Concept explainers
A rigid tank contains a mixture of 4 kg of He and 8 kg of O2 at 170 K and 7 MPa. Heat is now transferred to the tank, and the mixture temperature rises to 220 K. Treating the He as an ideal gas and the O2 as a nonideal gas, determine (a) the final pressure of the mixture and (b) the heat transfer.
(a)
The final pressure of the mixture.
Answer to Problem 96RP
The final pressure of the mixture is
Explanation of Solution
Write the expression to caculate the mole number of
Here, molar mass of
Write the expression to caculate the mole number of
Here, molar mass of
Write the expression to caculate the total number of moles
Write the expression to caculate the partial volume of helium
Here, universal gas constant is
Write the equation to calculate the reduced temperature and pressure at initial state.
Write the expression to caculate the partial volume of helium
Here, the compressibility factor is Z
Write the expression to calculate volume of the tank.
Write the expression to calculate partial pressure at final stage.
Write the equation to calculate the reduced temperature of argon gas after mixing.
Here, temperature at final stage is
Write the equation to calculate the reduced volume of argon gas.
Here, the mole number of oxygen gas
Write the equation to calculate the pressure of argon and nitrogen gases.
Write the expression to calculate the total final pressure.
Conclusion:
Substitute
Substitute
Substitute
Substitute
Refer Table A-1, “Molar mass, gas constant, and critical2point properties”, obtain the critical temperature and pressure of oxygen as follows.
Substitue
Substitue
Refer to Figure A-15, obtain the compressibility factor for argon gas by reading the reduced temperature and reduced pressure of
Substitute
Substitute
Substitute
Substitute
Substitute
Refer to Figure A-15, obtain the reduced pressure of argon gas by reading the values of reduced temperature and reduced volume of
Substitute 0.39 for
Substitute
Thus, the final pressure of the mixture is
(b)
The amount of heat transfer into the closed system.
Answer to Problem 96RP
The amount of heat transfer into the closed system is
Explanation of Solution
Write the expression to obtain the initial and final reduced pressure of
Write the equation to calculate the reduced temperature of nitrogen gas.
Here, mixture temperature is
Write the closed system energy balance relation.
Here, input energy is
Write the expression to obtain the initial and final reduced pressure of
Write formula for enthalpy departure factor
Here, the molar enthalpy at ideal gas state is
Rearrange the Equation (XVIII) to obtain
Refer Equation (XIX) express as two states of enthalpy difference (final – initial).
Write the expression to calculate partial pressure at inital stage.
Write the expression to calculate the total inital pressure.
Conclusion:
Substitute
Refer Figure A-29, “Generalized enthalpy departure chart”, obtain the value of
Substitute
Substitute
Substitute
Substitute
Thus, the amount of heat transfer into the closed system is
Want to see more full solutions like this?
Chapter 13 Solutions
THERMODYNAMICS(SI UNITS,INTL.ED)EBOOK>I
- A mixture of 5 kg of Hydrogen and 26 kg of Nitrogen are contained in a piston cylinder assembly at a pressure of 6.78 MPa and a temperature of 125 K. heat is transferred to the device and the mixture expands at a constant pressure until the temperature rises to 135 K. Determine the heat transfer in kJ during the process by treating the mixture as a non-ideal gas and using the Amagat's law.arrow_forwardPlease answer step by steparrow_forwarduestion 4: (a) An 88-litre gas cylinder is filled with propane gas at a pressure of 1.15 MPa and 18°C. The propane is used to fuel a gas burner. After some time, the pressure and temperature are 210 kPa and 23°C respectively. Determine the mass of propane used. The molar mass of propane is 44 g/mole. (b) A piston-cylinder device filled with air at 365 kPa and 12°C, has an initial volume of 1.3 litres. The air is expanded at constant pressure to a volume of 3.6 litres and 516°C. Determine the amount of heat and work involved in this process and state whether the heat and work are into, or out of the gas.arrow_forward
- A rigid container contains 0.5 kmol of Ar and 2 kmol of N2 at 250 kPa and 280 K.The mixture is now heated to 400 K. Determine the volume of the container and the final pressure of the mixture.arrow_forwardA volume of 0.3 m³ of O₂ at 200 K and 8 MPa is mixed with 0.5 m³ of N₂ at the same temperature and pressure, forming a mixture at 200 K and 8 MPa. Determine the volume of the mixture, using (a) the ideal-gas equation of state, (b) Kay's rule, and (c) the compressibility chart and Amagat's law.arrow_forwardThe gas constant of CO2, N2, and He are 0.1889, 0.2968, and 2.077 kJ/kg-°K respectively. The three are mixed with 0.4 kg CO2, 0.7 kg, N2, and 0.05 kg He. The mixture has a temperature of 35°C and pressure of 180 kPa. Calculate the volume of the mixture in cubic meters. 0.1598 0.6625 0.7856arrow_forward
- A closed rigid vessel contains 40% liquid water and 60% water vapor by volume. The liquid-vapor mixture is in equilibrium at 150°C. What is the quality of the mixture?arrow_forwardOn a hot summer day, you decide to make some iced tea. First, you brew 1.50 L of hot tea and leave it to steep until it has reached a temperature of Ttea = 75.0 ∘C. You then add 0.975 kg of ice taken from the freezer at a temperature of Tice = 0 ∘C. By the time the mix reaches equilibrium, all of the ice has melted. What is the final temperature Tf of the mixture? For the purposes of this problem, assume that the tea has the same thermodynamic properties as plain water. The specific heat of water is c = 4190 J/kg⋅∘C The heat of fusion of ice is Lf = 3.33×105 J/kg The density of the tea is ρ tea = 1.00 kg/Larrow_forwardAt 1.2 Mpa, a mixture of saturated steam and liquid water exists in equilibrium.If the specific enthalpy of the mixture is 1700 kJ/kg. Determine the temperature ofmixture. Calculate the quality of steam, percent moisture content of the mixture,specific volume, specific internal energy and specific entropy.arrow_forward
- Thermodynamics questionarrow_forwardA sealed container of volume 7 m3 has two compartments with a barrier in between them. In one compartment, there is O2 at an initial pressure of 3 atm, initial temperature of 540 K, and volume 3 m3. In the other compartment, there is CO2 at an initial pressure of 5 atm, initial temperature of 430 K, and volume 4 m3. The barrier in the middle is punctured and the two gases mix together. What is the final pressure and temperature of the two gases? Options: A) 4.08 atm, 452.42 K B) 3.87 atm, 429.13 K C) 4.08 atm, 476.35 K D) 3.87 atm, 452.42 K E) 4.37 atm, 484.58 Karrow_forwardThe wall separating the two compartments is removed and the two gases are allowed to mix. Assuming constant specific heats, find the simplest expression for the mixture temperature written in the form where m3 and T3 are the mass and temperature of the final mixture, respectivelyarrow_forward
- Elements Of ElectromagneticsMechanical EngineeringISBN:9780190698614Author:Sadiku, Matthew N. O.Publisher:Oxford University PressMechanics of Materials (10th Edition)Mechanical EngineeringISBN:9780134319650Author:Russell C. HibbelerPublisher:PEARSONThermodynamics: An Engineering ApproachMechanical EngineeringISBN:9781259822674Author:Yunus A. Cengel Dr., Michael A. BolesPublisher:McGraw-Hill Education
- Control Systems EngineeringMechanical EngineeringISBN:9781118170519Author:Norman S. NisePublisher:WILEYMechanics of Materials (MindTap Course List)Mechanical EngineeringISBN:9781337093347Author:Barry J. Goodno, James M. GerePublisher:Cengage LearningEngineering Mechanics: StaticsMechanical EngineeringISBN:9781118807330Author:James L. Meriam, L. G. Kraige, J. N. BoltonPublisher:WILEY