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| author | prashantsinalkar | 2020-04-14 10:19:27 +0530 |
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| committer | prashantsinalkar | 2020-04-14 10:23:54 +0530 |
| commit | 476705d693c7122d34f9b049fa79b935405c9b49 (patch) | |
| tree | 2b1df110e24ff0174830d7f825f43ff1c134d1af /Power_System_Engineering_by_S_Chakraborthy/22-INSULATION_COORDINATION.ipynb | |
| parent | abb52650288b08a680335531742a7126ad0fb846 (diff) | |
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diff --git a/Power_System_Engineering_by_S_Chakraborthy/22-INSULATION_COORDINATION.ipynb b/Power_System_Engineering_by_S_Chakraborthy/22-INSULATION_COORDINATION.ipynb new file mode 100644 index 0000000..d784da7 --- /dev/null +++ b/Power_System_Engineering_by_S_Chakraborthy/22-INSULATION_COORDINATION.ipynb @@ -0,0 +1,134 @@ +{ +"cells": [ + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "# Chapter 22: INSULATION COORDINATION" + ] + }, +{ + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Example 22.1: Highest_voltage_to_which_the_transformer_is_subjected.sce" + ] + }, + { +"cell_type": "code", + "execution_count": null, + "metadata": { + "collapsed": true + }, + "outputs": [], +"source": [ +"// A Texbook on POWER SYSTEM ENGINEERING\n", +"// A.Chakrabarti, M.L.Soni, P.V.Gupta, U.S.Bhatnagar\n", +"// DHANPAT RAI & Co.\n", +"// SECOND EDITION \n", +"\n", +"// PART II : TRANSMISSION AND DISTRIBUTION\n", +"// CHAPTER 15: INSULATION CO-ORDINATION\n", +"\n", +"// EXAMPLE : 15.1 :\n", +"// Page number 398-399\n", +"clear ; clc ; close ; // Clear the work space and console\n", +"\n", +"// Given data\n", +"L = 30.0 // Height of arrester located(m)\n", +"BIL = 650.0 // BIL(kV)\n", +"de_dt = 1000.0 // Rate of rising surge wave front(kV/µ-sec)\n", +"V = 132.0 // Transformer voltage at HV side(kV)\n", +"E_a = 400.0 // Discharge voltage of arrester(kV)\n", +"v = 3.0*10**8 // Velocity of surge propagation(m/sec)\n", +"\n", +"// Calculations\n", +"E_t = E_a+(2.0*de_dt*L/300) // Highest voltage the transformer is subjected(kV)\n", +"\n", +"// Results\n", +"disp('PART II - EXAMPLE : 15.1 : SOLUTION :-')\n", +"printf('\nHighest voltage to which the transformer is subjected, E_t = %.f kV', E_t)" + ] + } +, +{ + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Example 22.2: Rating_of_LA_and_Location_with_respect_to_transformer.sce" + ] + }, + { +"cell_type": "code", + "execution_count": null, + "metadata": { + "collapsed": true + }, + "outputs": [], +"source": [ +"// A Texbook on POWER SYSTEM ENGINEERING\n", +"// A.Chakrabarti, M.L.Soni, P.V.Gupta, U.S.Bhatnagar\n", +"// DHANPAT RAI & Co.\n", +"// SECOND EDITION \n", +"\n", +"// PART II : TRANSMISSION AND DISTRIBUTION\n", +"// CHAPTER 15: INSULATION CO-ORDINATION\n", +"\n", +"// EXAMPLE : 15.2 :\n", +"// Page number 399\n", +"clear ; clc ; close ; // Clear the work space and console\n", +"\n", +"// Given data\n", +"V_hv = 132.0 // Voltage at the HV side of transformer(kV)\n", +"V_lv = 33.0 // Voltage at the LV side of transformer(kV)\n", +"V = 860.0 // Insulator allowable voltage(kV)\n", +"Z = 400.0 // Line surge impedance(ohm)\n", +"BIL = 550.0 // BIL(kV)\n", +"\n", +"// Calculations\n", +"V_rating_LA = V_hv*1.1*0.8 // Voltage rating of LA(kV)\n", +"E_a = 351.0 // Discharge voltage at 5 kA(kV)\n", +"I_disc = (2*V-E_a)*1000/Z // Discharge current(A)\n", +"L_1 = 37.7 // Separation distance in current b/w arrester tap and power transformer tap(m)\n", +"dist = 11.0 // Lead length from tap point to ground level(m)\n", +"de_dt = 500.0 // Maximum rate of rise of surge(kV/µ-sec)\n", +"Inductance = 1.2 // Inductance(µH/metre)\n", +"di_dt = 5000.0 // di/dt(A/µ-sec)\n", +"lead_drop = Inductance*dist*di_dt/1000 // Drop in the lead(kV)\n", +"E_d = E_a+lead_drop // (kV)\n", +"V_tr_terminal = E_d+2*de_dt*L_1/300 // Voltage at transformer terminals(kV)\n", +"E_t = BIL/1.2 // Highest voltage the transformer is subjected(kV)\n", +"L = (E_t-E_a)/(2*de_dt)*300 // Distance at which lightning arrester located from transformer(m)\n", +"L_lead = (E_t-E_a*1.1)/(2*de_dt)*300 // Distance at which lightning arrester located from transformer taken 10% lead drop(m)\n", +"\n", +"// Results\n", +"disp('PART II - EXAMPLE : 15.2 : SOLUTION :-')\n", +"printf('\nRating of L.A = %.1f kV', V_rating_LA)\n", +"printf('\nLocation of L.A, L = %.f m', L)\n", +"printf('\nLocation of L.A if 10 percent lead drop is considered, L = %.1f m', L_lead)\n", +"printf('\nMaximum distance at which a ligtning arrester is usually connected from transformer is %.f-%.f m', L-2,L+3)" + ] + } +], +"metadata": { + "kernelspec": { + "display_name": "Scilab", + "language": "scilab", + "name": "scilab" + }, + "language_info": { + "file_extension": ".sce", + "help_links": [ + { + "text": "MetaKernel Magics", + "url": "https://github.com/calysto/metakernel/blob/master/metakernel/magics/README.md" + } + ], + "mimetype": "text/x-octave", + "name": "scilab", + "version": "0.7.1" + } + }, + "nbformat": 4, + "nbformat_minor": 0 +} |