{ "cells": [ { "cell_type": "markdown", "metadata": {}, "source": [ "# Chapter 8 - Thermal flow" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 1 - pg 168" ] }, { "cell_type": "code", "execution_count": 1, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "(a)Final velocity of steam is (m/s) = 636.38\n", "(b)Percentage reduction in velocity is (percent) = 6.19\n" ] } ], "source": [ "#calculate the Final velocity and percentage reduction in velocity\n", "#Input data\n", "P1=12.;#Pressure of Dry saturated steam entering a steam nozzle in bar\n", "P2=1.5;#Discharge pressure of Dry saturated steam in bar\n", "f=0.95;#Dryness fraction of the discharged steam\n", "l=12.;#Heat drop lost in friction in percentage\n", "hg1=2784.8;#Specific enthalpy of steam at 12 bar from steam tables in kJ/kg\n", "hg2=2582.3;#Specific enthalpy of 0.95 dry steam at 1.5 bar from steam tables in kJ/kg\n", "\n", "#Calculations\n", "hd=hg1-hg2;#Heat drop in kJ/kg\n", "V1=44.72*(hd)**(0.5);#Velocity of steam at discharge from the nozzle in m/s\n", "n=1-(l/100.);#Nozzle coefficient when 12 percent heat drop is lost in friction\n", "V2=44.72*(n*hd)**(0.5);#Velocity of steam in m/s\n", "percentV=((V1-V2)/V1)*100;#Percentage reduction in velocity\n", "\n", "#Output\n", "print '(a)Final velocity of steam is (m/s) = ',round(V1 ,2)\n", "print '(b)Percentage reduction in velocity is (percent) = ',round(percentV,2)\n" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 2 - pg 174" ] }, { "cell_type": "code", "execution_count": 2, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "The mass of steam discharged,when the exit diameter of the nozzle is 12mm is (kg/hour) = 236.47\n" ] } ], "source": [ "#calculate the mass of steam\n", "#Input data\n", "P1=12.;#Initial pressure of dry saturated steam expanded in a nozzle in bar\n", "P2=0.95;#Final pressure of dry saturated steam expanded in a nozzle in bar\n", "f=10.;#Frictional loss in the nozzle of the total heat drop in percentage\n", "d=12.;#Exit diameter of the nozzle in mm\n", "hd=437.1;#Heat drop in kJ/kg from steam tables\n", "q=0.859;#Dryness fraction of steam at discharge pressure\n", "vg=1.777;#Specific volume of dry saturated steam at 0.95 bar\n", "\n", "#Calculations\n", "n=1-(f/100);#Nozzle coefficient from moiller chart\n", "V2=44.72*(n*hd)**(0.5);#Velocity of steam at nozzle exit in m/s\n", "A=(3.14/4)*(0.012)**(2);#Area of the nozzle at the exit in mm**2\n", "m=((A*V2)/(q*vg))*3600;#Mass of steam discharged through the nozzle per hour in kg/hour\n", "\n", "#Output\n", "print 'The mass of steam discharged,when the exit diameter of the nozzle is 12mm is (kg/hour) = ',round(m,2)\n" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 3 - pg 176" ] }, { "cell_type": "code", "execution_count": 3, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "(a)Throat area of steam nozzle is (cm^2) = 1.67\n", "(b)Exit area of steam nozzle is (cm^2) = 2.016\n", "(c)Exit velocity of the nozzle is (m/s) = 831.62\n" ] } ], "source": [ "#calculate the throat area of steam and exit area,exit velocity\n", "#Input data\n", "P1=12.;#Inlet pressure of steam nozzle in bar\n", "T1=250.;#Inlet temperature of steam nozzle in degrees celcius\n", "P2=2.;#Final pressure of the steam nozzle in bar\n", "n=1.3;#Polytropic constant for superheated steam\n", "St=6.831;#For isentropic expansion, entropy remains constant in kJ/kg\n", "h1=2935.4#Enthalpy of steam at P1 from steam table in kJ/kg\n", "ht=2860.;#Enthalpy of steam at pt in kJ/kg\n", "vt=0.325;#Specific volume of steam at the throat conditions in m**3/kg\n", "m=0.2;#Mass of steam discharged through the nozzle in kg/hour\n", "q=0.947;#The dryness fraction of steam at exit from steam tables\n", "hg=2589.6;#Enthalpy of steam at exit in kJ/kg\n", "vs=0.8854;#Specific volume of saturated steam in m**3/kg\n", "\n", "#Calculations\n", "pt=(P2/(n+1))**(n/(n-1))*P1;#Critical pressure ratio i.e.,Throat pressure in bar\n", "Vt=(2*1000*(h1-ht))**(0.5);#Velocity of steam at throat in m/s\n", "At=((m*vt)/Vt)*10**4;#Area of the throat in cm**2 from continuity equation\n", "ve=q*vs;#Specific volume of steam at exit in m**3/kg\n", "Ve=(2*1000*(h1-hg))**(0.5);#Velocity of steam at nozzle exit in m/s\n", "Ae=((m*ve)/Ve)*10**4;#Exit area in cm**2\n", "\n", "#Output\n", "print '(a)Throat area of steam nozzle is (cm^2) = ',round(At,2)\n", "print '(b)Exit area of steam nozzle is (cm^2) = ',round(Ae,3)\n", "print '(c)Exit velocity of the nozzle is (m/s) = ',round(Ve,2)\n" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 4 - pg 177" ] }, { "cell_type": "code", "execution_count": 4, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "(a)Final exit velocity of steam is (m/s) = 785.246\n", "(b)Cross sectional area of the nozzle at exit for maximum discharge is (mm^2) = 677.736\n" ] } ], "source": [ "#calculate the Final exit velocity, Cross sectional area\n", "#Input data\n", "P1=10.;#Pressure of steam in bar\n", "f=0.9;#Dryness fraction of steam\n", "At=350.;#Throat area in mm**2\n", "Pb=1.4;#Back pressure in bar\n", "h1=2574.8;#Enthalpy of steam at nozzle inlet from steam tables in kJ/kg\n", "ft=0.87;#Dryness fraction of steam at throat pressure\n", "fe=0.81;#Dryness fraction of steam at exit pressure\n", "ht=2481.;#Enthalpy of steam at throat pressure at ft in kJ/kg\n", "vt=0.285;#Specific volume of steam at throat in m**3/kg\n", "he=2266.2;#Enthalpy of steam at exit conditions in kJ/kg\n", "ve=1.001;#Specific volume of steam at exit conditions in m**3/kg\n", "\n", "#Calculations\n", "Pt=0.582*P1;#Steam pressure at the throat in bar\n", "hd=h1-ht;#Enthalpy drop upto the throat in kJ/kg\n", "Vt=44.7*(hd)**(0.5);#Velocity of steam at the throat in m/s\n", "hde=h1-he;#Enthalpy drop from nozzle entrance to exit in kJ/kg\n", "Ve=44.7*(hde)**(0.5);#Velocity of steam at nozzle exit in m/s\n", "Ae=(At*Vt*ve)/(Ve*vt);#Exit area of nozzle from the mass rate of flow equation in mm**2\n", "\n", "#Output\n", "print '(a)Final exit velocity of steam is (m/s) = ',round(Ve,3)\n", "print '(b)Cross sectional area of the nozzle at exit for maximum discharge is (mm^2) = ',round(Ae,3)\n" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 5 - pg 192" ] }, { "cell_type": "code", "execution_count": 5, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "(a)Velocity of steam at throat is (m/s) = 530.78\n", "(b)Temperature of steam at the throat is (degrees celcius) = 202.8\n", "(c)Cone angle of the divergent portion is (degrees) = 2.134\n" ] } ], "source": [ "#calculate the Velocity of steam at throat, temperature and cone angle\n", "#Input data\n", "import math\n", "P1=7.;#Inlet pressure of a convergent divergent steam nozzle in bar\n", "T1=275.;#Inlet temperature of the nozzle in degrees celcius\n", "P2=1.;#Discharge pressure of steam in bar\n", "l=60.;#Length of diverging portion of the nozzle in mm\n", "dt=6.;#Diameter of the throat in mm\n", "f1=10.;#Percent of total available enthalpy drop lost in friction in the diverging portion in percentage\n", "h1=3006.9;#Enthalpy of steam at 7bar pressure and 275 degrees celcius in kJ/kg\n", "ht=2865.9;#Enthalpy at the throat from Moiller chart in kJ/kg\n", "he=2616.7;#Enthalpy at the exit from moiller chart in kJ/kg\n", "vt=0.555;#Specific volume of steam at throat in m**3/kg\n", "Tt=202.8;#Temperature of steam at throat in degrees celcius from moiller chart\n", "ve=1.65;#Volume of steam at exit in m**3/kg\n", "\n", "#Calculations\n", "Pt=0.546*P1;#The throat pressure for maximum discharge in bar\n", "hd=h1-ht;#Enthalpy drop upto throat in kJ/kg\n", "Vt=44.7*(hd)**(0.5);#Velocity of steam at throat in m/s\n", "hid=h1-he;#Total isentropic drop from 7 bar,275 degrees celcius to 1 bar in kJ/kg\n", "hda=(1-(f1/100.))*(hid);#Actual heat drop in kJ/kg\n", "Ve=44.7*(hda)**(0.5);#Velocity at exit in m/s\n", "At=(3.14/4)*(6./1000)**(2);#Throat area of the nozzle in m**2\n", "m=(At*Vt)/vt;#Mass flow rate at nozzle throat in kg/s\n", "Ae=((m*ve)/Ve)*10**4;#Exit area of the nozzle in cm**2\n", "de=(((Ae*4)/3.14)**(0.5))*10;#Diameter of the nozzle at exit in mm\n", "alpha=math.atan((de-dt)/(2*60))*180/math.pi;#Half of the cone angle of the nozzle in degrees\n", "alpha1=2*alpha;#Cone angle of the nozzle in degrees\n", "\n", "#Output\n", "print '(a)Velocity of steam at throat is (m/s) = ',round(Vt,2)\n", "print '(b)Temperature of steam at the throat is (degrees celcius) =',Tt\n", "print '(c)Cone angle of the divergent portion is (degrees) =',round(alpha1,3)\n" ] } ], "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": "2.7.9" } }, "nbformat": 4, "nbformat_minor": 0 }