In an armature, a busbar unit includes at least first-, second-, and third-phase busbars electrically connected to respective first-, second-, and third-phase armature windings. The first-phase busbar serves as a lowermost busbar in the axial direction, the second-phase busbar serves as an intermediate busbar stacked over the lowermost busbar in the axial direction, and the third-phase busbar serves as an uppermost busbar stacked over the intermediate busbar in the axial direction. A resin member of the busbar unit covers the lowermost busbar, intermediate busbar, and uppermost busbar stacked in the axial direction, so that the lowermost busbar, intermediate busbar, and uppermost busbar are integrated to constitute a busbar stack. A protrusion member is mounted to the intermediate busbar and protruding radially outward from the intermediate busbar. At least part of the protrusion member is located to be nonoverlapped with the uppermost busbar and the lowermost busbar.

In an armature, a busbar unit includes at least first-, second-, and third-phase busbars electrically connected to respective first-, second-, and third-phase armature windings. The first-phase busbar serves as a lowermost busbar in the axial direction, the second-phase busbar serves as an intermediate busbar stacked over the lowermost busbar in the axial direction, and the third-phase busbar serves as an uppermost busbar stacked over the intermediate busbar in the axial direction. A resin member of the busbar unit covers the lowermost busbar, intermediate busbar, and uppermost busbar stacked in the axial direction, so that the lowermost busbar, intermediate busbar, and uppermost busbar are integrated to constitute a busbar stack. A protrusion member is mounted to the intermediate busbar and protruding radially outward from the intermediate busbar. At least part of the protrusion member is located to be nonoverlapped with the uppermost busbar and the lowermost busbar.

Magnets are configured to generate absorption force for holding a movable member at each of first and second positions. A power generator includes a mover configured to move in conjunction with the movable member. The power generator is configured to convert kinetic energy of the mover into electrical energy. When an operator moves in a direction in which a first pressing part approaches a second holding part while the movable member is at the first position, a spring member is compressed by the first pressing part and the second holding part. The spring member then generates restoring force for moving the movable member to the second position. When the operator moves in a direction in which a second pressing part approaches a first holding part while the movable member is at the second position, the spring member is compressed by the second pressing part and the first holding part. The spring member then generates restoring force for moving the movable member to the first position.

The present invention provides a vibration generator capable of accurately adapting to fine vibration. The vibration generator has a stationary permanent magnet, a yoke for the permanent magnet, a coil fixed to the yoke, four springs provided to the yoke, and a movable piece supported with the yoke through the four springs. The end portions of the movable piece are arranged between the respective two pairs of the projections with first gaps. The central portion of the movable piece is arranged in the through-hole with the second gaps, the second gaps having a size to allow oscillation, which is regulated by the first gaps, of the central portion of the movable piece.

The present invention provides a vibration generator capable of accurately adapting to fine vibration. The vibration generator has a stationary permanent magnet, a yoke for the permanent magnet, a coil fixed to the yoke, four springs provided to the yoke, and a movable piece supported with the yoke through the four springs. The end portions of the movable piece are arranged between the respective two pairs of the projections with first gaps. The central portion of the movable piece is arranged in the through-hole with the second gaps, the second gaps having a size to allow oscillation, which is regulated by the first gaps, of the central portion of the movable piece.

An apparatus for self-generating power and a wireless switch applying same are provided. The apparatus includes a coil assembly and a permanent magnet assembly. In an initial state, left and right ends of a soft magnetic plate come into contact with a first permanent magnet and a second upper soft magnetic plate respectively to form a first closed magnetic circuit, when the soft magnetic plate is rotated relative to the permanent magnet assembly, the left and the ends of the soft magnetic plate come into contact with a first upper soft magnetic plate and a second permanent magnet respectively to form a second closed magnetic circuit, and a direction of a magnetic line of force passing through the soft magnetic plate in the first closed magnetic circuit is opposite to that of a magnetic line of force passing through the soft magnetic plate in the second closed magnetic circuit.

An apparatus for self-generating power and a wireless switch applying same are provided. The apparatus includes a coil assembly and a permanent magnet assembly. In an initial state, left and right ends of a soft magnetic plate come into contact with a first permanent magnet and a second upper soft magnetic plate respectively to form a first closed magnetic circuit, when the soft magnetic plate is rotated relative to the permanent magnet assembly, the left and the ends of the soft magnetic plate come into contact with a first upper soft magnetic plate and a second permanent magnet respectively to form a second closed magnetic circuit, and a direction of a magnetic line of force passing through the soft magnetic plate in the first closed magnetic circuit is opposite to that of a magnetic line of force passing through the soft magnetic plate in the second closed magnetic circuit.

An apparatus for self-generating power with two magnets at two ends and a wireless switch using same are provides, and which belong to the field for self-generating power. The apparatus for self-generating power with two magnets at two ends of the present disclosure includes a coil assembly and a permanent magnet assembly. The permanent magnet assembly includes a left permanent magnet, a right permanent magnet and a soft magnetic frame, wherein the coil assembly includes a coil and a soft magnetic plate, and the soft magnetic plate is arranged between the left permanent magnet and the right permanent magnet in an up-down rotation manner. In an initial state, a closed magnetic circuit is defined by a left end and a right end of the soft magnetic plate and the soft magnetic frame, and when the soft magnetic plate rotates relative to the permanent magnet assembly, a closed magnetic circuit with magnetic lines of force opposite in direction is defined by the left end and the right end of the soft magnetic plate and the soft magnetic frame. The wireless switch of the present disclosure includes a radio frequency control board, a switch body used for controlling an electric device, and the apparatus for self-generating power, wherein the coil of the apparatus for self-generating power is electrically connected to the radio frequency control board.

An apparatus for self-generating power with two magnets at two ends and a wireless switch using same are provides, and which belong to the field for self-generating power. The apparatus for self-generating power with two magnets at two ends of the present disclosure includes a coil assembly and a permanent magnet assembly. The permanent magnet assembly includes a left permanent magnet, a right permanent magnet and a soft magnetic frame, wherein the coil assembly includes a coil and a soft magnetic plate, and the soft magnetic plate is arranged between the left permanent magnet and the right permanent magnet in an up-down rotation manner. In an initial state, a closed magnetic circuit is defined by a left end and a right end of the soft magnetic plate and the soft magnetic frame, and when the soft magnetic plate rotates relative to the permanent magnet assembly, a closed magnetic circuit with magnetic lines of force opposite in direction is defined by the left end and the right end of the soft magnetic plate and the soft magnetic frame. The wireless switch of the present disclosure includes a radio frequency control board, a switch body used for controlling an electric device, and the apparatus for self-generating power, wherein the coil of the apparatus for self-generating power is electrically connected to the radio frequency control board.

The invention relates to an electromagnetic device (10) comprising: a coil; a main magnet pivoting about an axis XX′, a first and second yoke (50, 50′), a first and second stabilizer magnet (41, 42), as well as a first and second actuator magnet (31, 32) arranged to slide along the axis YY′ that is perpendicular to the pivot axis XX′, in such a way as to force the main magnet (30) to adopt an equilibrium position, the stabilizer magnets (41, 42) being arranged such that this sliding is accompanied by a movement of the stabilizer magnets (41, 42) so as to position one of the stabilizer magnets (41, 42) in a given position in order to limit the leaks which could occur at one of the two yokes.