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 /3472/CH17/EX17.8 | |
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 '3472/CH17/EX17.8')
-rw-r--r-- | 3472/CH17/EX17.8/Ex17_8.png | bin | 0 -> 9743 bytes | |||
-rw-r--r-- | 3472/CH17/EX17.8/Example17_8.sce | 58 |
2 files changed, 58 insertions, 0 deletions
diff --git a/3472/CH17/EX17.8/Ex17_8.png b/3472/CH17/EX17.8/Ex17_8.png Binary files differnew file mode 100644 index 000000000..e82294481 --- /dev/null +++ b/3472/CH17/EX17.8/Ex17_8.png diff --git a/3472/CH17/EX17.8/Example17_8.sce b/3472/CH17/EX17.8/Example17_8.sce new file mode 100644 index 000000000..092fd7d61 --- /dev/null +++ b/3472/CH17/EX17.8/Example17_8.sce @@ -0,0 +1,58 @@ +// A Texbook on POWER SYSTEM ENGINEERING
+// A.Chakrabarti, M.L.Soni, P.V.Gupta, U.S.Bhatnagar
+// DHANPAT RAI & Co.
+// SECOND EDITION
+
+// PART II : TRANSMISSION AND DISTRIBUTION
+// CHAPTER 10: POWER SYSTEM STABILITY
+
+// EXAMPLE : 10.8 :
+// Page number 273-275
+clear ; clc ; close ; // Clear the work space and console
+funcprot(0)
+
+// Given data
+V = 33.0*10**3 // Line voltage(V)
+R = 6.0 // Resistance per phase(ohm)
+X = 15.0 // Reactance per phase(ohm)
+
+// Calculations
+V_S = V/3**0.5 // Sending end phase voltage(V)
+V_R = V/3**0.5 // Receiving end phase voltage(V)
+beta = atand(X/R) // β(°)
+Z = (R**2+X**2)**0.5 // Impedance(ohm)
+delta_0 = 0.0 // δ(°)
+P_0 = (V_R/Z**2)*(V_S*Z*cosd((delta_0-beta))-V_R*R)/10**6 // Power received(MW/phase)
+delta_1 = 30.0 // δ(°)
+P_1 = (V_R/Z**2)*(V_S*Z*cosd((delta_1-beta))-V_R*R)/10**6 // Power received(MW/phase)
+delta_2 = 60.0 // δ(°)
+P_2 = (V_R/Z**2)*(V_S*Z*cosd((delta_2-beta))-V_R*R)/10**6 // Power received(MW/phase)
+delta_3 = beta // δ(°)
+P_3 = (V_R/Z**2)*(V_S*Z*cosd((delta_3-beta))-V_R*R)/10**6 // Power received(MW/phase)
+delta_4 = 90.0 // δ(°)
+P_4 = (V_R/Z**2)*(V_S*Z*cosd((delta_4-beta))-V_R*R)/10**6 // Power received(MW/phase)
+delta_5 = 120.0 // δ(°)
+P_5 = (V_R/Z**2)*(V_S*Z*cosd((delta_5-beta))-V_R*R)/10**6 // Power received(MW/phase)
+delta_6 = (acosd(R/Z))+beta // δ(°)
+P_6 = (V_R/Z**2)*(V_S*Z*cosd((delta_6-beta))-V_R*R)/10**6 // Power received(MW/phase)
+
+
+delta = [delta_0,delta_1,delta_2,delta_3,delta_4,delta_5,delta_6]
+P = [P_0,P_1,P_2,P_3,P_4,P_5,P_6]
+a = gca() ;
+a.thickness = 2 // sets thickness of plot
+plot(delta,P,'ro-')
+a.x_label.text = 'Electrical degree' // labels x-axis
+a.y_label.text = 'Power in MW/phase' // labels y-axis
+xtitle("Fig E10.7 . Power angle diagram")
+xset('thickness',2) // sets thickness of axes
+xstring(70,14.12,'P_max = 14.12 MW/phase(approximately)')
+P_max = V_R/Z**2*(V_S*Z-V_R*R)/10**6 // Maximum power transmitted(MW/phase)
+delta_equal = 0.0 // δ With no phase shift(°)
+P_no_shift = (V_R/Z**2)*(V_S*Z*cosd((delta_equal-beta))-V_R*R)/10**6 // Power transmitted with no phase shift(MW/phase)
+
+// Results
+disp("PART II - EXAMPLE : 10.8 : SOLUTION :-")
+printf("\nPower angle diagram is plotted and is shown in the Figure 1")
+printf("\nMaximum power the line is capable of transmitting, P_max = %.2f MW/phase", P_max)
+printf("\nWith equal voltage at both ends power transmitted = %.f MW/phase", abs(P_no_shift))
|