Linear vibrating motor

What is claimed is: 1. A linear vibrating motor, comprising a housing, a vibrator and a stator that is secured to the housing and is parallel to the vibrator, wherein the vibrator comprises a mass block and a vibrating block embedded in middle of the mass block, and the vibrating block includes a permanent magnet, and wherein push-pull structures adjoin two ends of the vibrating block; each push-pull structure comprises a push-pull magnet embedded in the mass block and a push-pull coil secured to the housing; an interaction force for enhancing a magnetic field is generated between the push-pull magnet and an adjacent permanent magnet; and the push-pull coil generates a push-pull force in a horizontal direction together with the push-pull magnet after being electrified to provide a push-pull force for a reciprocating motion of the vibrator in a direction that is parallel to a plane where the stator is located, wherein at least one pair of push-pull magnet securing grooves is symmetrically provided in the mass block, and wherein each push-pull magnet securing groove accommodates two push-pull magnets distributed in a vertical direction and a magnetic induction yoke located between the two push-pull magnets. 2. The linear vibrating motor according to claim 1 , wherein the stator comprises a magnetic induction block which is opposite to the vibrator and secured to the housing, and the magnetic induction block is subject to a magnetic field force that is the same as and/or opposite to a vibration direction of the vibrator. 3. The linear vibrating motor according to claim 2 , wherein when the vibrator is in a balanced state, a resultant force of a magnetic field force is zero; and when the magnetic induction block is subject to a relative displacement with the vibrator in a vibration direction of the vibrator under an action of a push-pull force that is generated by the push-pull structure, a direction of a resultant force of the magnetic field force is the same as that of the relative displacement, and a magnitude of the resultant force of the magnetic field force and the relative displacement are in direct proportion. 4. The linear vibrating motor according to claim 2 , wherein a make-way structure that corresponds to the push-pull coil and the magnetic induction block is disposed in the middle of the mass block; a groove for accommodating the vibrating block is provided in the mass block; and the vibrating block is secured in the groove by means of gluing. 5. The linear vibrating motor according to claim 1 , wherein the push-pull magnet is magnetized in the vertical direction, the permanent magnet is magnetized in the horizontal direction, and adjacent ends of the permanent magnet and an adjacent push-pull magnet have opposite magnetic poles. 6. The linear vibrating motor according to claim 1 , wherein four pairs of push-pull magnet securing grooves are symmetrically provided in the mass block, and each push-pull magnet securing groove accommodates two push-pull magnets that are distributed in the vertical direction; four push-pull coils, positions of the four push-pull coils corresponding to positions of the push-pull magnets, are secured to the housing; and the push-pull coils are located at upper and lower sides of the corresponding push-pull magnets, and a winding direction of each push-pull coil is perpendicular to a magnetization direction of the corresponding push-pull magnet. 7. The linear vibrating motor according to claim 1 , wherein a magnetic liquid is filled between the push-pull coil and an adjacent push-pull magnet. 8. The linear vibrating motor according to claim 1 , wherein the push-pull coil is an irregularly-wound coil, and a winding quantity of the push-pull coil in a position, with concentrated magnetic induction lines, of the push-pull magnet is increased. 9. The linear vibrating motor according to claim 1 , wherein the push-pull coil is a superimposedly wound coil or an interleavingly wound coil. 10. The linear vibrating motor according to claim 1 , wherein when the vibrator is in a balanced state, a resultant force of a magnetic field force is zero; and when a magnetic induction block is subject to a relative displacement with the vibrator in a vibration direction of the vibrator under an action of a push-pull force that is generated by the push-pull structure, a direction of a resultant force of the magnetic field force is the same as that of the relative displacement, and a magnitude of the resultant force of the magnetic field force and the relative displacement are in direct proportion. 11. The linear vibrating motor according to claim 1 , wherein a make-way structure that corresponds to the push-pull coil and a magnetic induction block is disposed in the middle of the mass block; a groove for accommodating the vibrating block is provided in the mass block; and the vibrating block is secured in the groove by means of gluing.