Abstract: Systems and methods for magnetic shielding are described. A magnetic shield formed of a material having a high magnetic permeability may be degaussed using a toroidal degaussing coil. The toroidal degaussing coil may enclose at least a portion of the shield. Magnetic field gradients may be actively compensated using multiple magnetic field sensors and local compensation coils. Trapped fluxons may be removed by an application of Lorentz force wherein an electrical current is passed through a superconducting plane.

Abstract: A power-source protection circuit includes a power source including a first voltage rail and a second voltage rail, a pass switch connected across the first voltage rail and a third voltage rail, a control switch connected to the second voltage rail and a control terminal of the pass switch, such that the pass switch turns on in response to the control switch turning on and the pass switch turns off in response to the control switch turning off, and output terminals connected to the third voltage rail and the second voltage rail. The control switch is arranged to switch on when the power source is started and the control switch is arranged to switch off when the output terminals are short-circuited and to switch on when the short-circuit is removed.

Abstract: The present application relates to a static discharger and an aircraft including the static discharger. According to an aspect of the present application, a static discharger is provided which includes: a basement; and a discharger body adapted to be installed to the basement. The static discharger further includes a first fixing mechanism adapted to fix the discharger body to the basement. A pivoting mechanism is provided between the basement and the discharger body, the pivoting mechanism allowing the discharger body to pivot with respect to the basement so as to adjust an installation orientation of the discharger body with respect to the basement during an on-site-installation of the static discharger. According to the present application, for example, installation adaptation and universality of the static discharger can be improved.

Abstract: An electrostatic chuck device includes a base plate, an electrostatic chuck plate coupled to an upper surface of the base plate and including a mount region on which an attraction subject is mounted, an electrostatic electrode embedded in the chuck plate, a focus ring that is located on the upper surface of the base plate and covers an outer side surface and a portion of an upper surface of the chuck plate. A groove is located in the upper surface of the chuck plate at a portion that corresponds to a region between the focus ring and the mount region in a plan view. The groove is filled with a protective layer. The groove is located at a position separated from the electrostatic electrode in a plan view. The protective layer is formed from a material having a higher plasma resistance than a material forming the chuck plate.

Abstract: Provided is a current control apparatus including a first cooler that cools a switch element, a bus bar connected to the switch element, a core penetrated by the bus bar, a magneto-electric transducer, which is inserted into the core in order to detect a value of a current supplied to the switch element, a controller that controls the switch element, a case, and a cover, wherein the core includes an exposed disposal structure in which a part of the core is exposed to the exterior of the case as an exposed portion, and the current control apparatus further includes a divided cooling structure in which the exposed portion is cooled without being affected by the temperature of the first cooler that cools the switch element.

Abstract: The present invention is directed to an electrical wiring device including a housing assembly with a cover assembly, a back body member, and a plurality of line terminals, feed-through load terminals, and receptacle load terminals; a fault protection circuit disposed in the back body and substantially disposed on at least one printed circuit board, and being configured to provide a fault detection stimulus in response to detecting at least one type of predetermined fault condition, the fault detection stimulus decoupling a reset pin from a latching element, the reset pin being coupled to the latching element in response to a reset stimulus; and a circuit interrupter disposed inside the housing including a latch block assembly with an upper latch block and being moveable between a first state in response to the reset stimulus and a second state in response to the fault detection stimulus, wherein the reset pin is positioned through the upper latch block, and the upper latch block is configured to drive the cir

Abstract: Electrical apparatuses with connector overheating protection and methods for protecting electrical apparatuses from connector overheating during current sinking and current sourcing operations are presented. The electrical apparatus includes an electrical connector and a temperature sensor, which is in direct contact with a physical part of the electrical connector. The temperature sensor monitors a temperature of the electrical connector during current sinking and current sourcing operations. During current sinking, if the temperature sensor senses a predetermined level of overheating of the electrical connector, then the sourcing of current to the electrical apparatus is switched off. During current sourcing, if the temperature sensor senses a predetermined level of overheating of the electrical connector, then the sourcing of current to the sinking device is switched off.

Abstract: An overvoltage protection apparatus and method. The overvoltage protection apparatus includes: a determining unit, having an input end connected to an input end of the apparatus and an output end connected to an input end of a soft-start unit, and configured to determine whether an input voltage at the input end of the apparatus exceeds a preset protection voltage; and the soft-start unit, having an input end connected to the input end of the apparatus and an output end connected to an output end of the apparatus, where if the determining unit determines that the input voltage does not exceed the preset protection voltage and remains stable in a preset delay time, the soft-start unit delivers the input voltage to the output end of the apparatus; and otherwise, the soft-start unit does not deliver a voltage signal to the output end of the apparatus.

Abstract: A circuit assembly and method use a breakover device that changes states in response to a change in electric energy in a helper circuit that supplies current from a power source to a powered system. The helper circuit includes an inductive element connected with the powered system. The breakover device is in a non-conducting state prior to a discharge event from the powered system to prevent the current from the power source from being conducted through the resistive element. The breakover device changes to a conducting state responsive to the powered system discharging current into the helper circuit. The breakover device conducts the current that is discharged from the powered system through the resistive element to reduce the electric energy in the helper circuit from the current that is discharged.

Abstract: An ESD protection circuit having a discharging transistor and a body snatching circuit. The discharging transistor is electrically coupled between a first node and a second node. The gate and the body of the discharging transistor are electrically coupled together. The body snatching circuit receives the voltages at the first and second nodes and outputs either the voltage at the first node or the voltage at the second node based on which of these two voltages have a lower value. The output voltage of the body snatching circuit is provided to the body of the discharging transistor.

Abstract: The present invention provides an ESD protection circuit electrically connected between a high voltage power line and a low voltage power line, and the ESD protection circuit includes a bipolar junction transistor (BJT) and a trigger source. A collector of the BJT is electrically connected to the high voltage power line, and an emitter and a base of the BJT are electrically connected to the low voltage power line. The trigger source is electrically connected between the base of the BJT and the high voltage power line.

Abstract: An electrostatic holding device (100) for holding component (1) by electrostatic holding forces includes clamp carrier (10) which has electrode device (11) and is configured for receiving component (1), voltage source device (20) for provision of a source charge current for charging clamp carrier (10), source switching device (30) which is arranged for a switchable connection of voltage source device (20) with electrode device (11), and at least one charge storage device (40, 40A, 40B) which has storage capacitor (41, 41A, 41B) and is configured to receive a clamp discharge current and temporarily store electrical charges of clamp carrier (10) in storage capacitor (41, 41A, 41B) and provide a storage charge current for charging clamp carrier (10). Also described is a method for operating holding device (100) and transfer circuit (200) for transmitting charges from working capacitor (201) to storage capacitor (202).

Abstract: An emergency stop device including a control assembly which can be actuated in translation along a control axis between a released position and an actuated position, a locking element cooperating with the control assembly and able to assume a locking position to hold the control assembly in its actuated position, a read device configured to generate a command for authorising unlocking of the control assembly, an unlocking actuator configured to act on the locking device to release the control assembly from its actuated position, an actuating element which can be actuated in movement to generate a mechanical energy, and an energy generator configured to convert the mechanical energy supplied by a movement of the actuating element into an electrical energy intended to power the read device.

Abstract: A transient response circuit provides faster transient response time of an electronic device so that less overshoot or undershoot of an output signal of the electronic device occurs when a large load and/or line transient signal is present at an input and/or output terminal of the electronic device. The transient response circuit has a transient detection circuit and an assist circuit. The transient detection circuit monitors a feedback signal applied to an input terminal of the control stage, and generates transient detection signals indicating that detection of a large load and/or line transient signal has occurred. The assist circuit communicates receives the transient detection signal and charges or discharges a loop filter capacitor of the control stage for causing the control stage to regulate the output signal to decrease overshoot or undershoot upon receipt of the transient detection signal.

Abstract: Embodiments are directed to a transient protection circuit configured for use in a SSPC having a plurality of power channels. The transient protection circuit includes a shared transient voltage suppressor, and a shared protection line communicatively coupled to the shared transient voltage suppressor. The shared protection line is configured to be communicatively coupled to and shared by the plurality of power channels. When the shared protection line is communicatively coupled to and shared by the plurality of power channels, energy above a threshold on any one of the plurality of power channels is dissipated through the shared protection line and the shared transient voltage suppressor.

Abstract: An electrostatic chuck comprises a ceramic body having a top and a bottom, one or more heating elements disposed in the ceramic body, and one or more electrodes disposed in the ceramic body. The electrostatic chuck further comprises a plurality of objects bonded to the bottom of the ceramic body by a metal bond, wherein collectively the plurality of objects comprise a plurality of features distributed over the bottom of the ceramic body at a plurality of different distances from a center of a circle defined by the bottom of the ceramic body, and wherein a feature of the plurality of features accommodates a fastener.

Abstract: A solenoid device includes two electromagnetic coils, two stationary cores, two plungers and a yoke that surrounds the two electromagnetic coils. When a first electromagnetic coil is energized, magnetic flux flows through a first magnetic circuit that includes the first stationary core. When the two electromagnetic coils are energized, magnetic flux of the first electromagnetic coil flows through the first magnetic circuit, and magnetic flux of the second electromagnetic coil flows through a second magnetic circuit that includes a second stationary core. When energization of the first electromagnetic coil is stopped while maintaining energization of the second electromagnetic coil, the magnetic flux of the second electromagnetic coil continues to flow through the second magnetic circuit and a third magnetic circuit that includes the two stationary cores. A magnetism limiting portion is disposed in a portion of the second magnetic circuit that does not overlap the third magnetic circuit.

Abstract: An electric power delivery system may be protected upon occurrence of a fault condition by the systems and methods disclosed herein by detecting the fault condition and signaling a protective action before the overcurrent condition reaches the protective equipment. The protective action may be an opening of a circuit breaker or engagement of a fault current limiter. The overcurrent condition may be a non-steady-state condition. The fault may be detected using traveling wave or incremental quantity techniques.

Abstract: Methods, systems, and apparatus for circuit breakers with integrated safety, control, monitoring, and protection features. In one aspect, a circuit breaker includes, an input and an output, a switch coupled between the input and the output, a sensor configured to measure the current flowing from the input to the output, and a control system coupled to the sensor and the switch, wherein the control system is configured to perform operations including comparing a rate of change of the current measured by the sensor to a threshold rate of change of current, determining that the rate of change of the current measured by the sensor exceeds the threshold rate of change of current for at least a predetermined period of time, and as a consequence of determining that the rate of change of current exceeds the threshold rate of change, opening the switch, thereby disconnecting the input from the output.

Abstract: An ultra-low capacitance ESD protection device with an ultra-fast response time and a low turn-on voltage, and a high holding current. The device may include: a heavily-doped p-type substrate; a lightly-doped n-type epitaxial layer with a heavily-doped n-type buried layer; and a semiconductor-controlled rectifier (SCR) structure within the epitaxial layer. The SCR structure includes, between a ground terminal and a pad terminal: a shallow P+ region within a moderately-doped n-type well to form an emitter-base junction of a trigger transistor; a shallow N+ region within a moderately-doped p-type well to form an emitter-base junction of a latching transistor, and a PN junction coupled to either of the shallow regions as a forward-biased series diode. To reduce capacitance, the n-type and p-type wells are separated by a lightly-doped portion of the epitaxial layer having a small lateral dimension for enhanced switching speed.