EBK INTRODUCTION TO CHEMICAL ENGINEERIN
EBK INTRODUCTION TO CHEMICAL ENGINEERIN
8th Edition
ISBN: 9781259878091
Author: SMITH
Publisher: MCGRAW HILL BOOK COMPANY
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Chapter 7, Problem 7.1P
Interpretation Introduction

Interpretation:

The temperature drops of air as it expands adiabatically through a nozzle under the given conditions needs to be calculated

Concept Introduction:

  • An adiabatic process is one in which there is no transfer of heat (Q) between the system and surroundings.
  • Based on the first law of thermodynamics, a steady state, steady flow process between one entrance and one exit (like in the case of a nozzle) can be expressed mathematically as:

  ΔH + Δu22 + gΔz = Q + W ------(1)where: ΔH = change in enthalpyΔu = change in velocityg = acceleration due to gravityΔz = elevation differenceQ = heat involvedW = work done

  

Temperature drop of air = -52.5 K

Given Information:

Initial velocity of air = negligible  0 ms-1

Final velocity of air = 325 ms-1

Explanation:

Since the process is adiabatic, Q = 0. If we assume that the elevation difference is negligible, and no shat work is done, then, Δz = W = 0. The equation (1) reduces to:

  ΔH + Δu22 = 0 ----(2)

Since air is assumed to be an ideal gas, the enthalpy change is related to the temperature difference as:

  ΔH =  CpΔT----(3)where Cp is the heat capacity at constant pressure

Calculation:

Step 1:

Calculate the enthalpy change

Based on equation (2) we have:

  ΔH = - u22u122 = - (325)2(0)22( m 2 s 2) = -52813 m2/s2Since 1 kJ/kg = 1000 m2/s2ΔH = -52.813 kJ/kgNow, molar mass of air = 0.02897 kg/molTherefore, ΔH = -52.813 kJ/kg × 0.02897 kg/mol = -1.529 kJ/mol

Step 2:

Calculate the temperature drop (ΔT)

Based on equation (3) we have

  ΔT = ΔHCp=1.529 kJ.mol1(7/2)×0.008314 kJ.K1.mol1=52.5 K

The temperature drop of air is -52.5 K

Expert Solution & Answer
Check Mark

Answer to Problem 7.1P

Temperature drop of air = -52.5 K

Explanation of Solution

Given Information:

Initial velocity of air = negligible  0 ms-1

Final velocity of air = 325 ms-1

Since the process is adiabatic, Q = 0. If we assume that the elevation difference is negligible, and no shat work is done, then, Δz = W = 0. The equation (1) reduces to:

  ΔH + Δu22 = 0 ----(2)

Since air is assumed to be an ideal gas, the enthalpy change is related to the temperature difference as:

  ΔH =  CpΔT----(3)where Cp is the heat capacity at constant pressure

Calculation:

Step 1:

Calculate the enthalpy change

Based on equation (2) we have:

  ΔH = - u22u122 = - (325)2(0)22( m 2 s 2) = -52813 m2/s2Since 1 kJ/kg = 1000 m2/s2ΔH = -52.813 kJ/kgNow, molar mass of air = 0.02897 kg/molTherefore, ΔH = -52.813 kJ/kg × 0.02897 kg/mol = -1.529 kJ/mol

Step 2:

Calculate the temperature drop (ΔT)

Based on equation (3) we have

  ΔT = ΔHCp=1.529 kJ.mol1(7/2)×0.008314 kJ.K1.mol1=52.5 K

Conclusion

The temperature drop of air is -52.5 K

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