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//CHAPTER 8- DIRECT CURRENT MACHINES
//Example 10
disp("CHAPTER 8");
disp("EXAMPLE 10");
//VARIABLE INITIALIZATION
P=6; //number of poles
I=80; //current per conductor in Amperes
Z=400; //tottal number of conductors
phi=0.020; //flux per pole in Wb
N=1800; //in rpm
//SOLUTION
//soluion (a): for wave connected
disp("(a) For Wave connected");
//(i)
A=2; //A=number of parallel paths
I_a=I*A;
disp(sprintf("(i) The total current is %f A",I_a));
//(ii)
E_a=(phi*Z*N*P)/(60*A);
disp(sprintf("(ii) The emf is %f V",E_a));
//(iii)
p=E_a*I_a;
disp(sprintf("(iii) The power developed in armature is %f kW",p/1000));
w=(2*%pi*N)/60;
T_e=p/w;
disp(sprintf("The electromagnetic torque is %f N-m",T_e));
//soluion (b): for lap connected
disp("(b) For Lap connected");
//(i)
A=P;
I_a=I*A;
disp(sprintf("(i) The total current is %f A",I_a));
//(ii)
E_a=(phi*Z*N*P)/(60*A);
disp(sprintf("(ii) The emf is %f V",E_a));
//(iii)
p=E_a*I_a;
disp(sprintf("(iii) The power developed in armature is %f kW",p/1000));
w=(2*%pi*N)/60;
T_e=p/w;
disp(sprintf("The electromagnetic torque is %f N-m",T_e));
//END
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