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// Variable Declaration
V = 400.0 //Voltage supplied(V)
f = 50.0 //Frequency(Hz)
P_1 = 75.0 //Power of induction motor at middle of distributor(kVA)
pf_1 = 0.8 //Power factor of induction motor at middle of distributor
P_2 = 50.0 //Power of induction motor at far end(kVA)
pf_2 = 0.85 //Power factor of induction motor at far end
demand_f = 1.0 //Demand factor
diver_f = 1.2 //Diversity factor
L = 150.0 //Length of line(m)
// Calculation Section
theta_1 = acos(pf_1) //Power factor angle for 75 kVA(radians)
theta_2 = acos(pf_2) //Power factor angle for 50 kVA(radians)
load = P_1*exp(%i*theta_1)+P_2*exp(%i*theta_2) //Total connected load(kVA)
pf_r = cos(phasemag(load)*%pi/180) //Resultant power factor
I_max = abs(load)*1000/(3**0.5*V*diver_f) //Maximum distributor current per phase(A)
L_1 = L/2
V_per = 0.06*V/3**0.5 //Permissible voltage drop(V)
R_f = 0.734*10**-3 //Resistance(ohm/m)
X_f = 0.336*10**-3 //Reactance(ohm/m)
I_2f = P_2*10**3/(3**0.5*V)
I_1f = P_1*10**3/(3**0.5*V)
V_f = I_1f*L_1*(R_f*pf_1+X_f*sin(theta_1))+I_2f*L*(R_f*pf_2+X_f*sin(theta_2))
d_f = 9.0 //Overall conductor diameter(mm)
area_f = %pi*d_f**2/4 //Area of ferret conductor(mm^2)
R_R = 0.587*10**-3 //Resistance(ohm/m)
X_R = 0.333*10**-3 //Reactance(ohm/m)
I_2R = P_2*10**3/(3**0.5*V)
I_1R = P_1*10**3/(3**0.5*V)
V_R = I_1R*L_1*(R_R*pf_1+X_R*sin(theta_1))+I_2R*L*(R_R*pf_2+X_R*sin(theta_2))
d_R = 10.0 //Overall conductor diameter(mm)
area_R = %pi*d_R**2/4 //Area of rabbit conductor(mm^2)
// Result Section
if(V_f > V_per) then
printf('Overall cross-sectional area of the 7/3.35 mm Rabbit ACSR conductors having overall conductor diameter of 10.0 mm = %.2f mm^2' ,area_R)
else
printf('Overall cross-sectional area of the 7/3.00 mm Ferret ACSR conductors having overall conductor diameter of 9.0 mm = %.2f mm^2' ,area_f)
end
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