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diff --git a/basic_electrical_engineering_by_nagsarkar_and_sukhija/chapter6_7Vcvq3x.ipynb b/basic_electrical_engineering_by_nagsarkar_and_sukhija/chapter6_7Vcvq3x.ipynb deleted file mode 100644 index 9192cf83..00000000 --- a/basic_electrical_engineering_by_nagsarkar_and_sukhija/chapter6_7Vcvq3x.ipynb +++ /dev/null @@ -1,678 +0,0 @@ -{ - "cells": [ - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "# Chapter 6:Transformer Principles" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Example 6.1:Page number-343" - ] - }, - { - "cell_type": "code", - "execution_count": 2, - "metadata": { - "collapsed": false - }, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "bm= 0.7207 Wb/m2\n", - "e2= 800.0 V\n" - ] - } - ], - "source": [ - "import math\n", - "#given\n", - "a=50*(10**-4)\n", - "e=400\n", - "f=50\n", - "n1=500\n", - "n2=1000\n", - "#phym=bm*a\n", - "#case a\n", - "#e=4.44*f*n*bm*a\n", - "bm=(e)/float(4.44*f*n1*a)\n", - "print \"bm=\",format(bm,'.4f'),\"Wb/m2\"\n", - "#case b\n", - "e2=4.44*f*n2*bm*a\n", - "print \"e2=\",format(e2,'.1f'),\"V\"\n", - "\n", - "\n" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Example 6.2" - ] - }, - { - "cell_type": "code", - "execution_count": 4, - "metadata": { - "collapsed": false - }, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "cross sectional area= 0.02065 m2\n", - "secondary voltage on no load= 440.0 V\n", - "primary magnetising current= 1.133 A\n", - "core loss= 366.7 W\n" - ] - } - ], - "source": [ - "import math\n", - "#given\n", - "e=3300\n", - "f=50\n", - "n1=600\n", - "n2=80\n", - "bm=1.2\n", - "h=425\n", - "l=1.6\n", - "density=7400\n", - "loss=1.5\n", - "#case a\n", - "phym=e/float(4.44*f*n1)\n", - "csa=phym/bm\n", - "print \"cross sectional area=\",format(csa,'.5f'),\"m2\"\n", - "#case b\n", - "sv=(e*n2)/n1\n", - "print \"secondary voltage on no load=\",format(sv,'.1f'),\"V\"\n", - "#case c\n", - "mc=(h*l)/n1\n", - "print \"primary magnetising current=\",format(mc,'.3f'),\"A\"\n", - "#case d\n", - "v=l*csa\n", - "m=v*density\n", - "closs=m*loss\n", - "print \"core loss=\",format(closs,'.1f'),\"W\"" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Example 6.3:Page number-356" - ] - }, - { - "cell_type": "code", - "execution_count": 9, - "metadata": { - "collapsed": false - }, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "0.0333333333333\n", - "30\n", - "number of turns of high voltage soil= 2640.0\n", - "number of turns of high voltage soil= 88.0\n", - "primary current as a step down transformer is= 1.515 A\n", - "secondary current as a step down transformer is= 45.45 A\n" - ] - } - ], - "source": [ - "import math\n", - "#given\n", - "#as per step up tranformer\n", - "v1=220\n", - "v2=6600\n", - "f=50\n", - "vturn=2.5\n", - "kva=10000\n", - "#case a\n", - "a=v1/float(v2)\n", - "print a\n", - "#as per step down case b\n", - "v1=6600\n", - "v2=220\n", - "a=v1/v2\n", - "print a\n", - "#case c\n", - "#high voltage soil\n", - "n=v1/float(vturn)\n", - "print \"number of turns of high voltage soil=\",format(n,'.1f')\n", - "#low voltage soil\n", - "n1=v2/float(vturn)\n", - "print \"number of turns of high voltage soil=\",format(n1,'.1f')\n", - "#case d\n", - "i=kva/float(v1)\n", - "print \"primary current as a step down transformer is=\",format(i,'.3f'),\"A\"\n", - "#case e\n", - "i=kva/float(v2)\n", - "print \"secondary current as a step down transformer is=\",format(i,'.2f'),\"A\"" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Example 6.4:Page number-357" - ] - }, - { - "cell_type": "code", - "execution_count": 14, - "metadata": { - "collapsed": false - }, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "turns ratio for impedance machting is 0.25\n" - ] - } - ], - "source": [ - "import math\n", - "#given\n", - "rl=32\n", - "#let ratio of sides be a\n", - "rs=2\n", - "a=(2/float(32))\n", - "p=a**0.5\n", - "print \"turns ratio for impedance machting is\",format(p,'.2f')" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Example 6.5:Page number-364" - ] - }, - { - "cell_type": "code", - "execution_count": 15, - "metadata": { - "collapsed": true - }, - "outputs": [], - "source": [ - "import math\n", - "#given\n", - "n1=2200\n", - "n2=220\n", - "kva=100\n", - "f=50\n", - "r1=0.75\n", - "r2=0.0007\n", - "x2=0.0009\n", - "#case a\n", - "#subcase 1\n", - "#lv side leakage impedance=r2+jx2-->complex number\n", - "#hv side leakage impedance=r1+jx1\n", - "#hv side impedance referred to lv side is r1'+jx1'=(r1+jx1)/a**2=(0.0075+j0.0115)\n", - "#shunt branch resistance referred to lv side gc-jbm=(0.0035-j0.025)\n", - "#The equivqlent circuit is shown in the diagram\n", - "#subcase 2\n", - "#lv side impedance referred to hv side is r2'+jx2'=a**2*(r2+jx2)=(0.70+j0.90)ohm\n", - "#the magnetising admittance refferred to hv side (gc-jbm)/a**2=(0.000035-j0.00025)\n", - "#the equivalent circuit is as in figure\n", - "#case b\n", - "#for an approximate equivalent circuit the magnetised admittance is neglected from the exact circuit\n", - "#subcase 1\n", - "#equivalent impedance referred to lv side (r2+r1')+j(x2+x1')=(0.0145+j0.0205)ohm\n", - "#equivalent circuit is shown in figure\n", - "#subcase 2\n", - "#equivalent impedance referred to hv side is (r1+r2')+j(x1+x2')=(1.45+j2.05)ohm\n", - "#equivalent circuit is shown in figure\n", - "\n" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Example 6.6:Page number-369" - ] - }, - { - "cell_type": "code", - "execution_count": 17, - "metadata": { - "collapsed": false - }, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "yc= 0.0050 S\n", - "gc= 0.0025 S\n", - "bm= 0.0043 S\n", - "req= 0.8500 ohm\n", - "zeq= 1.5000 ohm\n", - "xeq= 1.2359 ohm\n", - "req1= 0.2125 ohm\n", - "xeq1= 0.3090 ohm\n", - "zeq1= 0.3750 ohm\n" - ] - } - ], - "source": [ - "import math\n", - "#case a\n", - "#from oc test data shunt admittances are determined as follows\n", - "#given\n", - "v1=200\n", - "i0=1\n", - "pc=100\n", - "yc=i0/float(v1)\n", - "print \"yc=\",format(yc,'.4f'),\"S\"\n", - "gc=pc/float(v1**2)\n", - "print \"gc=\",format(gc,'.4f'),\"S\"\n", - "bm=(((0.005**2)-(0.0025**2))**0.5)\n", - "print \"bm=\",format(bm,'.4f'),\"S\"\n", - "#from sc test data\n", - "p=85\n", - "isc=10\n", - "vsc=15\n", - "req=p/float(isc**2)\n", - "print \"req=\",format(req,'.4f'),\"ohm\"\n", - "zeq=vsc/float(isc)\n", - "print \"zeq=\",format(zeq,'.4f'),\"ohm\"\n", - "xeq=(((zeq**2)-(req**2))**0.5)\n", - "print \"xeq=\",format(xeq,'.4f'),\"ohm\"\n", - "#case b\n", - "a=0.5\n", - "#equivalent impedance parameters referred to lv side\n", - "re=(a**2)*req\n", - "print \"req1=\",format(re,'.4f'),\"ohm\"\n", - "xe=(a**2)*xeq\n", - "print \"xeq1=\",format(xe,'.4f'),\"ohm\"\n", - "ze=(a**2)*zeq\n", - "print \"zeq1=\",format(ze,'.4f'),\"ohm\"\n", - "#equivalent circuit referred to lv side is as shown" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Example 6.8:Page number-376" - ] - }, - { - "cell_type": "code", - "execution_count": 1, - "metadata": { - "collapsed": false - }, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "n=((10xScos(angle))/(10xScos(angle)+pc+0.0001x2Pcu))\n" - ] - }, - { - "data": { - "image/png": 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9pqopOHM/Xe55f7iIxAI/4cxM2RK4BIhRZ8bVdOBTH8dk\nzAnl3A7AmGIaDTwH3AUswZlG/SvyWGaQol1Is+/GMzj5BqpSEY6VfbyccQiAiETg9Gd0VtVUEfkO\np0ksd23AkoHxG6shmKAlIucCDVR1Cc4FOvvimdfFeinO9OPgdBYv8fY0nq9bgAs8UwnXBK4oQsgK\nfA/c5JlSuwrOcpVLgOpAsicZnI9To1Gc1QO7i0htz7ohtxXhvMZ4xWoIJpg9hzO9LzjTAk/HWa1t\ndB77DgXeF5FHcBaA6efZ7tUKYaq6TUQ+A9YBm4DVhYw1+zhrROQD/pqX/h1VXSsiG4DBIrIe+A2n\n2QhV3S0iYzw/H8CZvtn6EIxf2PTXxhhjAGsyMsYY42EJwRhjDGAJwRhjjIclBGOMMYAlBGOMMR6W\nEIwxxgCWEIwxxnhYQjDGGAPA/wMqL97FjXaK2wAAAABJRU5ErkJggg==\n", - "text/plain": [ - "<matplotlib.figure.Figure at 0x7f42d136e490>" - ] - }, - "metadata": {}, - "output_type": "display_data" - } - ], - "source": [ - "import math\n", - "#case a\n", - "#transformer output=0.01x1000cos(angle)W\n", - "#loss=10xScos(angle)\n", - "#transformer efficiency n=(10xScos(angle)/(10xScos(angle)+pc+0.0001x2Pcu))\n", - "print \"n=((10xScos(angle))/(10xScos(angle)+pc+0.0001x2Pcu))\"\n", - "%matplotlib inline\n", - "import matplotlib.pyplot as plt\n", - "x1=20.5\n", - "x2=30\n", - "x3=40\n", - "x4=50\n", - "x5=60.5\n", - "x6=70\n", - "x7=80\n", - "x8=90\n", - "x9=100\n", - "x10=110\n", - "y1=94.3\n", - "y2=95\n", - "y3=96\n", - "y4=96.5\n", - "y5=96.8\n", - "y6=96.9\n", - "y7=97\n", - "y8=97\n", - "y9=97\n", - "y10=97\n", - "plt.plot([x1,x2,x3,x4,x5,x6,x7,x8,x9,x10],[y1,y2,y3,y4,y5,y6,y7,y8,y9,y10],marker='o',color='b',label='0.65')\n", - "p1=120.5\n", - "p2=30\n", - "p3=40\n", - "p4=50\n", - "p5=70\n", - "p6=80\n", - "p7=90\n", - "p8=100\n", - "p9=110\n", - "q1=95.3\n", - "q2=86\n", - "q3=96.7\n", - "q4=97.2\n", - "q5=97.5\n", - "q6=97.5\n", - "q7=97.5\n", - "q8=97.5\n", - "q9=97.5\n", - "plt.plot([p1,p2,p3,p4,p5,p6,p7,p8,p9],[q1,q2,q3,q4,q5,q6,q7,q8,q9],marker='o',color='g',label='0.8')\n", - "x2=[20.5,30,40,50,70,80,90,100,110]\n", - "y2=[96.2,96.6,97.4,97.6,98,98,98,98,98]\n", - "plt.plot(x2,y2,label='pf=1')\n", - "plt.xlabel('% of full load')\n", - "plt.ylabel('% efficiency')\n", - "plt.legend()\n", - "plt.show()\n", - "\n", - "\n" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Example 6.10:Page number-378\n" - ] - }, - { - "cell_type": "code", - "execution_count": 14, - "metadata": { - "collapsed": false - }, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "15306.122449\n", - "306.12244898\n", - "0.971216989926\n" - ] - } - ], - "source": [ - "import math\n", - "#at unity power factor\n", - "op=15000\n", - "n=0.98\n", - "i=op/float(n)\n", - "print i\n", - "loss=i-op\n", - "print loss\n", - "pc=float(loss)/2000 #actually division by 2 but value given only to make pc 0.153 instead of 153\n", - "t=pc*24 #iron loss in a day\n", - "toteng=20+96+108 #sum of energy outputs\n", - "engloss=0.109+1.224+1.632 #sum of energy losses\n", - "n=toteng/float(engloss+toteng+t)\n", - "print n" - ] - }, - { - "cell_type": "markdown", - "metadata": { - "collapsed": true - }, - "source": [ - "## Example 6.11:Page number-381" - ] - }, - { - "cell_type": "code", - "execution_count": 16, - "metadata": { - "collapsed": false - }, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "0.9726443769\n", - "30\n", - "0.990625\n" - ] - } - ], - "source": [ - "import math\n", - "kva=10000\n", - "pf=0.8\n", - "iloss=75\n", - "closs=150\n", - "a=0.5\n", - "#case a\n", - "po=kva*pf\n", - "loss=75+150\n", - "n=po/float(po+loss)\n", - "print n\n", - "#case b\n", - "i2=(10*1000)/(200)\n", - "i1=i2+((10*1000)/400)\n", - "kvar=(600*50)/1000\n", - "print kvar\n", - "po=30*0.8\n", - "n=1-(0.225/24)\n", - "print n" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Example 6.12:Page number-382" - ] - }, - { - "cell_type": "code", - "execution_count": 22, - "metadata": { - "collapsed": false - }, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "sat= 180.0 Kva\n", - "sat= 900.0 kva\n" - ] - } - ], - "source": [ - "import math\n", - "#case 1\n", - "#2300 winding used as secondary\n", - "#given and derived\n", - "st=150\n", - "v1=13800\n", - "v2=2300\n", - "a=(v1-v2)/v2\n", - "b=a+1\n", - "sat=(6*150)/5\n", - "print \"sat=\",format(sat,'.1f'),\"Kva\"\n", - "#case 2\n", - "v1=13.8\n", - "v2=11.5\n", - "a=(v1-v2)/v2\n", - "sat=((1+a)/a)*150\n", - "print \"sat=\",format(sat,'.1f'),\"kva\"" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Example 6.13:Page number-391" - ] - }, - { - "cell_type": "code", - "execution_count": 23, - "metadata": { - "collapsed": false - }, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "v2l= 440.0 V\n", - "i2p= 86.6 A\n", - "i2l= 150.0 A\n", - "v2p= 254.0 V\n", - "v2l= 440.0 V\n", - "i2p=i2l= 150.0 A\n", - "v2p= 440.0 V\n", - "v2l= 762.1 V\n", - "i2p= 86.6 A\n", - "v2p= 254.0 V\n", - "i2p= 150.0 A\n", - "i2l= 259.8 A\n" - ] - } - ], - "source": [ - "import math\n", - "#given and 1.732 is the value of root 3\n", - "v=6600\n", - "i=10\n", - "n=15\n", - "#case a\n", - "v2l=v/n\n", - "print \"v2l=\",format(v2l,'.1f'),\"V\"\n", - "i1p=10/1.732\n", - "i2p=i1p*n\n", - "print \"i2p=\",format(i2p,'.1f'),\"A\"\n", - "i2l=n*i1p*1.732\n", - "print \"i2l=\",format(i2l,'.1f'),\"A\"\n", - "#case b\n", - "v2p=v/(n*1.732)\n", - "print \"v2p=\",format(v2p,'.1f'),\"V\"\n", - "v2l=v2p*1.732\n", - "print \"v2l=\",format(v2l,'.1f'),\"V\"\n", - "i2l=i2p=n*i\n", - "print \"i2p=i2l=\",format(i2p,'.1f'),\"A\"\n", - "#case c\n", - "v2p=v/n\n", - "print \"v2p=\",format(v2p,'.1f'),\"V\"\n", - "v2l=(v*1.732)/n\n", - "print \"v2l=\",format(v2l,'.1f'),\"V\"\n", - "i1p=i/1.732\n", - "i2p=i2l=(n*i1p)\n", - "print \"i2p=\",format(i2p,'.1f'),\"A\"\n", - "#case d\n", - "v1p=v/1.732\n", - "v2p=v2l=v/(n*1.732)\n", - "print \"v2p=\",format(v2p,'.1f'),\"V\"\n", - "i1p=10\n", - "i2p=i1p*n\n", - "print \"i2p=\",format(i2p,'.1f'),\"A\"\n", - "i2l=i2p*1.732\n", - "print \"i2l=\",format(i2l,'.1f'),\"A\"\n", - "\n" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Example 6.14" - ] - }, - { - "cell_type": "code", - "execution_count": 24, - "metadata": { - "collapsed": false - }, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "ihv= 3.69402 A\n" - ] - } - ], - "source": [ - "import math\n", - "#given\n", - "hp=75\n", - "v=415\n", - "n=0.9\n", - "pf=0.85\n", - "op=75*746 #since its horse power\n", - "ip=op/n\n", - "ilv=ip/(1.732*v*pf) #line current on low voltage start side\n", - "a=(6600*1.732)/415 #given in question\n", - "ihv=ilv/a\n", - "print \"ihv=\",format(ihv,'.5f'),\"A\"\n", - "\n" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": { - "collapsed": true - }, - "outputs": [], - "source": [] - } - ], - "metadata": { - "kernelspec": { - "display_name": "Python 2", - "language": "python", - "name": "python2" - }, - "language_info": { - "codemirror_mode": { - "name": "ipython", - "version": 2 - }, - "file_extension": ".py", - "mimetype": "text/x-python", - "name": "python", - "nbconvert_exporter": "python", - "pygments_lexer": "ipython2", - "version": "2.7.5" - } - }, - "nbformat": 4, - "nbformat_minor": 0 -} |