A computing device of an information handling system includes a connector that receives a component, the connector including a contact that forms a physical connection, with the component, that supports an electrical connection between the connector and the component, the contact includes an interface surface, disposed in a high corrosion risk area of the connector, that forms the physical connection with the component while the component is disposed in the connector. The computing device also includes a corrosion management component that: reduces a rate of corrosion of the contact in the high corrosion risk area of the connector, and increases a second rate of corrosion in a low corrosion risk area of the connector.

A cathodic protection (CP) interruption system includes a metallic structure and a plurality of passive CP units embedded in an electrolytic medium, a plurality of test units electrically coupled with the structure and each of the CP units, and a low-power consumption component arrangement. The arrangement includes a real-time clock (RTC) and a GPS receiver coupled with each test unit for receiving GPS time from a GPS satellite. A controller is communicatively coupled with each RTC and GPS receiver for activating the GPS receiver once the RTC reaches a predetermined time to synchronize a RTC time of each RTC with GPS time. Interruption modules are coupled in electrical and data communication with the controller. The controller selectively changes an activation state of each interruption module once the RTC time reaches a predetermined activation state change time to selectively electrically couple or decouple each CP unit from the structure.

A cathodic protection (CP) interruption system includes a metallic structure and a plurality of passive CP units embedded in an electrolytic medium, a plurality of test units electrically coupled with the structure and each of the CP units, and a low-power consumption component arrangement. The arrangement includes a real-time clock (RTC) and a GPS receiver coupled with each test unit for receiving GPS time from a GPS satellite. A controller is communicatively coupled with each RTC and GPS receiver for activating the GPS receiver once the RTC reaches a predetermined time to synchronize a RTC time of each RTC with GPS time. Interruption modules are coupled in electrical and data communication with the controller. The controller selectively changes an activation state of each interruption module once the RTC time reaches a predetermined activation state change time to selectively electrically couple or decouple each CP unit from the structure.

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. A current limiter is provided which prevents excess current draining the supply. This can be a semi-conductive device such as a transistor or diode is connected in the path from the anode to the metal section to limit the cathodic protection current to a value of the order of 1 milliamp. When a diode or similar device is used the current can be limited to the reverse leakage current of the diode.

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. A current limiter is provided which prevents excess current draining the supply. This can be a semi-conductive device such as a transistor or diode is connected in the path from the anode to the metal section to limit the cathodic protection current to a value of the order of 1 milliamp. When a diode or similar device is used the current can be limited to the reverse leakage current of the diode.

A cathodic protection (CP) interruption system includes a metallic structure and a plurality of passive CP units embedded in an electrolytic medium, a plurality of test units electrically coupled with the structure and each of the CP units, and a low-power consumption component arrangement. The arrangement includes a real-time clock (RTC) and a GPS receiver coupled with each test unit for receiving GPS time from a GPS satellite. A controller is communicatively coupled with each RTC and GPS receiver for activating the GPS receiver once the RTC reaches a predetermined time to synchronize a RTC time of each RTC with GPS time. Interruption modules are coupled in electrical and data communication with the controller. The controller selectively changes an activation state of each interruption module once the RTC time reaches a predetermined activation state change time to selectively electrically couple or decouple each CP unit from the structure.

A cathodic protection (CP) interruption system includes a metallic structure and a plurality of passive CP units embedded in an electrolytic medium, a plurality of test units electrically coupled with the structure and each of the CP units, and a low-power consumption component arrangement. The arrangement includes a real-time clock (RTC) and a GPS receiver coupled with each test unit for receiving GPS time from a GPS satellite. A controller is communicatively coupled with each RTC and GPS receiver for activating the GPS receiver once the RTC reaches a predetermined time to synchronize a RTC time of each RTC with GPS time. Interruption modules are coupled in electrical and data communication with the controller. The controller selectively changes an activation state of each interruption module once the RTC time reaches a predetermined activation state change time to selectively electrically couple or decouple each CP unit from the structure.

A computer-implemented method of training a classification model includes the steps of obtaining, by at least one computer, a plurality of historical resistance trends from a plurality of installed rectifier sites and rectifier site metadata for each installed rectifier site of the plurality of installed rectifier sites; labelling each historical resistance trend of the plurality of historical resistance trends as one of a plurality of historic resistance trend classifications; and, inputting into a machine learning algorithm the historical resistance trends and the rectifier site metadata of the plurality of installed rectifier sites to train the classification model to output a predicted resistance trend classification in response to rectifier site metadata input into the model.

This application discloses magnetically coupled integrated probes and probe systems, attachable to the robotic arms of a remotely operated vehicle to perform both cathodic protection (CP) voltage measurements and ultrasonic testing (UT) thickness measurements at an underwater surface. The integrated probe system can include a spring for coupling to an ROV end effector. An ultrasonic probe is disposed within and extends from the sleeve housing. A magnetic carrier, flux concentrator, and gimbal surround a portion of the ultrasonic probe, and one or more electrically conductive legs extend from the front surface of the gimbal to function as a CP probe. The legs are arranged about the ultrasonic probe, which has a flexible membrane exposed at the front surface of the gimbal, such that during inspection, at least one leg contacts the surface and the ultrasonic probe is sufficiently proximate to provide substantially simultaneous CP and UT measurements.

A method and apparatus for using cathodic currents from individual electrodes of a multielectrode sensor to indicate how safely a pipe in soil or a metal structure in an electrolyte is cathodically protected. This method uses a simple parameter derived from the multielectrode sensor, called cathodic protection effectiveness margin or CPEM, to indicate and control, the cathodic protection (CP) system so that the CP operates within the optimal range. This method is solely based on the measurements of currents and eliminates the reference electrode that has been one of the most important components in the present CP practice.