Controlling local fluid age in a stirred reactor

The invention claimed is: 1. A method to determine a preferred inlet location for a continuous stirred tank reactor comprising: 1) preparing a transparent model reactor comprising, an agitator, a number of alternate inlet ports, and at least one planar exterior surface, which model reactor will be used to generate data to be stored from subsequent steps of the method; 2) filling the model reactor with a test fluid having a viscosity chosen to produce the desired Reynolds number, which fluid contains a uniform concentration of a tracer dye which fluoresces under a known wavelength of incident light; 3) flowing six times the model reactor volume of test fluid without dye into and through the model reactor using a selected inlet port with the agitator running at a constant speed to provide a constant Reynolds number to introduce a step change in concentration of the tracer dye in the model reactor; 4) while the dye is being washed out of the model reactor and during mixing, subjecting the model reactor contents to a plane of laser light through the planar exterior surface of the model reactor, whose wavelength causes the dye to fluoresce at a different wavelength from that of the laser; 5) taking digital images of the fluorescent light from the model reactor through a filter to filter out the incident laser light at a rate synchronized with the rate of rotation of the agitator; 6) calculating a normalized dye concentration in each pixel of each image; 7) integrating the normalized concentration in each pixel over all images in time to calculate an average local fluid age of each pixel; 8) calculating a standard deviation and a mean of the local ages and a coefficient of variance; 9) iteratively repeating steps 1 through 8 for different inlets to the model reactor, wherein the calculated normalized dye concentration, calculated average local fluid age, calculated standard deviation and mean of the local ages, and calculated coefficient of variance become stored data; 10) comparing the stored data to determine the inlet which provides at least one of: i) a normalized dye concentration from 0.5 to 1.3; ii) a coefficient of variance from 0.01 to 0.1; and iii) a minimum standard deviation in the average local age of the model reactor contents; and iv) a minimum standard deviation in the average age of the model reactor contents, and 11) selecting the input port, which provides the preferred values from step 8. 2. A method to determine a preferred agitator for a continuous stirred tank reactor (CSTR) reactor comprising: 1) preparing a transparent model reactor comprising, an agitator, a number of alternate inlet ports, and at least one planar exterior surface, which model reactor will be used to generate data to be stored from subsequent steps of the method; 2) filling the model reactor with a test fluid having a viscosity chosen to produce the desired Reynolds number, which fluid contains a uniform concentration of a tracer dye which fluoresces under a known wavelength of incident light; 3) flowing six times the model reactor volume of test fluid without dye into and through the model reactor using a selected inlet port and agitator running at a constant speed to provide a constant Reynolds number to introduce a step change in concentration of the tracer dye in the model reactor; 4) while the dye is being washed out of the model reactor and during mixing, subjecting the model reactor contents to a plane of laser light through the planar exterior surface of the model reactor, whose wavelength causes the dye to fluoresce at a different wavelength from that of the laser; 5) taking digital images of the fluorescent light from the model reactor through a filter to filter out the incident laser light at a rate synchronized with the rate of rotation of the agitator; 6) calculating a normalized dye concentration in each pixel of each image; 7) integrating the normalized concentration in each pixel over all images in time to calculate an average local fluid age of each pixel; 8) calculating a standard deviation and a mean of the local ages and a coefficient of variance; 9) iteratively repeating steps 1 through 8 for different agitators, wherein the calculated normalized dye concentration, calculated average local fluid age, calculated standard deviation and mean of the local ages, and calculated coefficient of variance become stored data; 10) comparing the stored data to determine the agitator which provides at least one of: i) a normalized dye concentration from 0.5 to 1.3; ii) a coefficient of variance from 0.01 to 0.1; and iii) a minimum standard deviation in the average age of the model reactor contents, and 11) selecting the agitator which provides the preferred values from step 8. 3. A method to determine a preferred feed flow rate to a continuous stirred tank reactor (CSTR) reactor comprising: 1) preparing a transparent model reactor comprising, an agitator, a number of alternate inlet ports, and at least one planar exterior surface, which model reactor will be used to generate data to be stored from subsequent steps of the method; 2) filling the model reactor with a test fluid having a viscosity chosen to produce the desired Reynolds number, which fluid contains a uniform concentration of a tracer dye which fluoresces under a known wavelength of incident light; 3) flowing six times the model reactor volume of test fluid without dye into and through the model reactor at a constant flow rate using a selected feed port and agitator running at a constant speed to provide a constant Reynolds number to introduce a step change in concentration of the tracer dye in the model reactor; 4) while the dye is being washed out of the model reactor and during mixing, subjecting the model reactor contents to a plane of laser light through the planar exterior surface of the model reactor, whose wavelength causes the dye to fluoresce at a different wavelength from that of the laser; 5) taking digital images of the fluorescent light from the model reactor through a filter to filter out the incident laser light at a rate synchronized with the rate of rotation of the agitator; 6) calculating a normalized dye concentration in each pixel of each image; 7) integrating the normalized concentration in each pixel over all images in time to calculate an average local fluid age of each pixel; 8) calculating a standard deviation and a mean of the local ages and a coefficient of variance; 9) iteratively repeating steps 1 through 8 for different feed flow rates to the model reactor, wherein the calculated normalized dye concentration, calculated average local fluid age, calculated standard deviation and mean of the local ages, and calculated coefficient of variance become stored data; 10) comparing the stored data to determine the model reactor feed rate which provides at least one of: i) a normalized dye concentration from 0.5 to 1.3; ii) a coefficient of variance from 0.01 to 0.1; and iii) a minimum standard deviation in the average age of the model reactor contents, and 11) selecting the model reactor feed rate which provides the preferred values from step 8. 4. A method to determine a preferred agitator speed for a continuous stirred tank reactor (CSTR) reactor comprising: 1) preparing a transparent model reactor comprising, an agitator, a number of alternate inlet ports, and at least one planar exterior surface, which model reactor will be used to generate data to be stored from subsequent steps of the method; 2) filling the model reactor with a test fluid having a viscosity chosen to produce the desired Reynolds number, which fluid contains a uniform concentration of a tracer dye which fluoresces under a known wavelength of incident light; 3) flowing six times the model reactor volume of test fluid without dye into