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{

 "metadata": {

  "name": "",

  "signature": "sha256:f398a98eb03764e3df9c76bb9b69ca1418effde2602c77ec655bb3f8f666faf0"

 },

 "nbformat": 3,

 "nbformat_minor": 0,

 "worksheets": [

  {

   "cells": [

    {

     "cell_type": "heading",

     "level": 1,

     "metadata": {},

     "source": [

      "Chapter13:Miscellaneous Non-conventional Technologies"

     ]

    },

    {

     "cell_type": "heading",

     "level": 2,

     "metadata": {},

     "source": [

      "Ex13.1:pg-400"

     ]

    },

    {

     "cell_type": "code",

     "collapsed": false,

     "input": [

      "import math\n",

      "# given data\n",

      "A=0.25 # area in m^2\n",

      "d=0.5 # distance between electrodes in m \n",

      "B=1.8 # flux density in Wb/m^2\n",

      "u=1200.0 # average gas velocity in m/s\n",

      "sigma=10.0 # mho/m\n",

      "\n",

      "Vo=B*u*d #  in Volts\n",

      "Pmax=1*sigma*(u**2)*(B**2)*A*d/(4.0*10**6) #  in MW\n",

      "\n",

      "print \"Maximum Power output\",Pmax,\"MW\""

     ],

     "language": "python",

     "metadata": {},

     "outputs": [

      {

       "output_type": "stream",

       "stream": "stdout",

       "text": [

        "Maximum Power output 1.458 MW\n"

       ]

      }

     ],

     "prompt_number": 8

    }

   ],

   "metadata": {}

  }

 ]

}