Section IV – First Law Applied to Open SystemsPage 1
SECTION IV – FIRST LAW APPLIED TO OPEN SYSTEMS
Refrigerant-12 vapour enters a steady-flow compressor as a saturated vapour at 12C. The outlet conditions are 0.6 MPa and 50C, and the process is assumed to be adiabatic. Calculate the power in Kilowatts, required if the refrigerant flow rate is 20 kg/min. Determine the diameter of the inlet tubing to the compressor if the inlet velocity is not to exceed 3 m/s.
Schematic of compressor
Inlet conditions TI = 12C, saturated vapour
Exit Conditions
Pe = 0.6 MPa, Te = 50C
Pe < Osat = 1.2193 MPa corresponding to
Te = 50C Refrigerant-12 is superheated
at the exit.
Process is adiabetic
Flow through compressor is steady
Assumptions
- Properties are uniformly distributed at the inlet and exit.
- epot and ekin are negligible compared to h.
Steady-state, steady-flow form of the conservation of energy for the compressor as an open system is then:
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Steam enters a turbine at 600C and 6 MPa with a velocity of 300 m/s. The mass flow rate entering the turbine is 400 kg/min. Assume the turbine is well-insulated and the exhaust steam leaves the turbine at a low velocity. The steam exits the turbine at 200 KPa and 260C. Calculate the power developed by the turbine and the inlet-duct area.
Schematic of turbine
Inlet Conditions: TI = 600C, PI = 6 MPa,
Exit Conditions: Te = 260C, Pe = 200 KPa
Turbine is well-insulated
Assumptions
- flow through turbine is steady i.e. no mass build-up in turbine
- flow properties are uniformly distributed at the inlet and exit to turbine
- changes in potential energy of working fluid are negligible compared to change in enthalpy
- neglect kinetic energy at the exit since the velocity will be low
Steady-state, steady-flow form the conservation of energy for the turbine as an open system is then:
- steam is superheated at the inlet since T > Tsat = 275.64C corresponding to P = 6 MPa hI = 3658.4
- steam is also superheated at the outlet since P < Psat = 4.688 Mpa corresponding to P = 200 KPa
4-64 Boles & Cengel
Refrigerant –12 at 1MPa and 80C is cooled to 1MPa and 30C in a condenser by air. The air enters at 100KPa and 27C with a volume flow rate of 800 m3/min and leaves at 95KPa and 60C. Determine the mass flow rate of the refrigerant.
Can air be treated as an ideal gas under the given conditions?
Z3 = Z4 1 (See p. 807 of Text)
Assumptions:
- Flow of Refrigerant –12 is steady
- Flow of air is steady
- Heat lost by R-12 is gained by air Qie air = -Qie R-12
- Properties are uniformly distributed at 1 & 2 and at 3 & 4.
- Conservation of energy applied to the flow of air:
ie air ie air = (h4 – h3)
see p. 788 of text
- Conservation of energy applied to the flow of Refrigerant –12:
(no work done on or by the Refrigerant –12)
T1 = 80C Tsat = 41.64C corresponding to P1 = 1MPa R-12 is a superheated vapor at 1
h1 = 232.91 KJ/Kg (see p.784 of Text)
T2 = 30C Tsat = 41.64C corresponding to P2 = 1MPa R-12 is a subcooled liquid at 2
(see pp. 780-781 of text)
The operating data from the simple, steady-flow, steam-power plant cycle shown in the accompanying figure are summarized in the table below. Determine the power output of the turbine, the heat-transfer rate in the steam generator, the power input to the pump, and the thermal efficiency of the cycle.
10.010.0
248°C
35450° C
40.95
Other data:
Mass flow rate of steam = 20 kg/s
Negligible pressure drops through steam generator and condenser
1 / 0.01 / 0.0
2 / 5 / 48C
3 / 5 / 450
4 / 0.01 / 0.95
Assumptions:
- ep < h, ek < h for all units
- Properties are uniformly distributed at the inlet and exit of each unit of the cycle
-Pressure drop through steam generator is negligible P2 P3 = 5Mpa
-Pressure drop through condenser is negligible P4 P1 = 0.01 Mpa = 10KPa
- Flow through the steam generator:
First law:
T2 = 48C < Tsat = 263.99C
Corresponding to P2 = 5MPa
water is a compressed liquid at state (2)
T3 = 450C > Tsat = 263.99C corresponding to P3 = 5Mpa water is a superheated vapor at state(3).
h3 = 3316.2 KJ/Kg
Flow through the turbine:
First Law:
- Flow through the pump:
First law:
Power input
Flow through the condenser:
First law:
- Thermal Efficiency:
Check:
(17024 – 283.8) = (52203.6 – 45463.4)
16740.216740.2Check!