JPH0679383B2 - Objective lens drive - Google Patents

Description

The present invention relates to an objective lens driving device in an optical pickup used for an optical disc device or the like.

(Prior Art) In an optical disc device using an optical disc as a recording medium,
An optical pickup is used to write and read information signals on a disc. In this optical pickup, an objective lens driving device for accurately focusing the laser beam on the information pit of the disc is used. Therefore, in this objective lens driving device, it is necessary to precisely control the position of the objective lens two-dimensionally in the focusing direction and the tracking direction, and in order to precisely perform this two-dimensional follow-up servo, the objective lens is predetermined. Manufacturing to maintain the neutral point is an important factor that determines the performance of the optical pickup.

The objective lens support structure in the conventional objective lens drive device is a combination of a metal plate spring used to hold the objective lens at a predetermined neutral point and an elastic holding damper such as a molded spring used for the support shaft. It is roughly divided into things. The former can be used for both positioning and elastic holding of the lens,
Slight bending of the leaf spring may cause abnormal resonance, or the braking performance at resonance may be insufficient and unstable, and the optical axis accuracy of the lens may be difficult to obtain. While the latter makes it easy to obtain the optical axis accuracy with a support shaft, many of the elastic members used in combination with this are molded products made of rubber or resin, which are disadvantageous in terms of temperature characteristics and aging, and Since the size of the spring is reduced along with the size reduction, there is a problem that the linearity range of the characteristic is narrowed and the follow-up characteristic is deteriorated in a disk with large surface wobbling and eccentricity.

Therefore, in order to improve these problems, some proposals have been made in which the objective lens is held at a neutral point by giving a magnetic restoring force. 58
-179635, JP 58-163908, JP 62-
The example described in Japanese Patent No. 141646 is an example.

(Problems to be Solved by the Invention) According to the objective lens driving device having the magnetic restoring force described above, the range in which the magnetic restoring force is uniform is narrow, and a plurality of magnetic pieces are used to compensate for this. It is necessary to improve such as use, and the neutral point is held by one magnetic piece in either the focusing direction or the tracking direction, and the neutral point in both the focusing direction and the tracking direction is set. If it were to be put out, there was a problem that two sets of magnetic pieces were required, the structure was complicated and the cost was high.

The present invention has been made in order to solve the above-mentioned problems of the prior art, and is one in which a neutral point is provided by utilizing a magnetic restoring force, and a focusing direction and a tracking direction are formed by a pair of magnetic pieces. It is possible to generate a restoring force in a two-dimensional manner and to generate a neutral point in a two-dimensional manner, and to obtain a stable restoring force, and at the same time, an inexpensive and highly reliable objective lens. An object is to provide a drive device.

(Means for Solving the Problems) In the objective lens driving device according to the present invention, the magnet disposed to face the driving coil is polarized and magnetized in at least one of the focusing direction and the tracking direction. A rectangular magnetic piece is arranged in the magnetic circuit including the magnet so as to face the central portion of the magnet, and the long side of the rectangular magnetic piece is oriented in the polarization direction of the magnet, and the other short side is It is characterized in that it is formed smaller than the width of the magnet, and the restoring force is two-dimensionally generated in the focusing direction and the tracking direction by the magnetic attractive force acting on the magnetic piece to hold the objective lens at the neutral point.

(Operation) By arranging the magnetic piece in the magnetic circuit including the polarized magnetized magnet, a magnetic attractive force is generated in the magnetic piece. This magnetic attraction force tends to be stably held at the maximum point of the magnetic flux, and this stable holding force becomes the magnetic restoring force, and the objective lens is held at the neutral point. Since the magnet is polarized and magnetized in at least one of the focusing direction and the tracking direction, a magnetic restoring force is generated in the magnetic piece in the polarization direction and a direction orthogonal thereto, and the objective lens is focused in the focusing direction. Hold at the neutral point in both the tracking direction and the tracking direction.

(Example) Hereinafter, an example of an objective lens driving device according to the present invention will be described with reference to the drawings.

In FIGS. 1 to 4, reference numeral 1 is a lens holder, and the lens holder 1 is supported so as to be rotatable around a fixed shaft 7 and movable along the shaft 7. An objective lens 2 is attached to the lens holder 1 with its optical axis parallel to the axis 7. A balancer 8 is fixed to the lens holder 1 on the opposite side of the objective lens 2 about the axis 7. A focusing drive coil 4 and a tracking drive coil 3 are fixed to the outer peripheral surface of the lens holder 1 at symmetrical positions with respect to the axis 7. The outer peripheral surface of the lens holder 1 to which the focusing drive coil 4 and the tracking drive coil 3 are fixed is a common continuous arc surface centered on the axis 7, and the coils 4 and 3 are along the arc surface. Is bent and fixed to the lens holder 1.

The shaft 7 is fixed to a boss portion 9a formed by burring at the center of an outer yoke 9 as a fixing member by means of press fitting or adhesion. The outer yoke 9 is formed in a fan shape on both sides of the shaft 7, and the outer peripheral edge portion of the fan shape is bent at a right angle and rises so as to face the coils 4 and 3. Each rising portion of the outer yoke 9 is formed along an arc centered on the shaft 7, and the arc-shaped magnet 6 is fixed to the inner surface of the rising portion. The magnet 6 is integrally molded with, for example, a resin binder. As shown in FIGS. 5 and 7, the magnet 6 has a groove 6c formed in the middle portion in a direction parallel to the shaft 7. The focusing magnet portion is formed with the groove 6c as a boundary.
6a and a tracking magnet portion 6b.
The focusing magnet portion 6a is polarized and magnetized so that the N pole and the S pole are aligned in the axis 7 direction, while the tracking magnet portion 6b is polarized and polarized in a direction orthogonal to the magnetization direction of the focusing magnet portion 6a. By being magnetized, an N pole and an S pole are formed in the circumferential direction. Since the magnet portions 6a and 6b are integrally formed in this manner, they are arranged on a continuous common surface.

As shown in FIG. 6, the first focusing drive coil 4 is formed in a horizontally long rectangle, and its long sides are arranged so as to face the magnetic poles of the focusing magnet portion 6a. Also, the tracking drive coil 3
Is formed in a vertically long rectangle and is arranged such that its long side faces each magnetic pole of the tracking magnet portion 6b.

The inner yoke 5 is superposed on the outer yoke 9 and is fixed based on the outer diameter of the boss portion 9a. Similarly to the outer yoke 9, the inner yoke 5 sandwiches the shaft 7 and is formed into a fan shape on both sides, and the outer peripheral edge portion of the fan shape is bent at a right angle to stand up. The rising portion is formed along an arc centered on the shaft 7. The rising portion penetrates the window hole 1a formed in the lens holder 1 with a spatial margin, and sandwiches the coils 4 and 3 to face the magnet portions 6a and 6b. As described above, from the inside, the inner yoke 5, the drive coils 3 and 4, the magnet 6,
The outer yokes 9 are arranged along arcs centering around the shaft 7, respectively, and a substantially closed magnetic path passing therethrough is formed.

A magnetic piece 10 is fixed to the fan-shaped outer peripheral edge portion of the lens holder 3 at a position facing the center of the magnetic pole of the focusing magnet portion 6a. The magnetic piece 10 is a rectangular member having a narrow width and long in the direction of the shaft 7. As shown in FIGS. 8 and 9, the side in the circumferential direction around the shaft 7 is a short side. The width dimension x is considerably smaller than the dimension of the focusing magnet portion 6a in the circumferential direction, the side in the axis 7 direction is a long side and is oriented in the polarization direction of the magnet 6a, and the length dimension y is Shaft 7 of focusing magnet 6a
It is formed shorter than the dimension in the direction.

Next, the operation of the above embodiment will be described.

Magnetic flux and magnetic piece 10 due to focusing magnet 6a
The relationship with is shown in FIGS. 8 and 9. The focusing magnet portion 6a is polarized and magnetized in the direction of the axis 7
As shown in the figure, in the plane orthogonal to the axis 7, the magnetic flux has a maximum in the circumferential center of the air gap and decreases toward both ends of the air gap.
Since the magnetic pieces 10 are arranged, the magnetic attraction force by the focusing magnet portion 6a acts on the magnetic piece 10, and the restoring force is equal to the elastic restoring force that is trying to be stably held at the maximum point of the magnetic flux. Power acts. This restoring force holds the lens holder 1 at a neutral point in the circumferential direction,
Therefore, the objective lens 2 is held at the neutral point in the tracking direction. The restoring force depends on the gradient of the magnetic flux distribution and the magnetic piece 10.
Proportional to the area of. In the normal moving range of the objective lens 2 in the normal moving range, the magnetic flux gradient changes approximately linearly, so that the restoring force is substantially uniform in the normal moving range of the objective lens 2.

On the other hand, as shown in FIG. 9, in the cross section of the focusing magnet portion 6a in the axis 7 direction, the magnet portion 6a is polarized and magnetized in the axis 7 direction. The gradient of the magnetic flux inside is reversed at the intermediate portion in the vertical direction. Here, the magnetic piece 10 acts as a part of the magnetic path, and the magnetic piece 10 is magnetically attracted to the central portion of the polarized magnetization. This suction force acts as a restoring force, and the lens holder 1 is held at a predetermined position in the axial 7 direction,
The objective lens 2 is held at a neutral point in the focusing direction. Further, as described above, the magnetic piece 10 acts as a magnetic path of the magnetic flux emitted from the magnet portion 6a, so that the magnetic flux density is improved and the sensitivity of the objective lens driving device is improved.
Magnetic restoring force can be stably obtained over a wide range.

The primary resonance frequency f ₀ of the movable part of the objective lens driving device (10th
The restoring force is as important as the spring constant as a parameter for determining (see the figure). Normally, f ₀ is set slightly higher than the rotation frequency of the disc. Optimizing these constants is extremely important for achieving high efficiency and high performance of the objective lens driving device. This applies to both focusing and tracking. The magnetic restoring force described above is obtained by measuring the width x, the length y, and the thickness t of the magnetic piece 10.
By selecting, f ₀ can be optimized in both the focusing direction and the tracking direction.

In the magnetic circuit in a normal objective lens driving device,
The restoring force in the focusing direction shown in the figure is larger than the restoring force in the tracking direction shown in FIG. 8, and the range of the restoring force is wider in the focusing direction. For this reason,
The illustrated embodiment in which the magnetic piece 10 is arranged on the focusing side for sliding the movable part is more rational to the characteristics of the existing disc device such as a compact disc player or a video disc player. However, depending on other special discs, other uses, etc., a magnetic piece may be arranged on the tracking side, that is, the crocodile facing the tracking magnet portion 6b, depending on the requirements of those characteristics. Fourth
Reference numeral 11 in the drawing indicates an example of the magnetic piece when the magnetic piece is arranged on the tracking side.

When a driving current is passed through the focusing driving coil 4, a thrust is generated by the driving current and the magnetic flux in the magnetic circuit, and the objective lens 2 moves together with the lens holder 1 in the optical axis direction of the focusing operation. Done,
When a drive current is passed through the tracking drive coil 3, thrust is generated by the drive current and the magnetic flux in the magnetic circuit, and the objective lens 2 is driven in the tracking direction together with the lens holder 1 to perform the tracking operation. .

In the magnet, the focusing magnet portion and the tracking magnet portion can be integrated into one by molding as in the illustrated embodiment, and the number of parts can be reduced by doing so. Further, since the focusing magnet part and the tracking magnet part can be formed by polarization magnetization in the integrated magnet, the magnetizing cost can be suppressed to a level not much different from the case of the single pole magnetizing. Performance can be improved without increasing.

However, depending on the overall design of the objective lens driving device, the 11th
As shown in the figure, the focusing magnet portion 6a and the tracking magnet portion 6b may be used separately.

In the illustrated embodiment, the magnetic pole pieces are arranged on the outer peripheral surface of the lens holder so as to be surrounded by the drive coil, but they may be embedded in the lens holder. Further, magnetic pieces may be arranged at positions facing both the focusing magnet portion and the tracking magnet portion.

(Effects of the Invention) According to the present invention, a restoring force for holding the objective lens at a neutral point is magnetically obtained, and a leaf spring or molded rubber is not used. The linearity range of the restoring force is wide, and stable follow-up is possible even on a disk with a lot of surface wobbling and eccentricity. Further, since the restoring force can be obtained in two directions of the focusing direction and the tracking direction by one or one set of magnetic pieces, it is possible to provide a compact and lightweight objective lens driving device and to configure it with a small number of parts. It is possible to provide an objective lens driving device that is low in cost and highly reliable. Further, by arranging a rectangular magnetic piece so as to face the center of the magnet where the magnetic flux concentrates, a two-dimensional restoring force is generated and the objective lens is held at a neutral point. A stable restoring force can be obtained.

[Brief description of drawings]

FIG. 1 is a plan view showing an embodiment of an objective lens driving device according to the present invention, FIG. 2 is a vertical sectional view of the same embodiment, and FIG. 3 is a vertical sectional view of an objective lens portion of the same embodiment. FIG. 5 is an enlarged plan view of the magnet and coil portion of the above embodiment, FIG.
FIG. 6 is a front view of the magnet in the above embodiment, FIG. 6 is a front view of the coil in the above embodiment, FIG. 7 is a perspective view of the magnet, and FIG. 8 is a magnetic flux of the magnetic piece portion in the above embodiment. Fig. 9 is a plan view showing the state of Fig. 9, Fig. 9 is a longitudinal sectional view showing the state of the magnetic flux of the magnetic piece, Fig. 10 is a characteristic diagram showing an example of the primary resonance frequency of the movable part, and Fig. 11 is a magnet. It is a perspective view which shows the modification of. 1 ... Lens holder, 2 ... Objective lens, 3, 4 ... Drive coil, 6 ... Magnet, 9 ... Outer yoke as fixing member, 10 ... Magnetic piece

Claims (1)

[Claims] 1. A lens holder by arranging a drive coil in one of a lens holder holding an objective lens and a fixing member, and a magnet in the other, and facing the drive coil with the magnet, and energizing the drive coil. In the objective lens driving device that is driven in the focusing direction and the tracking direction, the magnet is polarized and magnetized in at least one of the focusing direction and the tracking direction, and the magnet including the magnetized in the polarization direction is used. A rectangular magnetic piece is arranged in the circuit so as to face the center of the magnet, and the long side of the rectangular magnetic piece is oriented in the polarization direction of the magnet, and the other short side is It is formed smaller than the width of the magnet, and the focussing force is generated by the magnetic attractive force acting on the magnetic piece. An objective lens driving device characterized in that a two-dimensional restoring force is generated in a tracking direction and a tracking direction to hold the objective lens at a neutral point.