KR20000077373A - optical pickup apparatus - Google Patents

Abstract

In particular, even if a carriage composed of a thin portion such as a metal plate carriage is used, it is possible to provide an optical pickup device without increasing the cost and having good assemblability, and which does not deteriorate performance against impacts during transportation of the optical disk device. Let's make it a task.

In order to solve the above problems, the main shaft 27 is inserted through the openings 21i and 21i, and the first cutout groove 21g is slidably supported by the subshaft 28 so that the carriage 21 is supported. At the same time, the second notch groove 21h is provided at the distal end of the second side wall portion 21e, and a gap is formed between the second notch groove 21h and the subshaft 28, so that the carriage 21 Is regulated so as not to be deformed beyond the gap.

Description

Optical pickup apparatus

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical pickup apparatus used for an optical disc apparatus to record or reproduce an optical disc.

The optical pickup device is mounted on the optical disc apparatus, is supported freely in the radial direction of the optical disc, and enters a laser beam into the information recording surface of the optical disc to record information on the information recording surface or reproduce the recorded information.

11 shows a conventional optical pickup device 50, on a carriage 51 attached to an optical disk device (not shown), a biaxial actuator 52, and a bottom plate portion 51a of the carriage 51. As shown in FIG. It consists of a reflecting mirror 53 which is inclined at approximately 45 degrees and is fixed and fixed, a light transmitting element 55 held in the holder 54, and a cover 56.

The biaxial actuator 52 includes a biaxial base 52a that is a fixed portion, a lens holder 52c that is elastically movable to the biaxial base 52a through a suspension wire 52b, and a lens holder 52c. And an objective lens 52d attached to the tip of the lens), and the carriage 51 is fixed to the carriage 51 by an adhesive S (see FIG. 12).

In the lens holder 52c, a yoke 52e constituting a magnetic circuit together with a magnet (not shown) is integrally formed, and energized by each coil of the coil bobbin 52f wound around the focusing coil and tracking, The magnetic flux generated in each coil interacts with the magnetic flux generated in the magnetic circuit so that the lens holder 52c is driven in the focusing direction and the tracking direction.

On the other hand, the light transmitting element 55 is mainly comprised by the light emitting element which emits a laser beam, and the light receiving element which receives a laser beam. The holder 54 holding the light transmitting element 55 is fixed to the carriage 51 by the adhesive agent T (see FIG. 12). The back of the light transmitting element 55 is provided with a circuit board (not shown) in which electronic components are soldered, and a cover 56 covering the circuit board is provided for protection of the circuit board, electromagnetic shielding, and the like. It is. The circuit board constitutes a circuit for supplying an electric signal to the light transmitting element 55, for driving the light emitting element stably.

The laser light emitted from the light emitting element is bent approximately 90 degrees by the reflecting mirror 53 through the light transmitting surface 55a of the light transmitting element 55 and along the optical axis of the objective lens 52d. Enters into. A focusing operation is performed such that the laser light condensed in the objective lens 52d is focused on the information recording surface of the optical disc, and a tracking operation is performed to follow the information recording track of the optical disc.

The return light reflected from the information recording surface of the optical disc again passes through the objective lens 52d, is bent by 90 degrees by the reflecting mirror 53, and received by the light receiving element in the light transmitting element 55 to obtain a reproduction signal from the optical disc. Can be.

On the other hand, the carriage 51 is formed of a metal plate, and has a substantially rectangular bottom plate portion 51a and first side wall portions 51b opposing each other along the longitudinal edges of the bottom plate portion 51a, respectively. And the second side wall portion 51c. One end of the first side wall portion 51b protrudes from the bottom plate portion 51a, and a cutout groove 51d is formed in the tip portion thereof.

Similarly to the first and second side wall portions 51b and 51c, the third side wall portions 51e and 51e which face each other in the longitudinal direction are formed integrally with the bottom plate portion 51a, respectively. In addition, annular holes 51f and 51f are formed in the third side wall portions 51e and 51e, respectively.

On the other hand, in the optical disk apparatus, the main shaft 57 and the sub shaft 58 are held at predetermined intervals so as to be parallel to each other, and the main shaft 57 is formed in the annular holes 51f and 51f formed in the carriage 51. Is passed through, and the subshaft 58 is slidably supported by the notch groove 51d, so that the optical pickup device 50 is slidably supported along each shaft.

On the other hand, in the conventional optical pick-up apparatus 50 of such a structure, there existed the following problems.

That is, although the conventional low cost metal plate was used, as shown in FIG. 12, the A part, B part, and the notch groove | channel in which the hole 51f, 51f and the main shaft 57 are engaged are engaged. 51d) About the center G of the triangle ABC comprised by the C part which the subshaft 58 engages, the center part of the bottom plate part 51a whose center of the optical pickup apparatus 50 is substantially rectangular ( G '), for example, in the case where an impact is applied during transportation of the optical disk device, the impact acts on the center G', and a torque is generated by misalignment with the center G of the triangle ABC, and the carriage The second side wall portion 51c side, in particular the end portion 51g, of the 51 is greatly deformed, and as a result, the biaxial actuator 52 and the reflecting mirror 53 or the holder 54 which are adhesively fixed to the carriage 51 ) Peels off and strength falls, their position shifts, or the carriage 51 itself The plastic deformation causes the optical axis to be displaced, making recording and reproducing impossible, thereby degrading the performance of the optical pickup device 50.

In order to prevent the above deformation | transformation, the notch groove 51d formed in the front-end | tip of the 1st side wall part 51b in the front-end | tip which extended the edge part 51g of the 2nd side wall-part 51c of the carriage 51, and Although not shown, the method of forming the notch groove 51d and supporting the carriage 51 at four points together with the A, B, and C portions can be considered. However, in this case, the main shaft 57 and the sub If the parallelism of the shafts 58 is maintained with good accuracy, and the respective positions of the annular holes 51f and 51f and the two cutout grooves 51d and 51d are not formed with high precision, between the shafts 57 and 58, respectively. The smooth movement of the carriage 51 cannot be obtained, and therefore, the optical disk device itself has to be designed with high precision, and there is a problem that the cost greatly increases.

Moreover, the pick-up sending mechanism described in JP-A-58-115659 of FIGS. 13A and 13B makes the movable table 102, which is a carriage, by bringing four rotors 101 into contact with each other from the inner side between the rails 100, 100 '. A point of support is provided. In this case, holders 103 and 103 for rotating the rotors 101 and 101 are fixed to the movable table 102 at predetermined intervals on the rail 100 side, and the rotors 101 and 101 are rotatably supported on the rail 100 'side. Since the holders 103 'and 103' are attached to the movable table 102 at predetermined intervals so as to be elastically displaceable in a direction connecting the rails 100 and 100 'to the movable table 102, Even if the parallel between the rails 100 and 100 'is slightly changed, since the change is absorbed by the leaf spring 104, the movable table 102 can be smoothly moved even if it is four points, but the leaf spring 104 and the holder are allowed. In addition to the movable table 102 such as the 103 and 103 'and the holding shaft 105, additional parts are required, and the cost is increased. In addition, it was not considered that the assembly property worsened.

In addition, in the structure shown in Fig. 11, by adopting a metal plate with a thick plate thickness, the strength of the carriage 51 can be increased, but the optical pickup device becomes heavy, so that the movement acceleration is small when the information recording surface of the optical disc is controlled. As the speed is slowed down, it is preferable to use a thin carriage. In addition, when machining a metal plate of a carriage with a thicker plate thickness, a larger press working machine is required, and therefore, there is a problem that the cost of the carriage increases due to the introduction of a large amount of equipment.

On the other hand, when the carriage is formed of alumina diecast or the like, the carriage can be thickened as a whole or in part, so that the carriage can be designed so that the carriage does not plastically deform to an impact of a predetermined strength. However, in recent years, small optical disk devices, such as a portable type, have been proposed, and an optical pickup device mounted thereon is also required to be lighter and shorter in size. In this situation, the carriage is inevitably designed to be thinner. Therefore, the same problem as the above-mentioned metal plate carriage arises even if it is a carry formed from aluminidecast.

In addition, in the case where a small optical disk device is not required, a carriage constituted in whole or in part above is used. Even in this case, a thin carriage is used when the optical disk device is placed under a condition where a strong impact is expected. Finally, the same problem occurs as.

In particular, the present invention does not increase the cost even when using a carriage composed of thin parts such as a metal plate carriage, and has good assembly performance, and an optical pickup in which performance is not deteriorated with respect to impact during transportation of the optical disk device. To provide a device.

1 is a perspective view of an optical pickup device of a first embodiment of the present invention.

2 is a partial side view of the optical pickup apparatus of the first embodiment of the present invention.

3 is a side view for explaining the function of the second notch groove, which relates to the optical pickup apparatus of the first embodiment of the present invention.

Fig. 4 is a partial sectional view for explaining the function of the second notch groove, which relates to the optical pickup device of the first embodiment of the present invention.

5 is a partial perspective view of the optical pickup apparatus of the second embodiment of the present invention.

Fig. 6 relates to the optical pickup device of the second embodiment of the present invention and is a partial side view for explaining the function of the small plate-shaped hole.

7 is a partial perspective view of the optical pickup apparatus of the third embodiment of the present invention.

Fig. 8 relates to the optical pickup device of the third embodiment of the present invention and is a partial side view for explaining the function of a notched groove with a bent piece.

9 is a partial perspective view of the optical pickup apparatus of the fourth embodiment of the present invention.

Fig. 10 is a partial sectional view for explaining the function of the guide member as it relates to the optical pickup apparatus of the fourth embodiment of the present invention.

11 is a perspective view of a conventional optical pickup device.

12 is a plan view of a conventional optical pickup apparatus.

13 is a plan view and a side view for explaining another conventional pickup transmitter mechanism.

* Description of the symbols for the main parts of the drawings *

20: optical pickup device 21: carriage

21h: 2nd notch groove 22: biaxial actuator

22a: objective lens 23: collimator lens

24: reflective mirror 25: light transmission element

26: holder 27: main shaft

28: subshaft

As a first solution for solving the above problems, one end of the carriage is supported along the longitudinal direction of the first shaft so as to be slidable at least at two locations on the first shaft, and at the other end, the first shaft and The support part slidably supported by the 2nd shaft arrange | positioned in substantially parallel, and the control part provided in parallel with the said support part in the longitudinal direction of the said 2nd shaft, and are prescribed | regulated between the said control part and the said 2nd shaft When the clearance is provided, and the carriage is displaced, the displacement is restricted by contacting the restricting portion with the second shaft.

In addition, as a second solution, the first shaft is inserted through a through hole provided in the carriage so that side walls are opposed to the longitudinal directions of the first and second shafts, and are provided at one end of the both side wall portions. And the supporting portion and the restricting portion are respectively provided at the other ends of the both side wall portions.

Further, as a third solution means, the carriage is made of a metal plate, and the two side wall portions are a pair of side wall portions bent a portion of the carriage.

Further, as a fourth solution, the support portion and the restricting portion are cutout grooves in which a part of the side wall portion is cut out.

(Example)

An optical pickup apparatus according to an embodiment of the present invention will be described below with reference to the drawings of FIGS. 1 to 10.

1 is a perspective view of an optical pickup device 20 which is a first embodiment of the present invention. The optical pickup device 20 includes a biaxial actuator 22 having a carriage 21 made of a metal plate formed by press working, an objective lens 22a attached and fixed to the carriage 21, and an objective lens 22a. ) And the light transmitting element 25 and the light transmitting element 25 which emit a laser beam through the collimator lens 23 and the reflection mirror 24 and inject the return light from the objective lens 22a. The holder 26 is comprised.

The carriage 21 has a substantially rectangular shape bottom plate portion 21c having a part of the curved portion 21a and the protrusion portion 21b, and a first first surface of the bottom plate portion 21c facing each other along the longitudinal edges thereof. It is comprised by the side wall part 21d, the 2nd side wall part 21e, and the 3rd side wall part 21f which penetrated along the longitudinal direction of the bottom plate part 21c from the said projection part 21b. One end of the first and second side wall portions 21d and 21e protrudes from the bottom plate portion 21c, and the first cutout groove 21g serving as the support portion and the second cutout groove 21h serving as the restricting portion are respectively at the front end thereof. ) Is formed.

In addition, through-holes 21i and 21i are formed in the end portion on the opposite side to the one end where the first cutout groove 21g in the first sidewall portion 21d is formed and in the third sidewall portion 21f, respectively. .

Next, the substantially rectangular opening part 21j is formed in the substantially center part of the bottom plate part 21c, and a pair of protrusion formation part is formed in the edge part of the longitudinal direction with respect to the bottom plate part 21c of this opening part 21j. It is formed by arranging (21k, 21k) oppositely. Side walls 211 and 211 are provided on opposing surfaces of the protrusion forming portions 21k and 21k.

On the other hand, the first bent piece 21m is placed adjacent to the curved portion 21a of the bottom plate portion 21c. Moreover, the substantially triangular protrusion part 21n is provided in the upper end part of the 1st side wall part 21d, and the protrusion part 21n is comprised by the 2nd bending piece 21o and the support piece 21p. Further, the second bent piece 21o is substantially symmetrically arranged with respect to the straight line in the longitudinal direction passing through the center of the first bent piece 21m and the objective lens 22a.

Moreover, in the bottom plate part 21c, a pair of 3rd bend pieces 21q and 21q which entered the edge part of the longitudinal direction opposite to the annular hole 21i, 21i along the direction orthogonal to a longitudinal direction is predetermined | prescribed It is formed at intervals of.

Next, the collimator lens 23 is a lens for making the exit angle of the laser light emitted from the light transmitting element 25 to be substantially parallel light, and between the side wall surfaces 211 and 211 provided in the protrusion forming portions 21k and 21k. It is fixed using the adhesive attached to a predetermined position.

On the other hand, the reflection mirror 24 reflects the laser light incident on the mirror surface 24a through the collimator lens 23 from the light transmitting element 25 in the optical axis direction of the objective lens 22a. . The reflecting mirror 24 is attached at an angle of approximately 45 degrees with respect to the bottom plate portion 21c, and is attached between the side wall surfaces 211 and 211 of the protrusion forming portions 21k and 21k and fixed using an adhesive.

Next, the light transmitting element 25 is provided with a main body 25a and a stem portion 25b of a blade shape integrally assembled with the main body 25a, and inside the main body 25a. A light emitting element such as a laser diode (not shown) and a light receiving element such as a port diode are mainly housed. Further, a plurality of terminals 25c of the light emitting element and the light receiving element protrude outward (in the front direction in Fig. 1) on the rear portion of the stem portion 25b.

An optical element 25d for transmitting the laser light emitted from the light emitting element to guide the return light from the optical disk to the light receiving element is fixed to the front surface of the main body 25a by an adhesive. And the light transmission element 25 is hold | maintained in the holder 26 by press-fitting into the through-hole of the same shape as the said stem part 25b which the stem part 25b attached to the holder 26 has. The left and right both ends 26a and 26a of the holder 26 are provided at predetermined intervals at respective opposing surfaces with the third bent pieces 21q and 21q placed in the carriage 21, and are bonded or soldered to each other. It is fixed.

Next, the biaxial actuator 22 has a biaxial base 22b, an attachment portion 22c fixed to the biaxial base 22b, and one end of four suspension wires 22d at this attachment portion 22c. A lens holder 22e having an objective lens 22a and a yoke 22f integrated with the lens holder 22e is composed of a lens holder 22e which is fixed, and one end is fixed and held with plasticity.

The biaxial base 22b is provided with a pair of mounting pieces 22g and 22g which are placed substantially symmetrically. The biaxial actuator 22 is placed on the carriage 21 so that the attachment pieces 22g and 22g face the first and second bent pieces 21m and 21o formed on the carriage 21 through predetermined gaps, respectively. In this state, it is fixed by adhesive or soldering.

The optical pickup device 20 described above includes a first shaft, that is, a main shaft 27, in the annular holes 21i and 21i formed in the third sidewall portion 21f and the first sidewall portion 21d of the carriage 21, respectively. Is inserted, and the first notch 21g provided on the side opposite to the opening 21i of the first side wall portion 21d is slidably supported by the second shaft, i.e., the subshaft 28, It is slidably supported along the shafts 27 and 28.

Moreover, in the 2nd notch groove 21h provided in the edge part of the 2nd side wall part 21e, as shown in FIG. 2 which is a partial side view seen from the direction 2 in FIG. 1, the subshaft 28 and the 2nd The gaps d and d are provided between the upper end 29 and the lower end 30 of the notch groove 21h. As a result, even when an impact is applied to the optical disk device and the second side wall portion 21e is deformed to the upper side 31 or the lower side 32 as shown in B as shown in FIG. 3A, the maximum displacement amount is d and the carriage ( 21 is not plastically deformed, and the biaxial actuator 22 and the holder 26 or the reflection mirror 24 holding the transmissive light emitting element 25 fixed to the carriage 21 are peeled off. It does not lose or shift the position, that is, the performance of the optical pickup device 20 does not deteriorate.

Moreover, since the 2nd notch 21h can be formed simultaneously in the press work of the carriage 21, the cost of a component does not increase. When the optical disc apparatus is assembled, the sub shaft 28 supports the first and second cutout grooves 21g and 21h having a shape open at the end, even when the sub shaft 28 is held in the optical disc apparatus. Since it can be made, assembly property becomes favorable.

In the embodiment of the present invention, the gap d is set to about 0.2 mm. However, the gap d is not limited to this, and may be set within a range in which the performance of the optical pickup device does not deteriorate.

In the embodiment of the present invention, the optical pickup device 20 is provided with the main shaft 27 and the sub shaft 28 so that the optical axis of the laser beam emitted from the objective lens 22a is substantially perpendicular to the information recording surface of the optical disk. ), The angle adjustment (SKEW adjustment) is performed in the radial direction RAD and the tangential direction TAN of the optical disc shown in FIG. And after adjustment, as shown in FIG. 4 which is 4-4 sectional drawing of FIG. 1, in the state in which the subshaft 28 is parallel with the main shaft 27, it is perpendicular to the bottom plate part 21c of the carriage 21. Although the inclination may be inclined up to ± θ (≒ 0.5 degrees), the gap d is set so that the performance of the optical pickup device 20 does not deteriorate against the impact on the optical disk device.

FIG. 5: shows a 2nd Embodiment of this invention, and is a partial perspective view which shows the mode which replaced the 2nd notch 21h in FIG. 1 with the small plate-shaped hole 33. As shown in FIG.

FIG. 6 is a partial side view seen from the direction 6 in FIG. 5, and similarly to the first embodiment, each of the subshaft 28 and the upper end 34 and the lower end 35 of the small plate-shaped hole 33 is shown in FIG. 6. The gap (d, d) is provided in between.

By doing in this way, the same effect as that of the first embodiment can be obtained, and since the tip of the second side wall surface 21e is not cut off as in the first embodiment, even when a strong impact is applied, the tip is fired. With respect to deformation, there is an effect that the strength is further improved.

FIG. 7: is a partial perspective view which shows 3rd Embodiment of this invention and shows the state which substituted the 2nd notch groove 21h of FIG. 1 by the notch with the bending piece 36. FIG. The bent pieces 37 and 38 are placed so that the second side wall surface 21e is substantially 90 degrees along the upper end 29 and the lower end 30 of the second notched groove 21h shown in FIG. 2.

FIG. 8 is a partial side view seen from the direction 8 in FIG. 7, and similarly to the first and second embodiments, the subshaft 28, the upper end face 39 of the bent piece attaching notch 36, and The gaps d and d are provided between each of the lower surfaces 40.

Also in this case, the same effect as that of the first embodiment can be obtained, and when the impact is applied, the upper end face 39 and the lower end face 40 serving as the contact portion with the subshaft 28 are flat, As compared with the case where the edge of the metal plate is taken in as in the first and second embodiments, there is an effect that it is less likely to damage the surface of the subshaft 28.

Fig. 9 shows a fourth embodiment of the present invention and removes the first and second notch grooves 21g and 21h of Fig. 1, and removes the c-shaped guide member 41 from the bent pieces 41a and 41b. ) Is a partial perspective view showing a state in which the carriage 21 is fixed to the carriage 21 so as to be integral with the first and second side wall portions 21d and 21e of the carriage 21, respectively. And the guide member 41 is fixed with respect to the carriage 21 by methods, such as screwing, adhesion | attachment, soldering, and the like. A portion of the carriage 21 may be formed on the guide member 41.

The second section is similarly arranged so that the first and second ribs 44 and 44 having the function of the second notch 21g shown in FIG. 1 face the bent pieces 42 and 43 above and below the guide member 41. The second ribs 45 and 45 having the function of the groove 21h are formed to face each other.

FIG. 10: shows 10-10 sectional drawing in FIG. 9, and the subshaft 28 is slidably supported. In addition, as in the first to third embodiments, between the subshaft 28 and the upper surface 47 and the lower surface 48 of the second ribs 45 and 45, the gap d, d ) Is being installed.

In this case as well, the same effects as in the first embodiment can be obtained, and the first ribs 44 and 44 and the second ribs 45 and 45 can be processed on the same bent pieces 42 and 43. The position between the center between the sliding surfaces 46 and 46 of the first ribs 44 and 44 and the center between the upper surface 47 and the lower surface 48 of the second ribs 45 and 45 This has the effect of improving the accuracy of the alignment.

As mentioned above, although the case of the carriage of a metal plate was demonstrated in the 1st thru | or 4th embodiment of this invention, it is not limited to this, Even in the case of the carriage formed by die-casting and mold etc. of aluminum die-casting, this invention Can be applied.

In the optical pickup device 20 of the present invention, the laser light emitted from the light emitting element in the light transmitting element 25 is reflected by the mirror surface 24a of the reflecting mirror 24 through the collimator lens 23 and is perpendicular to each other. Is bent to enter the objective lens 22a.

The laser light emitted from the objective lens 22a condenses on the information recording surface of the optical disk and reflects the return light reflected on the information recording surface in accordance with the information through the same optical path. Enters into.

The information on the information recording surface of the optical disc can be read by converting the electric signal into a necessary electric signal in response to the light amount of the return light.

In addition, following the information recording surface of the optical disc, the carriage 21 of the optical pickup device 20 performs a controlled movement along each shaft 27, 28 of the optical disc apparatus.

As described above, according to the present invention, one end of the carriage is supported along the longitudinal direction of the first shaft so as to be slidable at least at two locations on the first shaft, and the other end is substantially parallel to the first shaft. The support part slidably supported by the 2nd shaft arrange | positioned and the control part provided with the said support part in the longitudinal direction of the said 2nd shaft are provided, and the predetermined clearance gap is provided between the said control part and the said 2nd shaft. When the carriage is displaced, the displacement is regulated by contacting the restricting portion with the second shaft, so that the restricting portion deforms the carriage having the predetermined gap or more against an impact during transportation to the optical disc device. In order to prevent this, the performance of the optical pickup apparatus can be prevented from deteriorating.

Moreover, the side wall part is provided in the carriage so that it may oppose the longitudinal direction of a 1st and 2nd shaft, the 1st shaft will be inserted through the through-hole provided in the said both side wall parts, and the support part and the restriction | limiting will be in the other end of the said both side wall parts. By providing the respective portions, even when the carriage composed of the thin portion is used, the performance of the optical pickup apparatus can be prevented from deteriorating against impact.

In addition, the carriage is made of a metal plate, and since both side wall portions are a pair of side wall portions bent by a part of the carriage, the support portion and the restricting portion can be processed simultaneously with the processing of the carriage. It is possible to prevent the performance of the optical pickup apparatus from deteriorating against impact.

In addition, the support portion and the restricting portion are cutout grooves in which a part of the side wall portion is cut out, and at the time of assembling the optical disk device, the second shaft can support the cutout groove even when the second shaft is held in the optical disk device. It can be made favorable.

Claims (4)

One end of the carriage is supported along the longitudinal direction of the first shaft so as to be slidable at least at two locations on the first shaft, and the other end is slidable to a second shaft disposed substantially parallel to the first shaft. The support portion and the support portion supported in the longitudinal direction of the second shaft, and a predetermined gap are formed between the control portion and the second shaft, and the carriage is displaced. And the displacement is regulated by contacting the restricting portion with the second shaft. The said 1st shaft is inserted through the through-hole provided in the said carriage by the side wall part facing the longitudinal direction of the said 1st and 2nd shaft, and formed in the one end part of the said both side wall part, And the support portion and the restricting portion are respectively provided at the other ends of both side wall portions. The optical pickup apparatus of claim 2, wherein the carriage is made of a metal plate, and the side wall portions are a pair of side wall portions bent a portion of the carriage. The optical pickup apparatus of claim 3, wherein the support portion and the restricting portion are cutout grooves in which a part of the sidewall portion is cut out.