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+// Calculating the magnetizing current per phase

+clc;

+disp('Example 10.16, Page No. = 10.44')

+// Given Data

+// 3 phase delta connected induction motor

+P = 75;// Power rating (in kw)

+V = 400;// Voltage rating

+f = 50;// Frequency (in Hz)

+p = 6;// Number of poles

+D = 0.3;// Diameter of motor core (in meter)

+L = 0.12;// Length of motor core (in meter)

+Nss = 72;// Number of stator slots

+Nc = 20;// Number of conductors per slot

+lg = 0.55;// Length of air gap (in meter)

+Kg = 1.2// Gap constraction factor

+Coil_Span = 11;// Coil span (slots)

+// Calculation of the magnetizing current per phase

+q = Nss/(3*p);// Slots per pole per phase

+Kd = sin(60/2*%pi/180)/(q*sin(60/(2*4)*%pi/180));// Distribution factor

+Ns_pole = Nss/p;// Slots per pole

+alpha = 1/Ns_pole*180;// Angle of chording (in degree).  Since the winding is chorded by 1 slot pitch

+Kp = cos(alpha/2*%pi/180);// Pitch factor

+Kws = Kd*Kp;// Stator winding factor

+Ns = Nss*Nc;// Total stator conductors

+Ts = Ns/(3*2);// Stator turns per phase

+Eb = V;// Stator voltage per phase.  Since machine is delta connected

+Fm = Eb/(4.44*f*Ts*Kws);// Flux per pole (in Wb)

+A = %pi*D*L/p;// Area per pole (in meter square)

+Bav = Fm/A;// Average air gap density (in Wb per meter square)

+Bg60 = 1.36*Bav;// Gap flux density at 30 degree from pole axis

+ATg = 800000*Bg60*Kg*lg*10^(-3);// Mmf required for air gap (in A)

+ATi = 0.35*ATg;// Mmf for iron parts (in A).  Since mmf required for iron parts is 35% of air gap mmf

+AT60 = ATg+ATi;// Total mmf (in A)

+Im = 0.427*p*AT60/(Kws*Ts);// Magnetizing current per phase (in ampere)

+disp(Im,'Magnetizing current per phase (Ampere) =');

+//in book answer is 4.56 Ampere.  The answers vary due to round off error