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Diffstat (limited to '3681/CH5/EX5.20/Ex5_20.sce')
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diff --git a/3681/CH5/EX5.20/Ex5_20.sce b/3681/CH5/EX5.20/Ex5_20.sce new file mode 100644 index 000000000..4f3410a03 --- /dev/null +++ b/3681/CH5/EX5.20/Ex5_20.sce @@ -0,0 +1,30 @@ +// Calculating the number of turns and no load current
+clc;
+disp('Example 5.20, Page No. = 5.101')
+// Given Data
+E = 6600;// Primary winding voltage (in volts)
+f = 60;// Frequency (in Hz)
+Ai = 22.6*10^(-3);// Area of cross section (in meter square)
+Bm = 1.1;// Maximum flux density of core (in Wb per meter square)
+Af = 1.52;// Amplitude factor
+Tp = 800;// Primary winding turns
+l = 2.23;// Mean length (in meter)
+mmf =232;// mmf per meter (in A per meter)
+n = 4;// Number of lap joints
+Gs = 7.5*10^(3);// Specific gravity of plates
+Ls = 1.76;// Specific loss (in W per kg)
+// Calculation of the number of turns
+Tp = E/(4.44*f*Ai*Bm);// Number of turns
+disp(Tp,'(a) Number of turns=');
+// Calculation of the no load current
+mmf_iron = mmf*l;// Mmf required for iron parts
+mmf_joints = 4*(1/4)*mmf;// Mmf required for joints. Since lap joints takes 1/4 times reactive mmf as required per meter of core
+AT0 = mmf_iron+mmf_joints;// Total magnetising mmf (in A)
+Kpk = Af*2^(1/2);// Peak factor
+Im = AT0/(Kpk*Tp);// Magnetising current (in A)
+W = Ai*l*Gs;// Weight of core (in kg)
+Pi = Ls*W;// Iron loss (in W)
+Il = Pi/E;// Loss component of no load current (in A)
+I0 =(Im*Im+Il*Il)^(1/2);// No load current (in A)
+disp(I0,'(b) No load current (Ampere)=');
+//in book answers are 1100 and 0.333 (A) respectively. The provided in the textbook is wrong
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