A linear vibration motor comprising a vibrator and a stator, wherein the vibrator comprises at least two permanent magnets disposed adjacent to each other and a magnetic yoke disposed between any two adjacent permanent magnets, and adjacent ends of the two adjacent permanent magnets have the same polarities; the stator comprises coils and magnetic cores disposed in the coils; magnetization directions of the permanent magnets are perpendicular to axis directions of the coils. The linear vibration motor enables the magnetic lines of flux of the permanent magnets to intensively pass through the coils by means of a repulsive force between two ends with same polarity of two permanent magnets so as to obtain a larger magnetic flux and a stronger vibration sensing effect.

An actuator includes: a magnet structure including first and second areas, a first magnet whose magnetic pole surface has an N pole and a second magnet whose magnetic pole surface has an S pole; and a circuit board including first and second wirings. When current flows from one end of the first wiring to the other end, the current circulates in one direction at least partially on the first magnet in the first area, while it circulates in a direction opposite to the one direction at least partially on the second magnet in the first area. When current flows from one end of the second wiring to the other end, the current circulates in the direction opposite to the one direction at least partially on the first magnet in the second area, while it circulates in the one direction at least partially on the second magnet in the second area.

A reciprocating ramp motor, including: an output shaft including an axis of rotation; a first electro-magnetic device including a first coil; an annular core plate disposed about the output shaft and axially off-set from the first electro-magnetic device in a first axial direction; a roller device; and a first ramp non-rotatably connected to the output shaft; and sloping in the first axial direction along a first circumferential direction. The first coil is arranged to be electrically energized to displace the annular core plate in a second axial direction, opposite the first axial direction. Displacement of the annular core plate in the second axial direction is arranged to roll the roller device along the first ramp in the second axial direction. Displacement of the roller device along the first ramp in the second axial direction is arranged to rotate the output shaft in the first circumferential direction.

A reciprocating ramp motor, including: an output shaft including an axis of rotation; a first electro-magnetic device including a first coil; an annular core plate disposed about the output shaft and axially off-set from the first electro-magnetic device in a first axial direction; a roller device; and a first ramp non-rotatably connected to the output shaft; and sloping in the first axial direction along a first circumferential direction. The first coil is arranged to be electrically energized to displace the annular core plate in a second axial direction, opposite the first axial direction. Displacement of the annular core plate in the second axial direction is arranged to roll the roller device along the first ramp in the second axial direction. Displacement of the roller device along the first ramp in the second axial direction is arranged to rotate the output shaft in the first circumferential direction.

The present disclosure provides a vibration motor. The vibration motor includes a housing having a bottom wall and a side wall, a vibrator received in the housing, and an elastic member supporting vibration of the vibrator. The side wall includes a first side wall extending in a long axis direction of the vibration motor and a second side wall extending in a short axis direction of the vibration motor. The coil is disposed inclined to the first side wall. The vibration motor provided by the present disclosure can simultaneously provide driving forces in two directions of X and Y, achieves dual-f0 vibration output, and is simple in structure, so that not only the working band is effectively expanded, but also the vibration effect is enriched.

The present disclosure provides a vibration motor. The vibration motor includes a housing having a bottom wall and a side wall, a vibrator received in the housing, and an elastic member supporting vibration of the vibrator. The side wall includes a first side wall extending in a long axis direction of the vibration motor and a second side wall extending in a short axis direction of the vibration motor. The coil is disposed inclined to the first side wall. The vibration motor provided by the present disclosure can simultaneously provide driving forces in two directions of X and Y, achieves dual-f0 vibration output, and is simple in structure, so that not only the working band is effectively expanded, but also the vibration effect is enriched.

An assembly configured to generate a propulsive force through a plurality of magnets. The assembly includes a rod having a center disk comprised of non-magnetic materials and configured to receive an electromagnet and a plurality of coaxial magnetic disks configured for selective movement about the rod when a magnetic field is generated by the electromagnet.

The present disclosure provides a linear vibration motor, including a base having an accommodating space, a vibration unit accommodated in the accommodating space, an elastic member that fixes and suspends the vibration unit in the accommodating space and a drive unit fixed to the base and configured to drive the vibration unit to vibrate along a direction perpendicular to a horizontal direction, herein the vibration unit includes a magnetic steel fixed to the elastic member; and the drive unit includes a coil fixed to the base, a winding plane of the coil being parallel to a vibration direction of the vibration unit. Compared with a related art, a linear vibration motor in the present disclosure has better vibration performance.

The present disclosure provides a linear vibration motor, including a base having an accommodating space, a vibration unit accommodated in the accommodating space, an elastic member that fixes and suspends the vibration unit in the accommodating space and a drive unit fixed to the base and configured to drive the vibration unit to vibrate along a direction perpendicular to a horizontal direction, herein the vibration unit includes a magnetic steel fixed to the elastic member; and the drive unit includes a coil fixed to the base, a winding plane of the coil being parallel to a vibration direction of the vibration unit. Compared with a related art, a linear vibration motor in the present disclosure has better vibration performance.

Disclosed is a linear vibration motor, including a base, a cover plate, a vibration unit, and a drive unit. The vibration unit includes a counterweight block and a magnetic steel. An accommodating groove is provided in the counterweight block. At least two pieces of magnetic steel are respectively located on two opposite sides of the accommodating groove. The drive unit includes an iron core accommodated in the accommodating groove and fixed on the base and two first coils and two second coils that are respectively fixedly sleeved over the iron core. The two second coils and two pieces of magnetic steel are together circumferentially disposed in the accommodating groove and are arranged alternately.