The final pressure of supercritical methane using ideal gas law . Concept Introduction: Write the expression to calculate the number of moles ( n ) . n = M M W Here, mass is M and molecular weight of methane is MW . Write the expression to calculate the molar volume. V _ = V n Here, volume of the vessel is V . Write the expression to calculate the pressure using Ideal gas. P = R T V _ Here, gas constant is R and temperature is T .

Question

Chemical Engineering Use the psychrometric chart and demonstrate the linear interpolation method to obtain -0.52 KJ/KgDA. This is the enthalpy deviation. The exercise is uploaded below.

Answer 1

Question

Definition Definition Law that is the combined form of Boyle's Law, Charles's Law, and Avogadro's Law. This law is obeyed by all ideal gas. Boyle's Law states that pressure is inversely proportional to volume. Charles's Law states that volume is in direct relation to temperature. Avogadro's Law shows that volume is in direct relation to the number of moles in the gas. The mathematical equation for the ideal gas law equation has been formulated by taking all the equations into account: PV=nRT Where P = pressure of the ideal gas V = volume of the ideal gas n = amount of ideal gas measured in moles R = universal gas constant and its value is 8.314 J.K-1mol-1 T = temperature

Chapter 7.7, Problem 8P

(A)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using ideal gas law.

Concept Introduction:

Write the expression to calculate the number of moles (n).

n=MMW

Here, mass is M and molecular weight of methane is MW.

Write the expression to calculate the molar volume.

V_=Vn

Here, volume of the vessel is V.

Write the expression to calculate the pressure using Ideal gas.

P=RTV_

Here, gas constant is R and temperature is T.

(B)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using van der Waals equation.

Concept Introduction:

Write the expressions to calculate the constants of van der Waals equation of state.

a=27R2Tc264Pc

b=RTc8Pc

Here, critical pressure and critical temperature is Pc and Tc respectively.

Write the van der Waals equation of state.

P=RTV_−b−aV_

(C)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using the Soave equation.

Concept Introduction:

Write the relationship between the parameter, m and Soave’s EOS.

m=0.480+1.574ω−0.176ω2

Here, the acentric factor is ω.

Write the expression to calculate the α expressed as a function of the reduced temperature.

α=[1+m(1−Tr0.5)]2

Here, reduced temperature is Tr.

Write the expression to calculate the reduced temperature.

Tr=TTc

Here, critical temperature is Tc and system temperature is T.

Write the expression to calculate the value of a at the critical point.

a=0.42747R2Tc2Pc×α

Write the expression to calculate the value of b using the Soave equation.

b=0.08664R(TcPc)

Write the expression for Soave equation of state.

P=RTV_−b−aV_(V_+b)

Here, system pressure is P.

(D)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Lee-Kesler generalized correlation.

Concept Introduction:

Write the expression to calculate the compressibility factor (Z).

Z=Z0+ωZ1

Here, compressibility of compound with ω=0 is Z0 and difference between Z0 and Z is Z1.

(E)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Figure 7-1.

Concept Introduction:

Write the expression to calculate the density.

ρ=MV

Here, mass and volume of a vessel is M and V respectively.

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Chemical Engineering Use the psychrometric chart and demonstrate the linear interpolation method to obtain -0.52 KJ/KgDA. This is the enthalpy deviation. The exercise is uploaded below.

Chemical Engineering Use the psychrometric chart. The remaining curves on the psychrometric chart are almost vertical and convex to the left, with labeled values (on Figure 8.4-1) of 0.05, 0.1, 0.2, and so on. (The units of these numbers arekJ/kg DA). Thesecurves are usedto determine theenthalpyof humid air that is not saturated. The procedure is as follows: (a) locate the point on the chart corresponding to air at its specified condition; (b) interpolate to estimate the enthalpy deviation at this point; (c) follow the constant wet-bulb temperature line to the enthalpy scale above the saturation curve, read the value on that scale, and add the enthalpy deviation to it. Also, you will see the exercise on the piece of paper.

Calculate the permeability of the bed of ion-exchange particles in Example 11.1.

Answer 2

Question

Definition Definition Law that is the combined form of Boyle's Law, Charles's Law, and Avogadro's Law. This law is obeyed by all ideal gas. Boyle's Law states that pressure is inversely proportional to volume. Charles's Law states that volume is in direct relation to temperature. Avogadro's Law shows that volume is in direct relation to the number of moles in the gas. The mathematical equation for the ideal gas law equation has been formulated by taking all the equations into account: PV=nRT Where P = pressure of the ideal gas V = volume of the ideal gas n = amount of ideal gas measured in moles R = universal gas constant and its value is 8.314 J.K-1mol-1 T = temperature

Chapter 7.7, Problem 8P

(A)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using ideal gas law.

Concept Introduction:

Write the expression to calculate the number of moles (n).

n=MMW

Here, mass is M and molecular weight of methane is MW.

Write the expression to calculate the molar volume.

V_=Vn

Here, volume of the vessel is V.

Write the expression to calculate the pressure using Ideal gas.

P=RTV_

Here, gas constant is R and temperature is T.

(B)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using van der Waals equation.

Concept Introduction:

Write the expressions to calculate the constants of van der Waals equation of state.

a=27R2Tc264Pc

b=RTc8Pc

Here, critical pressure and critical temperature is Pc and Tc respectively.

Write the van der Waals equation of state.

P=RTV_−b−aV_

(C)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using the Soave equation.

Concept Introduction:

Write the relationship between the parameter, m and Soave’s EOS.

m=0.480+1.574ω−0.176ω2

Here, the acentric factor is ω.

Write the expression to calculate the α expressed as a function of the reduced temperature.

α=[1+m(1−Tr0.5)]2

Here, reduced temperature is Tr.

Write the expression to calculate the reduced temperature.

Tr=TTc

Here, critical temperature is Tc and system temperature is T.

Write the expression to calculate the value of a at the critical point.

a=0.42747R2Tc2Pc×α

Write the expression to calculate the value of b using the Soave equation.

b=0.08664R(TcPc)

Write the expression for Soave equation of state.

P=RTV_−b−aV_(V_+b)

Here, system pressure is P.

(D)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Lee-Kesler generalized correlation.

Concept Introduction:

Write the expression to calculate the compressibility factor (Z).

Z=Z0+ωZ1

Here, compressibility of compound with ω=0 is Z0 and difference between Z0 and Z is Z1.

(E)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Figure 7-1.

Concept Introduction:

Write the expression to calculate the density.

ρ=MV

Here, mass and volume of a vessel is M and V respectively.

Expert Solution & Answer

Trending nowThis is a popular solution!

See solution

Check out sample textbook solution

Answer 3

Question

Definition Definition Law that is the combined form of Boyle's Law, Charles's Law, and Avogadro's Law. This law is obeyed by all ideal gas. Boyle's Law states that pressure is inversely proportional to volume. Charles's Law states that volume is in direct relation to temperature. Avogadro's Law shows that volume is in direct relation to the number of moles in the gas. The mathematical equation for the ideal gas law equation has been formulated by taking all the equations into account: PV=nRT Where P = pressure of the ideal gas V = volume of the ideal gas n = amount of ideal gas measured in moles R = universal gas constant and its value is 8.314 J.K-1mol-1 T = temperature

Chapter 7.7, Problem 8P

(A)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using ideal gas law.

Concept Introduction:

Write the expression to calculate the number of moles (n).

n=MMW

Here, mass is M and molecular weight of methane is MW.

Write the expression to calculate the molar volume.

V_=Vn

Here, volume of the vessel is V.

Write the expression to calculate the pressure using Ideal gas.

P=RTV_

Here, gas constant is R and temperature is T.

(B)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using van der Waals equation.

Concept Introduction:

Write the expressions to calculate the constants of van der Waals equation of state.

a=27R2Tc264Pc

b=RTc8Pc

Here, critical pressure and critical temperature is Pc and Tc respectively.

Write the van der Waals equation of state.

P=RTV_−b−aV_

(C)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using the Soave equation.

Concept Introduction:

Write the relationship between the parameter, m and Soave’s EOS.

m=0.480+1.574ω−0.176ω2

Here, the acentric factor is ω.

Write the expression to calculate the α expressed as a function of the reduced temperature.

α=[1+m(1−Tr0.5)]2

Here, reduced temperature is Tr.

Write the expression to calculate the reduced temperature.

Tr=TTc

Here, critical temperature is Tc and system temperature is T.

Write the expression to calculate the value of a at the critical point.

a=0.42747R2Tc2Pc×α

Write the expression to calculate the value of b using the Soave equation.

b=0.08664R(TcPc)

Write the expression for Soave equation of state.

P=RTV_−b−aV_(V_+b)

Here, system pressure is P.

(D)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Lee-Kesler generalized correlation.

Concept Introduction:

Write the expression to calculate the compressibility factor (Z).

Z=Z0+ωZ1

Here, compressibility of compound with ω=0 is Z0 and difference between Z0 and Z is Z1.

(E)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Figure 7-1.

Concept Introduction:

Write the expression to calculate the density.

ρ=MV

Here, mass and volume of a vessel is M and V respectively.

Expert Solution & Answer

Trending nowThis is a popular solution!

See solution

Check out sample textbook solution

Answer 4

Question

Definition Definition Law that is the combined form of Boyle's Law, Charles's Law, and Avogadro's Law. This law is obeyed by all ideal gas. Boyle's Law states that pressure is inversely proportional to volume. Charles's Law states that volume is in direct relation to temperature. Avogadro's Law shows that volume is in direct relation to the number of moles in the gas. The mathematical equation for the ideal gas law equation has been formulated by taking all the equations into account: PV=nRT Where P = pressure of the ideal gas V = volume of the ideal gas n = amount of ideal gas measured in moles R = universal gas constant and its value is 8.314 J.K-1mol-1 T = temperature

Chapter 7.7, Problem 8P

(A)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using ideal gas law.

Concept Introduction:

Write the expression to calculate the number of moles (n).

n=MMW

Here, mass is M and molecular weight of methane is MW.

Write the expression to calculate the molar volume.

V_=Vn

Here, volume of the vessel is V.

Write the expression to calculate the pressure using Ideal gas.

P=RTV_

Here, gas constant is R and temperature is T.

(B)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using van der Waals equation.

Concept Introduction:

Write the expressions to calculate the constants of van der Waals equation of state.

a=27R2Tc264Pc

b=RTc8Pc

Here, critical pressure and critical temperature is Pc and Tc respectively.

Write the van der Waals equation of state.

P=RTV_−b−aV_

(C)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using the Soave equation.

Concept Introduction:

Write the relationship between the parameter, m and Soave’s EOS.

m=0.480+1.574ω−0.176ω2

Here, the acentric factor is ω.

Write the expression to calculate the α expressed as a function of the reduced temperature.

α=[1+m(1−Tr0.5)]2

Here, reduced temperature is Tr.

Write the expression to calculate the reduced temperature.

Tr=TTc

Here, critical temperature is Tc and system temperature is T.

Write the expression to calculate the value of a at the critical point.

a=0.42747R2Tc2Pc×α

Write the expression to calculate the value of b using the Soave equation.

b=0.08664R(TcPc)

Write the expression for Soave equation of state.

P=RTV_−b−aV_(V_+b)

Here, system pressure is P.

(D)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Lee-Kesler generalized correlation.

Concept Introduction:

Write the expression to calculate the compressibility factor (Z).

Z=Z0+ωZ1

Here, compressibility of compound with ω=0 is Z0 and difference between Z0 and Z is Z1.

(E)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Figure 7-1.

Concept Introduction:

Write the expression to calculate the density.

ρ=MV

Here, mass and volume of a vessel is M and V respectively.

Expert Solution & Answer

Trending nowThis is a popular solution!

See solution

Check out sample textbook solution

Answer 5

Chapter 7.7, Problem 8P

(A)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using ideal gas law.

Concept Introduction:

Write the expression to calculate the number of moles (n).

n=MMW

Here, mass is M and molecular weight of methane is MW.

Write the expression to calculate the molar volume.

V_=Vn

Here, volume of the vessel is V.

Write the expression to calculate the pressure using Ideal gas.

P=RTV_

Here, gas constant is R and temperature is T.

(B)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using van der Waals equation.

Concept Introduction:

Write the expressions to calculate the constants of van der Waals equation of state.

a=27R2Tc264Pc

b=RTc8Pc

Here, critical pressure and critical temperature is Pc and Tc respectively.

Write the van der Waals equation of state.

P=RTV_−b−aV_

(C)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using the Soave equation.

Concept Introduction:

Write the relationship between the parameter, m and Soave’s EOS.

m=0.480+1.574ω−0.176ω2

Here, the acentric factor is ω.

Write the expression to calculate the α expressed as a function of the reduced temperature.

α=[1+m(1−Tr0.5)]2

Here, reduced temperature is Tr.

Write the expression to calculate the reduced temperature.

Tr=TTc

Here, critical temperature is Tc and system temperature is T.

Write the expression to calculate the value of a at the critical point.

a=0.42747R2Tc2Pc×α

Write the expression to calculate the value of b using the Soave equation.

b=0.08664R(TcPc)

Write the expression for Soave equation of state.

P=RTV_−b−aV_(V_+b)

Here, system pressure is P.

(D)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Lee-Kesler generalized correlation.

Concept Introduction:

Write the expression to calculate the compressibility factor (Z).

Z=Z0+ωZ1

Here, compressibility of compound with ω=0 is Z0 and difference between Z0 and Z is Z1.

(E)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Figure 7-1.

Concept Introduction:

Write the expression to calculate the density.

ρ=MV

Here, mass and volume of a vessel is M and V respectively.

Answer 6

Chapter 7.7, Problem 8P

(A)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using ideal gas law.

Concept Introduction:

Write the expression to calculate the number of moles (n).

n=MMW

Here, mass is M and molecular weight of methane is MW.

Write the expression to calculate the molar volume.

V_=Vn

Here, volume of the vessel is V.

Write the expression to calculate the pressure using Ideal gas.

P=RTV_

Here, gas constant is R and temperature is T.

Answer 7

Chapter 7.7, Problem 8P

(A)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using ideal gas law.

Concept Introduction:

Write the expression to calculate the number of moles (n).

n=MMW

Here, mass is M and molecular weight of methane is MW.

Write the expression to calculate the molar volume.

V_=Vn

Here, volume of the vessel is V.

Write the expression to calculate the pressure using Ideal gas.

P=RTV_

Here, gas constant is R and temperature is T.

Answer 8

(B)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using van der Waals equation.

Concept Introduction:

Write the expressions to calculate the constants of van der Waals equation of state.

a=27R2Tc264Pc

b=RTc8Pc

Here, critical pressure and critical temperature is Pc and Tc respectively.

Write the van der Waals equation of state.

P=RTV_−b−aV_

Answer 9

(B)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using van der Waals equation.

Concept Introduction:

Write the expressions to calculate the constants of van der Waals equation of state.

a=27R2Tc264Pc

b=RTc8Pc

Here, critical pressure and critical temperature is Pc and Tc respectively.

Write the van der Waals equation of state.

P=RTV_−b−aV_

Answer 10

(C)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using the Soave equation.

Concept Introduction:

Write the relationship between the parameter, m and Soave’s EOS.

m=0.480+1.574ω−0.176ω2

Here, the acentric factor is ω.

Write the expression to calculate the α expressed as a function of the reduced temperature.

α=[1+m(1−Tr0.5)]2

Here, reduced temperature is Tr.

Write the expression to calculate the reduced temperature.

Tr=TTc

Here, critical temperature is Tc and system temperature is T.

Write the expression to calculate the value of a at the critical point.

a=0.42747R2Tc2Pc×α

Write the expression to calculate the value of b using the Soave equation.

b=0.08664R(TcPc)

Write the expression for Soave equation of state.

P=RTV_−b−aV_(V_+b)

Here, system pressure is P.

Answer 11

(C)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using the Soave equation.

Concept Introduction:

Write the relationship between the parameter, m and Soave’s EOS.

m=0.480+1.574ω−0.176ω2

Here, the acentric factor is ω.

Write the expression to calculate the α expressed as a function of the reduced temperature.

α=[1+m(1−Tr0.5)]2

Here, reduced temperature is Tr.

Write the expression to calculate the reduced temperature.

Tr=TTc

Here, critical temperature is Tc and system temperature is T.

Write the expression to calculate the value of a at the critical point.

a=0.42747R2Tc2Pc×α

Write the expression to calculate the value of b using the Soave equation.

b=0.08664R(TcPc)

Write the expression for Soave equation of state.

P=RTV_−b−aV_(V_+b)

Here, system pressure is P.

Answer 12

(D)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Lee-Kesler generalized correlation.

Concept Introduction:

Write the expression to calculate the compressibility factor (Z).

Z=Z0+ωZ1

Here, compressibility of compound with ω=0 is Z0 and difference between Z0 and Z is Z1.

Answer 13

(D)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Lee-Kesler generalized correlation.

Concept Introduction:

Write the expression to calculate the compressibility factor (Z).

Z=Z0+ωZ1

Here, compressibility of compound with ω=0 is Z0 and difference between Z0 and Z is Z1.

Answer 14

(E)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Figure 7-1.

Concept Introduction:

Write the expression to calculate the density.

ρ=MV

Here, mass and volume of a vessel is M and V respectively.

Answer 15

(E)

Interpretation Introduction

Interpretation:

The final pressure of supercritical methane using Figure 7-1.

Concept Introduction:

Write the expression to calculate the density.

ρ=MV

Here, mass and volume of a vessel is M and V respectively.

Answer 16

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Answer 17

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Answer 27

Ch. 7.6 - Prob. 1E Ch. 7.6 - Prob. 2E Ch. 7.6 - Prob. 3E Ch. 7.6 - Prob. 4E Ch. 7.6 - Prob. 5E Ch. 7.6 - Prob. 6E Ch. 7.6 - Prob. 7E Ch. 7.7 - Prob. 8P Ch. 7.7 - Prob. 9P Ch. 7.7 - Prob. 10P

Solution Summary: The author analyzes the final pressure of supercritical methane using ideal gas law.

Interpretation:

The final pressure of supercritical methane using Lee-Kesler generalized correlation.

Concept Introduction:

Write the expression to calculate the compressibility factor (Z).

Z=Z0+ωZ1

Here, compressibility of compound with ω=0 is Z0 and difference between Z0 and Z is Z1.

Interpretation:

The final pressure of supercritical methane using Figure 7-1.

Concept Introduction:

Write the expression to calculate the density.

ρ=MV

Here, mass and volume of a vessel is M and V respectively.

Chapter 7 Solutions

Solution Summary: The author analyzes the final pressure of supercritical methane using ideal gas law.

Interpretation: The final pressure of supercritical methane using Lee-Kesler generalized correlation. Concept Introduction: Write the expression to calculate the compressibility factor (Z). Z=Z0+ωZ1 Here, compressibility of compound with ω=0 is Z0 and difference between Z0 and Z is Z1.

Interpretation: The final pressure of supercritical methane using Figure 7-1. Concept Introduction: Write the expression to calculate the density. ρ=MV Here, mass and volume of a vessel is M and V respectively.

Chapter 7 Solutions

Interpretation:

The final pressure of supercritical methane using Lee-Kesler generalized correlation.

Concept Introduction:

Write the expression to calculate the compressibility factor (Z).

Z=Z0+ωZ1

Here, compressibility of compound with ω=0 is Z0 and difference between Z0 and Z is Z1.

Interpretation:

The final pressure of supercritical methane using Figure 7-1.

Concept Introduction:

Write the expression to calculate the density.

ρ=MV

Here, mass and volume of a vessel is M and V respectively.