 J/kg. If the mass flow rate of the refrigerant is 0.08 kg/s, and superheated vapor exits the compressor at h = 420 J/kg, pression work will be equal to 1.6 kW inch-h) 6.08(420 - 6oo) = 1.6