diff --git a/js/CookingFormula.js b/js/CookingFormula.js index 2d12c52..8cf2361 100644 --- a/js/CookingFormula.js +++ b/js/CookingFormula.js @@ -1,5 +1,6 @@ //Useful Websites -//http://math.stackexchange.com/questions/406082/numerical-method-to-solve-a-trigonometric-cotangent-function-transient-heat +// http://math.stackexchange.com/questions/406082/numerical-method-to-solve-a-trigonometric-cotangent-function-transient-heat +// http://web.cecs.pdx.edu/~gerry/epub/pdf/transientConductionSphere.pdf //Global Variables for Turkey density = 996; // kg/m3 Assuming Density of Water 1000 kg/m3 @@ -54,38 +55,67 @@ complexRadius = Math.pow(rectangleVolume/((4/3)*Math.PI), 1/3); //Volume of 3D B console.log("Simple Radius " + simpleRadius + " Meters") console.log("Complex Radius " + complexRadius + " Meters") +return(complexRadius) } -function lumpedCapacitanceMethod (radiusTotal,radiusInner,tempInitial,tempInfini, t) { -name : "Skin" -volume = (4/3)*Math.PI*Math.pow(radiusTotal,3) - (4/3)*Math.PI*Math.pow(radiusInner,3); //3D Sphere -surfaceArea = 4*Math.PI*Math.pow(radiusTotal,2); //3D Sphere +function Turkey(weight,time) { -mass = density * volume; +totalRadius = calculateRadius(weight) +ovenTemp = 163; +airConvection = 12; // W/m2 K Some Reasonable estimate for natural Convection. Change as needed. 5-25 + function Layer(name) { + this.name = name + this.temperature = 20; + this.waterContent =100; + this.Qdot = 0; + } + +skin= new Layer("Skin") +body = new Layer("Body") +core = new Layer("Core") -charLength = volume/surfaceArea ; +skin.temperature = lumpedCapacitance(totalRadius,totalRadius*0.85,skin.temperature,ovenTemp,airConvection,time)[0] +body.temperature = lumpedCapacitance(totalRadius*0.85,totalRadius*0.30,body.temperature,skin.temperature,airConvection*1000,time)[0] +core.temperature = lumpedCapacitance(totalRadius*0.30,0,core.temperature,body.temperature,airConvection*1000,time)[0] -biotNum = heatConvection * charLength/thermalConduct +} +function lumpedCapacitance (outerRadius,radiusInner,tempInitial,tempInfini,heatConvectionTerm,t) { +volume = (4/3)*Math.PI*Math.pow(outerRadius,3) - (4/3)*Math.PI*Math.pow(radiusInner,3); //3D Sphere +surfaceArea = 4*Math.PI*Math.pow(outerRadius,2); //3D Sphere +mass = density * volume; +charLength = volume/surfaceArea ; +biotNum = heatConvectionTerm * charLength/thermalConduct console.log("The Biot Value is " + biotNum) - -b=(heatConvection)/(density*charLength*cp) +b=(heatConvectionTerm)/(density*charLength*cp) console.log("The time constant b is "+ b) - tempAtTime = Math.exp(-b*t)*(tempInitial-tempInfini)+tempInfini; console.log("The Temperature at time " + t +" seconds is " + tempAtTime) - -Qdot = -1*heatConvection*surfaceArea*(tempAtTime-tempInfini) //Heat Transfer Rate Useful for water Loss -console.log("The Heat Flux is " + Qdot ) +qDot = -1*heatConvectionTerm*surfaceArea*(tempAtTime-tempInfini) //Heat Transfer Rate Useful for water Loss +console.log("The Heat Flux is " + qDot ) +return([tempAtTime,qDot]) } -function advancedLumpedCapacitanceMethod() { - +function lumpedCapacitanceMethod (outerRadius,radiusInner,tempInitial,tempInfini, t) { +volume = (4/3)*Math.PI*Math.pow(outerRadius,3) - (4/3)*Math.PI*Math.pow(radiusInner,3); //3D Sphere +surfaceArea = 4*Math.PI*Math.pow(outerRadius,2); //3D Sphere +mass = density * volume; +charLength = volume/surfaceArea ; +biotNum = heatConvection * charLength/thermalConduct +console.log("The Biot Value is " + biotNum) +b=(heatConvection)/(density*charLength*cp) +console.log("The time constant b is "+ b) +tempAtTime = Math.exp(-b*t)*(tempInitial-tempInfini)+tempInfini; +console.log("The Temperature at time " + t +" seconds is " + tempAtTime) +Qdot = -1*heatConvection*surfaceArea*(tempAtTime-tempInfini) //Heat Transfer Rate Useful for water Loss +console.log("The Heat Flux is " + Qdot ) +return(tempAtTime) } + function transientSphereOneTerm (rPosition,rTotal,tempInitial,tempInfini,t) { alpha = thermalConduct/(density*cp) console.log("Alpha is " + alpha) @@ -107,42 +137,14 @@ tempAtTimeAndRadius=(sinPortion*expotentialPortion*(tempInitial-tempInfini))+tem console.log("The Temperature at radius " + rPosition + " m and time " + t + " seconds is " + tempAtTimeAndRadius + " C or " + celsiusToFarenheit(tempAtTimeAndRadius) + " F"); } - -function transientSphereEgg (rPosition,tempInitial,tempInfini,t) { -rTotal = 0.025 -heatConvection = 1200; // W/m2 K Some Reasonable estimate for natural Convection. Change as needed. 5-25 -thermalConduct = 0.627 // W/m K -alpha = 0.000000151 -console.log("Alpha is " + alpha) - -Fourier = alpha * t/Math.pow(rTotal,2) -console.log("Fourier is " + Fourier) -biotNum = heatConvection * rTotal/thermalConduct - -console.log("The Biot Value is " + biotNum) -temp=biotSphereCoefficients(biotNum) -lambdaOne=temp[0]; -alphaOne=temp[1]; -console.log("lambda1 is " + lambdaOne) -console.log("A1 is " + alphaOne) - -//This is only valid for Fourier greater than 0.2 -sinPortion= Math.sin(lambdaOne*rPosition/rTotal)/(lambdaOne*rPosition/rTotal); -expotentialPortion = alphaOne*(1/Math.exp(Math.pow(lambdaOne,2)*Fourier)) -tempAtTimeAndRadius=(sinPortion*expotentialPortion*(tempInitial-tempInfini))+tempInfini -console.log("The Temperature At radius " + rPosition +" m and time " + t + " seconds is " + tempAtTimeAndRadius + " C or " + celsiusToFarenheit(tempAtTimeAndRadius) + " F" ); -} - - - function findAllRoots (Biot) { -limit = 150; //Terms to Compute too +limit = 50; //Terms to Compute too storage = []; for (var k=0; k<=limit; k++) { minK = (k+0.5)*Math.PI; maxK = (k+1)*Math.PI; answer = bisectionMethod(minK,maxK,Biot); - if (answer !=null) { + if (answer !=undefined) { storage.push(answer); } } @@ -150,32 +152,53 @@ storage = []; return(storage) } - +function findAllRootsAlternative (min,max,splitsNum,Biot) { +var step = ( max - min ) / ( splitsNum - 1 ); +var storage = []; + for (var i = step; i < max; i=i+step ) { + negativeTest = lambdaFormula(i-step, Biot)*lambdaFormula(i, Biot); + if (negativeTest <= 0) { + answer = bisectionMethod(i-step,i,Biot); + if (answer !=undefined) { + storage.push(answer); + } + } + else { + //console.log("No Bracketed Root " + negativeTest) + } + } +return(storage) +} + +function linspace(min, max, length) { +var arr = new Array(length); +var step = ( max - min ) / ( length - 1 ); +for (var i = 0; i < length; ++i ) + arr[i] = min + ( i * step ) + return arr +} + function bisectionMethod(min,max,Biot) { errorTolerance = (1/Math.pow(10,9)) result = Infinity // some large value to ensure the calculation goes through. negativeTest =lambdaFormula(min, Biot)*lambdaFormula(max, Biot) -if (negativeTest <=0 ) { - while (Math.abs(result) > errorTolerance) { - lambdaN = (min+max)/2 - result=lambdaFormula(lambdaN, Biot) - - if (Math.abs(result) <= errorTolerance) { - return (lambdaN); //At Root - } - else if ((lambdaFormula(min, Biot)*lambdaFormula(lambdaN, Biot))>=0) { - min=lambdaN; - } - else if ((lambdaFormula(max, Biot)*lambdaFormula(lambdaN, Biot))>=0) { - max=lambdaN; + if (negativeTest <=0 ) { + var antiFreeze=0; + while (Math.abs(result) > errorTolerance && antiFreeze<=10000) { + lambdaN = (min+max)/2 + result=lambdaFormula(lambdaN, Biot) + if (Math.abs(result) <= errorTolerance && result<=errorTolerance) { + return (lambdaN); //At Root + } + else if ((lambdaFormula(min, Biot)*lambdaFormula(lambdaN, Biot))>=0) { + min=lambdaN; + } + else if ((lambdaFormula(max, Biot)*lambdaFormula(lambdaN, Biot))>=0) { + max=lambdaN; + } + antiFreeze++ } } - return (lambdaN); -} -else -{ -//console.log("No Bracketed Root " + negativeTest) -} } function lambdaFormula(lambdaN, Biot) {