A method for predicting corrosion rates of a material during service conditions is provided, the method having the steps of determining a first phase composition of the material; exposing the material to service conditions chemical environment; applying an electrical potential to the exposed material to represent the solution redox; identifying ranges of the applied potential that correspond to different corrosion behaviors of the material; quantifying current and surface electrical properties during corrosion; and determining a second phase composition of the material to identify corroded phases. Also provided is a method for determining radionuclide source terms, the method having the steps of supplying a multiphase metallic waste containing the radionuclides; immersing the waste in a solution representing repository chemistry conditions; and oxidizing the immersed waste for a period of time and at particular imposed voltages representing solution redox values to establish a steady current representing corrosion rate of the waste.

A cathodic protection system providing substantially complete coverage to individual steel-in-concrete units in a multi-unit structure. The system includes a power supply, an electronic circuit board, a header cable, anode wire in each unit connected to the header cable, an adhesive fiber mat in each unit, and a conductive coating in each unit.

A cathodic protection system providing substantially complete coverage to individual steel-in-concrete units in a multi-unit structure. The system includes a power supply, an electronic circuit board, a header cable, anode wire in each unit connected to the header cable, an adhesive fiber mat in each unit, and a conductive coating in each unit.

A cathodic protection system that is able to monitor the operational status of a plurality of test points and rectifiers. The cathodic protection system includes a plurality of test point monitors that are associated with test points and a plurality of rectifier controllers that are associated with the rectifiers located along a utility pipeline. The test point monitors are battery powered while the rectifier controllers may be utility line powered. Each of the test point monitors and rectifier controllers communicates with a base station utilizing a wireless communication technique. The base station communicates with a back end server that operates to accumulate data and visually present the data to an operator on a display associated with cathodic protection software application. The software application allows the operator to monitor the health of the system and address alerts generated by any of the test points or monitored rectifiers.

A cathodic protection system that is able to monitor the operational status of a plurality of test points and rectifiers. The cathodic protection system includes a plurality of test point monitors that are associated with test points and a plurality of rectifier controllers that are associated with the rectifiers located along a utility pipeline. The test point monitors are battery powered while the rectifier controllers may be utility line powered. Each of the test point monitors and rectifier controllers communicates with a base station utilizing a wireless communication technique. The base station communicates with a back end server that operates to accumulate data and visually present the data to an operator on a display associated with cathodic protection software application. The software application allows the operator to monitor the health of the system and address alerts generated by any of the test points or monitored rectifiers.

In a method for cathodically protecting and/or passivating a metal section in an ionically conductive material such as steel reinforcement in concrete or mortar, an impressed current or sacrificial anode communicates ionic current to the metal section and a storage component of electrical energy which can be a cell, battery or capacitor is provided as a component of the anode. The storage component can have replacement energy introduced by re-charging or replacing the component from an outside supply. Typically the cell or storage capacitor has an outer case which carries an anode material as an integral outer component. A mechanical clamp is provided to attach the assembly to a rebar. A current limiter is provided which prevents excess current draining the supply.

In a method for cathodically protecting and/or passivating a metal section in an ionically conductive material such as steel reinforcement in concrete or mortar, an impressed current or sacrificial anode communicates ionic current to the metal section and a storage component of electrical energy which can be a cell, battery or capacitor is provided as a component of the anode. The storage component can have replacement energy introduced by re-charging or replacing the component from an outside supply. Typically the cell or storage capacitor has an outer case which carries an anode material as an integral outer component. A mechanical clamp is provided to attach the assembly to a rebar. A current limiter is provided which prevents excess current draining the supply.

A system and methods of controlling a powered anode are disclosed. The method includes varying an electrical power input driving the powered anode through a range of values of a first electrical parameter, the range defined by an upper range limit and a lower range limit and measuring a current value of a second electrical parameter of the electrical power input during the varying. The method also includes determining a slope between the measured current values of the first and corresponding second electrical parameters and measured previous values of the first and second electrical parameters and comparing the determined slope to a predetermined slope threshold range and applying the current value of a first electrical parameter to the electrical power input when a discontinuity in the slope is determined.

A system and methods of controlling a powered anode are disclosed. The method includes varying an electrical power input driving the powered anode through a range of values of a first electrical parameter, the range defined by an upper range limit and a lower range limit and measuring a current value of a second electrical parameter of the electrical power input during the varying. The method also includes determining a slope between the measured current values of the first and corresponding second electrical parameters and measured previous values of the first and second electrical parameters and comparing the determined slope to a predetermined slope threshold range and applying the current value of a first electrical parameter to the electrical power input when a discontinuity in the slope is determined.

A cathodic protection system includes a vessel for containing a fluid or a mixture of fluids, a plurality of anodes positioned inside the vessel, an encapsulant encapsulating the plurality of anodes, the encapsulant being a wax repellant material that is sufficiently porous to allow ions to pass therethrough, and an impressed current source electrically connected to each of the anodes and the vessel. The impressed current source produces a continuous high current output, and the vessel acts as a cathode when current is applied from the impressed current source. The anodes are monitored and controlled from outside of the vessel using one or more adjustable resistors, which are installed in a junction box located either inside or outside the vessel. The resistors are configured to adjust the individual anode current output based upon a predetermined cathodic protection criteria.