diff options
author | prashantsinalkar | 2017-10-10 12:27:19 +0530 |
---|---|---|
committer | prashantsinalkar | 2017-10-10 12:27:19 +0530 |
commit | 7f60ea012dd2524dae921a2a35adbf7ef21f2bb6 (patch) | |
tree | dbb9e3ddb5fc829e7c5c7e6be99b2c4ba356132c /3574/CH8/EX8.1/EX8_1.sce | |
parent | b1f5c3f8d6671b4331cef1dcebdf63b7a43a3a2b (diff) | |
download | Scilab-TBC-Uploads-7f60ea012dd2524dae921a2a35adbf7ef21f2bb6.tar.gz Scilab-TBC-Uploads-7f60ea012dd2524dae921a2a35adbf7ef21f2bb6.tar.bz2 Scilab-TBC-Uploads-7f60ea012dd2524dae921a2a35adbf7ef21f2bb6.zip |
initial commit / add all books
Diffstat (limited to '3574/CH8/EX8.1/EX8_1.sce')
-rw-r--r-- | 3574/CH8/EX8.1/EX8_1.sce | 80 |
1 files changed, 80 insertions, 0 deletions
diff --git a/3574/CH8/EX8.1/EX8_1.sce b/3574/CH8/EX8.1/EX8_1.sce new file mode 100644 index 000000000..24ec65239 --- /dev/null +++ b/3574/CH8/EX8.1/EX8_1.sce @@ -0,0 +1,80 @@ +// Example 8.1
+// Determine (a) Developed torque (b) Armature current (c) Excitation voltage
+// (d) Power angle (e) Maximum torque
+// Page No. 317
+
+clc;
+clear;
+close;
+
+// Given data
+f=60; // Operating frequency
+P=4; // Number of poles
+Pmech=100; // Mechanical power
+eta=0.96; // Efficiency
+FP=0.80; // Power factor leading
+V=460; // Motor voltage
+Xs_Mag=2.72; // Synchronous reactnace magnitude
+Xs_Ang=90; // Synchronous reactnace magnitude
+deltaPull=-90; // Pullout power angle
+// (a) Developed torque
+ns=120*f/P; // Synchronous speed
+Td=5252*Pmech/(ns*eta);
+
+
+// (b) Armature current
+S=Pmech*746/(eta*FP);
+Theta=-acosd(FP); // Power factor angle (negative as FP is leading)
+V1phi=V/sqrt(3); // Single line voltage
+S1phi_Mag=S/3; // Magnitude
+S1phi_Ang=Theta; // Angle
+VT_Mag=V1phi;
+VT_Ang=0;
+Ia_Mag=S1phi_Mag/VT_Mag; // Armature current magnitude
+Ia_Ang=S1phi_Ang-VT_Ang; // Armature current angle
+Ia_Ang=-Ia_Ang; // Complex conjugate of Ia
+
+// (c) Excitation voltage
+Var1_Mag=Ia_Mag*Xs_Mag;
+Var1_Ang=Ia_Ang+Xs_Ang;
+
+/////////
+N01=VT_Mag+%i*VT_Ang;
+N02=Var1_Mag+%i*Var1_Ang;
+// Polar to Complex form
+
+N01_R=VT_Mag*cos(-VT_Ang*%pi/180); // Real part of complex number 1
+N01_I=VT_Mag*sin(VT_Ang*%pi/180); //Imaginary part of complex number 1
+
+N02_R=Var1_Mag*cos(-Var1_Ang*%pi/180); // Real part of complex number 2
+N02_I=Var1_Mag*sin(Var1_Ang*%pi/180); //Imaginary part of complex number 2
+
+FinalNo_R=N01_R-N02_R;
+FinalNo_I=N01_I-N02_I;
+FinNum=FinalNo_R+%i*FinalNo_I;
+// Complex to Polar form...
+
+FN_M=sqrt(real(FinNum)^2+imag(FinNum)^2); // Magnitude part
+FN_A = atan(imag(FinNum),real(FinNum))*180/%pi;// Angle part

+//////
+Ef_Mag=FN_M;
+Ef_Ang=FN_A;
+// (d) Power angle
+delta=Ef_Ang;
+
+// (e) Maximum torque
+Pin=3*(-VT_Mag*Ef_Mag/Xs_Mag)*sind(deltaPull); // Active power input
+Tpull=5252*Pin/(746*ns);
+
+
+
+// Display result on command window
+printf("\n Developed torque = %0.0f lb-ft ",Td);
+printf("\n Armature current magnitude= %0.2f A ",Ia_Mag);
+printf("\n Armature current angle= %0.2f deg ",Ia_Ang);
+printf("\n Excitation voltage magnitude = %0.0f V ",Ef_Mag);
+printf("\n Excitation voltage angle = %0.1f deg ",Ef_Ang);
+printf("\n Power angle = %0.1f deg ",delta);
+printf("\n Maximum torque = %0.0f lb-ft ",Tpull);
+
+
|