From b1f5c3f8d6671b4331cef1dcebdf63b7a43a3a2b Mon Sep 17 00:00:00 2001
From: priyanka
Date: Wed, 24 Jun 2015 15:03:17 +0530
Subject: initial commit / add all books

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 2762/CH3/EX3.1.4/3_1_4.sce | 27 +++++++++++++++++++++++++++
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+//Transport Processes and Seperation Process Principles
+//Chapter 3
+//Example 3.1-4
+//Principles of Momentum Transfer and Applications
+//given data
+D=0.61;//diameter of bed in m
+h=2.44;//height of bed
+A=(3.14*D*D)/4;//cross section area in m2
+mdot=0.358;//mass flow rate of air in kg/s
+E=0.38//void fraction
+G=mdot/A;
+Dp=0.0127;//diameter of spheres in m
+mu=1.9e-5;//viscosity of air Pa.s
+delL=2.44;
+Re= (Dp*G/((1-E)*mu));//Reynolds Number
+delP=0.05e+5;//assumed pressure difference in pascal
+p1=1.115*101325;//air entering at this pressure in Pa
+p2=p1-delP;
+avgP=(p1+p2)/2;//average pressure
+M=28.97;//molecular weight of air in SI units 
+R=8314.34;//gas constant
+T=311;//temp of air in K
+avgrho=(M/(R*T))*avgP;//Avg density 
+//(delP*rho/G*G)*(Dp/delL)*(E^3/(1-E))= (150/Re)+1.75: erguns equation in dimensionless groups
+delPn=((150/Re)+1.75)*((G*G*delL*(1-E))/(avgrho*E*E*E*Dp));//calculated pressure drop
+mprintf("calculated pressure drop= %f Pa",delPn)
+//end
-- 
cgit