A switch includes a fixed member, a sliding member and a processor, and the fixed member includes a sensor module. The sliding member is spaced apart from the fixed member and can be movable along a preset direction relative to the fixed member. The sliding member includes a magnetic head, and the magnetic head at least partially coincides with a projection of the sensor module, so that the sensor module can determine a position of the sliding member relative to the fixed member. The processor is electrically connected to the sensor module, and the processor enables the switch to be in a corresponding operating mode according to information of the position of the sliding member relative to the fixed member. An electronic device includes the switch.

An interrupter system includes a first coil and an interrupter electrically connected to the first coil. The interrupter includes: a first terminal; a second terminal electrically connected to the first terminal; a third terminal electrically separated from the first terminal and the second terminal; a heat generating element electrically connected to the third terminal; and an explosive configured to be ignited by the heat generating element to produce a gas for interrupting an electrical connection between the first terminal and the second terminal. The first coil is electrically connected to the heat generating element via the third terminal. Moreover, the first coil is configured to, when an abnormal current flows between the first terminal and the second terminal, generate an electric power for igniting the explosive from the abnormal current.

High voltage micro-electromechanical systems (MEMS) switches are described. A MEMS teeter-totter switch connected between two terminals of a circuit breaker can include a beam coupled to an anchor on a substrate and two control electrodes, disposed on a surface of the substrate. An electrical overstress device connected between the two terminals in parallel with the MEMS teeter-totter switch may protect the MEMS teeter-totter switch when a high voltage transient signal is applied across the teeter-totter switch.

High voltage micro-electromechanical systems (MEMS) switches are described. A MEMS teeter-totter switch connected between two terminals of a circuit breaker can include a beam coupled to an anchor on a substrate and two control electrodes, disposed on a surface of the substrate. A protective switch connected between the two terminals in parallel with the MEMS teeter-totter switch may turn on during transition of the MEMS teeter-totter switch between ON and OFF states to protect the MEMS teeter-totter switch from large currents and voltages that may flow or develop across the MEMS teeter-totter switch when the voltage between two terminals is large.

High voltage micro-electromechanical systems (MEMS) switches are described. A MEMS teeter-totter switch can include a beam coupled to an anchor on a substrate and two control electrodes, disposed on a surface of the substrate. A control circuit may include an optical isolator that provides an isolated activation voltage to a voltage supply and control circuit. The voltage supply and control circuit uses the isolated activation voltage to supply a control voltage to one of the control electrodes with respect to a first reference voltage, causing the beam to provide an input voltage received from an input terminal to a contact electrode of the MEMS teeter-totter switch electrically connected to an output terminal. The input voltage is applied on the beam with respect to a second reference voltage different from the first reference voltage.

Circuit breakers based on micro-electromechanical systems (MEMS) switches are described. A high voltage MEMS teeter-totter switch can include a beam coupled to an anchor on a substrate and two control electrodes, disposed on a surface of the substrate. A control voltage applied on one of the control electrodes with respect to a first reference voltage puts one of the two ends of the beam in electric contact with one of two contact electrodes of the MEMS teeter-totter switch to electrical connected two terminals of a circuit breaker. The input voltage is applied on the beam with respect to a second reference voltage different from the first reference voltage. A MEMS teeter-totter switch network comprises a plurality of MEMS teeter-totter switches configured to switch high voltage and high current between the two terminals of the circuit breaker.

An interrupter system includes a first coil and an interrupter electrically connected to the first coil. The interrupter includes: a first terminal; a second terminal electrically connected to the first terminal; a third terminal electrically separated from the first terminal and the second terminal; a heat generating element electrically connected to the third terminal; and an explosive configured to be ignited by the heat generating element to produce a gas for interrupting an electrical connection between the first terminal and the second terminal. The first coil is electrically connected to the heat generating element via the third terminal. Moreover, the first coil is configured to, when an abnormal current flows between the first terminal and the second terminal, generate an electric power for igniting the explosive from the abnormal current.

A system for remotely operating a control panel reset switch for electrical equipment includes a remote control device, and a portable apparatus in communication with the remote control device. The portable apparatus includes a housing configured to be removably attached to the control panel and an electromagnetic actuator attached to the housing. The electromagnetic actuator includes a solenoid with a plunger. A rod is attached to the plunger and is movable through an opening in the housing from a retracted position to an extended position when the solenoid is energized. The rod contacts and operates the reset switch when in the extended position. The portable apparatus includes a camera that acquires images of the rod and reset switch during operation. The remote control device includes a switch for operating the electromagnetic actuator and at least one display configured to display operational messages and images from the camera.