Contactor for an electric vehicle, with at least one fixed contact element and a movable contact element which, in a disconnection position, is spaced from the at least one fixed contact element in order to interrupt an electrical connection of the two contact elements, and which, in a closed position, is in electrically conductive contact with the at least one fixed contact element in order to create an electrical connection of the two contact elements, and with a switch actuator, associated with the movable contact element, which is designed to move the movable contact element into the disconnection position or into the closed position.

[Object] To provide a solenoid with which, when attaching an iron core to a yoke, the iron core can be easily and firmly attached using an inexpensive, small, and general-purpose hand tool without crimping the iron core using a large press machine.

[Solution] A solenoid of the present invention is configured to include a yoke having a U-shaped cross section, a bobbin having an electromagnetic coil disposed inside the yoke, a fixed iron core disposed inside the bobbin, and a flapper attached to the yoke to be able to swing freely. The fixed iron core and a bottom surface of the yoke are integrally coupled by threaded fitting. Thus, the fixed iron core can be easily attached to the bottom surface of the yoke using a general-purpose, inexpensive, and small hand tool (a hand drill or an electric driver) without requiring a large workplace for crimping the fixed iron core as in the related art.

An electromechanical transducer includes: a structural portion configured such that two pairs of magnets magnetized in opposite directions, a yoke configured to guide magnetic fluxes from the magnets, and a coil configured to receive a supplied electric signal are located integrally; an armature having an inner portion penetrating an internal space of the structural portion and outer portions protruding from the inner portion toward both sides in a first direction, forming, together with the structural portion, a magnetic circuit through regions of the inner portion facing the two pairs of magnets, and configured to displace in a second direction perpendicular to the first direction by magnetic force of the magnetic circuit; and a pair of elastic members each located on both sides of the armature in the second direction, and configured to provide, to the armature, restoring force according to relative displacement of the armature corresponding to the structural portion.

An electromechanical transducer includes: a structural portion configured such that two pairs of magnets magnetized in opposite directions, a yoke configured to guide magnetic fluxes from the magnets, and a coil configured to receive a supplied electric signal are located integrally; an armature having an inner portion penetrating an internal space of the structural portion and outer portions protruding from the inner portion toward both sides in a first direction, forming, together with the structural portion, a magnetic circuit through regions of the inner portion facing the two pairs of magnets, and configured to displace in a second direction perpendicular to the first direction by magnetic force of the magnetic circuit; and a pair of elastic members each located on both sides of the armature in the second direction, and configured to provide, to the armature, restoring force according to relative displacement of the armature corresponding to the structural portion.

An actuator device has at least one actuator element which at least in part is composed of a magnetically shape-shiftable material, and has a magnet unit which comprises at least one first magnetic element that is implemented as a coil unit and at least one second magnetic element that is implemented as a permanent magnet,

at least the first magnetic element and the second magnetic element are configured for interacting in at least one operating state so as to cause a local deformation of the actuator element in a partial region of the actuator element.

An actuator device has at least one actuator element which at least in part is composed of a magnetically shape-shiftable material, and has a magnet unit which comprises at least one first magnetic element that is implemented as a coil unit and at least one second magnetic element that is implemented as a permanent magnet,

at least the first magnetic element and the second magnetic element are configured for interacting in at least one operating state so as to cause a local deformation of the actuator element in a partial region of the actuator element.

An electromagnetic actuator for use in locking mechanisms comprises a housing, a plurality of coils and an armature which is linearly moveable relative to the housing between two end-of-travel positions by selectively energising the coils of the actuator. The actuator includes a fail-safe mechanism which is operable to urge the armature towards one of the two end-of-travel positions.

An electric switch is provided. The electric switch comprises a contact system, an actuation element, an engaging latch, and an actuator. The actuation element moves between an initial position and an actuation position to switch and changeover the contact system. The actuation element is located in a direction of the initial position by a force of a return spring. The engaging latch locks the actuation element in the initial position or the actuation position. A non-manual unlocking between the actuation element and the engaging latch is performed by the actuator.

An electric switch is provided. The electric switch comprises a contact system, an actuation element, an engaging latch, and an actuator. The actuation element moves between an initial position and an actuation position to switch and changeover the contact system. The actuation element is located in a direction of the initial position by a force of a return spring. The engaging latch locks the actuation element in the initial position or the actuation position. A non-manual unlocking between the actuation element and the engaging latch is performed by the actuator.

The present invention provides an actuator, a remote triggering apparatus, a governor, and an elevator. The actuator includes: a mandrel, the mandrel having a proximal end and a distal end, and the mandrel being driven to move from a contraction position toward an actuation position; a mandrel sleeve, the mandrel sleeve being sleeved on the distal end of the mandrel; and a shell, the shell defining a channel, wherein the actuator further includes at least one sliding member, and when the mandrel moves from the contraction position toward the actuation position, the at least one sliding member is located at a first radial position where the mandrel is joined to the mandrel sleeve, such that the mandrel sleeve can move along the channel together with the mandrel; and wherein at the actuation position, the at least one sliding member moves outward radially to a second radial position where the mandrel sleeve is joined to the shell, thus locking the mandrel sleeve.