Method for determination of system parameters for reducing crude unit corrosion

The invention claimed is: 1. A method of detecting a first property and a second property of a sample that is predominantly liquid, the method comprising the steps of: detecting the first property, wherein detecting the first property comprises the steps of: adding at least one chemical reagent to a first portion of the sample, the at least one chemical reagent capable of inducing an optical effect when added to the first portion of the sample that is directly related to the first property, determining the optical effect related to the first property, wherein determining includes one or both of measuring and calculating, and deducing the value of the first property by comparing the determined optical effect related to the first property to predetermined values associated with the first property, wherein the relationship between the determined optical effect related to the first property and the first property is independent of a volume of the first portion of the sample to which the at least one chemical reagent is added and independent of a volume of the at least one chemical reagent added to the first portion of the sample; and detecting the second property, wherein detecting the second property comprises the steps of: removing sulfoxy compounds from a second portion of the sample by adding to the second portion of the sample a cleansing composition, the cleansing composition comprising water, 2-10% peracetic acid, and 10-35% hydrogen peroxide, the peracetic acid being in equilibrium with the hydrogen peroxide; adding at least one chemical reagent to the second portion of the sample, the at least one chemical reagent capable of inducing an optical effect when added to the second portion of the sample that is directly related to the second property, determining the optical effect related to the second property, wherein determining includes one or both of measuring and calculating, and deducing the value of the second property by comparing the determined optical effect related to the second property to predetermined values associated with the second property, wherein the cleansing composition has no measured impact on the determined optical effect related to the second property other than preventing reactions between the sulfoxy compounds and the at least one chemical reagent. 2. The method of claim 1 wherein the first property is one item selected from the list consisting of: pH, iron concentration, and any combination thereof, and wherein the second property is chloride concentration. 3. The method of claim 1 wherein the determined optical effect related to the first property is a colorimetric effect, or a fluorescent effect, and wherein the determined optical effect related to the second property is a turbidity effect. 4. The method of claim 1 wherein the optical effect related to the first property is further determined by the at least one chemical reagent being at least two fluorescent dyes, one of the dyes' fluorescence at a first wavelength is affected by the value of the first property and one of the other dyes' fluorescence at a second wavelength is unaffected by the value of the first property, the method further comprising the steps of determining the ratio of the fluorescence intensity of the first and second wavelengths in the first portion of the sample, comparing that ratio to the ratio of the fluorescence of the first and second wavelengths in a control having a known value of the first property, determining a proportional change in the two ratios, and correlating the proportional change in the two ratios to the value of the first property. 5. The method of claim 1 wherein the optical effect related to the first property is further determined by the absorbance and fluorescence of at least one of the added at least one chemical reagent, where the absorbance is unaffected by the value of the first property and the fluorescence is affected by the value of the first property, by comparing the ratio of the fluorescence to absorbance to a control having a known value of the first property, determining a proportional change in the two ratios, and correlating the proportional change in the two ratios to the first property. 6. The method of claim 1 wherein at least one of the added at least one chemical reagent forms a complex with a compound that causes the first property, the absorbance of the complex at a pre-determined wavelength is directly related to the amount of that compound present and not to the amount of the at least of the added at least one chemical reagent, and correction for color and turbidity of the first portion of the sample is made by reading at a wavelength where the complex does not absorb. 7. The method of claim 1 wherein at least one of the first portion of the sample and the second portion of the sample is positioned within an apparatus, the apparatus comprises at least one reagent source constructed and arranged to feed the at least one chemical reagent into a chamber where it is mixed with the first portion of the sample or the second portion of the sample, and the first portion of the sample or the second portion of the sample containing the at least one chemical reagent is moved past an optical sensor that detects the optical effect. 8. The method of claim 7 further comprising emitting light from a light source. 9. The method of claim 7 further comprising emitting light from a light source positioned in line or perpendicular to the optical sensor. 10. The method of claim 9 further comprising detecting an optical property related to the first property or the second property of the sample using at least two light sources and corresponding optical sensors in line with the light sources, each of the two light sources and corresponding optical sensors detecting the optical property of the same volume of sample in the same region of the flow path, and the in line path between the light sources and optical sensors being substantially perpendicular to the flow path of the sample. 11. The method in claim 10 further comprising turning on all the light sources and taking all sensor readings simultaneously. 12. The method of claim 7 further comprising passing a sample through a boron doped diamond (BDD) cell before the at least one chemical reagent is added, the BDD cell is constructed and arranged to oxidize sulfoxy compounds. 13. The method of claim 7 further comprising flowing at least one of the first portion of the sample and the second portion of the sample through a vertically angled sensor flow path, and wherein detected light passing to the optical sensor passes horizontally through the first portion of the sample or the second portion of the sample. 14. The method of claim 7 further comprising facilitating the migration of gas bubbles away from the sensor via a tube, wherein the tube is positioned downstream from the sensor, at least a portion of the tube is higher than the sensor and is horizontally angled, and the tube is in one shape selected from the list consisting of: inverted U -shaped, bent, and curved. 15. The method of claim 7 further comprising sparging undesired materials away from the sample via a gas source upstream from the sensor, and adding a pre-sparge material to the sample prior to its sparging, the pre-sparge material being one item selected from the list consisting of: acid, hydrogen peroxide, and any combination thereof, the pre-sparge material increasing the rate of expulsion of undesired materials from the sample. 16. The method of claim 7 in which the apparatus is interfaced with a control system governing at least some of the