An electromagnetic piston engine is characterized by an engine block containing at least one cylinder, within which at least one electromagnet is positions. Within the cylinder, the present invention may also provide for a piston attached to a camshaft, the piston having a magnetic end element fixably attached to its terminus. By means of a power source, the present invention may energize the electromagnet(s), which may provide for an electromagnetic force to be generated within the cylinder and which may act on the magnetic end element(s). The effect of this electromagnetic force may be to either attract or repel, or alternatingly attract and repel, the magnetic end element, thereby moving the piston back and forth within the cylinder, rotating the camshaft and powering a vehicle.

An electromagnetic piston engine is characterized by an engine block containing at least one cylinder, within which at least one electromagnet is positions. Within the cylinder, the present invention may also provide for a piston attached to a camshaft, the piston having a magnetic end element fixably attached to its terminus. By means of a power source, the present invention may energize the electromagnet(s), which may provide for an electromagnetic force to be generated within the cylinder and which may act on the magnetic end element(s). The effect of this electromagnetic force may be to either attract or repel, or alternatingly attract and repel, the magnetic end element, thereby moving the piston back and forth within the cylinder, rotating the camshaft and powering a vehicle.

A vibration motor is provided in the present disclosure. The vibration motor includes a stationary part, a vibration part and an elastic connector. The stationary part includes a housing providing an accommodating space. The vibration part is suspended within the accommodating space by the elastic connector. The stationary part comprises a coil, and the vibration part comprises a first magnet set and a second magnet set; the first magnet set and the second magnet set are respectively disposed at two opposite sides of the coil to generate a closed magnetic loop. The first magnet set includes a first left magnet, a first middle magnet and a first right magnet, the second magnet set includes a second left magnet, a second middle magnet and a second right magnet which are opposite to the first left magnet, the first middle magnet and the first right magnet respectively.

A vibration motor is provided in the present disclosure. The vibration motor includes a stationary part, a vibration part and an elastic connector. The stationary part includes a housing providing an accommodating space. The vibration part is suspended within the accommodating space by the elastic connector. The stationary part comprises a coil, and the vibration part comprises a first magnet set and a second magnet set; the first magnet set and the second magnet set are respectively disposed at two opposite sides of the coil to generate a closed magnetic loop. The first magnet set includes a first left magnet, a first middle magnet and a first right magnet, the second magnet set includes a second left magnet, a second middle magnet and a second right magnet which are opposite to the first left magnet, the first middle magnet and the first right magnet respectively.

A linear vibration motor includes a housing with an accommodation space; a vibration system in the accommodation space; an elastic part supporting the vibration system; and a magnetic circuit system with a magnetic gap for driving the vibration system to vibrate. The vibration system includes a connecting part including a first support portion, a plurality of second support portions extending respectively from the first support portion for fixing the weights, a coil suspended by the elastic part in the magnetic gap, two weights located symmetrically about the coil and fixed by the connecting part, and at least two clamping portions extending from the first support portion and connected respectively to two weights at the side near the coil for limiting the movement of two weights relative to the coil.

A linear vibration motor includes a housing with an accommodation space; a vibration system in the accommodation space; an elastic part supporting the vibration system; and a magnetic circuit system with a magnetic gap for driving the vibration system to vibrate. The vibration system includes a connecting part including a first support portion, a plurality of second support portions extending respectively from the first support portion for fixing the weights, a coil suspended by the elastic part in the magnetic gap, two weights located symmetrically about the coil and fixed by the connecting part, and at least two clamping portions extending from the first support portion and connected respectively to two weights at the side near the coil for limiting the movement of two weights relative to the coil.

A linear motor includes a housing, a mover and a stator unit. The mover is movable relative to the housing, and includes a rod member, a plurality of first magnetic poles mounted to the rod member, and a plurality of second magnetic poles mounted to the rod member. The first and second magnetic poles are arranged alternately in a circumferential direction of the rod member, and are partially overlapped circumferentially. The stator unit is disposed in the housing, surrounds the mover, and is able to be energized to drive reciprocal movement of the mover relative to the housing.

A linear motor includes a housing, a mover and a stator unit. The mover is movable relative to the housing, and includes a rod member, a plurality of first magnetic poles mounted to the rod member, and a plurality of second magnetic poles mounted to the rod member. The first and second magnetic poles are arranged alternately in a circumferential direction of the rod member, and are partially overlapped circumferentially. The stator unit is disposed in the housing, surrounds the mover, and is able to be energized to drive reciprocal movement of the mover relative to the housing.

A vibration device includes a housing having accommodating space, a vibrator, a stator and an elastic member configured to suspend the vibrator in the accommodating space, the vibrator, the stator and the elastic member are accommodated in the housing, one of the vibrator and the stator includes a magnetic circuit unit while the other one includes a coil, the housing includes a pair of first side walls symmetrically arranged in its long axis direction and a pair of second side walls symmetrically arranged in a short axis direction, the elastic member is a sheet-like spring perpendicular to vibrating direction of the vibrator, the elastic member includes a first fixing portion fixedly connected with the second side wall, a second fixing portion fixedly connected with the vibrator, and an S-shaped connecting portion which connects the first fixing portion with the second fixing portion and extends along long axis direction.

A vibration motor is disclosed. The vibration motor includes a housing, a substrate engaging with the housing, a vibration unit received in the housing, an elastic member suspending the vibration unit, and a coil assembly interacting with the vibration unit. The vibration unit includes an avoidance corresponding to the coil assembly for preventing the vibration unit interfering with the coil assembly.