An electromagnetic feedback actuator for an operating element includes an electromagnet, a magnet armature, and a metal body. The electromagnet includes a magnetic coil and a magnetic core. The magnet armature is moveable relative to the electromagnet. The operating element includes an actuating element (e.g., touch surface, sensor surface). The magnet armature is mechanically coupled to the operating element to provide a force pulse to the operating element in response to contact with, or pressure actuation on, an actuating element of the operating element. The electromagnet is arranged in the metal body. The metal body, in integral fashion, forms the magnet armature, a magnet yoke for the magnetic core of the electromagnet, and a holder for the electromagnet. An arrangement includes at least one such electromagnetic feedback actuator coupled to an operating element.

An electromagnetic feedback actuator for an operating element includes an electromagnet, a magnet armature, and a metal body. The electromagnet includes a magnetic coil and a magnetic core. The magnet armature is moveable relative to the electromagnet. The operating element includes an actuating element (e.g., touch surface, sensor surface). The magnet armature is mechanically coupled to the operating element to provide a force pulse to the operating element in response to contact with, or pressure actuation on, an actuating element of the operating element. The electromagnet is arranged in the metal body. The metal body, in integral fashion, forms the magnet armature, a magnet yoke for the magnetic core of the electromagnet, and a holder for the electromagnet. An arrangement includes at least one such electromagnetic feedback actuator coupled to an operating element.

A magnetic latching mechanism including a servo-motor configured to rotate an axle; a latching rotor attached to the axle and configured to rotate; and a pair of latching permanent magnets attached to the latching rotor. A north pole of a permanent magnet and a south pole of another permanent magnet of the pair are facing along a same direction.

There is provided a pole-piece for a torque motor, the pole-piece comprising a first section formed separate from a second section, wherein the first section and the second section are configured to abut each other to form one or more lines of abutment on an outer surface thereof, and each line of abutment follows an S- or Z-shape when the first section abuts the second section.

A torque motor for use in a servovalve wherein only two holes must be provided through each of the pole pieces in order to assemble the torque motor together. The torque motor comprises first and second opposing pole pieces, first and second permanent magnets positioned between the first and second pole pieces; an armature comprising a magnetic plate and a flapper, the magnetic plate being positioned between the first and second permanent magnets, the flapper being connected at one end to the magnetic plate; and further comprising: first and second fastening means each extending through the first pole piece, the armature and the second pole piece to thereby fasten the torque motor together.

A torque motor for use in a servovalve wherein only two holes must be provided through each of the pole pieces in order to assemble the torque motor together. The torque motor comprises first and second opposing pole pieces, first and second permanent magnets positioned between the first and second pole pieces; an armature comprising a magnetic plate and a flapper, the magnetic plate being positioned between the first and second permanent magnets, the flapper being connected at one end to the magnetic plate; and further comprising: first and second fastening means each extending through the first pole piece, the armature and the second pole piece to thereby fasten the torque motor together.

An electromagnetic actuator includes an electromagnetic coil, a yoke serving as a magnetic path of a magnetic flux of the electromagnetic coil, an armature configured to move in an axial direction while being attracted by the yoke by energization of the electromagnetic coil, and a housing that houses the armature. The armature and the housing are coupled to each other by an engagement structure in which protrusions provided on one of the members engage with engagement grooves formed in the other one of the members. At least a part of the engagement groove is inclined with respect to the axial direction. When the armature moves while being attracted by the yoke, the protrusions of the armature slide along the engagement grooves of the housing, and the armature turns relative to the housing along the inclination of the engagement grooves.

An electromagnetic actuator includes an electromagnetic coil, a yoke serving as a magnetic path of a magnetic flux of the electromagnetic coil, an armature configured to move in an axial direction while being attracted by the yoke by energization of the electromagnetic coil, and a housing that houses the armature. The armature and the housing are coupled to each other by an engagement structure in which protrusions provided on one of the members engage with engagement grooves formed in the other one of the members. At least a part of the engagement groove is inclined with respect to the axial direction. When the armature moves while being attracted by the yoke, the protrusions of the armature slide along the engagement grooves of the housing, and the armature turns relative to the housing along the inclination of the engagement grooves.

A valve includes an electrodynamic actuator which has a magnet arrangement for generating a magnetic field and a control element movable relative to the magnet arrangement. The control element includes an energizable coil which is arranged in the magnetic field and is firmly coupled to a coil carrier. The control element is movable between at least two defined positions. There are provided permanent-magnetically interacting holding force which retain the control element in at least one of the defined positions, even when the coil is currentless.

An electromagnetic actuator including an attractor to exert a magnetic attractive force in one side in a first direction, a frame, and a lever. The frame includes a frame body fixed to the attractor, and a support on an oblique-direction side relative to the attractor. The lever includes a fulcrum portion pivotally supported by the support, a first displaceable portion arranged on the other side in the second direction relative to the fulcrum portion and on the other side in the first direction relative to the attractor and magnetically attractable by the attractor to be displaced to the one side in the first direction, and a second displaceable portion arranged on the one side in the first direction relative to the fulcrum portion and on the one side in the second direction relative to the attractor and/or the frame and displaceable away from the attractor and/or the frame by the pivot of the lever.