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+

+// ELECTRICAL MACHINES

+// R.K.Srivastava

+// First Impression 2011

+// CENGAGE LEARNING INDIA PVT. LTD

+

+// CHAPTER : 7 : SPECIAL MOTORS AND INTRODUCTION TO GENERALIZED MACHINE THEORY

+

+// EXAMPLE : 7.3

+

+clear ; clc ; close ; // Clear the work space and console

+

+

+// GIVEN DATA

+

+m = 2;                                          // Total number of phase in servo Motor

+f = 50;                                         // Frequency in Hertz

+V = 220;                                        // Operating Voltage of the servo Motor in Volts

+R1 = 250;                                       // Circuit Parameter in Ohms

+R2 = 750;                                       // Circuit Parameter in Ohms

+X1 = 50;                                        // Circuit Parameter in Ohms

+X2 = 50;                                        // Circuit Parameter in Ohms

+Xm = 1000;                                      // Circuit Parameter in Ohms

+s = 0.6;                                        // Slip

+Va = 220;                                       // Unbalanced Voltage in Volts

+Vb = 150 * exp(%i * (-60) * %pi/180);           // Unbalanced Voltage in Volts

+

+

+// CALCULATIONS

+

+Va1 = (Va + %i*Vb)/2;                                      // Positive sequence voltage in Volts

+Va2 = (Va - %i*Vb)/2;                                      // Negative sequence voltage in Volts

+Z11 = (R1+%i*X1);

+Z12 =  (((%i*Xm)*(R2/s+%i*X2))/(%i*Xm+R2/s+%i*X2));

+Z1 = Z11 + Z12 ;                                           // Positive sequence impedance in Ohms

+Z2 = (R1+%i*X1) + (((%i*Xm)*(R2/(2-s)+%i*X2))/(%i*Xm+R2/(2-s)+%i*X2));    // Negative sequence impedance in Ohms

+Ia1 = Va1/Z1;                                              // Positive sequence current in Amphere

+I12 = (Ia1*Z12)/(R2/s);                                    // Positive sequence current in Amphere

+Ia2 = Va2/Z2;                                              // Negative sequence current in Amphere

+I22 = (Ia2*Z2)/(R2/(2-s));                                 // Negative sequence current in Amphere

+T1 = 2*(abs(I12)^2)*R2/s;                                  // Positive sequence torque in Newton-meter

+T2 = 2*(abs(I22)^2)*R2/(2-s);                              // Negative sequence torque in Newton-meter

+T = T1 - T2;                                               // Resultant torque in Newton-meter

+Ia = Ia1 + Ia2;                                            // Line current in Amphere

+Ib = (-%i*Ia1) + (%i*Ia2);                                 // Line current in Amphere

+

+

+// DISPLAY RESULTS

+

+disp("EXAMPLE : 7.3: SOLUTION :-");

+printf("\n (a) Resultant torque, T = %.2f N-m \n",T)

+printf("\n (b) Phase currents (line currents), Ia = %.2f < %.2f A \n\n                                     Ib = %.2f < %.2f \n",abs(Ia),atand(imag(Ia),real(Ia)),abs(Ib),atand(imag(Ib),real(Ib)))

+printf("\n\n IN THE ABOVE PROBLEM ALL THE VALUES PRINTED IN THE TEXT BOOK ARE NOT ACCURATE, SO VALUE OF THE TORQUE AND LINE CURRENTS ARE DIFFERING, WHEN WE COMPARED TO THE TEXT BOOK ANSWERS FOR THE SAME. \n\n")

+printf("\n IN EVERY CALCULATED PARAMETER IN THE TEXT BOOK SLIGHT VARIATION IS THERE AS WE COMPARED TO MANUAL CALCULATION ITS FROM POSITIVE SEQUENCE VOLTAGE (Va1) \n")