Patent Number: 
Section: claims

1. A method of modeling noble metal loading reactions for a noble metal deposition process throughout a water flow circuit of a nuclear reactor, comprising the steps of: dividing the primary water circuit into a plurality of separate regions each comprising a plurality of cells of equal flow residence time;  performing a mass balance evaluation for each individual cell;  determining noble metal concentrations and surface loadings in each cell using chemical kinetic equations based on local reaction rate constants for each cell;  sampling the reactor water at one or more selected locations throughout the water flow circuit to determine concentrations of noble metals at each sample location; and  updating one or more values used for local reaction rate constants based on sampled concentrations from said selected locations. 2. A method for modeling noble metal loading occurring within a water flow circuit for a nuclear reactor during a noble metal deposition process, comprising the steps performed by a computer of: a) dividing the water flow circuit into a plurality of separate regions each comprising a plurality of cells of equal flow residence time;  b) determining noble metal concentrations and surface loadings in each cell using chemical kinetic equations based on local reaction rate constants for each cell; and  c) updating one or more values used for local reaction rate constants based on sampled noble metal concentrations obtained from said selected locations within the water flow circuit. 3. A method of maintaining proper noble metal loading within a primary water flow circuit for a nuclear reactor for performing a noble metal deposition process, comprising the steps of: a) obtaining data representing the initial state of the reactor water chemistry and initial operating conditions of the reactor;  b) using a computer to model noble metal loading throughout the primary water flow circuit, wherein noble metal loading reactions are modeled by dividing the primary water circuit into a plurality of separate regions each comprising a plurality of cells of equal flow residence time and performing a mass balance evaluation for each individual cell;  c) sampling the reactor water at one or more selected locations throughout the water flow circuit and measuring concentrations of noble metals for each sample;  d) comparing measured concentrations of noble metals from each sample with concentration values produced by the computer modeling in step (b);  e) calibrating a computer model used in computing noble metal reactions by altering values of reaction rate constants used by the computer model until the model results agree with the samples; and  f) altering the operating conditions of the reactor if subsequent loading rates determined by the computer model are inconsistent with predetermined target goals. 4. The method as defined in  claim 3 , wherein modeling of noble metal loading is performed using a portable computer. claim 3 5. The method as defined in  claim 3 , wherein a computer modeling of the noble metal deposition also models reactor water chemistry, pH, and conductivity. claim 3 6. A method for controlling the amount of noble metal atoms deposited over time into an oxide layer present on a metal surface of an object in contact with a high temperature fluid containing a compound having said metal atoms, which metal atoms increase the corrosion resistance of said metal surface when present in the oxide film, said method comprising the steps of: a) using a computer to model noble metal loading in the fluid;  b) sampling the fluid at one or more selected times during deposition and measuring concentrations of noble metals at each sample time;  d) comparing measured concentrations of noble metals from at least one sample with concentration values computed by the computer model;  e) calibrating the computer model by altering values of reaction rate constants used by the computer model until the model results agree with the sampled concentrations; and  f) altering temperature conditions and/or noble metal concentrations in the fluid if subsequent loading rates determined by the computer model are inconsistent with predetermined deposition goals.