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+// Calculating the amount of water required per second, area of water duct and pumping power

+clc;

+disp('Example 4.27, Page No. = 4.52')

+// Given Data

+Q = 800;// Stator copper losses (in kW)

+Ti = 38;// Temperature of water inlet (in degree celsius)

+To = 68;// Temperature of water outlet (in degree celsius)

+Ns = 48;// Number of slots

+v = 1;// velocity (in meter per second)

+p = 300*10^(3);// Pumping pressure (in N per meter square)

+n = 0.6;// Efficiency

+// Calculation of the volume of water required per second

+T = To-Ti;// Temperature rise of water (in degree celsius)

+Vwl = 0.24*Q/T;// Amount of water (in litre per second)

+Vwm = Vwl*10^(-3);// Amount of water (in meter cube per second)

+N_cond = 2*Ns;// Since each slot has two conductors  Total number of stator conductors

+N_sub_cond = 32*N_cond;// Since each conductor is subdivided into 32 sub-conductors

+Vw_sub_cond = Vwl/N_sub_cond;// Volume of water required for each sub-conductors (in litre per second)

+disp(Vw_sub_cond,'Volume of water required for each sub-conductors (litre per second)=');

+A = Vw_sub_cond*10^(-3)/v;// Area of each duct (in meter square)

+A = A*10^(6);// Area of each duct (in mm square)

+disp(A,'Area of each duct (mm square)=');

+Q = 800-500;// Since it ia a 500 KW direct cooled turbo-alternator (in kW)

+P = (Q*10^(3)*Vwm/n)*10^(-3);// Pumping power (in kW)

+disp(P,'Pumping power (kW)=');

+//in book Vwl is equal to 0.00208 (litre per second), A is 2 (mm square) and pumping power is 3.2 (kW).  The answers vary due to round off error