An apparatus includes a surge protection device, a current sensor configured to sense a current through the surge protection device, and a surge discriminator circuit coupled to the current sensor and configured to discriminate among a plurality of surge levels for the surge protective device responsive to the sensed current. The current sensor may include a current transformer configured to generate a secondary current responsive to the sensed current and the surge discriminator circuit may be configured to discriminate among a plurality of surge levels responsive to the generated secondary current.

A semiconductor device that can have both noise resistance and ESD resistance is provided.

The semiconductor device includes a first and a second digital circuits, a first and a second ground potential lines respectively provided corresponding to the first and the second digital circuits, a first and a second analog circuits, a third and a fourth ground potential lines respectively provided corresponding to the first and the second analog circuits, a first bidirectional diode group provided between the first and the second ground potential lines, a second bidirectional diode group provided between the third and the fourth ground potential lines, and a third bidirectional diode group provided between the first and the third ground potential lines. The number of stages of bidirectional diodes of the third bidirectional diode group is greater than that included in each of the first and the second bidirectional diode groups.

A modular distribution block for a high-current power system includes a ground module and one or more phase modules. The ground module includes a grounding clamp configured to electrically and mechanically connect to a DIN rail and to retain the distribution block in place with respect to the DIN rail. The phase module(s) include: a conductive splice block that connects a line current from a power supply to a powered device; and, a first surge protective device (SPD) terminal and a second SPD terminal configured to together receive and electrically connect to an SPD module, such connection forming a surge protection circuit within the distribution block, the first SPD terminal electrically connecting to the bus terminal and the second SPD terminal electrically connecting, to the splice block. A rigid bus bar electrically connects the ground module to the phase module(s).

The disclosed technology generally relates to electrical overstress protection devices, and more particularly to electrical overstress monitoring devices for detecting electrical overstress events in semiconductor devices. In one aspect, an electrical overstress monitor and/or protection device includes a two different conductive structures configured to electrically arc in response to an EOS event and a sensing circuit configured to detect a change in a physical property of the two conductive structures caused by the EOS event. The two conductive structures have facing surfaces that have different shapes.

An input overvoltage protection circuit is equipped with a first wiring and a second wiring which are connected to a protected circuit in order to supply a voltage thereto, a fuse inserted in series in the first wiring and which interrupts a current flowing through the first wiring when a current greater than or equal to a predetermined value flows therethrough, a silicon surge absorber, one end of which is connected between the protected circuit and the fuse in the first wiring, and the other end of which is connected to the second wiring, and a bidirectional two-terminal thyristor connected to the first wiring and to the second wiring at a location between the silicon surge absorber and the protected circuit.

The present invention relates to an electrostatic discharge protection device provided with an insulating laminate containing a first and a second insulating substrate stacked there, a first and a second discharge electrode disposed inside the insulating laminate, a first insulating layer having glass disposed on the side surfaces of the first and the second discharge electrodes, a second insulating layer having glass disposed on the main surfaces of the first and the second discharge electrodes, and an discharge inducing section disposed between the side surfaces of the first and the second discharge electrode, wherein, the distance between the side surfaces of the first and the second discharge electrodes was set as ΔG and the thickness of the second insulating layer was set as ΔZ which two adapt to inequations 3 μm≦ΔZ≦35 μm and ΔG≦40 μm.

An overvoltage protection circuit which can be applied to a motor controller is provided. The overvoltage protection circuit is coupled to an input terminal for receiving an input voltage. The overvoltage protection circuit comprises a switch circuit, a controller, and a comparing unit. When the input voltage is greater than a first voltage, a discharging mechanism is forced to start so as to suppress a voltage spike. When the input voltage is less than a second voltage, the discharging mechanism is closed so as to operate normally.

A surge protection device includes: a pair of terminal fittings to be connected to a pair of power supply terminals of a. field device together with a power supply cable; a circuit board on which a surge protection element is mounted, the surge protection element including two electrodes connected to the pair of terminal fittings and a ground electrode configured to cause a surge current to flow to a ground when a surge voltage is applied between the two electrodes; an earth wiring cable connected to the ground electrode; and a main body that houses the circuit board, the main body being configured such that the pair of terminal fittings and the earth wiring cable protrude from an inside of the main body to an outside.

The application relates to the technical field of sensors, in particular to a lightning proof sensor comprising a sensor housing, a signal generation assembly, a PIN needle and a shielding case. The sensor housing has a cavity; a signal generation assembly is disposed in the cavity and forms insulation contact with an inner wall of the sensor housing; a PIN needle is disposed on the connector on one end of the sensor, and electrically connected with the signal generation assembly; and the shielding case is installed between the signal generation assembly and the sensor housing and covers the signal generation assembly, and the shielding case forms insulation contact with the signal generation assembly and the sensor housing. The sensor provided by the application has better lightning proof performance, and can simultaneously detect two parameters comprising temperature and acceleration speed, so that it has better environmental adaptability.

An electronic equipment item for an electronic system, comprising a housing, a backplane board, at least one daughterboard and at least one lightning protection board housed in the housing. A connector is fixed to the backplane board and configured to be connected to the rest of the electronic system. For each daughterboard there is provided one lightning protection board. For each lightning protection board, a first port is arranged to connect the lightning protection board to the backplane board, and a second port is arranged to connect the daughterboard to the lightning protection board.