A monolithic integrated proximity sensor device includes a semiconductor substrate with an active surface with at least one active or passive component or bond pad; an interconnection stack having a plurality of at least two metal layers; at least a first transmitter coil having a first spiral course with at least three turns formed in at least one or at least two metal layers and defining the first region having a first inner and outer periphery; at least a first receiver coil having a second spiral course with at least three turns formed in at least one or at least two metal layers and defining a second region having a second inner and outer periphery. At least one component or bond pad is located inside the first or second inner periphery.

An induction sensor assembly for a securing and locking unit of a telescoping jib having at least one signal transmitter configured for generating an electromagnetic stray field oriented towards its active switching surface, and at least one switching element provided for contactless cooperation with the signal transmitter. The signal transmitter and switching element are displaceable relative to each other in relation to an adjusting direction extending in parallel with a main plane. To provide a simple and cost-effective installation of the induction sensor assembly despite having high detection security, the active switching surface of the signal transmitter and the main plane are inclined with respect to each other. As such, the electromagnetic stray field of the signal transmitter is also advantageously inclined whereby a possible displacement between the signal transmitter and switching element cannot exert an influence on the precision of the position detection in relation to the adjusting direction.

A magnetic switch sensor is provided having a magnetic field sensing element configured to generate a magnetic field signal in response to a magnetic field indicative of a distance or angle between the magnetic field sensing element and a target, a first circuit coupled to receive the magnetic field signal and having an output to provide a comparison signal, and a debounce circuit coupled to receive the comparison signal and having an output to provide a debounced signal. The sensor can include a second circuit having an input coupled to receive the debounced signal and an output at which is provided a toggle signal that transitions between first and second levels every other time the magnetic field signal crosses a threshold level.

To improve toughness of a non-contact type safety door switch. A safety switch includes a metallic casing integrated as a first part of an enclosure, having an opening in a front side, a cover integrated as a front part of the enclosure, covering the opening, the cover having a surface as a front surface of the enclosure, a wireless means, a determination means, an output means, circuit substrates provided inside the metallic casing and the cover, on which the wireless means, the determination means and the output means are mounted, and attachment holes on a side surface of the metallic casing, the side surface being adjacent to the front surface of the enclosure for attaching the casing.

A switch is disclosed. The switch includes a body; and an actuator configured to provide a magnetic force to the body and induce an electrical switching of the body, wherein the body includes a housing with a first surface; and a plurality of hall sensors sequentially disposed adjacent to the first surface, wherein the actuator includes a case with a second surface; and a first magnetic body and a second magnetic body sequentially disposed adjacent to the second surface, wherein the first magnetic body includes a first polarity; and a second polarity opposite to the first magnetic body, wherein the second magnetic body includes a third polarity; and a fourth polarity opposite to the third magnetic body, wherein the first polarity, the second polarity, the third polarity, and the fourth polarity are sequentially disposed along the second surface.

To improve toughness of a non-contact type safety door switch. A safety switch includes a metallic casing integrated as a first part of an enclosure, having an opening in a front side, a cover integrated as a front part of the enclosure, covering the opening, the cover having a surface as a front surface of the enclosure, a wireless means, a determination means, an output means, circuit substrates provided inside the metallic casing and the cover, on which the wireless means, the determination means and the output means are mounted, and attachment holes on a side surface of the metallic casing, the side surface being adjacent to the front surface of the enclosure for attaching the casing.

An inductive sensor includes a core body, a coil wound on the core body, a cavity having a fixed volume within the core body, and an epoxy mixture filling a controlled portion of the fixed volume. The controlled portion of the fixed volume filled with the epoxy mixture controls an inductance of the sensor.

A sensor is provided with a cylindrical-shaped housing which has an opening formed at one end, an electronic component which is housed in the housing, a cylindrical-shaped clamp of which one end is inserted into the housing from the opening, and a sealing resin which seals the gap between the inner wall of the housing and the outer wall of the clamp. On the outer wall, the clamp has a rib which rises towards the inner wall of the housing. The rib includes an apex and a sloped surface which extends from the apex towards another end of the clamp and which intersects the outer wall of the clamp. The sealing resin, which exudes from between the inner wall of the housing and the apex and which is positioned on the sloped surface, has a recess resulting from surface tension.

A manufacturing process switch with a housing consisting of a first member and a second member. The first member is rotatable from a closed position to an open position. A proximity sensor is secured to the housing that detects the proximity of the first member to the second member and generates a signal when the first member is in the open position. An engagement device is secured to the housing for retaining the first member to the second member in the closed position. A cable attachment mechanism is attached to the first member of the housing and securable to a cable of a tool. The first member is rotatable from the closed position to the open position when a breakaway force is applied to the cable attachment mechanism. The manufacturing process is stopped when the first member is in the open position.

A method is provided for sensing proximity of a target. The method includes sensing inductance associated with a magnetic field, wherein the inductance is affected by the target when the target is proximate the magnetic field. The method further includes providing the sensed inductance for processing. The processing includes determining an inductance value from at least the sensed inductance and estimating a parameter of a gap between a location of sensing the inductance and the target as a function of the inductance value and application of a nonlinear model of a relationship between the gap and inductance,