JPH04209333A - Light pickup - Google Patents

Abstract

PURPOSE:To improve reliability by making both edge parts of a flexible substrate for a plane perpendicular to the direction of focus, its central part for a plane perpendicular to the direction of tracking, and making effective length of flexibility in the focal direction equal to the effective length of suspension. CONSTITUTION:Information on a recording surface is read by a pick up. At this time, laser beam from a light emitting part 16b is reflected on a surface of a mirror 16c and condensed to a disk D by an objective lens 16d. This reflected beam is reflected inside a mirror 16c through a lens 16d and made incident in a light receiving part 16e. With that output, pickup and tracking are carried out. Because both edge parts of the flexible wiring plate 17 are planes 17g which are perpendicular to the focal direction, and the central part is the plane 17h perpendicular to the direction of tracking, the effective length in the focal direction is made approximately equivalent to the effective length of suspension, and inclination of a holder 16 is prevented even when there is a variation in the focal direction.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an optical pickup for reproducing information recorded on a disk.

(Prior Art) Optical pickups reproduce information recorded on compact discs (CDs) and laser discs (LDs), and generate signals, focus error signals, and tracking error signals for reproducing the information. It has the function of In recent years, as shown in the specification of Utility Model Application No. 1-52593 filed by the present applicant, optical pickups with lower costs and smaller sizes are being developed. FIG. 10 shows an example of such an optical pickup, which includes a holder 1 containing a light source and an objective lens, a light receiving element for receiving a reflected beam from a disk, and the like. A focus coil 2 and a tracking coil (not shown) are arranged on opposing surfaces of the holder 1, respectively. These focus coil 2 and tracking coil are arranged in a magnetic circuit formed by a yoke 4 to which a magnet 3 is attached. The holder 1 is supported in a cantilever manner by a suspension spring 5 attached to a fixed plate 6. One end of a flexible wiring board 7 is attached to the side surface of the holder 1. The pattern is connected to each element such as a holder in the holder 1. A relay board 8 attached to the yoke 4 is attached to the other end of the flexible wiring board 7 . The flexible wiring board 7 is curved near its center. In an optical pickup with this configuration,
An excitation current is supplied to the focus coil 2 and the tracking coil through each suspension spring 5, thereby performing focusing and tracking. On the other hand, in the flexible wiring board 7, reading signals and the like are exchanged with the light source and the light receiving element in the holder 1.

(Problems to be Solved by the Invention) In the above-described conventional optical pickup, when the holder 1 moves in the focusing direction, especially when focusing, twisting occurs near the center of the flexible wiring board 7. When such twisting occurs, a restoring force acts on the flexible wiring board 7 itself, causing the holder 1 to be tilted clockwise. In this way, if the holder 1 is tilted clockwise, it becomes difficult to obtain accurate focus. It becomes a hindrance. The present invention was made in response to such circumstances, and an object of the present invention is to provide an optical pickup that can improve reliability.

(Means for Solving the Problems) In order to achieve the above object, the optical pickup of the present invention includes a suspension base disposed on the upper surface of the yoke base, and a suspension base sandwiched between coil substrates via a wire spring. In an optical pickup in which a holder is supported on a cantilever, a flexible wiring board is interposed between the suspension base and the holder, and an end of the flexible wiring board is connected to a relay board, the focus direction of the flexible wiring board is The flexible effective length is approximately equal to the suspension effective length, and both ends thereof are perpendicular to the focusing direction, and the center thereof is a surface perpendicular to the tracking direction.

(Function) In the optical pickup of the present invention, when the pickup is focused, the flexible effective length in the focusing direction is approximately equal to the suspension effective length, and the holder is prevented from tilting even if it is displaced in the focusing direction. Further, in the tracking direction, the movable range is, for example, about 1/3 to 115 times that in the focus direction, so even if the effective length is short, there is no significant influence. Therefore, it is possible to avoid adverse effects caused by the flexible wiring board in the focusing direction and the tracking direction.

(Example) Hereinafter, details of an example of the present invention will be described based on the drawings. 1 and 2 show one implementation of the optical pickup of the present invention. As shown in these figures, the optical pickup is equipped with a yoke base 10 having a mounting piece 10b in which a screw insertion hole 10a is formed.

Further, the yoke base 10 is formed with a screw insertion hole 10c. Further, the yoke base 10 is provided with yoke parts 11.11 arranged opposite to each other, and a magnet 12 is attached to each yoke part 11. A suspension base 13 is arranged on the upper surface of the yoke base 10. Here, the suspension base 13 is attached to the yoke base 10 by screws 13b inserted into screw insertion holes 13a of the suspension base 13.
This is done by screwing the end of the yoke into the screw insertion hole 10c of the yoke base 10. The suspension base 13 has metal wire springs 14, 14 . A holder 16 sandwiched between the coil substrates 15a and 15b is supported in a cantilever manner. Inside the holder 16, a light emitting section 16b, an objective lens 16d, a light receiving section 16e, etc. are housed, as will be described later. In addition, each coil board 15a, 15b
Excitation coils 15x and 15y, which will be described later, are arranged in a flat manner. Further, a flexible wiring board 17 is interposed between the suspension base 13 and the holder 16, and the end thereof is connected to a relay board 18. The relay board 18 is provided with a mounting piece 18b having a screw insertion hole 18a. Here, the relay board 18 is attached to the yoke base 10 by screwing the end of a screw (not shown) inserted into the screw insertion hole 10a of the mounting piece 10b into the screw insertion hole 18a of the mounting piece 18b. This is done by Excitation current is supplied to each coil substrate 15a, 15b via each wire spring 14. Further, read signals etc. from the holder 16 are input/output via a flexible wiring board 17. Here, the suspension base 13 is made of resin. Further, a copper alloy terminal 13e is press-fitted or insert-molded into the suspension base 13, and one end thereof is connected to each wire spring 14, and the other end is connected to a terminal portion 18e of the relay board 18. ing. Moreover, each coil board 15a.

15b is a plurality of patterned excitation coils 15a, 15b stacked as shown in FIGS. 3 and 4, and each excitation coil 15x, 15y is used for focus drive or tracking drive. There is.

Furthermore, each coil board 15a, 15b has an excitation coil 15.
They share arbitrary layers x and 15y and are connected via a flexible relay member 15c. As a result, the number of parts of each coil board 15a, 15b can be significantly reduced, soldering can be made unnecessary, and the dimensions can also be reduced. In addition, the coil board 1
5a is provided with lands 15e for soldering the ends of the wire spring 14, as shown in FIGS. 5 and 6, and the ends are fixed to these lands 15e via solder. ing. In this way, a plurality of lands 15e
By soldering the end of the wire spring 14 to the wire spring 14, the soldering area of the end is expanded, so that the fixation becomes reliable. Furthermore, as shown in Fig. 7, each land 1
5e may be connected within the through hole 15f, and the end of each wire spring 14 may be soldered to each land 15e in the same manner as described above. In this case, even if a soldering defect occurs, each land 15e is connected within the through hole 15f, so by soldering to any one land 15e, the continuity is ensured. Become something. FIG. 8 shows the above-mentioned holder 16. Inside the body 16a, a light emitting part 16b that emits a laser beam,
A mirror 16c that reflects the laser beam toward the disk D side, and an objective lens 16d that focuses the reflected light onto the disk D.
, a light receiving section 16e that receives reflected light from the disk D is housed. The laser beam from the light emitting section 16b is reflected by the surface of the mirror 16c, and then focused onto the disk D by the objective lens 16d. The reflected light from the Deinuk D passes through the objective lens lad, is reflected by the inside of the mirror 16c, and is guided to the light receiving section 16e. FIG. 9 shows the flexible wiring board 17 described above. As shown in the figure, a flexible wiring board 17
has both ends thereof as a surface 17g perpendicular to the focusing direction, and a central portion thereof as a surface 17h perpendicular to the tracking direction. Thereby, the flexible effective length in the focus direction becomes approximately equal to the suspension effective length, and the holder 16 is prevented from tilting even if it is displaced in the focus direction.

Further, in the tracking direction, the movable range is about ⅓ to 115 times smaller than that in the focus direction, so even if the effective length is short, there is no significant influence. Next, the operation of the pickup configured as described above will be explained. First, after the pickup is moved in the radial direction of the disk D by a drive mechanism (not shown), information on the recording surface is read. At this time, the laser beam from the light emitting section 16b is reflected by the surface of the mirror 16c and focused onto the disk D by the objective lens 16d. The reflected light from the disk D passes through the objective lens 16d, is reflected by the inside of the mirror 16c, and is guided to the light receiving section 16e. Focusing and tracking of the pickup are then performed based on the reflected light from the disk D that is guided to the light receiving section 16e. At this time, when the pickup is focused, the flexible effective length in the focusing direction is approximately equal to the suspension effective length, and the holder 16 is prevented from tilting even if it is displaced in the focusing direction. Further, in the tracking direction, the movable range is about ⅓ to 115 times smaller than that in the focus direction, so even if the effective length is short, there is no significant influence. As described above, in this embodiment, both ends of the flexible substrate are made into surfaces perpendicular to the focus direction, the central part thereof is made into a surface perpendicular to the tracking direction, and the effective length of the flexible substrate in the focus direction is approximately equal to the effective length of the suspension. I made it so. Therefore, even if the holder is displaced in the focus direction, the holder is prevented from tilting. Also, in the tracking direction,
Since the movable range is approximately 1/3 to 115 times that of the focus direction, even if the effective length is short, there is no significant effect. In addition, in this embodiment, the suspension base is formed of resin, and a terminal made of copper alloy is press-fitted or insert-molded into the suspension base, one end of which is connected to each wire spring, and the other end is connected to the terminal part of the relay board. Since the number of parts is significantly reduced, the number of parts and the assembly work are also significantly reduced.

(Effects of the Invention) As explained above, according to the optical pickup of the present invention, the flexible effective length in the focus direction is approximately equal to the suspension effective length, and the holder is prevented from tilting even when displaced in the focus direction. . Further, in the tracking direction, the movable range is, for example, about 1/3 to 115 times that in the focus direction, so even if the effective length is short, there is no significant influence. Therefore, the adverse effects caused by the flexible substrate in the focusing direction and the tracking direction are avoided, so that reliability can be improved.

[Brief explanation of the drawing]

1 and 2 are perspective views showing one embodiment of the optical pickup of the present invention, FIG. 3 is a plan view showing a coil board of the optical pickup, and FIG. 4 is a side view showing the coil board, and FIG. 5 to 7 are enlarged views showing the lands provided on the coil substrates in FIGS. 3 and 4, and FIG.
Figure 9 shows the holder of the optical pickup in Figures and Figure 2.
The figure shows a folded state of the printed wiring board of FIGS. 1 and 2, and FIG. 10 is a configuration diagram showing an example of a conventional optical pickup. 10... Yoke base, 12... Magnet, 13
... Suspension base, 14... Wire spring,
15a, 15b...Coil board, 16...Holder,
17... Flexible wiring board, 18... Relay board.

[Figure 9]

Claims (1)

[Claims] (1) A suspension base is arranged on the upper surface of the yoke base, a holder sandwiched between coil boards is cantilever-supported on this suspension base via a wire spring, and a flexible wiring board is interposed between the suspension base and the holder. In this optical pickup in which the ends of the flexible wiring board are connected to the relay board, the flexible effective length of the flexible wiring board in the focusing direction is approximately equal to the suspension effective length, and both ends thereof are set in the focusing direction. An optical pickup characterized in that the surface is vertical, and the center thereof is perpendicular to the tracking direction.