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+{
+ "metadata": {
+ "name": "ch6",
+ "signature": "sha256:a29072d0985b8dbf41dbd6153642bf709b504655904069bc08292ea01d2d0ef9"
+ },
+ "nbformat": 3,
+ "nbformat_minor": 0,
+ "worksheets": [
+ {
+ "cells": [
+ {
+ "cell_type": "heading",
+ "level": 1,
+ "metadata": {},
+ "source": [
+ "Chapter 6 : Drying"
+ ]
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.1 "
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "\n",
+ "H1=.005; #humidity of incoming air per kg of dry air\n",
+ "T1=25.; #wet bulb temperature\n",
+ "\n",
+ "\n",
+ "print \"\\n the solid temp. correspond to wbt and they are 23, 27,32 and 34 degree respectively\"\n",
+ "\n",
+ "#part(ii)\n",
+ "Ybar=.032; #kg water/kg dry air#final moist air condotions \n",
+ "T2=42.; #dry bulb temperature\n",
+ "Mair=28.84; #molecular weight of air \n",
+ "Mwater=18; #molecular weight of water\n",
+ "pt=1.013*10**5; #total pressure in pascal\n",
+ "Vh=8315*((1/Mair)+(Ybar/Mwater))*((T2+273)/pt);\n",
+ "r=300; #flow rate of moist air leaving the dryer\n",
+ "a=r*60/Vh; #amount of dry air leaving /hr\n",
+ "w=a*(Ybar-0.005); # water removed /hr\n",
+ "\n",
+ "# Result\n",
+ "print \"\\n the water removed /hr is :%fkg /hr\"%w\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the solid temp. correspond to wbt and they are 23, 27,32 and 34 degree respectively\n",
+ "\n",
+ " the water removed /hr is :515.648113kg /hr\n"
+ ]
+ }
+ ],
+ "prompt_number": 22
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.2 "
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "%pylab inline\n",
+ " \n",
+ "\n",
+ "Ls=262.5; #mass of bone dry solid ais the drying surface\n",
+ "A=262.5/8; #both upper surafce and lower surface are exposed\n",
+ "Nc=0.3; #in kg/m**2*hr\n",
+ "x2=.06; #moisture content on wet basis finally after drying\n",
+ "x1=.25; #moisture content on wet basis finally after drying\n",
+ "Xcr=0.20; #crtical moisture content\n",
+ "X1=x1/(1-x1); #moisture content on dry basis intially\n",
+ "X2=x2/(1-x2); #moisture content on dry basis finally after drying\n",
+ "Xbar=0.025; #equillibrium moisture \n",
+ "\n",
+ "# Calculation \n",
+ "t1=Ls/(A*Nc) *(X1-Xcr); #so for constant rate period \n",
+ "\n",
+ "#for falling rate period we find time graphically\n",
+ "p = [.20 ,.18, .16, .14, .12, .10, .09, .08, .07, .064];\n",
+ "a = [3.3, 5.56, 6.25, 7.14, 8.32, 10.00, 11.11, 12.5, 14.29, 15.625];\n",
+ "from matplotlib.pyplot import *\n",
+ "\n",
+ "# Result\n",
+ "plot(p,a);\n",
+ "title(\"Fig.6.18 Example2 1/N vs X for fallling rate period\");\n",
+ "xlabel(\"X-- Moisture content, X(kg/kg)\");\n",
+ "ylabel(\"Y-- 1/N, hr,m**2/kg\");\n",
+ "\n",
+ "Area=1.116; #area under the curve\n",
+ "t2=Area *Ls/A; #falling rate period we find time graphically\n",
+ "ttotal=t1+t2; #total time for drying\n",
+ "print \"\\n the total time for drying the wet slab on wet basis is :%f min\"%ttotal\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ "Welcome to pylab, a matplotlib-based Python environment [backend: module://IPython.zmq.pylab.backend_inline].\n",
+ "For more information, type 'help(pylab)'.\n"
+ ]
+ },
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the total time for drying the wet slab on wet basis is :12.483556 min\n"
+ ]
+ },
+ {
+ "output_type": "display_data",
+ "png": 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NzQ3dunWDv79/qQpXGVQFTQoAkJsrXNz288/CXElOTlJHxBjTFRpLCm8iIly4\ncAGHDx/GjBkzSlW4yqAqcFLIs2ULMGECEBoqTI3BGGNvo/aL165fv46IiAikpqYqFZqYmKi2hMAE\ngwcLo5GCgoQ5kxhjTBNUJoXVq1ejT58+WLNmDRwdHbF3717xsenTp2skuIquTRvg7Flg/XrgP/8B\nsrOljogxVt6pXHntxx9/xIULF2BoaIjY2Fj069cPsbGxGD9+vCbjq/AaNBASg7+/sHrb9u2AiYnU\nUTHGyiuVNQUigqGhIQDAzs4OCoUCYWFhmDBhQoVv79c0ExPhiudGjYDWrYE7d6SOiDFWXqlMCnXq\n1EF0dLR429DQEAcPHsTTp08LLLrD1E9fH/j+e2DMGCExnD0rdUSMsfJI5eij+/fvw8DAAHXr1lW6\nn4hw5swZtayjIAbFo4+KdOgQMHy4MAX3oEFSR8MY0xZqHX1kY2ODiIgIAMC2bduUClVnQmBv1707\nEBEBTJ8OzJkjTKzHGGNlocghqQkJCdixYwfi4uI0FQ8rJmdn4M8/gSNHgIAA4WpoxhgrLZVJYd68\neXj27BkGDRqEZ8+eYd68eZqMixWDhQVw7BggkwEdOgCPHkkdEWNM1xV5RfPy5cthZWWF+Ph4TJ48\nWXNBcZ9CiRAJU2OEhAhTYzg7Sx0RY0wKar+iuV69eggICICVlVWpCmHqJZMBc+cCCxcCPj5CRzRj\njL2Lty7H+a6CgoJgYWEB5zd+tj579gydOnVC48aN0blzZzx//lxdxVdIgwYJs6t+9BGwejV3QDPG\nSk5tHc0jRoxAeHi40n2LFy9Gp06dcPPmTfj4+GDx4sUlPi4rWt41DD/8wFNjMMZKTm0dzd7e3jAz\nM1O6b//+/eKKbYGBgUrzKbGykzc1xu3bwsI9XCFjjBWXyrmP5syZg+XLl2Pz5s1l1tH86NEjWPx/\n5RgLCws8KmK4zNy5c8W/5XI55HJ5qcuvSExMhE7nKVOENRm++w7o00fqqBhjZUmhUEChUJTpMYsc\nfbRlyxYMHjwY27ZtQ0BAQIkPHhsbC19fX1y+fBkAYGZmhqSkJPFxc3NzPHv2rGBQPPqoTJ08CYwa\nJYxKWrMGqFdP6ogYY+qg9tFHgwcPBgB06dIFly5dQlRUlPjvXVhYWODhw4cAgAcPHqBOnTrvdBxW\nMm3bApcuAU2bAq6uwE8/cSc0Y6xwKpuP8syaNQshISFo2LAh9PRe55Djx4+XuLBevXohNDQUU6dO\nRWhoKPpMtCu0AAAf50lEQVRwe4bGVK0KfP21MAX3yJHAL78AP/4ING4sdWSMMW3y1uU4GzdujCtX\nrqBy5colOnBAQABOnDiBJ0+ewMLCAvPnz0fv3r3h7++Pe/fuwc7ODjt27ICpqWnBoLj5SK1ycoRm\npK+/BiZNAiZPBgwMpI6KMVZaGlmjuW/fvli/fr3YQawJnBQ0IzZWmIr7wQOhSalFC6kjYoyVhkaS\nwl9//YXevXvDyckJVapUEQvev39/qQouMihOChpDBGzdKtQYBg8G5s8HatSQOirG2LvQSFKwt7fH\n2LFj4eTkJPYpyGQytGvXrlQFFxkUJwWNS0wEJk4ETp8W1oTu0kXqiBhjJaWRpNCiRQv89ddfpSqk\npDgpSOfwYaFJydsb+OYboFYtqSNijBWXRpLCxIkTUaVKFfTq1UtsPgIAd3f3UhVcZFCcFCSVmgrM\nni00K33zjbBeg0wmdVSMsbfRSFKQy+WQFfKN8C5DUosdFCcFrXDunDB81doaWLcOsLWVOiLGWFE0\nkhSkwElBe2RlAcuWCTWGWbOESfYqVZI6KsZYYSRJCnv37kW9evXQqlWrUhVcFE4K2ufvv4HRo4GM\nDGH4Ki/kw5j2KYvvzrde0Zzfn3/+iStXriArK6vA1Nis/GrSBDh+HNi4UVj6c8wYYMYM4Uppxlj5\nUWRNITc3F5GRkWjdurUmY+KagpZLSAA+/RS4ehXYsEEYqcQYk55Gmo+aNWuG6OjoUhVSUpwUdMPu\n3UJy8PUFliwRputmjElH7bOkAkDHjh2xc+dO/pJmBfj5CbUFAHB0FJYCZYzptrfWFAwNDfHy5UtU\nqlQJVf/fgCyTyZCcnKy+oLimoHN4zQbGpKeRmkJqaipyc3ORlZWFlJQUpKSkqDUhMN2Ut2aDvT2v\n2cCYLivWkNT4+HjcvXsX2W+sAt+2bVv1BcU1BZ12+bJw0Vu1arxmA2OapJGO5qlTp2L79u1wcHBA\npTeuWjpw4ECpCi4yKE4KOi8nR1gX+quveM0GxjRFI0mhcePGuHz5stK8R+rGSaH8iI0Fxo4VhrHy\nmg2MqZdG+hQaNWqEzMzMUhXCKi47O+DQIWDqVGHo6qRJQFqa1FExxlRRWVP49NNPAQAJCQmIjo6G\nj4+P0iI7q1evVl9QXFMol548EdZsOHWK12xgTB3U2nwUEhIizo5KRAX+DgwMLFXBRQbFSaFc4zUb\nGFMPniWV6Sxes4GxssdJgem8v/4Shq9aWQFLlwJOTlJHxJju0khHM2Pq1KIFcP68MPNq585CP8OR\nI3zhG2NS4ZoC0xqvXgHbtgErVghNSRMnCs1KGhwNzZhOk6SmMH36dCxZsgRPnz5950IXLVoER0dH\nODs7Y9CgQXj16tU7H4uVH1WqAMOHAzExwPLlQoJo0ABYtAh49kzq6BirGEqcFFq0aIFKlSph/Pjx\n71RgbGwsNmzYgKioKFy+fBk5OTn49ddf3+lYrHySyYSmpMOHhX83bwLvvSdM033rltTRMVa+lXjl\ntb59+5aqQGNjYxgYGIgzr758+RJWVlalOiYrv5ydgeBg4Yro774DPD2FyfcmTQI0vPYTYxWCyqQw\nb968Qu/Pu15h9uzZ71Sgubk5Jk2ahPr166NatWro0qULOnbsWGC7uXPnin/L5XLI5fJ3Ko+VD5aW\nwMKFwhKgwcHA0KFAnTpCcujbF3hjWi7GKgyFQgGFQlGmx1TZ0bx8+XIxAeRJS0vDxo0b8eTJE6S9\n41wFt27dgq+vL06dOgUTExP0798f/fr1w+DBg18HxR3N7C1ycoB9+4RO6QcPgPHjgaAgwNBQ6sgY\nk45aO5onT56MSZMmYdKkSRg1ahTS09MRHByMgQMH4s6dO+9c4Pnz59G6dWvUrFkT+vr68PPzw9mz\nZ9/5eKxiqlRJWPntzBnhArhTp4R5lqZNA+LjpY6OMd1VZEfz06dPMXPmTLi6uiIrKwtRUVFYsmQJ\n6tSp884FNm3aFJGRkUhPTwcR4ejRo3BwcHjn4zHm6Qn897/AuXNAerrQDzFsmLDoD2OsZIqsKbRs\n2RJGRkaIiYnBvHnzYGZmVuoCXV1dMWzYMHh4eMDFxQUAMHr06FIfl7GGDYFvvxVGKDk6Aj16AJ06\nAeHhfDEcY8Wlsk9BT08PlStXhkEhK6PwGs1MF2RmAtu3C9c85OQIF8MNHswXw7Hyi+c+YqwYiICI\nCKFTOjoa+OQTYeGfmjWljoyxsqXWjubmzZvj888/R3h4ODIyMkpVCGNSksmAjh2BsDDg6FHgzh3g\n/feBceOAf/6ROjrGtIvKmkJWVhZOnz6N8PBwKBQKmJubo2vXrujWrRsaq3kldq4pMHV7+BD4/nvg\nhx+Ei+AmTQI++ICn72a6TaPNR/Hx8QgPD8fhw4fx77//wtPTE2vXri1V4SqD4qTANCQtDQgNBVau\nBMzMhOTw4YeAfomv9WdMepL1KeTk5CAyMhJt2rQpVeGqcFJgmpaTAxw4IPQ73L8vXAz30UeAkZHU\nkTFWfJKtpzB27Fi1JQTGpFCpEtCnj3AR3I4dwB9/CDO0fvEFEBcndXSMaY7KmsIzFXMVExFcXFwQ\nr8bLRrmmwLRBbKxw3UNoKNC9u9C05OYmdVSMqabW5iM9PT3Y2toWulN8fDwyMzNLVXCRQXFSYFrk\n+XNgwwZg9WphCu/AQKFWYWoqdWSMKVNrUnjvvfcQERFRaGKwsbHB/fv3S1VwkUFxUmBaKCsL2L1b\nWPzn2DFALgcGDAB69eK+B6Yd1NqnMH78eCQlJRX62JQpU0pVKGO6yMBASAJ79wqd0f36CZPxWVsL\nI5a2bxdGMzGmy/iKZsZK6dkzIVFs3w5ERgJduwrJo1s3oFo1qaNjFQlPc8GYlklMFJqYduwALlwQ\nJuUbMADo0oXnXGLqx0mBMS328CGwa5dQg7hyReh7GDAA8PEBKleWOjpWHnFSYExHxMcDO3cKCeLm\nTWH00oABQPv2fPU0Kzsav3jtzXWTGWPFZ2UFfP45cPas0KzUtCkwfbqw9vTYscDx48JV1YxJrUQ1\nBTc3N1y8eFGd8QDgmgKrOG7fFvoftm8Xmpv69RNqEK1bA3rvNN8Aq8g0XlPgL2rGylbDhsK60hcv\nAidOAHXqCDWH+vWBCROE0Ux82jFNKlFNITc3F3oa+PnCNQVW0V29+roGkZEB+PsLNQh3d57em6mm\n8Y5md3d3REVFlarA4uCkwJiACIiJeZ0ggNcJwsWFEwRTptbmo27duuHOnTtK9/EXNWOaJZMBrq7A\nggXCKnHbtwPZ2UDv3oC9PTB7tlCrYKysqEwKQUFB6NKlCxYsWICsrCwAQI8ePTQWGGNMmUwGNG8O\nLF0qLCkaEgKkpgoXxjk5AV99Bfz9t9RRMl1XZPNRamoq5s+fj8OHD2Po0KGQ/b+uKpPJMHHiRPUF\nxc1HjBVbbq4w1HX7duFaCAsLoYmpc2dhqu9KlaSOkGmK2kcfGRgYwNDQEBkZGUhJSUFqaipSU1OR\nkpJSqkIZY2VHT09YX3rNGmFBoFWrhOGtw4YBtWsLk/WtXStcNMe/tdjbqKwphIeHY+LEifD19cWc\nOXNQvXr1Miv0+fPnGDlyJK5evQqZTIZNmzbB09PzdVBcU2CsTMTHC9N8R0QI/wBhmo28f5aW0sbH\nypZaRx95e3tj/fr1cHR0LFUBhQkMDES7du0QFBSE7OxspKWlwcTE5HVQnBQYK3NEQm0hL0EcPw7U\nrSskh44dgXbteOEgXafWpEBEYh9CWXrx4gXc3Nxw+/Zt1UFxUmBM7XJyhIvm8pLEH38ADg6vk0Tr\n1kDVqlJHyUpCJyfEi46OxscffwwHBwdcunQJzZs3x7fffqvUPCWTyTBnzhzxtlwuh1wu12SYjFU4\nGRlCYshLEleuAK1aCQnCx0e4cI47rbWLQqGAQqEQb8+bN0/3ksL58+fh5eWFs2fPokWLFhg/fjyM\njY0xf/7810FxTYExyb14IUy9kZckEhKEJqa8JNGkCV88p210sqbw8OFDeHl5iRfGnT59GosXL8bB\ngwdfB8VJgTGt8+DB607ro0eF5qe8BOHjI8wEy6Sl8QnxykLdunVhY2ODmzdvAgCOHj2qls5sxljZ\nqlcPGDwY2LQJuHsXUCgALy/gwAFhyo2mTYH//AfYswdQsbw70wGSLLJz6dIljBw5EpmZmWjUqBGC\ng4N59BFjOiw3F4iOft3UdOaMMA1HXi2iTRter1oTdLL5qDg4KTCm2169Eqb9zmtqiokROq3zRjY1\nb86d1urASYExphOSk4GTJ18nibg4odO6f39g0CDusC4rnBQYYzrp0SOh03rhQqBtW+Dbb3mt6rLA\nSYExptOSk4XaQqVKwoR+RkZSR6TbdHL0EWOM5TE2Bg4eBGxsAG9voVmJSYuTAmNMUgYGwPr1wnBX\nLy9h6g0mHW4+YoxpjZ07gXHjgOBggNf0KjluPmKMlSv9+gH79wOjRgHffy91NBUT1xQYY1rnzh2g\ne3egWzdg2TK+pqG4ePQRY6zcSkoSVo0zNga2bAFq1JA6Iu3HzUeMsXLLzAwIDxf+l8uFJUaZ+nFS\nYIxprcqVhQn4evcGPD2FNR6YenHzEWNMJ2zdCowfD/zyC9C5s9TRaCduPmKMVRiDBgG7dgHDhgE/\n/SR1NOUX1xQYYzrln3+EkUn9+gELFgB6/NNWxKOPGGMV0pMnQJ8+gKUlEBrKazXk4eYjxliFVKuW\nMAW3vr6wRkNiotQRlR+cFBhjOqlqVeH6BR8fYWTSjRtSR1Q+8AzmjDGdJZMBX30FNGwoLNqzfbtw\nTQN7d1xTYIzpvBEjgG3bgAEDgJ9/ljoa3cYdzYyxcuP6dWF21aFDgblzK94ynzz6iDHG8nn0COjV\nC3j/fWDjRqBKFakj0hwefcQYY/lYWADHjwMZGcKVz8+eSR2RbuGkwBgrd6pXB3bsAFq1ElZz+/df\nqSPSHZIlhZycHLi5ucHX11eqEBhj5ZieHrB0KTBxIvDBB8CZM1JHpBskSwrffvstHBwcIKtoPUGM\nMY36+GMgJATo21cYssqKJklSiIuLw6FDhzBy5EjuUGaMqV3XrsIV0F98ASxcCPDXjmqSXLw2YcIE\nLFu2DMnJySq3mTt3rvi3XC6HnK9IYYyVgosL8McfQM+ewK1bwPr1gIGB1FGVjkKhgEKhKNNjanxI\n6sGDBxEWFobvv/8eCoUCK1aswIEDB5SD4iGpjDE1SU0VpuF++RLYuRMwNZU6orKjk0NSz549i/37\n96NBgwYICAjAsWPHMGzYME2HwRiroAwNgT17AEdHoE0bIDZW6oi0i6QXr504cQLLly/nmgJjTBKr\nVwOLFwN79wItW0odTenpZE0hPx59xBiTymefAT/8IEyNsXu31NFoB57mgjFW4V24APTuDUyYIFzX\noKu/VXnuI8YYKyP37ws1hjZtgDVrhAV8dA0nBcYYK0PJyYC/v1BT2L4dMDaWOqKSKRd9Cowxpi2M\njYEDBwBbW8DbW6g9VDScFBhj7A0GBsC6dcKaDK1bAxcvSh2RZnHzEWOMqbBrFzBmDBAcLFwJre3K\n4rtTB7tSGGNMMz78ELC2rli1Ba4pMMZYOcEdzYwxxsoUJwXGGGMiTgqMMcZEnBQYY4yJOCkwxhgT\ncVJgjDEm4qTAGGNMxEmBMcaYiJMCY4wxEScFxhhjIk4KjDHGRJwUGGOMiTgpMMYYE3FSYIwxJuKk\nwBhjTCRJUrh//z7at28PR0dHODk5YfXq1VKEUWoKhULqEIqF4yxbuhCnLsQIcJzaSJKkYGBggJUr\nV+Lq1auIjIzE999/j+vXr0sRSqnoygeF4yxbuhCnLsQIcJzaSJKkULduXTRr1gwAYGhoCHt7eyQk\nJEgRCmOMsTdI3qcQGxuLixcvolWrVlKHwhhjFZ6kazSnpqZCLpdj5syZ6NOnz+ugZDKpQmKMMZ1W\n2q90/TKKo8SysrLw4YcfYsiQIUoJASj9k2KMMfZuJKkpEBECAwNRs2ZNrFy5UtPFM8YYU0GSpHD6\n9Gm0bdsWLi4uYlPRokWL0LVrV02Hwhhj7A0a72gODw/HyJEj0ahRIwQEBODixYu4ePGiUkL47LPP\n8P7778PV1RUXL14U73/+/Dn69esHe3t7ODg4IDIyUq1xNm3aFO+//z6WLFlS6Daq4ly0aBEcHR3h\n7OyMQYMG4dWrV5LEeOPGDXh5eaFq1apYsWJFifbVhjg1fT1LaV5PAMjJyYGbmxt8fX21Nk5tOoeK\nilNT51Bx4tyyZQtcXV3h4uKCNm3aICYmptj7akOcJT6PSIOys7OpUaNGdOfOHcrMzCRXV1e6du2a\n0ja//fYbdevWjYiIIiMjqVWrVuJjw4YNo40bNxIRUVZWFj1//lzr4rxz5w41aNCAMjIyiIjI39+f\nQkJCJInx8ePH9Ndff9GMGTNo+fLlJdpXG+J88OABXbx4kYiIUlJSqHHjxloZZ54VK1bQoEGDyNfX\nVy0xlkWc2nQOqYpTU+dQceM8e/as+DqFhYWJ57q2nUeq4izpeaTRmsK5c+fw3nvvwc7ODgYGBhg4\ncCD27duntM3+/fsRGBgIAGjVqhWeP3+OR48e4cWLFzh16hSCgoIAAPr6+jAxMdG6OI2NjWFgYICX\nL18iOzsbL1++hJWVlSQx1q5dGx4eHjAwMCjxvtoQpyavZylNnAAQFxeHQ4cOYeTIkWodKFGaOLXt\nHFIVp6bOoeLG6eXlJb5OrVq1QlxcXLH31YY4S3oeaTQpxMfHw8bGRrxtbW2N+Pj4t24TFxeHO3fu\noHbt2hgxYgTc3d0xatQovHz5UqvijI+Ph7m5OSZNmoT69evD0tISpqam6NixoyQxqmPfkiqrstR9\nPUtp45wwYQKWLVsGPT31nlKliVPbziFVNHUOvUucGzduRPfu3d9pX6nifFNxziONJoXiXn+Q/5eW\nTCZDdnY2oqKiMG7cOERFRaFGjRpYvHixOsJ85zgB4NatW1i1ahViY2ORkJCA1NRUbNmypaxDLNW1\nHJq8DqQsykpNTUW/fv3w7bffwtDQsAyiKqg0cR48eBB16tSBm5ub2odTlyZObTyHCqOpcwgoWZzH\njx/Hpk2bxPZ8bT2P8seZp7jnkUaTgpWVFe7fvy/evn//PqytrYvcJi4uDlZWVrC2toa1tTVatGgB\nAOjXrx+ioqK0Ls7z58+jdevWqFmzJvT19eHn54ezZ89KEqM69i2p0pZV1PUsZak0cZ49exb79+9H\ngwYNEBAQgGPHjmHYsGFaF6e2nUOqaOocKkmcMTExGDVqFPbv3w8zM7MS7St1nEDJziONJgUPDw/8\n888/iI2NRWZmJrZv345evXopbdOrVy/8/PPPAIDIyEiYmprCwsICdevWhY2NDW7evAkAOHr0KBwd\nHbUuziZNmiAyMhLp6ekgIhw9ehQODg6SxJgn/6/XkuwrZZxEhI8++ggODg4YP368WuIrizgXLlyI\n+/fv486dO/j111/RoUMH8bOhTXFq2zmkKs6mTZtq5Bwqbpz37t2Dn58ffvnlF7z33nsl2lcb4izx\neVR2/ePFc+jQIWrcuDE1atSIFi5cSERE69evp/Xr14vbfPLJJ9SoUSNycXGhCxcuiPdHR0eTh4cH\nubi4UN++fdU2cqK0cS5ZsoQcHBzIycmJhg0bRpmZmZLE+ODBA7K2tiZjY2MyNTUlGxsbSklJUbmv\nurxrnKdOnSKZTEaurq7UrFkzatasGYWFhWldnG9SKBRqHX1U2ji16RwqKk5NnUPFifOjjz4ic3Nz\n8TPYokWLIvfVtjhLeh5JOvcRY4wx7SL5LKmMMca0BycFxhhjIk4KjDHGRJwUGGOMiTgpMADCuOeG\nDRsiKSkJAJCUlISGDRvi3r17xT6GQqGAnp4eNm7cKN4XHR0NPT29QieQe9OcOXMQERGh8vF9+/Zp\n/Trely5dQlhYWKmOsXDhwrduk5OTAw8PD5w6dUq8r3Pnzti1a5d4u2PHjkhJSUFsbCycnZ1LHMfi\nxYuxdetWjBgxQum4b7N//3589dVXJS6PaQ9OCgwAYGNjg7Fjx2LatGkAgGnTpuHjjz9G/fr1i30M\nmUwGJycn7NixQ7xv27ZtcHV1fesVmfPmzYOPj4/Kx/fs2YNr164VOxZAuIJXky5evIhDhw6V6hiL\nFi166zaVKlXC2rVr8Z///AfZ2dnYtm0b9PX18eGHHwIAjh07hiZNmsDIyOid4zhy5Ag6d+5c4v18\nfX2xa9cuZGVlvXPZTFqcFJhowoQJiIyMxKpVq3D27FlMnjy5xMewtbXFq1ev8PjxYxARDh8+jG7d\nuokXKEVHR8PT0xOurq7w8/PD8+fPAQDDhw8Xf5FOmzYNjo6OcHV1xZQpU/DHH3/gwIEDmDJlCtzd\n3XH79m3I5XJcuHABAPDkyRM0aNAAABASEoJevXrBx8cHnTp1wsuXLxEUFIRWrVrB3d0d+/fvLzTu\nJUuWwMXFBc2aNcOXX35ZZKxyuRzTpk1Dq1at0KRJE5w+fRpZWVmYPXs2tm/fDjc3N/z3v/9FWlpa\noWWHhITAz88P3bp1Q+PGjTF16lTxeaenp8PNzQ1Dhw4t8nVu2bIlvLy8MGfOHMyYMQPfffed+NjW\nrVvRu3fvAvvcvn0b7u7uuHDhAl6+fAl/f384OjrCz88Pnp6e4uuZnJyMzMxM1KpVC8DrKRZmzZqF\nESNGIDc3F4cOHYK9vT08PDzw2WefidOFy2QyeHl54ciRI0XGz7SYWq+2YDonPDycZDIZHT16tMT7\nKhQK6tmzJ61Zs4a+++47OnPmDI0YMYLmzp0rTo3s7OxMJ0+eJCKi2bNn0/jx44mIaPjw4bRr1y56\n8uQJNWnSRDzmixcvlB7PI5fLxQsGExMTyc7OjoiIgoODydrampKSkoiI6Msvv6RffvmFiIiSkpKo\ncePGlJaWphT3oUOHqHXr1pSeni5uV1SscrmcJk+eLO7bsWNHIiIKCQmhTz/9VDyuqrKDg4OpYcOG\nlJycTBkZGWRra0txcXFERGRoaFjs1/vZs2dUvXp1mjlzptL9TZs2padPnxKRMA21k5MT3bhxg9zc\n3CgmJoaIiJYtW0ZjxowhIqIrV66Qvr6++Hru2rWL5syZI77uO3fupMmTJ9PYsWOJiCg9PZ1sbGwo\nNjaWiIgCAgKULtjbtGkTffHFF8V+Hky7cE2BKQkLC4OlpSUuX75c4n3p/7WB/v37Y8eOHdi2bRsC\nAgLEx5OTk/HixQt4e3sDAAIDA3Hy5EmlY5iamqJq1ar46KOPsGfPHlSrVq3A8d+mU6dOMDU1BSA0\ngyxevBhubm5o3749Xr16pTSHDABEREQgKCgIVatWFWN48eJFkbH6+fkBANzd3REbGyvG92aMhZV9\n7949yGQy+Pj4wMjICFWqVIGDgwPu3r1brOf2phMnTsDU1LTAe5WQkABzc3Px9uPHj9GnTx9s3bpV\n7F84c+YMBg4cCABwdHSEi4uLuH1e7S7vOX311VdITk7G2rVrAQiL4zRs2BC2trYAgICAAKXnbWlp\nKb4mTPdwUmCi6OhoHD16FH/88QdWrlyJhw8fIi4uDm5ubnBzc8MPP/yAtWvXws3NDe7u7nj48GGh\nx7GwsEDlypVx9OhRsZ+gsD6F/F/yRIRKlSrh3Llz6NevHw4ePKi0It+bx9DX10dubi4AICMjQ+k4\nNWrUULq9e/ducYW/2NhYNGnS5K2xvO3xKlWqABDa94vqu8hfdtOmTZX2L84xCpOWloapU6fi+PHj\nePz4cZEd3KamprC1tVXqmC7sOeU5d+4cWrZsCUB4zVu0aIELFy6IgxDyv5f5j5Obm6vRGURZ2eKk\nwAAIJ/bYsWPx7bffwsbGBlOmTMHkyZNhbW0tfql9/PHHGDduHC5evIioqCjUrVtX5fHmz5+PJUuW\nQE9PT/wFbWxsDDMzM5w+fRoAsHnzZsjlcqX90tLS8Pz5c3Tr1g3ffPMNLl26BAAwMjJCcnKyuJ2d\nnR3Onz8PANi5c6fKOLp06aK0/OCby6bm6dSpE4KDg5Geng5AGHllYmLy1ljzMzY2RkpKylvLLioB\nGRgYKCUIHx8fPHjwoMB28+fPx4ABA9C4cWOsXbsWEyZMEJestLS0xNOnT8VtK1eujN27d+Pnn3/G\ntm3bAABt2rQRBwRcu3ZNrG1cvXoVTZs2VfpS79q1K6ZNm4YePXogNTUVjRs3xu3bt8Xazfbt25Vi\ne/DggViLYLqHkwIDAGzYsAF2dnbiL/tx48bh+vXrBX5dFkUmk4lfJl5eXuIsjm/eHxoaiilTpsDV\n1RUxMTGYPXu20v4pKSnw9fWFq6srvL29sXLlSgDAwIEDsWzZMjRv3hx37tzB5MmTsW7dOri7u+Pp\n06fi8d8sCxA6R7OysuDi4gInJyfMmTOnQNxdunRBr1694OHhATc3N3H4bFGx5n/eANC+fXtcu3ZN\n7GhWVXb+GN80evRouLi4YOjQoSAi3Lp1S6kpCBC+uPft24cZM2YAAJo1a4YuXbpg6dKlAIAPPvhA\nTJh55VWvXh0HDx7EypUrcfDgQYwbNw6JiYlwdHTErFmz4OjoCGNjY4SFhYlNR2/u369fP4waNQq9\nevWCTCbD2rVr0bVrV3h4eMDY2FhpBbdz586hbdu2hT4/pv14QjzGtNTVq1cRHByM5cuXl2g/hUKB\n7du3Y926dSq3yc3NRVZWFqpUqYJbt26hc+fOuHHjBnr06IHNmzfDwsKiyDLS0tLEZrpPPvkEjRs3\nxueff47c3Fy4u7vj/Pnz0NfXL1HcTDtwUmCsHOrYsSP27Nmj8lqFlJQUdOjQAVlZWSAiLF26FF26\ndCn28VetWoXQ0FBkZmbC3d0dGzZsQNWqVbF//37ExMRg5syZZfVUmIZxUmCMMSbiPgXGGGMiTgqM\nMcZEnBQYY4yJOCkwxhgTcVJgjDEm4qTAGGNM9D/a8te+YditMAAAAABJRU5ErkJggg==\n"
+ }
+ ],
+ "prompt_number": 1
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.3.a "
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "#part(i)\n",
+ "\n",
+ "# Variable Declaration \n",
+ "p = [1.0,0.6,.44,0.4,.36,.224, 0.14];\n",
+ "a = [5.0,5.0, 4.5, 4.0, 3.5, 2.00, 1.00];\n",
+ "\n",
+ "i=0; #looping for calc. of 1/N \n",
+ "t = [0,0,0,0,0,0,0]\n",
+ "\n",
+ "# Calculation \n",
+ "while(i<7): #looping begins\n",
+ " t[i]=1./(a[i]);\n",
+ " i=i+1;\n",
+ "\n",
+ "from matplotlib.pyplot import *\n",
+ "\n",
+ "# Result\n",
+ "plot(p,a);\n",
+ "title(\"Fig.6.19(a) Example3 Drying Rate curve\");\n",
+ "xlabel(\"X-- Moisture content, X(kg/kg) ---->\");\n",
+ "ylabel(\"Y-- Drying Rate, N(kg/hr.m**2 ---->\");\n",
+ "#xset('window',1);\n",
+ "plot(p,t,\"o-\");\n",
+ "title(\"Fig.6.19(b) Example3 1/N vs X\");\n",
+ "xlabel(\"X-- Moisture content, X(kg/kg) --->\");\n",
+ "ylabel(\"Y-- 1/N, hr,m**2/kg --->\");\n",
+ "show()\n",
+ "#from X=0.6 to 0.44 ,falling rate is non linear and from X=.44 to .14 falling rate is linear\n",
+ "\n",
+ "print \"\\n from the graph we get critical moisture content as 0.6 kg moisture/kg dry solid\"\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "display_data",
+ "png": 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+ },
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " from the graph we get critical moisture content as 0.6 kg moisture/kg dry solid\n"
+ ]
+ }
+ ],
+ "prompt_number": 2
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.3.b"
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "# Variable Declaration \n",
+ "#part(ii)\n",
+ "w1=5.; #wet of wet solid\n",
+ "c1=.5/(1-.5); #moisture content per kg wet solid\n",
+ "w2=5.*0.5; #moisture for 5kg wet solid\n",
+ "w3=w1-w2; #weight of dry solid\n",
+ "xbar=0.05; #equillibrium moisture content\n",
+ "Xbar=xbar/(1-xbar); #equillibrium moisture content\n",
+ "Ls=2.5; #mass of bone dry solid ais the drying surface\n",
+ "A=5.; #both upper surafce and lower surface are exposed\n",
+ "Nc=0.6; #in kg/m**2*hr\n",
+ "#from X=0.6 to 0.44 ,falling rate is non linear and from X=.44 to .14 falling rate is linear\n",
+ "X2=.15/(1-.15);\n",
+ "Xcr=.6; #kg moisture per kg dry solid\n",
+ "#so we can find time fro drying from 0.6 to .44 graphically and then for X=.44 to .1765\n",
+ "X1=1.; #moisture content on dry basis intially\n",
+ "\n",
+ "# Calculation \n",
+ "t1=Ls/(A*Nc) *(X1-Xcr); #time taken for constant drying rate(fromX=1 to .6) \n",
+ "X1=.44; #moisture content on dry basis\n",
+ "import math\n",
+ "t2=(Ls/(A*Nc))*((Xcr-Xbar)*math.log((X1-Xbar)/(X2-Xbar)));\n",
+ "t3=0.0336*Ls/Nc; #fro graph we get from X=.6 to .44\n",
+ "ttotal=t1+t2+t3; #total time for drying the wet slab\n",
+ "\n",
+ "# Result\n",
+ "print \"\\n the total time for drying the wet slab to 15 percent moisture on wet basis is :%f min\"%(ttotal*60)\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the total time for drying the wet slab to 15 percent moisture on wet basis is :59.610778 min\n"
+ ]
+ }
+ ],
+ "prompt_number": 24
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.4"
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ "\n",
+ "#let Ls/A=p\n",
+ "# Variable Declaration \n",
+ "p=48.; #mass of bone dry solid ais the drying surface\n",
+ "v=1.5*1.5*.5; #volume of material\n",
+ "Nc=1.22; #in kg/m**2*hr\n",
+ "Xcr=0.2; #crtical moisture content\n",
+ "X1=0.25; #moisture content on dry basis intially\n",
+ "X2=0.08; #moisture content on dry basis finally after drying\n",
+ "Xbar=0.025; #equillibrium moisture \n",
+ "\n",
+ "#tbar=(Ls/(A*Nc))*((Xcr-Xbar)*log((Xcr-Xbar)/(X2-Xbar)));\n",
+ "# Calculation \n",
+ "t1=p/(Nc) * (X1-Xcr); #time taken for constant drying rate period \n",
+ "\n",
+ "# equillibrium relation is given under\n",
+ "p = [.18,.15,.14,.11,.07,.05];\n",
+ "a = [.8772,1.11,1.25,1.7857,4.545,20];\n",
+ "from matplotlib.pyplot import *\n",
+ "\n",
+ "# Result\n",
+ "plot(p,a);\n",
+ "title(\"Fig.6.20 Example4 1/N vs X for fallling rate period\");\n",
+ "xlabel(\"X-- Moisture content, X(kg/kg) ---->\");\n",
+ "ylabel(\"Y-- 1/N, hr,m**2/kg ---->\");\n",
+ "\n",
+ "a=14*.025*1; #area under the curve\n",
+ "t2=a*48; #time taken for varying drying period\n",
+ "ttotal=t1+t2; #total time taken \n",
+ "print \"\\n total time for drying the material from 25 to 8 percent moisture under same drying conditions is :%f hr\"%(ttotal)\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " total time for drying the material from 25 to 8 percent moisture under same drying conditions is :18.767213 hr\n"
+ ]
+ },
+ {
+ "output_type": "display_data",
+ "png": 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fLeE0HY9uZoxpGoVF4bvvvsOVK1fwyy+/4Ny5c1i2bBk2bNigzmwaj4sCY0zT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\nAAAAAElFTkSuQmCC\n"
+ }
+ ],
+ "prompt_number": 3
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.5.a"
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "# Variable Declaration \n",
+ "w=[5.314,5.238,5.162,5.124,5.048,4.972,4.895,4.819,4.743,4.667,4.524,4.468,4.426,4.340,4.120]\n",
+ "t=[0.0,0.4,0.8,1.0,1.4,1.8,2.2,2.6,3.0,3.4,4.2,4.6,5.0,6.0]\n",
+ "#part(i)\n",
+ "x=4.120; #weight of the dried material\n",
+ "print \"\\n moisture content (dry basis) \"\n",
+ "i=0; \n",
+ "p = [] #looping starts\n",
+ "\n",
+ "# Calculation \n",
+ "while(i<15): #calculation of moisture content\n",
+ " p.append((w[i]-x)/x);\n",
+ " print \"\\n :%f\"%p[i]\n",
+ " i=i+1;\n",
+ "\n",
+ "print \"Drying rate kg/hr*m**2\"\n",
+ "i=1;\n",
+ "a = []\n",
+ "for i in range(15):\n",
+ " a.append(0)\n",
+ " \n",
+ "while(i<14):\n",
+ " a[i] =((p[i-1]-p[i])*4.12/(t[i]-t[i-1]))\n",
+ " print \" %f \"%a[i]\n",
+ " i=i+1;\n",
+ "from matplotlib.pyplot import *\n",
+ "a[0]=.19;\n",
+ "a[14]=0;\n",
+ "\n",
+ "# Result\n",
+ "print \"\\n\\n from the above data it is clear that critical moisture content Xcr=0.11\"\n",
+ "plot(p,a);\n",
+ "title(\"Fig.6.19(a) Example3 Drying Rate curve\");\n",
+ "xlabel(\"X-- Moisture content, X(kg/kg) ---->\");\n",
+ "ylabel(\"Y-- Drying Rate, N(kg/hr.m**2 ---->\");\n",
+ "show()\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " moisture content (dry basis) \n",
+ "\n",
+ " :0.289806\n",
+ "\n",
+ " :0.271359\n",
+ "\n",
+ " :0.252913\n",
+ "\n",
+ " :0.243689\n",
+ "\n",
+ " :0.225243\n",
+ "\n",
+ " :0.206796\n",
+ "\n",
+ " :0.188107\n",
+ "\n",
+ " :0.169660\n",
+ "\n",
+ " :0.151214\n",
+ "\n",
+ " :0.132767\n",
+ "\n",
+ " :0.098058\n",
+ "\n",
+ " :0.084466\n",
+ "\n",
+ " :0.074272\n",
+ "\n",
+ " :0.053398\n",
+ "\n",
+ " :0.000000\n",
+ "Drying rate kg/hr*m**2\n",
+ "\n",
+ "\n",
+ " from the above data it is clear that critical moisture content Xcr=0.11\n"
+ ]
+ },
+ {
+ "output_type": "display_data",
+ "png": 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XNOptVTeoOmDAALi7u2Pw4MF47733MHjw4Cr7Ojk5ITo6GkuWLEHLli3h4uKClStXSl+k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\n"
+ }
+ ],
+ "prompt_number": 4
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.5.b "
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "# Variable Declaration \n",
+ "#part(ii)\n",
+ "w1=4.934; #weight after two hours\n",
+ "w0=5.314; #initial weight \n",
+ "w2=w0-w1; # water evaporated in 2 hrs\n",
+ "H1=.01; #humidty of incoming air\n",
+ "H2=.03; #humidity of leaving air\n",
+ "yout=.03;\n",
+ "yin=.01;\n",
+ "\n",
+ "# Calculation \n",
+ "Gs=w2/(yout- yin); #water carried away\n",
+ "\n",
+ " # Result\n",
+ "print \"\\n the amount of air required in 2hours is :%f kg\"%Gs\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the amount of air required in 2hours is :19.000000 kg\n"
+ ]
+ }
+ ],
+ "prompt_number": 27
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.5.c "
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "# Variable Declaration \n",
+ "#part(iii)\n",
+ "#let us choose the consistency of 11 and 13 readings\n",
+ "Xbar=0; #equillibrium moisture content\n",
+ "Ls=4.12; #mass of bone dry solid ais the drying surface\n",
+ "A=1.; #both upper surafce and lower surface are exposed\n",
+ "Nc=0.19; #in kg/m**2*hr\n",
+ "X1=.098; #moisture content on dry basis intially\n",
+ "Xcr=.11; #kg moisture per kg dry solid\n",
+ "X2=0.074; #moisture content on dry basis finally\n",
+ "# Calculation \n",
+ "import math\n",
+ "tfall=(Ls/(A*Nc))*((Xcr-Xbar)*math.log((X1-Xbar)/(X2-Xbar)));\n",
+ "\n",
+ "# Result\n",
+ "print \"\\n from this data we get time as :%f hour\"%tfall\n",
+ "print \"\\n the actual time is 0.8 hours\"\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " from this data we get time as :0.670026 hour\n",
+ "\n",
+ " the actual time is 0.8 hours\n"
+ ]
+ }
+ ],
+ "prompt_number": 28
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.6"
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "# Variable Declaration \n",
+ "Xcr=0.55; #crtical moisture content\n",
+ "X1=1; #moisture content on dry basis intially\n",
+ "X2=.1; #moisture content on dry basis finally after drying\n",
+ "Xbar=.06; #equillibrium moisture \n",
+ "#since eqn 1 is tobe divided by eqn 2 so let the value of Ls/A*Nc be = 1 as it will be cancelled \n",
+ "p=1; #let Ls/A*Nc be =p\n",
+ "#p=poly([0],'p'); #calc. of time 1\n",
+ "tbar=1; #since the eqns are independent of tbar\n",
+ "\n",
+ "# Calculation \n",
+ "import math\n",
+ "t1=0.5960514 #roots(tbar- p*((X1-Xcr)+(Xcr-Xbar)*math.log((Xcr-Xbar)/(X2-Xbar)))); #------eqn1\n",
+ "X2bar=.16; \n",
+ "#p=poly([0],'p'); #calc. of time 2\n",
+ "t2=0.8138516 #roots(tbar- p*((X1-Xcr)+(Xcr-Xbar)*math.log((Xcr-Xbar)/(X2bar-Xbar))));#------eqn2\n",
+ "\n",
+ "#let t1/t2 be = k\n",
+ "k=t1/t2;\n",
+ "ans=1./k-1; #reduction in time for drying \n",
+ "\n",
+ "# Result\n",
+ "print \"\\n the reduction in time for drying is :%f percent\"%(ans*100)\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the reduction in time for drying is :36.540506 percent\n"
+ ]
+ }
+ ],
+ "prompt_number": 29
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.7 "
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "#Ls/ A*Nc is unknown;\n",
+ "# Variable Declaration \n",
+ "Xcr=0.14; #crtical moisture content\n",
+ "X1=.3/(1-.3); #moisture content on dry basis intially\n",
+ "X2=0.1/(1-0.1); #moisture content on dry basis finally after drying\n",
+ "Xbar=.04; #equillibrium moisture \n",
+ "tbar=5; #time needed to dry from 30 to 6 percent on bone dry basis\n",
+ "\n",
+ "#let Ls / A*Nc be = p\n",
+ "#p=poly([0],'p'); #calc. of Ls / A*Nc be = p value\n",
+ "# Calculation and Result\n",
+ "x= 15.495992 #roots(tbar-p * ((X1-Xcr)+(Xcr-Xbar)*log((Xcr-Xbar)/(X2-Xbar))));\n",
+ "print \"\\n the value of Ls/ A*Nc is :%f\"%x\n",
+ "import math\n",
+ "#new X1 AND X2 are now given as follows\n",
+ "X1=0.3/(1-.3); #new moisture content on dry basis intially\n",
+ "X2=0.064; #new moisture content on dry basis finally after drying\n",
+ "tbar=x * ((X1-Xcr)+(Xcr-Xbar)*math.log((Xcr-Xbar)/(X2-Xbar)));\n",
+ "print \"\\n the time for drying the sheets from 30 to 6 percent moisture under same drying conditions is :%f hr\"%tbar\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the value of Ls/ A*Nc is :15.495992\n",
+ "\n",
+ " the time for drying the sheets from 30 to 6 percent moisture under same drying conditions is :6.683159 hr\n"
+ ]
+ }
+ ],
+ "prompt_number": 30
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.8.a"
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "# Variable Declaration \n",
+ "Ls=1000.; #mass of bone dry solid ais the drying surface\n",
+ "A=55.; #both upper surafce and lower surface are exposed\n",
+ "v=.75; #velocity of air\n",
+ "Nc=.3*10**-3; #in kg/m**2*s\n",
+ "x2=.2; #moisture content on wet basis finally after drying\n",
+ "Xcr=0.125; #crtical moisture content\n",
+ "X1=0.15; #moisture content on dry basis intially\n",
+ "X2=0.025; #moisture content on dry basis finally after drying\n",
+ "Xbar=0.0; #equillibrium moisture \n",
+ "import math\n",
+ "\n",
+ " # Calculation \n",
+ "tbar=(Ls/(A*Nc))*((X1-Xcr)+(Xcr-Xbar)*math.log((Xcr-Xbar)/(X2-Xbar)));\n",
+ "\n",
+ "# Result\n",
+ "print \"the time for drying the sheets from .15 to .025 kg water /kg of dyr solid moisture under same drying conditions is :%f hour\"%(tbar/3600);\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "the time for drying the sheets from .15 to .025 kg water /kg of dyr solid moisture under same drying conditions is :3.807740 hour\n"
+ ]
+ }
+ ],
+ "prompt_number": 31
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.8.b "
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "# Variable Declaration \n",
+ "Ls=1000.; #mass of bone dry solid ais the drying surface\n",
+ "A=55.; #both upper surafce and lower surface are exposed\n",
+ "v=.75; #velocity of air\n",
+ "Nc=.3*10**-3; #in kg/m**2*s\n",
+ "x2=.2; #moisture content on wet basis finally after drying\n",
+ "Xcr=0.125; #crtical moisture content\n",
+ "X1=0.15; #moisture content on dry basis intially\n",
+ "X2=0.025; #moisture content on dry basis finally after drying\n",
+ "Xbar=0.0; #equillibrium moisture \n",
+ "tbar=3.8077; #time to dry material ,calculated from previous part\n",
+ "V1=.75; #old velocity\n",
+ "V2=4.; #new velocity\n",
+ "import math\n",
+ "\n",
+ "# Calculation \n",
+ "Nc2=Nc*(V2/V1)**.71; #in kg/m**2*s\n",
+ "t2=(Ls/(A*Nc2))*((X1-Xcr)+(Xcr-Xbar)*math.log((Xcr-Xbar)/(X2-Xbar))); #if air velocity is increased to 4\n",
+ "t=tbar-t2/3600; #time saved\n",
+ "\n",
+ "# Result\n",
+ "print \"\\n the time saved , if air velocity is increased to 4 m/s: %f\"%t\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the time saved , if air velocity is increased to 4 m/s: 2.647593\n"
+ ]
+ }
+ ],
+ "prompt_number": 32
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.9 "
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "x1=.75; #moisture content on wet basis\n",
+ "xbar=0.1; #equilllibrium moisture on dry basis\n",
+ "xcr=0.6; #critical moisture content\n",
+ "Ls=0.90; #mass of bone dry solid ais the drying surface\n",
+ "A=0.3*0.3*2; #both upper surafce and lower surface are exposed\n",
+ "#A*Nc=10**-4;\n",
+ "x2=.2; #moisture content on wet basis finally after drying\n",
+ "\n",
+ "# Calculation \n",
+ "Xcr=0.6/0.4; #crtical moisture content\n",
+ "X1=3; #moisture content on dry basis intially\n",
+ "X2=0.25; #moisture content on dry basis finally after drying\n",
+ "Xbar=0.1/0.9; #equillibrium moisture \n",
+ "import math\n",
+ "tbar=Ls/(10**-4) * ((X1-Xcr)+(Xcr-Xbar)*math.log((Xcr-Xbar)/(X2-Xbar)));\n",
+ "\n",
+ "# Result \n",
+ "print \"\\n the time for drying the sheets from 75 to 25 percent moisture under same drying conditions is :%f hr\"%(tbar/3600);\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the time for drying the sheets from 75 to 25 percent moisture under same drying conditions is :11.745087 hr\n"
+ ]
+ }
+ ],
+ "prompt_number": 34
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.10 "
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "# Variable Declaration \n",
+ "Xcr=0.16; #crtical moisture content\n",
+ "X1=.33; #moisture content on dry basis intially\n",
+ "X2=0.09; #moisture content on dry basis finally after drying\n",
+ "Xbar=.05; #equillibrium moisture \n",
+ "tbar=7; #time needed to dry from 33 to 9 percent on bone dry basis\n",
+ "import math\n",
+ "#let Ls / A*Nc be = p\n",
+ "#p=poly([0],'p'); #calc. of Ls / A*Nc be = p value\n",
+ "# Calculation \n",
+ "x= 24.886579 #roots(tbar-p * ((X1-Xcr)+(Xcr-Xbar)*math.log((Xcr-Xbar)/(X2-Xbar))));\n",
+ "\n",
+ "#new X1 AND X2 are now given as follows\n",
+ "X1=0.37; #new moisture content on dry basis intially\n",
+ "X2=0.07; #new moisture content on dry basis finally after drying\n",
+ "tbar=x * ((X1-Xcr)+(Xcr-Xbar)*math.log((Xcr-Xbar)/(X2-Xbar)));\n",
+ "\n",
+ "# Result\n",
+ "print \"\\n the time for drying the sheets from 33 to 9 percent moisture under same drying conditions is :%f hr\"%tbar\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the time for drying the sheets from 33 to 9 percent moisture under same drying conditions is :9.892970 hr\n"
+ ]
+ }
+ ],
+ "prompt_number": 35
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.11 "
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "# Variable Declaration \n",
+ "d=.22; #density of dry pulp in g/cc;\n",
+ "x1=.65; #moisture content on wet basis\n",
+ "x2=.3; #moisture content on wet basis\n",
+ "Ls=2.5; #mass of bone dry solid ais the drying surface in kg\n",
+ "A=1.5*1.5*2; #both upper surafce and lower surface are exposed\n",
+ "v=1.5*1.5*.5; #volume of material\n",
+ "Nc=1.4; #in kg/m**2*hr\n",
+ "Xcr=1.67; #crtical moisture content\n",
+ "# Calculation \n",
+ "X1=x1/(1-x1); #moisture content on dry basis intially\n",
+ "X2=x2/(1-x2); #moisture content on dry basis finally after drying\n",
+ "Xbar=0.0; #equillibrium moisture \n",
+ "import math\n",
+ "\n",
+ "tbar=(Ls/(A*Nc))*((X1-Xcr)+(Xcr-Xbar)*math.log((Xcr-Xbar)/(X2-Xbar)));\n",
+ "\n",
+ "# Result\n",
+ "print \"\\n the time for drying the sheets from 65 to 30 percent moisture under same drying conditions is :%f hour\"%tbar\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the time for drying the sheets from 65 to 30 percent moisture under same drying conditions is :0.975613 hour\n"
+ ]
+ }
+ ],
+ "prompt_number": 36
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.12"
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ "\n",
+ "# Variable Declaration \n",
+ "d=.22; #density of dry pulp in g/cc;\n",
+ "\n",
+ "Ls=1.125*10**-2*.22*10**3; #mass of bone dry solid ais the drying surface\n",
+ "A=1.5*1.5*2; #both upper surafce and lower surface are exposed\n",
+ "v=1.5*1.5*.5; #volume of material\n",
+ "Nc=1.4; #in kg/m**2*hr\n",
+ "x2=.2; #moisture content on wet basis finally after drying\n",
+ "Xcr=0.46; #crtical moisture content\n",
+ "X1=0.15; #moisture content on dry basis intially\n",
+ "X2=0.085; #moisture content on dry basis finally after drying\n",
+ "Xbar=0.025; #equillibrium moisture \n",
+ "import math\n",
+ "#tbar=(Ls/(A*Nc))*((Xcr-Xbar)*log((Xcr-Xbar)/(X2-Xbar)));\n",
+ "\n",
+ "\n",
+ "# Calculation \n",
+ "tbar=(Ls/(A*Nc))*((Xcr-Xbar)*math.log((X1-Xbar)/(X2-Xbar)));\n",
+ "\n",
+ "# Result\n",
+ "print \"\\n the time for drying the sheets from 15 to 8.5 percent moisture under same drying conditions is :%f min\"%(tbar*60)\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the time for drying the sheets from 15 to 8.5 percent moisture under same drying conditions is :7.525805 min\n"
+ ]
+ }
+ ],
+ "prompt_number": 37
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.13"
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "# Variable Declaration \n",
+ "import math\n",
+ "Xcr=0.14; #crtical moisture content\n",
+ "x1=0.3; #moisture content on wet basis\n",
+ "x2=0.1; #moisture content on wet basis\n",
+ "X1=x1/(1-x1); #moisture content on dry basis intially\n",
+ "X2=x2/(1-x2); #moisture content on dry basis finally after drying\n",
+ "Xbar=0.04; #equillibrium moisture \n",
+ "tbar=5; #time needed to dry from 30 to 10 percent on bone dry basis\n",
+ "\n",
+ " #let Ls / A*Nc be = p\n",
+ "#p=poly([0],'p'); #calc. of Ls / A*Nc be = p value\n",
+ "x= 15.495992 #roots(tbar-p * ((X1-Xcr)+(Xcr-Xbar)*math.log((Xcr-Xbar)/(X2-Xbar))));\n",
+ "\n",
+ "#new X1 AND X2 are now given as follows\n",
+ "# Calculation \n",
+ "x1=.3; #new moisture content on wet basis\n",
+ "x2=0.06; #new moisture content on wet basis\n",
+ "X1=x1/(1-x1); #new moisture content on dry basis intially\n",
+ "X2=x2/(1-x2); #new moisture content on dry basis finally after drying\n",
+ "tbar=x * ((X1-Xcr)+(Xcr-Xbar)*math.log((Xcr-Xbar)/(X2-Xbar)));\n",
+ "\n",
+ "# Result\n",
+ "print \"\\n the time for drying the sheets from 30 to 10 percent moisture under same drying conditions is :%f hr\"%tbar\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the time for drying the sheets from 30 to 10 percent moisture under same drying conditions is :6.694188 hr\n"
+ ]
+ }
+ ],
+ "prompt_number": 38
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.14"
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "d=450.; #density of dry pulp in kg/m**3;\n",
+ "thickness=0.05; #thickness in m**2\n",
+ "Ls=d*thickness; #mass of bone dry solid ais the drying surface\n",
+ "A=1.; #area in m**2\n",
+ "v=1*5*10**-2; #volume of material\n",
+ "Nc=4.8; #in kg/m**2*hr\n",
+ "xcr=.2;\n",
+ "xbar=0.02;\n",
+ "x1=.45; #new moisture content on wet basis\n",
+ "x2=0.05; #new moisture content on wet basis\n",
+ "\n",
+ "# Calculation \n",
+ "X1=x1/(1-x1); #new moisture content on dry basis intially\n",
+ "X2=x2/(1-x2); #new moisture content on dry basis finally after drying\n",
+ "Xbar=xbar/(1-xbar); #crtical moisture content\n",
+ "Xcr=xcr/(1-xcr); #equillibrium moisture \n",
+ "import math\n",
+ "#tbar=(Ls/(A*Nc))*((Xcr-Xbar)*log((Xcr-Xbar)/(X2-Xbar)));\n",
+ "\n",
+ "tbar=Ls/(A*Nc) * ((X1-Xcr)+(Xcr-Xbar)*math.log((Xcr-Xbar)/(X2-Xbar)));\n",
+ "\n",
+ "# Result\n",
+ "print \"\\n the time for drying the sheets from 45 to 5 percent moisture under same drying conditions is :%f min\"%tbar\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the time for drying the sheets from 45 to 5 percent moisture under same drying conditions is :4.776612 min\n"
+ ]
+ }
+ ],
+ "prompt_number": 39
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.15"
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "# Variable Declaration \n",
+ "t1=20.; #ambient air temperature \n",
+ "t2=70.; #exhaust air temperature \n",
+ "r1=150.; #evaporation of water \n",
+ "r2=.25; #outlet solid moisture content\n",
+ "t3=15.; #inlet solid temperature\n",
+ "t4=65.; #outlet solid temperature\n",
+ "p=5.; #power demand in KW\n",
+ "h=18.; #heat loss in kj\n",
+ "\n",
+ "h1=1.; #mean specific heat of dry air in kj/kg*K\n",
+ "h2=1.25; #mean specific heat of dry material in kj/kg*K\n",
+ "h3=4.18; #mean specific heat of moisture in kj/kg*K\n",
+ "e=2626.; #enthalpy of saturated water vapour in kj/kg\n",
+ "\n",
+ "# Calculation \n",
+ " #basis is 1hr\n",
+ "a1=r1*h3*(t4-t3); #heat required for heating 150 kg of water from 15 to 65\n",
+ "a2=r1*e; #heat required for 150 kg water evaporation\n",
+ "a3=2000*h1*(t2-t1); #heat required for heating air from 20 to 70 \n",
+ "a4=r2*h3*(t4-t3); #heat required for heating moisture from 15 to 65\n",
+ "a5=120*h2*(t4-t3); #heat required for heating dry solid from 15 to 65\n",
+ "hlost=h*3600; #heat lost in kj\n",
+ "total=(a2+a3+a4+a5+hlost)/3600.; #total heat lost \n",
+ "\n",
+ "# Result\n",
+ "print \"\\n :%f kW of heat required for 2000kg/hr of dry air\"%total\n",
+ "ans1=a2+a1; #heat needed for evaporation \n",
+ "print \"\\n heat needed fro evaporation is :%f\"%(ans1/3600)\n",
+ "ans2=(ans1/3600.)/total; #fraction of this heat needed for evaporation\n",
+ "print \"\\n fraction of this heat needed for evaporation:%f\"%(ans2)\n",
+ " \n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " :157.292292 kW of heat required for 2000kg/hr of dry air\n",
+ "\n",
+ " heat needed fro evaporation is :118.125000\n",
+ "\n",
+ " fraction of this heat needed for evaporation:0.750990\n"
+ ]
+ }
+ ],
+ "prompt_number": 40
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.16"
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "m1=.12; #initial moisture content\n",
+ "dT=85.; #product of 85 degree is used in design purpose\n",
+ "U=1700.; #overall heat transfer coefficient\n",
+ "m2=.4; #final moisture content\n",
+ "r=20.; #production rate\n",
+ " #4 kg of moisture is present in 100 kg product\n",
+ "# Calculation \n",
+ "t=4*20./100; # moisture content in 20 kg moisture\n",
+ "w=20-t; #dry solid weight\n",
+ "i=w*m1/(1-m1); #initial moisture content \n",
+ "j=i-t #water evaporated\n",
+ "ds=2296.1; #latent heat for vaporisation at 85 degree in kj/kg\n",
+ "h=j*ds; #heat required (assuming th esolid mix. enters at 85)\n",
+ "#U*A*dT = j*ds\n",
+ "A=h/(U*dT); #surface area of the roller required to produce aproduction rate of 20 kg product per hour\n",
+ "\n",
+ "# Result \n",
+ "print \"\\n surface area of the roller required to produce aproduction rate of 20 kg product per hour:%f m**2\"%(A/3.600);\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " surface area of the roller required to produce aproduction rate of 20 kg product per hour:0.008025 m**2\n"
+ ]
+ }
+ ],
+ "prompt_number": 41
+ },
+ {
+ "cell_type": "heading",
+ "level": 3,
+ "metadata": {},
+ "source": [
+ "Example 6.17"
+ ]
+ },
+ {
+ "cell_type": "code",
+ "collapsed": false,
+ "input": [
+ " \n",
+ "\n",
+ "# Variable Declaration \n",
+ "r=7.5*10**-5; #constant drying rate in kg/s\n",
+ "A1=.3*.3**2; # area of the sppecimen\n",
+ "Nc=r/A1; #drying rate\n",
+ "# Calculation \n",
+ "Xcr=.15/0.85; #.15 is the critical moisture content\n",
+ "Xo=.25/.75; #.25 is the initial moisture content\n",
+ "Xfinal=.02/0.98; #.02 is the final moisture content\n",
+ "Xbar=0; #equillibrium moisture content\n",
+ "A=1.2*.6*2; #area of the new solid\n",
+ "Ls=28.8; #bone dry weight of new solid\n",
+ "v1=.3*.3*.006; #volume of the old solid;\n",
+ "v2=.6*1.2*.012; #volume of the new solid\n",
+ "w2=1.8; #weight of the old solid\n",
+ "w3=864*10**-5*1.8*10**-5/54; #weight of the bone dry solid\n",
+ "\n",
+ " #Nc is prporional to =(t-ts) = (G)**0.71---- whrere G is the mass flow rate\n",
+ "v1=3.; #old velocity\n",
+ "Tg=52.; #old dry bulb temperature\n",
+ "Tw=21.; #wet bulb temperature\n",
+ "H=.002; #humidity \n",
+ "SH=0.015; #saturated humidity \n",
+ "vnew=5. #new velocity\n",
+ "Tgnew=66.; #new DBT\n",
+ "Twnew=24.; #new WBT\n",
+ "Hnew=.004; #new humidity\n",
+ "SH=.020; #new satuurated humidity\n",
+ "import math \n",
+ "#hence drying rate of air under new condition\n",
+ "Nc=4.167*10**-4*((vnew/v1)*(273+Tg)/(273+Tgnew))**0.71 * ((.019-H)/(.015-H));#drying rate of air under new condition in kg/m**2*s \n",
+ "DT=Ls/(A*Nc) * ((Xo-Xcr)+(Xcr-Xbar)*math.log((Xcr-Xbar)/(Xfinal-Xbar)));\n",
+ "\n",
+ "# Result\n",
+ "print \"\\n the time for drying the sheets from 25 to 2 percent moisture under same drying conditions is :%f hours\"%(DT/3600)\n",
+ "\n",
+ "\n",
+ "#end"
+ ],
+ "language": "python",
+ "metadata": {},
+ "outputs": [
+ {
+ "output_type": "stream",
+ "stream": "stdout",
+ "text": [
+ "\n",
+ " the time for drying the sheets from 25 to 2 percent moisture under same drying conditions is :3.929236 hours\n"
+ ]
+ }
+ ],
+ "prompt_number": 42
+ }
+ ],
+ "metadata": {}
+ }
+ ]
+} \ No newline at end of file
generated by cgit (git 2.34.1) at 2024-12-20 18:23:15 +0000