KR200347981Y1 - Yoke Structure of Optical Pickup Actuator - Google Patents

Abstract

The present invention aims to improve driving sensitivity by allowing the magnet to maintain an optimum distance from the tracking coil and the focusing coil by adjusting the distance of the bending piece for fixing the magnet.

The present invention has a lens holder 40 to which the objective lens 42 is fixed, a plurality of suspension wires 30 supporting both sides of the lens holder 40, and a suspension PCB 22 supporting the suspension wires 30. In the optical pickup actuator provided with a yoke 10 having a support 16 for fixing the suspension PCB 22, a pair of fixing pieces 14 each having a first tooth type 15 on both sides and A yoke structure including a plurality of second teeth 11 formed on the yoke 10 and correspondingly coupled to the first teeth 15, the first teeth 15 of the fixing piece 14 being magnet 18. ) Is coupled to the second tooth type 11 in which the distance between the tracking coil 46 and the focusing coil 44 is optimal, thereby equalizing the driving force generated by the tracking coil 46 and the focusing coil 44 to achieve a lens holder. There is an effect that can prevent the negative resonance of (40).

Description

Yoke Structure of Optical Pickup Actuator

The present invention relates to a yoke structure of an optical pickup actuator, and in particular, an optical pickup for improving driving sensitivity by allowing the magnet to maintain an optimum distance from the tracking coil and the focusing coil by adjusting the distance of the bending piece for fixing the magnet. It relates to the yoke structure of the actuator.

In general, the optical pickup actuator moves the objective lens in the radial direction when the error of the optical axis or the radial direction occurs at the focal point of the laser beam formed on the recording pit of the disc through the objective lens in the hologram element. It is used as a driving means for correcting the error of the focus of the laser beam by finding the, and adjusting the size of the focus by moving in the focus direction.

A wire driving actuator generally used among these optical pickup actuators is shown in FIG. 1.

The actuator has a shape in which the lens holder 140 fixing the objective lens 142 is installed to the yoke 110 with a suspension wire 130 so as to be movable. The objective lens 142 is located at the center of the lens holder 140. ), And a focusing coil 144 was wound around the lens holder 140, and then a tracking coil 146 wound in a rectangular shape on the front was attached thereto. The coil PC 148 was fixed to both sides of the lens holder 140 to connect the tracking coil 146 and the focusing coil 144.

In addition, the yoke 110 forms a pair of symmetrical outer bent pieces 114, and attaches and fixes the magnet 118 for generating an electromagnetic force by applying magnetic flux to the tracking coil 146 and the focusing coil 144. In addition, a pair of inner bent pieces 112 symmetrically formed inside the outer bent pieces 114 are bent upwardly at the yoke 110 to induce a flow of the magnetic flux of the magnet 118, so that the magnetic flux of the magnets 118 is reduced. A magnetic closure circuit was formed to strongly pass the tracking coil 146 and the focusing coil 144 horizontally, pass through the planes of the inner bent piece 112 and the yoke 110, and enter the magnet 118.

In addition, the support 116 is formed at one edge of the yoke 110 to fix the suspension PCB 122 with the screw 124, and one end of the suspension wire 130 is bonded to the lens holder 140 with the coil PCB ( 148 and the other end to the suspension PCB 122, thereby causing the lens holder 140 to float and be installed by the suspension wire 130, and the current applied from the signal processing unit to the suspension PCB 122 is suspended. And to the tracking coil 146 and the focusing coil 144 via wire 130.

Meanwhile, as a damping structure for attenuating the negative resonance of the suspension wire 130 of the actuator, conventionally, two gel holders 120 are integrally connected between the suspension PCB 122 and the support 116 so that the center is connected together. Fixed. Then, two suspension wires 130 each pass through the inside of each gel holder 120, and a viscous silicone gel (not shown) is injected into the gel holder 120, thereby providing suspension wire 130. Negative resonance was reduced rapidly by the viscosity of the silicone gel.

However, such an actuator may be installed near or away from the magnet 118 due to an error in soldering of the suspension wire 130, so that the lens holder 140 supported by the suspension wire 130 may have a tracking coil 146 and The intensity of the magnetic flux on the focusing coil 144 is different.

If the error is large, the deviation of the driving force of the tracking coil 146 and the focusing coil 144 that generates the driving force by the magnetic flux of the magnet 118 is large, the phenomenon that the lens holder 140 is driving in a sine, namely negative resonance There is a problem that occurs.

The present invention is devised to improve the conventional problems, the object of the present invention is to adjust the distance of the bending piece for fixing the magnet to maintain the optimum sensitivity of the magnet from the tracking coil and focusing coil, driving sensitivity It is to improve.

1 is an exploded perspective view of a typical optical pickup actuator.

2 is an exploded perspective view of an optical pickup actuator according to an embodiment of the present invention;

<Explanation of symbols for main parts of drawing>

10: York 11: second tooth

12: inner bending piece 14: fixing piece

15: first tooth 16: support

18: magnet 20: gel holder

22: suspension PC 24: screw

30: suspension wire 40: lens holder

42: objective 44: focusing coil

46: tracking coil 48: coil PC

The present invention for achieving the above object includes a lens holder supported by a suspension wire on the yoke, a focusing coil and a tracking coil and a magnet to form a magnetic circuit winding and bonded to the lens holder and a magnetic circuit. An optical pickup actuator configured to include; A plurality of second tooth shapes are formed on the yoke to adjust an optimal distance between the focusing coil and the tracking coil and the magnet, and the first piece is formed on the fixing piece to be selectively coupled to one second tooth shape.

The first tooth type of the fixing piece is coupled to the second tooth type in which the distance between the magnet, the tracking coil and the focusing coil is optimal, so that the driving force generated in the tracking coil and the focusing coil is made uniform. Thus, the drive sensitivity of the optical pickup actuator can be improved by the yoke structure of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the preferred embodiments of the present invention.

The configuration of the optical pickup actuator of this embodiment will be described with reference to FIG.

The actuator couples the objective lens 42 to the center of the lens holder 40, winds the focusing coil 44 around the lens holder 40, and then, in advance, a tracking coil wound in a square shape thereon. (46) is bonded.

The coil PC 48 is fixed to both sides of the lens holder 40, and the tracking coil 46 and the focusing coil 44 are connected to the coil PC 48.

It is also provided with a pair of fixing pieces 14, each having a first tooth 15 on both sides, the yoke 10 is formed a plurality of second tooth 11 to be coupled to correspond to the first tooth 15. do. The magnet 18 for generating an electromagnetic force by applying magnetic flux to the tracking coil 46 and the focusing coil 44 is bonded to and fixed to the fixing piece 14.

At the same time, a pair of inner bent pieces 12 symmetrically formed inside the fixing piece 14 are bent upwardly in the yoke 10 to induce the flow of the magnetic flux of the magnet 18, whereby the magnetic flux of the magnet 18 is increased. A magnetic closure circuit is formed which strongly passes the tracking coil 46 and the focusing coil 44 horizontally, passes through the planes of the inner bent pieces 12 and the yoke 10 and enters the magnet 18 again.

By coupling the first tooth 15 of the fixing piece 14 to the second tooth 11 with the optimum distance between the magnet 18, the tracking coil 46 and the focusing coil 44, the tracking coil 46 And the driving force generated by the focusing coil 44 are made uniform.

The support 16 is formed at one edge of the yoke 10, and the gel holder 20 and the suspension PCB 22 are fixed to the rear of the support 6 with the screw 24.

Subsequently, two suspension wires 36 having four suspension wires 36 are respectively connected to the two coil PCs 48 attached to the lens holder 40, and the other ends are passed through the respective gel holders 20 so that the suspension PCs ( 22).

Accordingly, the lens holder 40 is lifted by the suspension wire 36, and the current applied from the signal processing unit to the suspension PCB 22 is transferred to the tracking coil 46 and the focusing coil 44 through the suspension wire 30. Is passed on.

In addition, in order to attenuate the negative resonance of the suspension wire 30, a viscous silicone gel is injected into the gel holder 20 and cured appropriately, thereby quickly reducing the negative resonance of the suspension wire 30 with the viscosity of the silicone gel. To be reduced.

Hereinafter, the operation of the damping structure having the above configuration will be described.

As shown in FIG. 2, an external driving voltage input through the suspension PCB 22 is transmitted to the coil PC 48 through the suspension wire 30, and the signal is transmitted to the tracking coil 46 and the focusing coil ( 44 to drive the lens holder 40.

As a result, the tracking error and focusing error caused by the focus of the laser beam formed on the recording pit of the disc in the objective lens 42 fixed to the lens holder 40 is corrected.

As described above, an unintended negative resonance is generated in the lens holder 40 while the lens holder 40 is driven, and the negative resonance is attenuated by the damping action of the silicon gel in contact with the suspension wire 30.

As described in the above embodiment, the present invention provides a lens holder 40 supported by a suspension wire on the yoke 10, a focusing coil 44 and a tracking coil 46 wound and bonded to the lens holder 40. In the optical pickup actuator comprising a fixing piece 14 having a magnet 18 forming a magnetic circuit), the focusing coil 44 and the tracking coil 46 and the magnet 18 on the yoke 10. A plurality of second teeth 11 are formed to adjust the optimum distance between the two, and the fixing piece 14 is formed with a first tooth 15, which is selectively coupled to one second tooth 11, As the yoke structure of the pick-up actuator, the first tooth type 15 of the fixing piece 14 is coupled to the second tooth type 11 in which the distance between the magnet 18 and the tracking coil 46 and the focusing coil 44 is optimal. As a result, the driving force generated in the tracking coil 46 and the focusing coil 44 is made uniform, and the lens hole There is an effect that can prevent the negative resonance of the (40).

Claims (1)

A magnet 18 forming a magnetic circuit with a lens holder 40 supported by a suspension wire on the yoke 10, a focusing coil 44 and a tracking coil 46 wound and bonded to the lens holder 40. In the optical pickup actuator comprising a fixing piece 14 is attached to; A plurality of second teeth 11 are formed on the yoke 10 to adjust an optimal distance between the focusing coil 44 and the tracking coil 46 and the magnet 18, Yoke structure of an optical pickup actuator, characterized in that the first tooth (15) selectively coupled to one of the second tooth (11) is formed on the fixing piece (14).