JPS63279437A - Component assembling structure for optical head - Google Patents

Abstract

PURPOSE:To insert and fix a thin late like optical components on a mounting face with one touch without a deformation by forming a leaf spring assembly in which the thin plate like optical components is previously inserted to the leaf spring and directly inserting the spring into a case. CONSTITUTION:The mounting face is provided on the case, the thin plate form optical parts 8 is pinched by the leaf spring 20 to have the leaf spring assembly 100, the leaf spring assembly is inserted into the case, the thin plate like optical components 8 is brought into contact with the mounting surface and under the inserting state, the operating force of the leaf spring 20 for pressing the thin plate like optical component 8 to the mounting face is operated in an area surface brought into contact with the mounting face of the thin plate like optical components 8. Thereby, at the time of mounting and fixing the thin plate like optical components 8 on the case, it is not required to hold the thin plate like optical components so as not to be collapsed and the deformation of the thin plate like optical components due to the operating force can be suppressed to a minimum.

Description

[Detailed Description of the Invention] [Industrial Application Field] This invention relates to an optical head, that is, an optical information recording/reproducing pickup and a structure for assembling thin plate-like optical components such as mirrors mounted on the optical information reproducing pickup. It is something.

[Conventional technology]

Conventionally, for optical heads, for example, Japanese Patent Application Laid-Open No. 58-2
As described in Publication No. 15739, a semiconductor laser, a detector, and a plurality of optical components are mounted in the case.
The optical parts are composed of rectangular columnar optical parts as shown in FIG. 14, prisms made of triangular prism-like optical parts as shown in FIG. 15, mirrors, lenses made of cylindrical optical parts, and the like.

However, when rectangular columnar optical components and triangular columnar optical components are used as prisms and mirrors, the optical components become expensive, so they are being replaced by inexpensive thin plate-shaped optical components.

FIG. 16 is a perspective view showing a conventional optical head using a thin plate-like optical component. In the figure, 1 is a case, 30~
32 is a concave groove provided in the case 1; 2 is a semiconductor laser attached to the case 1; 6 is an objective lens actuator 6 attached to the case 1; 6-1 is an objective lens built into the objective lens actuator 6; 3 to 5 are optical components provided between the semiconductor laser 2 and the objective lens 6-1, and 4 is a beam splitter. 10.11 is a pair of detectors attached to the case 1, 7 to 9 are optical components provided between the objective lens 6-1 and the detector 10.11, and 8 is a corner mirror 19 which is a beam splitter. , the beam splitter 4, and the corner mirror 8 are composed of thin plate-like optical components. 12 is a disk,
12-1 is the recording surface of the disk 12, 12-3 is the recording surface 1
2-1 information track, 12-2 information track 12-
This is a bit provided in S.

In this optical head, a laser beam emitted from a semiconductor laser 2 is reflected by a beam splitter 4, enters an objective lens 6-1, and enters a recording surface 12-of a rotating disk 12.
1. Then, the reflected light from the disk 12 passes through the objective lens 6-1 and the beam splitter 4, and the transmitted light is reflected by the corner mirror 8, split by the beam splitter 9, and enters the detector 10.11. .

[Problem that the invention seeks to solve]

However, in such an optical head, when the beam splitter 4 and the corner mirror 8, which are made of thin plate-like optical components, are fixed to the case 1, the beam splitter 4 and the corner mirror 8 are easily deformed, and this deformation may occur. Yosi beam splitter 4. Since distortion occurs in the wavefront of the reflected light and transmitted light from the corner mirror 8, the characteristics deteriorate. In addition, since the beam splitter 4 and the corner mirror 8 are easy to fall down, the beam splitter 4 and the corner mirror 8 are glued to the case 1.
Before fixing the beam splitter 4 and the corner mirror 8 with a means such as a leaf spring, use a jig to hold the beam splitter 4 and the corner mirror 8 pressed against the mounting surface of the case 1 so that the beam splitter 4 and the corner mirror 8 do not fall down. I must stand.

This invention was made to solve the above-mentioned problems, and is an optical component of an optical head that can be inserted and fixed onto the mounting surface of a case with a single touch without deforming the thin plate-shaped optical component. The purpose is to provide an assembly structure.

[Failure to solve the problem]

In order to achieve this object, the present invention provides an optical component assembly structure for an optical head in which a thin plate-shaped optical component is attached to a case, in which a mounting surface is provided in the case, and the thin plate-shaped optical component is attached to a plate spring. Clamp them together to form a leaf spring assembly.
The plate spring assembly is inserted into the case, the thin plate optical component is brought into surface contact with the mounting surface, and the thin plate optical component is inserted into the case. The force of the leaf spring that suppresses the force on the mounting surface is made to act in a region of the thin plate-shaped optical component that is in surface contact with the mounting surface.

[Effect]

In the optical component assembly structure of this optical head, the thin plate-shaped optical component and the leaf spring can be handled as one body, so when mounting and fixing the thin plate-shaped optical component in the case, the thin plate-shaped optical component There is no need to hold the plate spring assembly so that it does not fall over, and when the plate spring assembly is inserted into the case, the force of the plate spring acts within the area that is in surface contact with the mounting surface of the thin plate optical component. It is possible to minimize deformation of the thin plate-like optical component due to acting force.

〔Example〕

1 is a perspective view showing a leaf spring used in the optical component assembly structure of an optical head according to the present invention; FIG. 2 is a perspective view showing a corner mirror attached to the leaf spring shown in FIG. 1; FIG. 3 is a sectional view taken along plane A in FIG. 2. In the figure, 20 is a leaf spring, 27 is a large rectangular window in the center of the leaf spring 20, and 25 is a leaf spring 20.
The upper element, 28 is the lower floor of the leaf spring 20, 41 and 42 are the side elements of the leaf spring 20, and 43 and 44 are the side elements 41 and 42.
26-1, 26-2 are side elements, 4
Taper provided at the bottom of 1°42, 21-1 to 21-
4 is a claw spring provided on the side elements 41 and 42, 22-1
~22-4 are right angle elements of claw springs 21-1 to 21-4,
The right angle elements 22-1.22-2 are arranged in the same plane, the right angle elements 22-3.22-4 are arranged in the same plane, and the right angle elements 22-1.22-2 and the right angle elements 2
2-5 and 22-4 is smaller than the width L1 of the corner mirror 8. 23-1 to 23-4 are parallel elements of the claw springs 21-1 to 21-4;
23-4 are arranged in the same plane. 24-1～
Reference numeral 24-4 denotes protrusions provided on the parallel elements 25-1 to 23-4, and the protrusions 24-1 to 24-4 protrude by a distance Δ on the mounting side of the corner mirror 8. And Konami 2-
The thickness of the corner mirror 8 is usually 2 tm or less, and a thin film of several μm or less is formed on the surface of the corner mirror 8 to improve reflection efficiency. The leaf spring assembly 100 is inserted into the window 27.
The sides 8-4 and 8- of the corner mirror 8
5 is in contact with the right angle elements 22-1 to 22-4, the back surface 8-2 of the corner mirror 8 is in contact with the projections 24-1 to 24-4, and the upper surface 8-3 of the corner mirror 8 is in contact with the upper element 25. Bottom surface 25
-1, and the reflective surface 8-1 of the corner mirror 8 protrudes from the leaf spring 20 by Δ2.

FIG. 4 is a plan view showing a case used in the optical component assembly structure of the optical head using the plate spring shown in FIG. 1, and FIG. 5 is a second view of the case shown in FIG. 4.

FIG. 3 is a plan view showing the assembled state of the leaf spring assembly, FIG. 6 is a sectional view taken along line BB in FIG. 4, FIG. 7 is a sectional view taken along line C-C in FIG. 5, and FIG. is a sectional view taken along line DD in FIG. 5. In the figure, 50.60 is a slot provided in the case 1, 55 is a mounting surface provided in the slot 50, and if the intersection of optical axis m-m and optical axis P-P is 0, the mounting surface The virtual plane r-r including 55 includes the intersection O. Further, when a normal line N-N is drawn from the intersection O on the virtual plane r-r, both the optical axis P-P and the optical axis m-m are at an angle θ from the normal line N=N. The mounting surfaces 55 are arranged at the same angle.

In this example, the angle between the optical axis m-m and the optical axis pp is set to be a right angle, and in that case, the mounting surface 55 is aligned with the optical axis m-p.
m and is tilted 45° from the optical axis P-P. 52.53
are a pair of hillocks provided in the slot 50, 53-1 is a parallel portion of the hillock 53, and the parallel portion 53-1 rises parallel to the mounting surface 55 from the bottom surface 54 of the slot 50 to point E. Oh dear,
With the leaf spring assembly 100 in contact with the bottom surface 54 of the slot 50, the protrusion 43 is located below point E, and the parallel portion 5
It is in contact with 3-1. 53-2 is a tapered portion of the hillock 53, and the tapered portion 53-2 is formed in a tapered shape in the direction in which the slot 50 widens as it goes upward from point E, and the hillock 52 has the same shape as the hillock 53. doing.

With the leaf spring assembly 100 inserted into the slot 5o, the reflective surface 8-1 of the corner mirror 8 is in surface contact with the mounting surface 55 of the slot 50, and the reflective surface 8-1 of the corner mirror 8 is in surface contact with the mounting surface 55 of the slot 50. 1 and the mounting surface 55 are in contact on both sides in the width direction, and the contact width is L6. L, in this example, the contact width L6 and the contact width L7 are the same size, and are given an appropriate value between 4 and 10I111I, but the contact width L6 and the contact width L7 are set to different dimensions. , it is also of course possible to set the contact widths L6 to L7 to values other than the above-mentioned dimensions. In addition, the protrusion 24 is used as a force to press the corner mirror 8 against the mounting surface 55.
-1 to 24-4 acting force F perpendicular to the mounting surface 55,
~F4 acts on the corner mirror 8, acting force F, ~F
4 is the width dimension L6 of the portion where the reflective surface 18-1 of the corner mirror 8 is in contact with the mounting surface 55. The acting force F, ~F4 is a value that does not cause the corner mirror 8 to separate from the mounting surface 55 and does not affect the characteristic surface due to the deformation of the corner mirror 8, for example. α5~2
．． It is set to 0 and 9f. However, the acting force F, ~F
The size of 4 depends on the thickness of the corner mirror 8 and the claw spring 21-1.
Since it varies depending on the position of 21-4, etc., it may be set to a different value for each example.

The beam splitter 40 assembly structure is based on the corner mirror 8.
The assembly structure is similar to that of

In this optical head optical component assembly structure, when the leaf spring assembly 100 is inserted into the slot 50 starting with the lower element 28, the leaf spring 20 moves downward while contacting the tapered portion 53-2 of the hillock 53. sent to. In this case, since both IllK f-pas 26-1 and 26-2 are formed at the lower part of the leaf spring 20, and the width dimension of the lower part of the leaf spring 20 is small, the leaf spring assembly 100 can be easily inserted into the slot 50.

Therefore, it is possible to insert the leaf spring assembly 100 into the case 1 with one touch. Also, the acting force F, ~F
4 is the mounting surface 5 of the reflective surface 8-1 of the corner mirror 8.
Since the corner mirror 8 is configured to act within the width dimension L6+L7 of the portion in surface contact with the corner mirror 5, the corner mirror 8 will not be bent by the acting forces F, -F4.

In addition, in this embodiment, the parallel elements 23-1 to 23-4 of the claw springs 21-1 to 21-4 have protrusions 24-1 to 24-4.
The projections 24-1 to 24-4 form the Konami 2
−8 was applied, but the protrusion 24-1
The parallel elements 23-1 to 23-4 that do not form 24-4 may be brought into direct contact with the corner mirror 8.

In addition, in this embodiment, the side elements 41 and 42 of the leaf spring 20 are
A protrusion 43.44 was formed in the protrusion 45.4.
The side elements 41 and 42 that do not form 4 are directly parallel to each other 53
Of course, it may be brought into contact with -1. moreover,
It is also possible to replace the projections 43, 44 with another leaf spring element, which is a bent part of the leaf spring 20. In addition, in this embodiment, the reflective surface 8-1 of the corner mirror 8 is brought into contact with the mounting surface 55, but the mounting surface of the corner mirror 8 is brought into contact with the mounting surface 55, and the laser beam is directed to the corner mirror 2-8. It is also possible to configure the laser beam so that it first passes through the mounting surface and then reflects it on the other surface that faces it.It is also possible to configure it so that the laser beam passes through the corner mirror 8. FIG. A perspective view showing a leaf spring used in the optical component assembly structure of the optical head, and FIG. 10 is a plane view showing a part of the case used in the optical component assembly structure of the optical head using the leaf spring shown in FIG. 11 is a sectional view taken along the line GG in FIG. 10. In the figure, 200 is a leaf spring of thickness t;
7a is a window provided in the center of the leaf spring 200, 201°2
02 is a claw spring arranged on both sides of the leaf spring 200, 221-1.221-2 is a claw spring arranged around the window 27a, and the claw spring 221-
1.degree. 221-2 are all bent at right angles toward the back of the paper as shown in FIG.

222-1.222-2 is the claw spring 221-1.221-
The corner mirror 8 is a right-angled element 222-1, with the reflecting surface 8-1 in surface contact with the plane 201.

The leaf spring assembly 21 is crimped and clamped between 222-2.
It constitutes 0. 205 and 204 are protrusions provided on the upper part of the leaf spring 200, and the protrusions 205 and 204 protrude to the side where the corner mirror 8 is inserted, and
The relative positioning of the corner mirror 8 and the corner mirror 8 in the height direction is performed by bringing the upper surface 8-3 of the corner mirror 8 into contact with the protrusions 203 and 204. 205 and 206 are leaf springs 20
The upper portions of the small springs 205 and 206 are bent toward the side opposite to the insertion side of the Konami 2-8. 500
is a slot provided in the case 1, and the slot 500 is located along the optical axis m-
It is installed at a certain point of intersection 0 between m and the optical axis pp. 550 is a mounting surface formed in the slot 500, and the mounting surface 5
50 forms an angle of 45° with the optical axis m-m and the optical axis p-p, and the mounting surface 550 is placed in front of the intersection point 0 by a distance equal to the thickness of the corner mirror 8. The rear surface 8-2 of the corner mirror 8 is in direct contact with the corner mirror 8, and the corner mirror 8 is arranged so that the intersection point O is on the reflective surface 8-1 of the corner mirror 8. 504 is a notch provided in the center of the mounting surface 550, 502 and 503 are the side walls of the slot 500, 554 is the bottom of the slot 500, and 502-1 stands parallel to the mounting surface 550 from the bottom 554 to point E. At the parallel portion of the raised side wall 502, the small piece spring 205 abuts against the parallel portion 502-1 with the leaf spring assembly 210 inserted into the slot 500. 502
-2 is a tapered portion of the side wall 502 that is inclined in the direction in which the slot 500 widens upward from point E, and the side walls 502 and 503 have the same shape.

In this optical head optical component assembly structure, first, the leaf spring assembly 210 is formed, and then the leaf spring assembly 210 is inserted into the slot 500. Here, side wall 502 of slot 500
, 505, the leaf spring assembly 210 can be easily moved downward with rough positioning. At that time, the lower end of the leaf spring 200 is sent downward along the tapered portion 502-2,
The lowermost end of the leaf spring 200 is brought into contact with the bottom surface 554 to complete the insertion. In this state, the force due to the elastic deformation of the small piece springs 205 and 206 is applied to the four outer peripheral corners 401 to 40 of the corner mirror 8.
04, the corner mirror 8 is pressed against the mounting surface 550, and the corner mirror 8 is fixed to the mounting surface 550. Here, since the force that presses the corner mirror 8 with the leaf spring 200 acts within the area that is in surface contact with the mounting surface 550 of the corner mirror 8, the corner mirror 8 does not bend due to the force. In addition, a notch 50 is provided on the mounting surface 550.
4, when the corner mirror 8 is crimped and fixed to the mounting surface 550, it is possible to eliminate deformation of the corner mirror 8 due to the ridges on the surface of the mounting surface 550. However, the corner mirror 8 due to the ridges on the mounting surface 5500
If the adverse effect on the characteristics caused by the deformation is slight and causes no problem, the cutout 504 may not necessarily be provided.

In this embodiment, the leaf spring 200 includes a small piece spring 205.
, 206 are installed, but the small springs 205, 206 may be replaced with the protrusions 43, 44 shown in FIG. In addition, the small piece springs 205 and 206 are not provided, and the leaf spring 200
Of course, it is also possible to configure the surface 202 of the case 1 to directly abut the side walls 502 and 503 of the case 1.

Further, in this embodiment, the back surface 8-2 of the corner mirror 8 is brought into contact with the mounting surface 500 of the case 1, and the laser beam is reflected by the reflective surface 8-1 facing the back surface 8-2 of the corner mirror 8. However, for example, when the reflective surface 8-1 of the corner mirror 8 is brought into contact with the mounting surface 500, the laser light inside the case 1 first passes through the back surface 8-2 of the Konami 2-8, and then is reflected by the reflective surface 8-1. It can also be applied in cases where a laser is used on the corner mirror 8.

Needless to say, this method can also be applied to cases where light is transmitted.

FIG. 12 is a perspective view showing a leaf spring used in another optical head optical component assembly structure according to the present invention. In the optical component assembly structure of this optical head, since the L-bending portion 226 is added to the upper part of the upper element 225 of the leaf spring 200, applying force to the L-bending portion 226 causes the case 1 to The leaf spring assembly 210 can be easily inserted.

FIG. 13 is a perspective view showing a leaf spring used in another optical head optical component assembly structure according to the present invention. In this optical head optical component assembly structure, since the upper element 225a of the leaf spring 200 is bent at right angles to the plane 202, by applying force to the upper element 225a, the leaf spring assembly 210 is attached to the case 1. can be easily inserted.

In addition, in these embodiments, the leaf spring 200 has an L bent portion 2.
26, the upper element 225a is provided, but the leaf spring 20 may be provided with the L bent portion 226 and the upper element 225a.

〔Effect of the invention〕

As explained above, in the optical component assembly structure of the optical head according to the present invention, a thin plate-shaped optical component is inserted into the plate spring in advance to form a plate spring assembly, and the plate spring assembly is directly attached to the case with one touch. Since the thin plate optical component can be inserted in the area where it is in surface contact with the mounting surface of the case of the thin plate optical component, there is no need to hold the thin plate optical component so that it does not fall down when fixing it. Since the structure is configured so that the action force of the leaf spring that fixes the thin plate-like optical component inside is applied, the thin plate-like optical component can be inserted into the mounting surface of the case without being distorted by the action force. Therefore, there is no distortion of the wavefront of the laser beam due to distortion of the thin plate-like optical component, and an optical head with good characteristics can be provided. in this way,
The effects of this invention are remarkable.

[Brief explanation of the drawing]

1 is a perspective view showing a leaf spring used in the optical component assembly structure of an optical head according to the present invention; FIG. 2 is a perspective view showing a corner mirror attached to the leaf spring shown in FIG. 1; Figure 3 is a cross-sectional view taken along plane A in Figure 2;
FIG. 4 is a plan view showing a case used in the optical component assembly structure of the optical head using the leaf spring shown in FIG. 1, and FIG. 5 is a plan view showing the case shown in FIG. 6 is a plan view showing the assembled state of the leaf spring assembly shown in FIG.
FIG. 7 is a sectional view taken along line C-C in FIG. 5, FIG. 8 is a sectional view taken along line DD in FIG. FIG. 10 is a perspective view showing a leaf spring used in the parts assembly structure; FIG. The figure is a sectional view taken along the line G-C in FIG. 10, FIGS. 12 and 13 are perspective views showing leaf springs used in the optical component assembly structure of another optical head according to the present invention, and FIG. 14 is a rectangular shape. FIG. 15 is a perspective view of a columnar optical component, FIG. 15 is a perspective view of a triangular prism-shaped optical component, and FIG. 16 is a perspective view of a conventional optical head using a thin plate-shaped optical component. 1... Case 4... Beam splitter 8... Corner mirror 8-1... Reflective surface 8-2... Back surface 20.200... Leaf springs 21-1 to 21-4, 221- 1 to 221-2...Claw springs 22-1 to 22-4, 222-1 to 222-2...
-Right angle elements 24-1 to 24-4...Protrusions 27, 27a...Windows 30 to 32...Concave grooves 45.44...Protrusions 50.60, 500...Slot holes 55. 550...Mounting surface 100.210...Plate spring assembly 205.204...Protruding portion 205.206...Small spring'-1 Fig. 1 Fig. z Fig. 5 Section 6 Fig. 7 Section Figure 3 Figure 9 Figure 10 Figure 1 Figure 13 Figure 161 yen] z

Claims (1)

[Claims] 1. In an optical component assembly structure for an optical head in which a thin plate-shaped optical component is attached to a case, the case is provided with a mounting surface, the thin plate-shaped optical component is held between leaf springs, and the plate is mounted. a spring assembly, and inserting the leaf spring assembly into the case,
When the thin plate-shaped optical component is in surface contact with the mounting surface and the plate spring assembly is inserted into the case, the acting force of the plate spring that presses the thin plate-shaped optical component against the mounting surface is An optical component assembly structure for an optical head, wherein the optical component assembly structure for an optical head is arranged to work within a region that is in surface contact with the mounting surface of the thin plate-shaped optical component. 2. As the leaf spring, use a leaf spring in which a plurality of claw springs are formed around a window whose center portion is removed, and the thin plate-shaped optical component is held between the claw springs, and the acting force is applied to the claws. An optical component assembly structure for an optical head according to claim 1, wherein the optical component assembly structure is provided by a spring. 3. Form a slot in the case where the mounting surface is placed,
Claim 1, characterized in that hillocks protruding into the slot are formed on both sides of the slot in the width direction, and a portion of the leaf spring abuts on the hillocks. Optical component assembly structure of the optical head described. 4. The optical component assembly for an optical head according to claim 1, wherein a thin film is formed on the surface of the thin plate-like optical component, and the laser light in the case is transmitted through or reflected by the thin film. Attached structure.