solved below........
average velocity of vapor is given Vvap = 75 m/s
So it's clear that the average velocity of the vapor exit port is higher. Because at vapor exit port its pure vapor form, a specific volume of vapor is much much more than the liquid state. So that we can justify that why velocity at vapor exit point is this much higher.
1. (10 points) A saturated water mixture enters a separator, which divides the fluid into a...
PROBLEM 4 A feedwater heater operates at steady state with liquid water entering at inlet 1 at 7 bar, 40°C, and a mass flow rate of 70 kg/s. A separate stream of water enters at inlet 2 as a two-phase liquid-vapor mixture at 7 bar with a quality of 97%. Saturated liquid at 7 bar exits the feedwater heater at 3. Ignoring heat transfer with the surroundings and neglecting kinetic and potential energy effects, determine the mass flow rate, in...
Liquid water enters a
feedwater heater at inlet 1 with inlet condition ls 15 mpa,
40celcius at 60kg/s. Another stream of water in saturated mixture
enters the heater at inlet 2 at temperature of 175 celcius. The
heater operates at steady state and heat transfer to surrounding
can be neglected. At exit 3, saturated liquid flows out at 275 kpa.
Select two different values of mixture quality at inlet 2 between
0.5 and 0.8, and subsequently plot the mass flow...
Question 4 Liquid water enters a feedwater heater at inlet 1 with inlet conditions 15 MPa, 40°C at 60 kg/s. Another stream of water in saturated mixture enters the heater at inlet 2 at temperature of 175 °C. The heater operates at steady state and heat transfer to surrounding can be neglected. At exit 3, saturated liquid flows out at 275 kPa. Select two (2) different values of mixture quality at inlet 2 between 0.5 and 0.8, and subsequently plot...
Question 4 Liquid water enters a feedwater heater at inlet 1 with inlet conditions 15 MPa, 40°C at 60 kg/s. Another stream of water in saturated mixture enters the heater at inlet 2 at temperature of 175 °C. The heater operates at steady state and heat transfer to surrounding can be neglected. At exit 3, saturated liquid flows out at 275 kPa. Select two (2) different values of mixture quality at inlet 2 between 0.5 and 0.8, and subsequently plot...
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
Problem 2: (50 points) Steam is the work Saturated vapor enters the turbine at (50 points) Steam is the working fluid in an ideal Rankine cycle. ated vapor enters the turbine at BO MPa and saturated liquid exits the ser at a pressure of 0.006 MPa. The not power output of the cycle is 500 MW.Also he = 1812.2 kJ/kg and he 157.56 kJ/kg a. Thermal Efficiency (30 points) b. Mass flow rate in kg/h (20 points) c. Bonus: Qin...
Steam is the working fluid in a simple, ideal Rankine cycle. Saturated vapor enters the turbine at 8 MPa and saturated liquid exits the condenser at a pressure of 8 kPa. The net power output of the cycle is 100 MW. Determine for the cycle: i. Thermal efficiency ii. Back work ratio iii. Mass flow-rate of the steam in kg/h iv. Rate of heat transfer to the working fluid as it passes through the boiler in MW v. Rate of...
A gas mixture at 1500 K with the molar analysis 10% C02, 20% H2O, 70% N2 enters a waste-heat boiler operating at steady state, and exits the boiler at 750 K. A separate stream of saturated liquid water enters at 25 bar and exits as saturated vapor with a negligible pressure drop. Ignoring stray heat transfer and kinetic and potential energy changes, determine the mass flow rate of the exiting saturated vapor, in kg per kmol of gas mixture
Water is the working fluid in a Rankine cycle. Superheated vapor enters the turbine at 10 Mpa, 560 C with a mass flow rate of 7.8kg/s and exits at 8 kPa. Saturated liquid enters the pump at 8 kPa. The isentropic turbine efficiency is 85%, and the isentropic pump efficiency is 85%. Cooling water enters the adiabatic condenser at 18 C and exits at 36 C with no significant change in pressure and assuming the specific heat of the cooling...
dtioh before Problemt vapor at 200 kPa. mixing it with saturated water Cold liquid water T, 20-C -200 kP Water Unknown quality P, 200 kPa Mixing Chamber Saturated water vapor P 200 kPa What is the enthalpy for the cold water (stream 1)? What is the enthalpy for the saturated vapor (stream 2)? If both the streams enter the mixing chamber at the same mass flow rate of 0.8 kg/s, determine the enthalpy of the exiting stream.