A vibration motor includes a stationary portion and a movable portion vibrable in an axis direction with respect to the stationary portion. The stationary portion includes a coil and a housing. The housing includes a first region expanding in a first direction orthogonal to the axis direction, and a second region disposed on one side in a second direction orthogonal to the axis direction and the first direction relative to the first region and expanding in the first direction. In a cross-section across the axis direction, a distance in the second direction between the second region and the first region is longest at a center in the first direction of the first region. In the cross-section, a shape formed by the first and second regions is asymmetric with respect to an axis extending parallel to the first direction through a center of the housing in the second direction.

A mass shifting mechanism between twin equilibrium points comprises a movable slider between two equilibrium positions and actuating means active on the slider to bring it and keep it in a first and a second stationary spatial configuration through an action of electromagnetic field, the second stationary spatial configuration being different from the first stationary spatial configuration.

A mass shifting mechanism between twin equilibrium points comprises a movable slider between two equilibrium positions and actuating means active on the slider to bring it and keep it in a first and a second stationary spatial configuration through an action of electromagnetic field, the second stationary spatial configuration being different from the first stationary spatial configuration.

A movable magnet is configured by alternately magnetizing an even number of magnetic poles forming an South pole and an North pole; a number of magnetic poles of a core body is equal to a number of magnetic poles of the movable magnet; an even number of magnetic poles of the core body is respectively arranged to face the movable magnet with an air gap therebetween on the outer peripheral side of a shaft portion; and a drive unit is provided with a magnet position holding portion to face the movable magnet and magnetically attracts the movable magnet to a reference position. A drive unit is attached to one wall portion of the pair of wall portions of a base portion, and an angle sensor portion for detecting a rotation angle of the shaft portion is attached to the other wall portion of the pair of wall portions.

A movable magnet is configured by alternately magnetizing an even number of magnetic poles forming an South pole and an North pole; a number of magnetic poles of a core body is equal to a number of magnetic poles of the movable magnet; an even number of magnetic poles of the core body is respectively arranged to face the movable magnet with an air gap therebetween on the outer peripheral side of a shaft portion; and a drive unit is provided with a magnet position holding portion to face the movable magnet and magnetically attracts the movable magnet to a reference position. A drive unit is attached to one wall portion of the pair of wall portions of a base portion, and an angle sensor portion for detecting a rotation angle of the shaft portion is attached to the other wall portion of the pair of wall portions.

The invention relates to electric machines, and more particularly to both linear and rotational generator/motors. The aim of the claimed invention is to increase the amount of EMF generated, minimize the number of magnets and windings used, and maximize the use thereof throughout the entire generation cycle. The Bayaliev universal generator/motor comprises a fixed magnetic core (stator), a movable magnetic core (rotor), a magnet, and windings, wherein the fixed magnetic core contains at least one main element configured in the form of a magnet having generating windings arranged on two sides thereof such as to provide for opposite magnetic flux reversals in the windings when the movable magnetic core is moving. To strengthen the magnetic flux, an excitation winding is mounted in the region of the magnet, said excitation winding being fed by the generating windings via a rectifier.

The invention relates to electric machines, and more particularly to both linear and rotational generator/motors. The aim of the claimed invention is to increase the amount of EMF generated, minimize the number of magnets and windings used, and maximize the use thereof throughout the entire generation cycle. The Bayaliev universal generator/motor comprises a fixed magnetic core (stator), a movable magnetic core (rotor), a magnet, and windings, wherein the fixed magnetic core contains at least one main element configured in the form of a magnet having generating windings arranged on two sides thereof such as to provide for opposite magnetic flux reversals in the windings when the movable magnetic core is moving. To strengthen the magnetic flux, an excitation winding is mounted in the region of the magnet, said excitation winding being fed by the generating windings via a rectifier.

In one embodiment, a gimbal adjustment system and an associated method for adjusting the position of an object. The system comprises a base, a plate and a shaft including a pivot attached to the plate. The pivot has a point of contact with the plate in a joint about which the plate is rotatable. Magnetic elements are positioned on the base and the plate to stabilize or rotate the plate. The object may be an optical unit attached to the plate. A combination comprising the plate, optical unit and magnetic elements may form a gimbaled assembly having a center of mass in the joint.

The present application discloses a brushless electromagnetic suspension vibration motor, which relates to the technical field of motors. A stator coil and a stator are respectively fixedly arranged inside a coil fixing base, elastic pieces are arranged on both sides of a bottom corner support, the top ends of the two elastic pieces are connected with an elastic piece connecting seat, a swing rod is arranged inside a through groove, the bottom end of the swing rod is fixedly connected with movers. According to the principle of magnetic induction, after the positive and negative alternating current is passed into the magnetic induction coil, under the action of the stator, the two movers are urged to move back and forth in a staggered manner. When the mover moves, the parts above the mover are driven to follow the movement, thereby causing the elastic pieces to deform and swing back and forth.

A vibration module is provided, having a main axis passing through the center of the vibration module, including a fixed part and a first vibration part. The first vibration part is disposed within the fixed part. The first vibration part includes a first moving member and a first driving assembly. The first driving assembly drives the first moving member to move relative to the fixed part.