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 7.5P
Interpretation Introduction

Interpretation:

The minimum pressure and the cross-sectional area at the nozzle exit under the given conditions needs to be calculated

Concept Introduction:

  • The energy balance equation that relates the inlet and outlet enthalpies and velocities is given based on the first law of thermodynamics as:
  • (H1+ u 1 22)inlet(H2+ u 2 22)outlet

    (or)

    ΔH + Δu22 = 0 ----(1)

  • For a process that takes place at constant entropy i.e. isentropic, the change in entropy is zero. In other words, the entropy in the final state (S2) is equal to that in the initial state (S1). The change in entropy is given as:
  • ΔS = S2-S1 -----(2)

    When, ΔS = 0 

    S2 = S1 

  • The rate of mass flow (m)˙ is related to the cross-sectional area (A) of a nozzle through the following expression:

    (m)˙  = uAV ----(3)

    where u = velocity and V = specific volume

Minimum pressure = 436.8 kPa

Cross-sectional area at the nozzle exit = 0.0190 m2

Given Information:

Inlet pressure of steam, P1 = 800 kPa

Inlet Temperature of steam T1= 280C0

Explanation:

The minimum pressure at the exit can be calculated based on the critical pressure ratio:

P2P1 = (2γ+1)γ/γ-1 -----(4)

Step 1:

Calculate the minimum pressure

Based on equation (4) we have:

P2= P1×(2γ+1)γ/γ-1

where: P1 = 800 kPa and γ = 1.3 for superheated steam 

P2= 800×(21.3+1)1.3/1.3-1=800×0.546=436.8 kPa

Step 2:

Calculate the exit velocity, u2

Based on the steam tables for inlet conditions, P1 = 800 kPa and T1= 280C0

Specific volume of vapor, Vg = V1= 0.31189 m3/kg

The velocity change is given as:

Δu2 = 2γP1V1γ-1[1-( P 2 P 1 )γ-1/γ]

=2(1.3)(800)(0.31189)1.3-1[1-( 436.8 800)1.3-1/1.3]=281.876 m2/s2

Δu2 = 281.876 m2/s2

u22u12=281.876

u220=281.876

u2=16.79 m/s

Step 4:

Calculate the exit cross-sectional area, A

Based on equation (3) we have:

A = m˙ Vu

where:

m˙ = exit mass flow rate = 0.75kg/s

V= specific volume of vapor = 0.42566 m3/kg

A = 0.75 kgs-1×0.42566 m3kg-116.79 ms-1=0.0190 m2

Thus, minimum pressure = 436.8 kPa

Cross-sectional area at the nozzle exit = 0.0190 m2

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