Unit Operations of Chemical Engineering
7th Edition
ISBN: 9780072848236
Author: Warren McCabe, Julian C. Smith, Peter Harriott
Publisher: McGraw-Hill Companies, The
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Chapter 7, Problem 7.2P
Interpretation Introduction
Interpretation:The inlet pressure for given catalyst tower should be determined.
Concept introduction: The pressure drop through the catalyst tower is calculated by the Ergun equation which is a combination of the Kozeny-Carman equation and Burke-Plummer equation.
The Kozeny-Carman equation is applicable for the particles in a bed whose Reynold’s number is less than 1. It is given as,
In the above formula, the notations used are,
The Burke Plummer equation is applicable for the particles in a bed whose Reynold’s number is more than 1000. It is given as,
The density of air can be given as,
In the equation (3), notations used are,
P is the pressure at which air enters
M is the molecular weight of air
R is the Universal Gas constant
T is the temperature at which air enters
Ergun equationis obtained by combining equation (1) and equation (2):
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Only focus on H(3), which the answer is minus 1.26 KJ/mol. This also has the ideal gas of nitrogen gas N2. Two enthalpies need to be calculated for this. The first enthalpy is H = (specific volume) times (pressure difference). For the specific volume of nitrogen, how was 12.089 x10^(-5) m^3/mol obtained? I understand the second enthalpy for the heat capacity for nitrogen gas.
chemical engineering.
The answer for H(3) is minus 1.26 KJ/mol. Demonstrate the reference state to the process state for nitrogen gas. I know that is an ideal gas law for the nitrogen gas. I know how to calculate the heat capacity for this.
Chapter 7 Solutions
Unit Operations of Chemical Engineering
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