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.

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.

The present disclosure provides a linear vibration motor, including a casing with an accommodation space, a vibration unit accommodated in the accommodation space, a vibration unit suspended in the accommodation space and a coil fixed on the casing and driving the vibration unit to vibrate. The casing includes a copper ring arranged around the vibration unit. In the linear vibration motor provided by the utility model, the copper ring is arranged around the vibration unit to provide a damping function for the linear vibration motor. Compared with the foam damping member in the related art, the linear vibration motor provided by the present disclosure may be arranged by an automatic device during the production and manufacture of the linear vibration motor, thereby greatly improving the production efficiency, and improving the automation degree.

The present disclosure provides a linear vibration motor, including a casing with an accommodation space, a vibration unit accommodated in the accommodation space, a vibration unit suspended in the accommodation space and a coil fixed on the casing and driving the vibration unit to vibrate. The casing includes a copper ring arranged around the vibration unit. In the linear vibration motor provided by the utility model, the copper ring is arranged around the vibration unit to provide a damping function for the linear vibration motor. Compared with the foam damping member in the related art, the linear vibration motor provided by the present disclosure may be arranged by an automatic device during the production and manufacture of the linear vibration motor, thereby greatly improving the production efficiency, and improving the automation degree.

Disclosed is a voice coil motor, the motor including a mover having a bobbin equipped with a lens and a coil block secured to an outer circumference of the bobbin; a stator having a magnet that is disposed in such a way as to face the coil block; elastic members coupled to a lower end of the bobbin and connected to both ends of the coil block; a base supporting the elastic members and the stator; and a cover can covering the mover, the stator and the base, with an opening being formed in the cover can to expose the lens therethrough, wherein each of the elastic members includes a terminal portion that extends between the cover can and a side surface of the base, the terminal portion including a short-circuit prevention portion so as to inhibit a short-circuit between the terminal portion and the cover can.

Disclosed is a voice coil motor, the motor including a mover having a bobbin equipped with a lens and a coil block secured to an outer circumference of the bobbin; a stator having a magnet that is disposed in such a way as to face the coil block; elastic members coupled to a lower end of the bobbin and connected to both ends of the coil block; a base supporting the elastic members and the stator; and a cover can covering the mover, the stator and the base, with an opening being formed in the cover can to expose the lens therethrough, wherein each of the elastic members includes a terminal portion that extends between the cover can and a side surface of the base, the terminal portion including a short-circuit prevention portion so as to inhibit a short-circuit between the terminal portion and the cover can.

A linear vibrator includes a stator having a housing including a receiving space, a moveable unit received in the receiving space, a coil attached to one of the stator and the moveable unit, a magnet assembly attached to the other of the stator and the moveable unit, an elastic member having one end connecting to the moveable unit and another end connecting to the stator for suspending the moveable unit in the receiving space, and a damping block located between the moveable unit and the elastic member, and deformable by the elastic member during the vibration of the moveable unit within a predetermined vibration amplitude. A boost force is produced by the damping block for accelerating the moveable unit to return to balanced position.

A linear vibrator includes a stator having a housing including a receiving space, a moveable unit received in the receiving space, a coil attached to one of the stator and the moveable unit, a magnet assembly attached to the other of the stator and the moveable unit, an elastic member having one end connecting to the moveable unit and another end connecting to the stator for suspending the moveable unit in the receiving space, and a damping block located between the moveable unit and the elastic member, and deformable by the elastic member during the vibration of the moveable unit within a predetermined vibration amplitude. A boost force is produced by the damping block for accelerating the moveable unit to return to balanced position.

The present disclosure discloses a linear motor system. The system includes a linear motor and a drive module which drives the linear motor to vibrate. The linear motor includes a housing having an accommodating space, a vibrating module accommodated in the accommodating space and an elastic part for supporting the vibrating module in the accommodating space elastically. The drive module includes a drive unit for driving the vibrating module to vibrate and a tuning unit for regulating the resonant frequency of the vibrating module. Moreover, the linear motor system of the present disclosure can meet vibration requirements of various application programs and scenes.

An operation on a vibration device presenting a force sense based on vibration to a human body is simplified. The vibration device includes: a base mechanism; an actuator configured to perform a physical motion based on a supplied control signal; a slide mechanism configured to perform a periodic reciprocating slide motion in a predetermined direction and an opposite direction to the predetermined direction with respect to the base mechanism based on the physical motion of the actuator and to give a force based on the reciprocating slide motion to a part of a human body with which the slide mechanism comes into direct or indirect contact; and a detection unit located in the predetermined direction with respect to the slide mechanism and configured to detect displacement of a specific portion included in the slide mechanism. The specific portion is movable in the predetermined direction by a width greater than an amplitude at the time of the reciprocating slide motion when a force is given to the slide mechanism from the part of the human body with which the slide mechanism comes into direct or indirect contact. Driving control is performed on the actuator when the detection unit detects the specific portion moved in the predetermined direction by the width greater than the amplitude at the time of the reciprocating slide motion.