A system for limiting power consumption from an auxiliary power supply is provided with a controller configured to toggle a switching circuit in accordance with an output of a sensing module and a time threshold, to sequentially cause the auxiliary power supply to be disconnected from an output terminal when the time threshold is reached and connected to the output terminal when a fault condition in the system is identified.

A circuit protection system includes a plurality of circuit protection devices and a central controller. Each circuit protection device includes a protection switch for connecting or disconnecting a corresponding protected circuit, and a sensing module for sensing electrical parameter data. The central controller is in communication with each of the circuit protection devices, and is constructed to receive the electrical parameter data; determine whether a fault condition has occurred based on the electrical parameter data; and send a signal to open the protection switch for each protected circuit experiencing a fault condition.

Systems and methods to isolate faults and restore power are described herein. For example, an intelligent electronic device (IED) may receive a blocking signal indicating a fault is detected on a power line. The IED may obtain one or more current measurements of the power line. The IED may determine that a fault is not present on the power line at the IED based on the one or more current measurements. The IED may trip a first current interruption device of the IED The IED may send a close permissive signal to another IED indicating that the other IED is permitted to permitted to close an open current interruption device of the other IED to restore power to one or more loads.

A ground overcurrent control system includes ground circuit with a first section and a second section. The first section is electrically connected to a ground member of an electrical connector and the second section is electrically connected to a ground reference. A switch element is positioned between the first section of the ground circuit and the second section of the ground circuit. A controller is configured to determine the current within the ground circuit while current is passing through the switch element and, upon the current exceeding a current threshold, the switch element is modified to an open condition. Upon determining that the voltage between the first section of the ground circuit and the ground reference is less than a voltage threshold, a command is generated to modify the switch element back to a closed condition.

A system is provided to eliminate risks of electric damage in buildings from irregular, abnormal currents in electrical networks, devices, and ultimately the entire building, with automatic cutoff and restart of electrical fluid, restoring proper function once electric flow is normalized. It offers protection of building electrical installations against electrical surges through sensors, continuously monitoring input conditions. When harmful voltages or currents are detected, electric flow is cut off temporarily, and then restored when conditions go back to normal. Current design uses transient suppressors, contactors, a timer, and thermomagnetic switches (FIG. 1). This concept is targeted at residential, commercial, and industrial electrical installations. It solves the vulnerability to unexpected, external, devastating electrical surges. It can be used as stand-alone safety equipment, or integrated to conventional thermomagnetic breaker systems. Design can be modified depending on desired electric-security level and availability of current or new technology in electrical components.

The present disclosure provides a method and device for overvoltage protection. Specifically, the present disclosure provides an overvoltage protection device which provides a feedback loop for electronic components such as amplifiers and digital to analog converters which require feedback. The overvoltage protection device also includes overvoltage switches in both the signal and feedback channels, which may be opened by a fault detector in the event of an overvoltage. The device also includes an overvoltage feedback channel coupled between the signal and feedback channels, and which also includes a switch which may be closed in the event of an overvoltage event. As such, the overvoltage device provides a closed loop feedback channel during an overvoltage event.

A power restoration system for restoring power to feeder segments in response to a fault. The system includes a reclosing device having a switch and one or more sensors for measuring current and/or voltage on the feeder, where the reclosing device performs a pulse testing process to determine circuit fault conditions. The system also includes a plurality of switching devices electrically coupled along the feeder, where each switching device includes a section switch and one or more sensors for measuring current and/or voltage on the at least one feeder. In one embodiment, each switching device recognizes predetermined pulse codes having a sequence of pulses, where the reclosing device uses the pulse testing process to generate and selectively transmit defined pulse codes on the feeder that selectively cause the section switches to change states between an open state and a closed state depending on the code.

Systems and methods to isolate faults and restore power are described herein. For example, an intelligent electronic device (IED) may receive a blocking signal indicating a fault is detected on a power line. The IED may obtain one or more current measurements of the power line. The IED may determine that a fault is not present on the power line at the IED based on the one or more current measurements. The IED may trip a first current interruption device of the IED The IED may send a close permissive signal to another IED indicating that the other IED is permitted to permitted to close an open current interruption device of the other IED to restore power to one or more loads.

In accordance with example embodiments, an automated ground fault interrupter includes means for resetting itself following detection of a ground fault. In accordance with example embodiments, when a ground fault is detected, a relay switch opens and breaks the conducting path between an AC input and a plug for connecting devices for a set amount of time after which the relay switch is closed again, restoring the conducting path between the plug and the AC input. Following restoration of the conducting path, the relay switch is opened again if a ground fault is detected. In accordance with example embodiments, the automated ground fault interrupter automatically tests itself at predetermined intervals. In accordance with example embodiments, the ground fault interrupter is automatically reset following the automatic test.

The invention relates to a method for operating a motor vehicle (2) which has an electric high-voltage network (3) and an electric low-voltage network (4), wherein the high-voltage network (3) has at least one traction battery (5) and at least one electric drive machine (6), the low-voltage network (4) has a vehicle electrical system battery (9), and the high-voltage network (3) is monitored for an electrical short-circuit and, upon detection of a short-circuit, the traction battery (5) is disconnected from the high-voltage network (3). According to the invention, in order to check the plausibility of the detected short-circuit before the traction battery (5) is reconnected to the high-voltage network (3), a boost current (1.sub.HV) is applied to the high-voltage network (3) through the low-voltage network (4) by means of a DC/DC converter (11), and a boost voltage (U.sub.HV) measured in the high-voltage network (3) is compared with an expected boost voltage (U.sub.HV,soll).