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+//Exa 4.3

+clc;

+clear;

+close;

+//given data

+k=40;// in W/mK

+rho=8200;// in kg/m^3

+C=400;// in J/kgK

+D=6*10^-3;// in m

+R=D/2;

+t_i=30;// in degree C

+t_infinite1=400;// for 10 sec in degree C

+t_infinite2=20;// for 10 sec in degree C

+h=50;// in W/m^2K

+

+// Part(a)

+//l_s= V/A = R/3

+l_s= R/3;// in m

+//toh= rho*V*C/(h*A) = rho*C*l_s/h

+toh= rho*C*l_s/h;// in sec

+disp(toh,"Time constance in sec")

+

+// Part (b)

+Bi= h*l_s/k;

+// since Bi < 0.1 , hence lumped heat capacity analysis is valid. Now , temperature attained by junction in 10 seconds when exposed to hot air at 400 degree C

+toh=10;// in sec

+// (t-t_infinite1)/(t_i-t_infinite1)= %e^(-h*A*toh/(rho*V*C)) = %e^(-h*toh/(rho*l_s*C))

+t= %e^(-h*toh/(rho*l_s*C))*(t_i-t_infinite1)+t_infinite1;// in degree C

+

+disp("The junction is taken out from hot air stream and placed in stream of still air 20 degree C. The initial temperature in this case will be "+string(t)+" .")

+t_i=t;

+toh=20;// in sec

+t= %e^(-h*toh/(rho*l_s*C))*(t_i-t_infinite2)+t_infinite2;// in degree C

+disp(t,"The temperature attained by junction in degree C");

+

+// Note: In the last, calculation to find the value of t is wrong so Answer in the book is wrong

+

+

+

+

+

+