An embodiment of the invention provides a linear vibration motor. The linear vibration motor includes a base with a containing space, a vibration unit arranged in the containing space, an elastic piece suspending the vibration unit in the containing space, and a magnet assembly fixed to the base and driving the vibration unit to vibrate. The vibration unit includes a weight, a containing groove penetrating through the weight and at least one pair of coils which are oppositely fixed to the weight. The magnet assemblies has two magnets which are respectively fixed on two opposite sides of the base. The two magnets are at least partially located in the containing grooves, and are magnetized in the vibration direction. Compared with the related art, the linear vibration motor is improved in vibration performance and reliability.

A linear compressor includes a cylinder that defines a compressor space and that is configured to compress refrigerant in the compressor space, a piston located in the cylinder and configured to perform a reciprocating motion in an axial direction relative to the cylinder, a mover coupled to the piston and configured to transmit a driving force to the piston to cause the piston to perform the reciprocating motion, a stator that defines a cylinder space that receives the cylinder, in which the stator is configured to generate the driving force together with the mover, and a supporting unit that includes an overlap portion that covers at least a portion of the stator, that is coupled to the stator, and that contacts the stator.

A rotary reciprocating drive actuator reciprocally and rotationally driving the movable body about the shaft part in relation to the fixed body by the electromagnetic mutual effect of the coil and the movable magnet, wherein the movable magnet is magnetized in the radial direction of the shaft part, the two magnetic poles are disposed facing each other across an air gap in the radial direction of the movable magnet and the shaft part, and the fixed body has a rotation-angle-holding part disposed facing the movable magnet across the air gap, the rotation-angle-holding part holding the rotation angle position of the movable magnet by the magnetic attraction force generated with the movable magnet.

A rotary reciprocating drive actuator reciprocally and rotationally driving the movable body about the shaft part in relation to the fixed body by the electromagnetic mutual effect of the coil and the movable magnet, wherein the movable magnet is magnetized in the radial direction of the shaft part, the two magnetic poles are disposed facing each other across an air gap in the radial direction of the movable magnet and the shaft part, and the fixed body has a rotation-angle-holding part disposed facing the movable magnet across the air gap, the rotation-angle-holding part holding the rotation angle position of the movable magnet by the magnetic attraction force generated with the movable magnet.

Provided is a linear vibration motor, including: a housing having a receiving space; a vibration unit received in the receiving space; an elastic assembly configured to suspend the vibration unit in the receiving space, and a driving unit fixed to the housing and configured to drive the vibration unit to vibrate. The linear vibration motor includes a coil assembly and two first permanent magnets respectively provided at two sides of the coil assembly. The vibration unit includes one of the coil assembly and the first permanent magnets, and the driving unit includes the other one. When the vibration unit is static, a central axis of the first permanent magnet perpendicular to a vibrating direction of the vibration unit and a central axis of the coil assembly perpendicular to the vibrating direction of the vibration unit are spaced apart from each other in the vibrating direction of the vibration unit.

Provided is a linear vibration motor, including: a housing having a receiving space; a vibration unit received in the receiving space; an elastic assembly configured to suspend the vibration unit in the receiving space, and a driving unit fixed to the housing and configured to drive the vibration unit to vibrate. The linear vibration motor includes a coil assembly and two first permanent magnets respectively provided at two sides of the coil assembly. The vibration unit includes one of the coil assembly and the first permanent magnets, and the driving unit includes the other one. When the vibration unit is static, a central axis of the first permanent magnet perpendicular to a vibrating direction of the vibration unit and a central axis of the coil assembly perpendicular to the vibrating direction of the vibration unit are spaced apart from each other in the vibrating direction of the vibration unit.

Disclosed is a vibration motor including: a housing having an accommodating space, a first vibrator accommodated in the housing and having a coil, a first elastic component elastically supporting the first vibrator, and a circuit board electrically connected to outside. The first elastic component includes a first fixed portion, an elastic arm bending and extending from the first fixed portion, and a second fixed portion bending and extending from the elastic arm. The first elastic component includes substrate layers located on two sides and a damping layer sandwiched therebetween. A lead is disposed in the damping layer. The lead extends along the first elastic component and respectively extends out of the first and second fixed portion to form a first and second electrical conductive terminal. The first electrical conductive terminal is electrically connected to the circuit board. The second electrical conductive terminal is electrically connected to the coil.

Disclosed is a vibration motor including: a housing having an accommodating space, a first vibrator accommodated in the housing and having a coil, a first elastic component elastically supporting the first vibrator, and a circuit board electrically connected to outside. The first elastic component includes a first fixed portion, an elastic arm bending and extending from the first fixed portion, and a second fixed portion bending and extending from the elastic arm. The first elastic component includes substrate layers located on two sides and a damping layer sandwiched therebetween. A lead is disposed in the damping layer. The lead extends along the first elastic component and respectively extends out of the first and second fixed portion to form a first and second electrical conductive terminal. The first electrical conductive terminal is electrically connected to the circuit board. The second electrical conductive terminal is electrically connected to the coil.

A linear vibration motor comprising a movable element, having an integrated magnet, and a coil wherein winding parts and are caused to cross lines of magnetic force M1 and M2 of the magnet, where the coil is near to the movable element, and wherein the movable element is caused to vibrate along an axial direction through application of power to the coil, wherein: in the magnet, the direction of magnetization is aligned with the axial direction, and the magnet has two magnet pieces and, lined up in a direction that crosses the axial direction, and that have magnetic poles in mutually opposing directions; and other magnet pieces and, having magnetic poles that are magnetized in a crossing direction, where magnetic poles are in contact with, or near to, the identical magnetic poles of the two opposing magnetic poles on the same end sides of the two magnet pieces.

A linear vibration motor comprising a movable element, having an integrated magnet, and a coil wherein winding parts and are caused to cross lines of magnetic force M1 and M2 of the magnet, where the coil is near to the movable element, and wherein the movable element is caused to vibrate along an axial direction through application of power to the coil, wherein: in the magnet, the direction of magnetization is aligned with the axial direction, and the magnet has two magnet pieces and, lined up in a direction that crosses the axial direction, and that have magnetic poles in mutually opposing directions; and other magnet pieces and, having magnetic poles that are magnetized in a crossing direction, where magnetic poles are in contact with, or near to, the identical magnetic poles of the two opposing magnetic poles on the same end sides of the two magnet pieces.