JP2003187477A - Optical pickup device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical pickup device which achieves miniaturization and weight saving and is also equipped with a semiconductor laser device having a superior cooling effect. <P>SOLUTION: A conduction sheet 40 is held tight between a press fitting 50 which presses a stand-alone semiconductor laser device 10 against a mounting hole prepared on a housing part 30, a stem bottom face of the semiconductor laser device 10, and a forming face of the mounting hole of the housing part 30, so as to contact with the pressed fitting 50 and both of the stem bottom face and the mounting hole forming face. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical pickup device for recording / reproducing information on / from an optical recording medium such as an optical disk, and more particularly to reducing the temperature rise of a semiconductor laser device mounted on the optical pickup device. The present invention relates to an optical pickup device provided with a heat radiating means.

[0002]

2. Description of the Related Art An optical pickup device is equipped with a semiconductor laser device having a light source such as a semiconductor laser, a condensing optical system such as an objective lens, and a light receiving section, and records information on an optical recording medium.
The information recorded on the optical recording medium is reproduced. Since the semiconductor laser device generates a laser beam for recording / reproducing information, heat generated by driving the semiconductor laser damages or deteriorates the semiconductor laser device and affects reliability.

In recent years, as the speed of recording information on an optical recording medium has been increased, the output of laser light has been increased, so that the semiconductor laser device is driven with high power consumption. The calorific value tends to increase. Further, the semiconductor laser device also tends to be downsized, and the cooling member for releasing the heat generated by the semiconductor laser device to the outside also tends to be downsized. Therefore, it is very important for practical use to efficiently release the heat generated from the semiconductor laser device to the outside and improve the cooling ability of the semiconductor laser device. In order to improve the cooling efficiency, a method of disposing the generated heat efficiently by providing a member having excellent thermal conductivity in the semiconductor laser device is considered.

In the optical pickup device disclosed in Japanese Unexamined Patent Publication No. 10-283650, two heat radiation members are provided in order to efficiently release the heat generated by the semiconductor laser device. These two heat dissipation members are in contact with each other via the heat conductive sheet, and the heat generated in the semiconductor laser device is conducted from the first heat dissipation member to the second heat dissipation member via the heat conductive sheet. Then, it is released from the second heat dissipation member to the outside.

On the other hand, in response to recent demands for downsizing and weight reduction of optical pickup devices, the semiconductor laser device has been reduced in the number of components, and the material of the components has been reduced in size and weight. Therefore, it is not preferable from the viewpoint of downsizing and weight saving of the device to provide a member dedicated to heat dissipation, which only releases heat, like the optical pickup device of the above publication.
Therefore, by also using another member provided in the semiconductor laser device as a heat dissipation member, the number of parts of the semiconductor laser device is reduced and the device is not enlarged,
There is an optical pickup device that enables efficient cooling.

For example, in Japanese Unexamined Patent Publication No. 8-287501, a metal pressing spring is used to mount the semiconductor laser device on the housing, and the pressing spring also functions as a heat dissipation member of the semiconductor laser device. As a result, it is possible to obtain an optical pickup device excellent in cooling ability while achieving downsizing of the device.

Further, in another conventional optical pickup device 90 shown in FIG. 9, a metal pressing member 9 used for mounting the semiconductor laser device 91 on the housing portion 93.
2 is also used as a heat dissipation member. In the optical pickup device 90, a plurality of lead terminals 94 connected to an integrated circuit for driving a laser project directly or indirectly via a wiring part or the like on the side surface of the base of the semiconductor laser device. The press fitting 92 is provided with a foot 92a, and the foot 92a is pressed against the bottom surface of the base of the semiconductor laser device 91, whereby the semiconductor laser device 91 is fixed to the housing portion 93.

The heat generated by the semiconductor laser device 91 of the optical pickup device 90 is temporarily generated by the semiconductor laser device 91.
Conductive to the foot 92a of the pressing metal fitting 92 provided in contact with the bottom surface of the base. Then, the heat is radiated from the entire surface of the pressing metal member 92 by being diffused from the foot 92a to the entire pressing metal member 92.

[0009]

However, in the optical pickup device disclosed in Japanese Unexamined Patent Publication No. 8-287501, when the semiconductor laser device is installed in the housing part,
Since the elastic force of the pressing spring is used for fixing, there is a problem that the semiconductor laser device and the pressing spring cannot be brought into contact with each other while maintaining a sufficiently close contact state due to the bending of the pressing spring. .

Further, when the lead terminal is projected from the bottom surface of the base of the semiconductor laser device, or at the bottom surface of the base, the lead terminal is directly or indirectly connected to the integrated circuit through the wiring portion. In that case, there is also a problem that heat is trapped in the gap between the bottom surface of the base and the wiring part or the integrated circuit, and the heat radiation effect from the bottom surface of the base of the semiconductor laser device is reduced.

Further, in the conventional optical pickup device 90 shown in FIG. 9, the semiconductor laser device 91 is pushed to the pressing metal fitting 92.
Since the heat conducted to the semiconductor laser device 91 is transmitted through the foot 92a which is in contact with the bottom surface of the base of the semiconductor laser device 91 in a small area, there is a problem that the heat conduction efficiency is low. Further, the foot 92a comes into contact with the bottom surface of the base of the semiconductor laser device 91, so that the press fitting 92 and the semiconductor laser device 9 are connected.
A gap is formed between the two. Since the heat emitted from the semiconductor laser device 91 is trapped in this gap,
There is a problem that the heat generated in the semiconductor laser device 91 cannot be efficiently cooled.

Therefore, in the conventional optical pickup device, the pressing spring or the pressing metal member 92 and the semiconductor laser device cannot be sufficiently brought into close contact with each other, so that the heat generation of the semiconductor laser device can be efficiently performed.
However, there is a problem in that it does not conduct heat to the battery and cannot obtain an excellent heat dissipation effect.

The second heat radiating member disclosed in Japanese Patent Laid-Open No. 10-283650 corresponds to the base of the semiconductor laser device,
There is no description relating to the improvement of the cooling ability of the semiconductor laser device, which is caused when the second heat radiation member is miniaturized as the semiconductor laser device is miniaturized. further,
The publication also does not describe mounting of the semiconductor laser device in the housing portion.

The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to realize a semiconductor laser device having an excellent cooling effect while realizing the size and weight reduction of the device. An object is to provide an optical pickup device provided with the optical pickup device.

[0015]

In order to solve the above problems, an optical pickup device of the present invention comprises a semiconductor laser device having a light source section for emitting a laser beam, and the semiconductor laser apparatus is provided in a housing section. In the optical pickup device, in which the base of the semiconductor laser device is pressed against the housing portion by using the pressing hole, the pressing member, the bottom surface of the base of the semiconductor laser device, and The heat conducting member is sandwiched between the pressing portion and the surface of the housing portion where the mounting hole is formed so as to be in contact with both the pressing member bottom surface and the mounting hole forming surface. .

According to the above construction, the heat generated in the light source section is conducted to the entire semiconductor laser device and is conducted from the bottom surface of the base of the semiconductor laser device to the pressing member via the heat conducting member. , Is emitted from the entire surface of the pressing member via a path that is transmitted from the semiconductor laser device to the housing portion and is conducted to the pressing member via the heat conducting member. As a result, the semiconductor laser device is efficiently cooled, the temperature rise of the semiconductor laser device can be suppressed, and the damage and deterioration of the semiconductor laser device can be prevented.

Further, since the pressing member also has a function as a heat radiating member for radiating the heat generated by the semiconductor laser device, the number of parts of the semiconductor laser device can be reduced to reduce the size and weight of the device. An optical pickup device having an excellent cooling effect for a semiconductor laser device can be provided.

Also, the optical pickup device of the present invention is the above-mentioned optical pickup device, wherein the heat conducting member is
It is characterized by having elasticity.

According to the above structure, even when a member having a rough surface such as a metal is brought into contact with the metal surface, the metal surface can be adhered closely to the metal surface and the heat conducting member has elasticity. The contact area can be increased as compared to the case without the contact. As a result, the heat conduction member can be brought into close contact with the bottom surface of the base of the semiconductor laser device, the housing portion, and the pressing member, so that heat is efficiently conducted from the semiconductor laser device to the pressing member via the above path, Heat can be efficiently dissipated from the surface of the pressing member to the outside air.

Further, the optical pickup device of the present invention is the above optical pickup device, wherein the heat conducting member is
It is characterized by being formed of any one of silicon resin, graphite, aluminum and silver.

According to the above construction, since the heat conducting member is formed of a soft material having excellent heat conductivity and elasticity, it should be in close contact with the semiconductor laser device, the housing portion and the pressing member. You can Therefore, the heat can be immediately absorbed from the semiconductor laser device and the housing, and can be quickly radiated to the pressing member, and the temperature rise of the semiconductor laser device can be reduced.

Further, the optical pickup device of the present invention is the above-mentioned optical pickup device, wherein the semiconductor laser device has a lead terminal for electrically connecting the integrated circuit for driving the semiconductor laser device and the light source section. The lead terminal is drawn out from the bottom surface of the base, and is directly or indirectly connected to the integrated circuit through a wiring portion.

According to the above structure, even when the lead terminal is pulled out from the bottom surface of the base and the contact area between the bottom surface of the base and the pressing member cannot be sufficiently secured, the heat conducting member presses the pressing member. Since it is in contact with both the bottom surface of the base and the surface where the mounting hole is formed, the semiconductor laser device can be cooled efficiently. Further, even when a gap is formed between the bottom surface of the base and the integrated circuit or the wiring portion, since the heat conducting member is in contact with both the pressing member and the bottom surface of the base and the surface where the mounting hole is formed, No heat is trapped in the gap. Therefore, the heat generated in the semiconductor laser device is efficiently released through the above-mentioned path.

Further, in the optical pickup device of the present invention, in the above optical pickup device, the bottom surface of the base of the semiconductor laser device is flush with the mounting hole provided in the housing part on the same plane as the mounting hole forming surface. The heat conducting member is formed in a sheet shape or is mounted so as to protrude from the surface where the mounting hole is formed within a manufacturing error range.

According to the above construction, since the bottom surface of the base of the semiconductor laser device forms the same plane as the surface of the mounting hole of the housing within the manufacturing error, the heat conducting member is in the form of a sheet. Also, by pressing the pressing member, the heat conducting member can be brought into close contact with the semiconductor laser device, the housing portion, and the pressing member. Further, since the sheet-shaped heat conduction member has elasticity, even when the bottom surface of the base of the semiconductor laser device slightly projects from the surface where the mounting hole of the housing is formed, the semiconductor laser device is elastically deformed. It is possible to make close contact with the housing part and the pressing member.

Further, the heat conducting member does not need to be processed into a complicated shape so as to be brought into close contact with the bottom surface of the base of the semiconductor laser device, the housing portion, and the pressing member, and the manufacturing process can be simplified. And, the cost can be reduced.

Further, the optical pickup device of the present invention is characterized in that, in the above-mentioned optical pickup device, the heat conducting member further has an electrical insulating property.

According to the above structure, when the lead terminal is pulled out from the bottom surface of the base, even if the lead terminal and the heat conducting member come into contact with each other, the electrical insulation between the lead terminals can be maintained. .

[0029]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described below with reference to FIGS. 1 to 8.

The optical pickup device 1 of this embodiment is
As shown in FIG. 1, a single semiconductor laser device 10, a housing portion 30, and a heat conductive sheet 40 that is a heat conductive member.
And a pressing metal fitting 50 which is a pressing member, and an FPC (flexible printed circuit board) 70 which is a wiring portion.

As shown in FIG. 2, the single semiconductor laser device 10 includes a laser chip 11 and a PIN chip 12 which are light source parts, a stem 13 which is a base, and a cap 15.
It has a plurality of, here three lead terminals 18, 18, 18. In this single-piece semiconductor laser device 10, a laser chip 11 and a PIN chip 12 are housed inside a cap 15 provided on the upper surface of a stem 13, and each lead terminal 18 is inside the cap 15 and the laser chip 1 is provided.
1 and the PIN chip 12 are connected. In the following, the side on which the cap 15 is provided is referred to as the stem upper surface 13a, and the side from which each lead terminal 18 is drawn out is referred to as the stem bottom surface (base bottom surface) 13b.

Each part of the single semiconductor laser device 10 will be described in detail below with reference to FIG.

The laser chip 11 is supplied with electric power through each lead terminal 18 and emits laser light.

The PIN chip 12 monitors the laser light emitted from the laser chip 11 in the direction opposite to the direction in which the laser light is emitted toward the collimator lens 4 shown in FIG. Power control) is applied to control the output of the laser light output from the laser chip 11.

The stem 13 is wholly formed of a metal such as copper having excellent thermal conductivity, and has a disk shape with a diameter of 5.6 mm. Laser chip 11 associated with emission of laser light
The heat generated in (1) is conducted to the stem 13 and diffused, and the heat is radiated from the entire surface of the stem 13 to reduce the temperature rise of the laser chip 11.

Further, as shown in FIG. 2, the stem upper surface 13a provided with the cap 15 has a protrusion 14 and a PIN.
The chip 12 is placed, and the laser chip 11 is bonded to the protrusion 14 with an adhesive having high thermal conductivity. Further, the stem upper surface 13a serves as a reference surface for determining the position when the single semiconductor laser device 10 is attached to the housing portion 30 shown in FIG.

Further, the stem 13 has a stem upper surface 13a.
Also, three through holes 17, 17, 17 penetrating the stem 13 are provided so as to be perpendicular to both surfaces of the stem bottom surface 13b parallel to the stem upper surface 13a. The through holes 17 provided in the stem 13 are arranged on a concentric circle with a radius of 1 mm from the center point of the stem bottom surface 13b. Each lead terminal 18 is inserted into each through hole 17, and each through hole 17
The space between the lead terminal 18 and each lead terminal 18 is sealed with a glass material.

The cap 15 includes the laser chip 11 and the PI.
It is installed on the stem upper surface 13a so that the N tip 12 and the protrusion 14 are stored inside. The cap 15 has a window 16 through which laser light emitted from the laser chip 11 toward the collimator lens 4 (see FIG. 1) passes.

Each lead terminal 18 is used for supplying power to the laser chip 11 or transmitting a signal from the PIN chip 12. Therefore, one of the lead terminals 18 is connected to the laser chip 11 via the gold wire 19 at one end protruding to the stem upper surface 13a side, and one end of the other lead terminal 18 is connected to the PIN chip via the gold wire 19. It is connected to 12. Further, as described above, since the glass material is provided between the through holes 17 and the lead terminals 18, the lead terminals 18 are electrically insulated from each other.

Subsequently, based on FIGS. 1 and 3, the optical pickup device 1 of the present embodiment described above is equipped with
The housing portion 30, the heat conductive sheet 40, the pressing metal fitting 50, and the FPC 70 will be described.

The housing portion 30 is, as shown in FIG.
It is a support for accommodating optical system elements such as the collimator lens 4, the reflection mirror 5, the objective lens 6, and the base for fixing the single semiconductor laser device 10. As shown in FIG. 3, the housing portion 30 is provided with a laser mounting hole 32 as a mounting hole on the end surface so that the single semiconductor laser device 10 can be mounted. Hereinafter, the end surface on which the laser mounting hole 32 is formed is referred to as a mounting hole forming surface 31.

The heat conductive sheet 40 is formed from the laser chip 11 shown in FIG. 1 to the stem 1 of the single semiconductor laser device 10.
The heat conducted to 3 and the housing part 30 via the stem 13.
The heat conducted to the heat transfer member is efficiently transferred to the pressing metal fitting 50 described later. The heat conductive sheet 40 is made of elastically deformable silicon resin, has a thermal conductivity of 1.7 W / m · K, and an electric volume resistivity of 1.0 × 10 ¹⁵ Ω · cm, which is excellent in thermal conductivity. It is a sheet material. The outer shape of the heat conductive sheet 40 is substantially the same as the outer shape of the pressing metal fitting 50. In addition, the heat conductive sheet 4
As shown in FIG. 3, 0 has three lead through holes 41, 41, 41 through which each lead terminal 18 penetrates, and metal fitting holes 42, 42 into which the feet 51, 51 of the pressing metal fitting 50 are fitted. .

The pressing metal fitting 50 is, as shown in FIG.
It is a flat plate formed of a metal having excellent thermal conductivity, and has a size that can be accommodated in the mounting hole forming surface 31 of the housing portion 30. A central hole 52 is provided in the central portion of the pressing metal fitting 50 so that the three lead terminals 18, 18, 18 can be penetrated and the FPC 70 described later does not contact the pressing metal fitting 50. There is. Further, the central hole 52
Feet 51 are provided at two opposite positions.
Each foot 51 is bent to have an L-shape, and protrudes from the surface of the pressing metal fitting 50 by the same amount as the thickness of the heat conductive sheet 40. Each foot 51 has a heat conductive sheet 40.
The single semiconductor laser device 10 is fitted into the metal fitting holes 42 and is pressed against the housing portion 30.

FPC (flexible printed circuit board) 70
Is a laser driving integrated circuit (not shown) and each lead terminal 18
Is a wiring portion for connecting the and, and sends a current signal to the single semiconductor laser device 10 via each lead terminal 18. Further, the FPC 70 has three land hole portions 71, 71.
71 is provided and is connected to each lead terminal 18 by soldering at each land hole portion 71.

Next, mounting of the single semiconductor laser device 10 on the housing portion 30 will be described with reference to FIG.

The single semiconductor laser device 10 includes the laser mounting hole 3 provided on the mounting hole forming surface 31 of the housing portion 30.
It is attached to 2. The laser mounting hole 32 is used for the stem 13
Has a contact surface 33 that contacts the stem upper surface 13a, and the position of the single semiconductor laser device 10 mounted in the housing portion 30 is determined by the stem upper surface 13a contacting the contact surface 33. By thus providing the laser mounting hole 32 in the housing portion 30, the positioning of the single semiconductor laser device 10 and the pressing fitting 5 to be described later are performed.
Fixing with 0 can be easily performed.

The length from the mounting hole forming surface 31 of the laser mounting hole 32 to the contact surface 33 is the stem upper surface 13 of the stem 13.
The length from "a" to the bottom surface 13b of the stem coincides with the manufacturing error. The manufacturing error of the present embodiment is
The maximum length from the mounting hole forming surface 31 to the contact surface 33,
It is within a range where the minimum length from the stem top surface 13a to the stem bottom surface 13b is equal. Therefore, when the single semiconductor laser device 10 is mounted in the laser mounting hole 32, the stem bottom surface 13b and the mounting hole forming surface 31 of the housing portion 30 are flush with each other, or the stem bottom surface 13
b is in a state of slightly protruding from the mounting hole forming surface 31.

Thereby, as will be described later, the heat conductive sheet 40 is formed on the stem bottom surface 13b and the mounting hole forming surface 31.
Even if the pressing metal fitting 50 is attached via, the gap is not formed between the stem bottom surface 13b and the heat conductive sheet 40.

On the other hand, when the single semiconductor laser device 10 is mounted so that the stem bottom surface 13b is recessed toward the housing portion 30 side from the mounting hole forming surface 31, the pressing metal fitting 50 has thermal conductivity. Even if the sheet 40 is pressed, a gap is formed between the heat conductive sheet 40 and the stem bottom surface 13b. Therefore, in order to prevent the formation of such a gap, it is desirable that the bottom surface 13b of the stem is designed to slightly project from the mounting hole forming surface 31 within a manufacturing error range.

When the single semiconductor laser device 10 is mounted in the laser mounting hole 32, the pressing metal fitting 50 is arranged on the mounting hole forming surface 31 of the housing portion 30 via the heat conductive sheet 40, and is fixed to the fixing screw 60. Will be concluded. The fixing screw 60 penetrates the screw holes 54, 54, 44, 44 provided in the pressing metal fitting 50 and the heat conductive sheet 40, respectively, and is fixed to the screw holes 34, 34 of the housing portion 30.

At this time, each lead terminal 18 protruding from the bottom surface 13b of the stem penetrates each lead through hole 41 of the heat conductive sheet 40 and passes through the central hole 52 of the pressing metal fitting 50 so that the heat conductive sheet is formed. 40 and pressing metal fitting 50
Are arranged. Further, both feet 51, 51 provided on the pressing metal fitting 50 are fitted into the metal fitting holes 42 of the heat conductive sheet 40. Since the protrusion amount of each foot 51 protruding from the plane of the pressing member 50 and the thickness of the heat conductive sheet 40 are designed to be substantially equal to each other, the heat conductive sheet 40 and each foot 51 have a stem. It can come into contact with the plane formed by the bottom surface 13b and the mounting hole forming surface 31.

Further, in the FPC 70, each land hole 71 and each lead terminal 18 protruding from the stem bottom surface 13b are connected by solder, and the central hole 52 of the pressing metal fitting 50 faces the heat conductive sheet 40. Is attached to.

As described above, the single semiconductor laser device 10
Since the heat conductive sheet 40 is sandwiched so as to contact the stem bottom surface 13b and the mounting hole forming surface 31 of the housing portion 30 and the pressing fitting 50, the stem bottom surface 13b and the mounting hole forming surface 31 Since no gap is formed between the pressing metal fitting 50, heat is efficiently transferred from the stem bottom surface 13b and the mounting hole forming surface 31 to the pressing metal fitting 50 through the heat conductive sheet 40.

Since the heat conductive sheet 40 has elasticity, it can be adhered to a metal having a rough surface, and is adhered to the stem bottom surface 13b, the mounting hole forming surface 31, and the pressing metal fitting 50. Are in contact with each other. Therefore, the heat conductive sheet 40 does not have elasticity as well as the case where the stem bottom surface 13b and the mounting hole forming surface 31 and the pressing metal fitting 50 are directly contacted without interposing the heat conductive sheet 40. Compared with the case, the heat conductive sheet 40 and the stem bottom surface 13
It is possible to increase the contact area between the b and the mounting hole forming surface 31, and the contact area between the heat conductive sheet 40 and the pressing fitting 50. By increasing the contact area, the heat conductive sheet 4 is removed from the stem bottom surface 13b and the mounting hole forming surface 31.
0, the heat conduction efficiency to the pressing fitting 50 can be increased, so that the temperature rise of the single semiconductor laser device 10 is reduced.

Further, since the stem bottom surface 13b and the mounting hole forming surface 31 form the same plane within the range of manufacturing error, even if the sheet-shaped heat conductive sheet 40 is used, The stem bottom surface 13b, the mounting hole forming surface 31, and the pressing fitting 50 can be brought into close contact with each other. Therefore, the stem bottom surface 13b, the mounting hole forming surface 3
1. The heat conducting member does not need to be processed intricately according to its shape so that it can be brought into close contact with the pressing fitting 50, and the manufacturing process can be simplified.

The bottom surface 13b of the stem is the mounting hole forming surface 3
Even when slightly projecting from 1, the heat conductive sheet 40 is elastically deformed by pressing the pressing metal fitting 50, and the stem bottom surface 13b and the mounting hole forming surface 31.
It plays the role of a cushion that absorbs the difference between and to adhere to both sides (cushion effect). Therefore, even if the sheet-shaped heat conductive sheet 40 is used, the heat generated in the single semiconductor laser device 10 is still applied to the stem bottom surface 13b and the mounting hole forming surface 3
From both of the above, it is efficiently transmitted to the pressing metal fitting 50 via the heat conductive sheet 40. Then, heat can be released from the entire surface of the pressing metal fitting 50 to the outside air, and the single semiconductor laser device 10 can be cooled efficiently.

On the contrary, the stem bottom surface 13b is the mounting hole forming surface 3
When the pressing metal fitting 50 presses the heat conductive sheet 40 when it is recessed toward the housing portion 30 side from 1, the gap is formed between the heat conductive sheet 40 and the stem bottom surface 13b. . Therefore, the contact area between the heat conductive sheet 40 and the stem bottom surface 13b decreases, and the heat conduction efficiency from the stem bottom surface 13b to the heat conductive sheet 40 decreases. As a result, the cooling efficiency of the single semiconductor laser device 10 decreases,
The service life of the single semiconductor laser device 10 is shortened.

Therefore, the stem bottom surface 13b and the mounting hole forming surface 31 form the same plane, or the stem bottom surface 13b projects from the mounting hole forming surface 31 within a manufacturing error. preferable.

Since the heat conductive sheet 40 has substantially the same outer shape as the pressing metal fitting 50, the stem 1
The heat absorbed by the thermally conductive sheet 40 from the housing 3 and the housing portion 30 can be immediately transferred to the entire pressing metal fitting 50 from the contact portion between the thermally conductive sheet 40 and the pressing metal fitting 50. Therefore, the heat generated in the single semiconductor laser device 10 is transferred from the stem bottom surface 13b to the heat conductive sheet 40.
Through the mounting hole forming surface 31 of the housing portion 30.
Is diffused to the entire pressing metal fitting 50 through the heat conductive sheet 40 and is released from the entire surface of the pressing metal fitting 50.

The heat conductive sheet 40 is pressed against the metal fitting 50.
Heat conduction to the heat conductive sheet 40 and the pressing metal fitting 50.
Since it is performed in the contact portion with the heat conducting sheet, the larger the contact area between the heat conducting sheet 40 and the pressing metal fitting 50, the higher the heat conducting efficiency. Therefore, the outer shape of the heat conductive sheet 40 is preferably at least larger than the outer shape of the pressing metal fitting 50. Thereby, the heat absorbed by the heat conductive sheet 40 from the single semiconductor laser device 10 can be efficiently conducted to the entire pressing metal fitting 50, so that an excellent cooling effect of the single semiconductor laser device 10 can be obtained. .

Further, even when each foot 51 provided on the pressing metal fitting 50 is bent near the base, the heat conductive sheet 4
Due to the cushioning effect of 0, the pressing metal fitting 50 can be brought into close contact with the heat conductive sheet 40.
The efficiency of heat transfer from 3 to the press fitting 50 does not decrease.

Further, by interposing the heat conductive sheet 40 between the FPC 70 and the stem bottom surface 13b, the lead terminal 18 is projected from the stem bottom surface 13b,
Even when the FPC 70 is arranged at a position facing the stem bottom surface 13b, from the entire stem bottom surface 13b,
Heat can be released to the pressing metal fitting 50 via the heat conductive sheet 40, and the heat dissipation effect of the pressing metal fitting 50 is improved.

Further, the material of the heat conducting member is FPC70.
Is not particularly limited as long as it is a material that can improve the heat radiation effect from the stem bottom surface 13b to the pressing fitting 50, which is not sufficient, and silicon resin, graphite, aluminum, silver, etc. can be used. Can be mentioned. Of these, a silicon resin is particularly preferable as a material capable of sufficiently conducting heat to the stem bottom surface 13b and the pressing metal fitting 50 and maintaining the electrical insulation between the lead terminals 18.

It is considered that the heat generated in the single semiconductor laser device 10 is efficiently cooled from the entire surface of the pressing metal fitting 50 mainly through the following paths.

The heat generated by the laser chip 11 inside the single semiconductor laser device 10 is transferred to the entire stem 13 via the protrusion 14 as shown in FIG.
3 is conducted to the housing portion 30 which is in contact therewith. Subsequently, the heat is transmitted from the housing portion 30 to the pressing metal fitting 50 through the heat conductive sheet 40, and is radiated to the outside from the pressing metal fitting 50. The heat generated by the laser chip 11 is generated by the stem 13
Is transmitted to the whole of the pressing metal fitting 50 from the stem bottom surface 13b through the foot 51. The heat generated by the laser chip 11 is transmitted to the stem 13, and is conducted to the entire pressing metal fitting 50 from the stem bottom surface 13b through the heat conductive sheet 40.

In this embodiment, the heat conductive sheet 40 is used as the heat conductive member, but the present invention is not limited to this, and the stem bottom surface 13b and the mounting hole forming surface 31 are used.
And a member which is in contact with the pressing member 50 and can efficiently transfer the heat generated in the single semiconductor laser device 10 to the pressing member 50.

The outer shape of the heat conducting member is not particularly limited, but the bottom surface 13 of the stem of the semiconductor laser device is used.
The mounting hole forming surface 32 of the housing portion 30 that is larger than b
It is preferable that the size is such that
Furthermore, it is preferable that the outer diameter of the pressing metal fitting 50 is similar to or larger than the outer shape of the pressing metal fitting 50.

The operation of the optical pickup device 1 including the single semiconductor laser device 10 mounted in the housing portion 30 as described above will be described with reference to FIG.

The laser light emitted from the laser chip 11 of the single semiconductor laser device 10 is converted from divergent light into parallel light by passing through the collimator lens 4.
Then, this parallel light is reflected by the reflection mirror 5 and is irradiated onto a predetermined position on the signal recording surface of the optical recording medium 7 via the objective lens 6. Then, the length of the pit on the signal recording surface of the optical recording medium 7 is changed in accordance with the digital signal based on the audio signal and other data, and the data is recorded.

The objective lens 6 is provided with a focus actuator for making the focal depth of the laser beam follow the surface wobbling of the optical recording medium 7 and a tracking actuator for making the track follow the eccentricity of the optical recording medium 7. It is also mounted on an objective lens actuator (not shown).

When reproducing information from the optical recording medium 7, the laser light is focused on the signal recording surface of the optical recording medium 7 and reflected according to the position of the pit with respect to the laser light spot on the signal recording surface. The intensity of light changes. This reflected light passes through the objective lens 6 and is reflected by the reflection mirror 5,
After passing through the collimator lens 4, it is incident on a light receiving element (not shown) by a beam splitter or the like. In the light receiving element, changes in reflected light are converted into changes in current. This current is output to the signal processing circuit or the like via the light receiving element or each lead terminal 18, amplified, and reproduced as a digital signal based on the audio signal recorded on the signal recording surface of the optical recording medium 7 or other data. To be done.

The light receiving element is provided not inside the single semiconductor laser device 10 but outside thereof, and is provided inside or outside the housing portion 30.

The above-mentioned optical recording medium 7 is, for example, a compact disc (CD) for reproduction only, a compact disc recordable (CD-R) of recordable type, a rewritable phase change disc (CD-RW). However, it is not particularly limited, and may be appropriately selected depending on the purpose and use.

In this embodiment, the integrated circuit drive source for driving the laser chip 11 and the lead terminals 18 are provided.
The FPC 70, which is the wiring unit, is used to connect to and, but the present invention is not limited to this. For example, an integrated circuit board (integrated circuit) 80 may be used as shown in FIG.

The integrated circuit board 80 has an integrated circuit for driving the laser chip 11 included in the single semiconductor laser device 10. The integrated circuit board 80 is connected to an integrated circuit drive source (not shown).

The integrated circuit board 80, as shown in FIG.
Three land holes 81.8 / 8 through which each lead terminal 18 passes
The integrated circuit board 80 and the lead terminals 18 are soldered to each other through the land holes 81, and are attached to the housing portion 30. The integrated circuit board 80 is attached so as not to contact the heat conductive sheet 40, and there is a space between the integrated circuit board 80 and the heat conductive sheet 40 as shown in FIG. 7.

In the optical pickup device 2 (see FIG. 5) to which the integrated circuit board 80 is attached, a current signal is sent from the integrated circuit drive source to the integrated circuit board 80 via a wire (not shown), and each An electric current is sent to the single semiconductor laser device 10 via the lead terminal 18. Then, the single semiconductor laser device 10 is driven, and the laser light is emitted from the laser chip 11.

In the optical pickup device 2, as shown in FIG. 7, the heat conductive sheet 40 is interposed between the stem bottom surface 13b and the integrated circuit board 80. Therefore, even when the integrated circuit board 80 is arranged at a position facing the stem bottom surface 13b, the heat conductive sheet 40 can absorb heat from the stem bottom surface 13b. Bottom of stem 1
The heat absorbed from 3b immediately diffuses from the contact surface between the heat conductive sheet 40 and the pressing metal fitting 50 to the entire pressing metal fitting 40, so that the heat can be efficiently released from the surface of the pressing metal fitting 50. It will be possible. As a result, the temperature rise of the single semiconductor laser device 10 is reduced, and the single semiconductor laser device 10 can be prevented from being damaged or deteriorated.

Further, in the present embodiment, a single semiconductor laser device is used as the semiconductor laser device, but the present invention is not limited to this, and a hologram semiconductor laser device can be used, for example. Figure 8 (a)
The hologram semiconductor laser device 20 will be described based on FIG.

The hologram semiconductor laser device 20 is shown in FIG.
As shown in (a), the stem 23, the cap 25,
It has a hologram element 26 and a plurality of lead terminals 27. This hologram semiconductor laser device 20 is provided inside the cap 25 provided on one surface of the stem 23 as shown in FIG.
As shown in (b), a light receiving element substrate 24 including a laser chip 21 and a plurality of, in this case, two light receiving elements 22, 22 is housed. In addition, from the side surface of the stem 23,
The lead terminal 27 projects.

In the following, the hologram semiconductor laser device 2 will be described.
Each unit of 0 will be described.

As shown in FIG. 8B, the laser chip 21 receives electric power from each lead terminal 27 and emits laser light.

The light receiving element 22 receives the reflected light from the optical recording medium 7 shown in FIG. 1 or FIG. 5, and detects the servo signal and the RF signal based on the incident light.

The stem 23, as shown in FIG.
It is composed of a metal portion 23a and a resin portion 23b. The light receiving element substrate 24 shown in FIG. 8B is directly or indirectly mounted on the metal portion 23a, and the laser chip 21 and the two light receiving elements 22 are provided on the light receiving element substrate 24. There is. The metal portion 23a is thermally coupled to the laser chip 21 via a material having good thermal conductivity, and efficiently radiates the heat generated in the laser chip 21 to the outside of the hologram semiconductor laser device 20. .

Further, the surface of the metal portion 23a on the laser light emitting side serves as a reference surface for determining the mounting position when the hologram semiconductor laser device 20 is mounted on the housing portion 30 of the optical pickup device.

The cap 25 is provided so as to cover the light receiving element substrate 24 placed on the metal portion 23a. The cap 25 has a window (not shown) through which laser light is emitted, and a hologram element 26 is provided on the window.

The hologram element 26 has a diffraction grating,
By this diffraction grating, the reflected light from the optical recording medium is diffracted by each light receiving element 22.

The lead terminal 27 is connected directly to an integrated circuit for driving the laser chip 21 or in order to supply electric power to the laser chip 21 and to extract a signal from each light receiving element 22, or through a wiring such as an FPC. Has been done.
One end of each lead terminal 27 projects into the cap 25 and is connected to the laser chip 21 and the light receiving element substrate 24 by a gold wire (not shown). The other end of each lead terminal 27 projects outward from the side wall of the resin portion 23b of the stem 23 and is connected to a wiring such as an integrated circuit or an FPC.

Hologram semiconductor laser device 2 having the above configuration
In the case of 0, when laser light is emitted, laser light is emitted from the laser chip 21 and passes straight through the hologram element 26, as shown in FIG. 8B. When the laser light is incident, the laser light is diffracted to the left and right and is incident on each light receiving element 22 when passing through the hologram element 26.

The hologram semiconductor laser device 20 includes:
Like the single semiconductor laser device 10 described above, it is used by being attached to the housing portion 30 of the optical pickup device.

Furthermore, the present invention is not limited to the above-mentioned embodiment, but various modifications can be made within the scope of the present invention.

For example, the semiconductor laser device used in the optical pickup device may be any of the above-mentioned single semiconductor laser device and hologram semiconductor laser device, and
This is applicable regardless of the shape, size, number of lead terminals, lead frame shape, stem shape, etc. of the package.

Also regarding the method of mounting the semiconductor laser device in the housing portion 30, the bottom surface of the stem of the semiconductor laser device and the heat conductive member such as the heat conductive sheet 40 are in contact with each other and pressed as a pressing member. There is no particular limitation as long as the metal fitting 50 and the heat conducting member can be attached so as to be in contact with each other. Therefore, the pressing metal fitting 50
The semiconductor laser device may be mounted by pushing it into the housing portion 30 without being screwed by the fixing screw 60. Also, as described in Japanese Patent Application Laid-Open No. 8-287501, a U-shape is provided. The semiconductor laser device may be mounted on the housing portion 30 by using a mold pressing spring as a pressing member.

With the above arrangement, the optical pickup device of the present invention can dissipate the heat generated in the semiconductor laser device to the pressing member and reduce the temperature rise of the semiconductor laser device.

Further, the outer shape of the pressing member, the shape of the central hole formed in the pressing member, and the shape of the foot are the lead terminal protruding from the bottom surface of the stem of the semiconductor laser device, and the wiring of the FPC 70 connected to the lead terminal. Parts and integrated circuit board 8
It may be designed so as not to interfere with 0.

Further, the semiconductor laser device is mounted on the housing portion 3
An intermediate member may be provided for the purpose of positioning with high accuracy or more easily when it is mounted on 0.

Further, regarding the overall shape of the heat conducting member, and the lead through holes and the metal fitting holes provided in the heat conducting member, the heat conducting member is in surface contact with both the bottom surface of the stem and the pressing member even in part. Therefore, if heat conduction from the bottom surface of the stem to the pressing member is efficiently performed, it may be appropriately selected depending on the number of lead terminals of the semiconductor laser device and the shape of the pressing member.

Further, the heat conducting member may be directly or indirectly connected to the heat radiating fin via a member having excellent heat conductivity. Thereby, the temperature rise of the semiconductor laser device can be further reduced.

The FPC 70 and the integrated circuit board 80 are
Although it may be in direct contact with the heat conducting member, in order to prevent the FPC 70 and the integrated circuit board 80 from being heated by the heat conducting member, a gap is provided between the FPC 70 and the integrated circuit board 80 and the heat conducting member. It may be provided, or a member made of a material having low thermal conductivity may be interposed.

[0100]

As described above, the optical pickup device of the present invention has the pressing member and the base between the pressing member and the bottom surface of the base of the semiconductor laser device and the surface of the housing portion where the mounting hole is formed. The heat conducting member is sandwiched so as to come into contact with both the bottom surface and the surface where the mounting hole is formed.

Therefore, the heat generated in the light source section is conducted to the entire semiconductor laser device and is conducted from the bottom surface of the base of the semiconductor laser device to the pressing member via the heat conducting member, and the semiconductor laser device. From the entire surface of the pressing member through the heat conduction member to the pressing member via the heat conducting member to the pressing member. As a result, the semiconductor laser device is efficiently cooled, the temperature rise of the semiconductor laser device can be reduced, and the damage and deterioration of the semiconductor laser device can be prevented.

Further, since the pressing member also has a function as a heat radiating member for radiating the heat generated by the semiconductor laser device, the semiconductor laser device can be made compact and lightweight, and the semiconductor laser device can be excellently cooled. It is possible to provide an improved optical pickup device.

The optical pickup device of the present invention is the same as the optical pickup device, wherein the heat conducting member is
It is made of any one of silicon resin, graphite, aluminum and silver.

Therefore, since the heat conducting member is formed of a soft material having excellent heat conductivity and elasticity, the heat conducting member can be brought into close contact with the semiconductor laser device, the housing portion and the pressing member. Play. Also,
Even when it is not possible to secure a sufficient contact area between the bottom surface of the base and the pressing member, a sufficient heat radiation path from the semiconductor laser device to the pressing member is secured, and heat radiation from the semiconductor laser device to the pressing member is ensured. There is an effect that can be efficiently performed.

The optical pickup device of the present invention is the same as the optical pickup device, wherein the heat conducting member is
It has elasticity.

Therefore, even when a member having a rough surface such as a metal is brought into contact with the metal surface, the metal surface can be closely adhered, and compared with the case where the metals are in contact with each other or the heat conducting member does not have elasticity. As a result, the contact area can be increased. As a result, the heat conducting member is brought into close contact with the bottom surface of the base of the semiconductor laser device, the housing portion, and the pressing member, and the heat can be efficiently dissipated from the semiconductor laser device to the outside air.

Further, the optical pickup device of the present invention is the above-mentioned optical pickup device, wherein the semiconductor laser device has a lead terminal for electrically connecting the integrated circuit for driving the semiconductor laser device and the light source section. The lead terminal is pulled out from the bottom surface of the base and directly connected to the integrated circuit or indirectly connected to the integrated circuit via a wiring portion.

Therefore, even when the lead terminal is pulled out from the bottom surface of the base and the contact area between the bottom surface of the base and the pressing member cannot be sufficiently secured, the semiconductor laser device can be cooled efficiently. It has the effect of being able to.
Further, even when a gap is formed between the bottom surface of the base and the integrated circuit or the wiring portion, there is an effect that heat is not trapped in the gap.

Further, in the optical pickup device of the present invention, in the above optical pickup device, the bottom surface of the base of the semiconductor laser device is flush with the mounting hole formed in the housing portion in the same plane as the mounting hole forming surface. The heat conducting member is formed into a sheet or is mounted so as to protrude from the surface where the mounting hole is formed within a manufacturing error range, and the heat conducting member is a sheet.

Therefore, even if the heat conducting member is in the form of a sheet, it is possible to bring the heat conducting member into close contact with the semiconductor laser device, the housing portion and the pushing member by pushing the pushing member. Even when the bottom surface of the base of the semiconductor laser device slightly projects from the surface of the housing part where the mounting hole is formed, the sheet-shaped heat conducting member is elastically deformed, so that the semiconductor laser device, the housing part, and the pressing part are pressed. The effect that it is possible to closely contact the contact member is achieved.

Further, the heat conducting member does not need to be processed into a complicated shape so as to be brought into close contact with the bottom surface of the base of the semiconductor laser device, the housing portion and the pressing member, and the manufacturing process can be simplified. Moreover, there is an effect that the cost can be reduced.

Further, in the optical pickup device of the present invention, in the above-mentioned optical pickup device, the heat conducting member further has electrical insulation.

Therefore, even if the lead terminals come into contact with the heat conducting member, there is an effect that the electrical insulation between the lead terminals can be maintained.

[Brief description of drawings]

FIG. 1 is a sectional view showing an embodiment of an optical pickup device according to the present invention.

FIG. 2 is a cross-sectional view showing a single semiconductor laser device mounted on the optical pickup device.

FIG. 3 is an exploded perspective view showing main components of the optical pickup device.

FIG. 4 is a cross-sectional view of the optical pickup device viewed from the optical recording medium side.

FIG. 5 is a sectional view showing another embodiment of the optical pickup device according to the present invention.

FIG. 6 is an exploded perspective view showing main components of an optical pickup device according to another embodiment.

FIG. 7 is a cross-sectional view of the other optical pickup device seen from the optical recording medium side.

FIG. 8 is a perspective view of a hologram semiconductor laser device mounted on the optical pickup device according to the present invention, FIG.
FIG. 3 is a perspective view showing the entire hologram semiconductor laser device, and FIG. 3B is a perspective view showing main parts of the hologram semiconductor laser device.

FIG. 9 is a cross-sectional view showing a conventional optical pickup device.

[Explanation of symbols]

1 Optical Pickup Device 2 Optical Pickup Device 10 Single Semiconductor Laser Device (Semiconductor Laser Device) 11 Laser Chip (Light Source Part) 13 Stem (Base) 13a Stem Top 13b Stem Bottom (Base Bottom) 18 Lead Terminal 20 Hologram Semiconductor Laser Device (Semiconductor laser device) 30 Housing portion 31 Mounting hole forming surface (forming surface) 32 Laser mounting hole (mounting hole) 40 Thermal conductive sheet (heat conducting member) 50 Pressing metal fitting (pressing member) 60 Fixing screw 70 FPC ( Wiring part) 80 integrated circuit board (integrated circuit)

Continued front page    F-term (reference) 5D117 HH01 HH12 JJ21                 5D119 AA33 CA09 DA01 DA05 FA05                       FA32 FA33 LB04 MA09                 5D789 AA33 CA09 DA01 DA05 FA05                       FA32 FA33 LB04 MA09                 5F073 AB21 AB25 AB27 BA04 FA02                       FA06

Claims (6)

[Claims] 1. A semiconductor laser device having a light source part for emitting laser light, wherein the semiconductor laser device presses a base of the semiconductor laser device against the housing part in a mounting hole provided in the housing part. In an optical pickup device fixed by using a pressing member, the pressing member is provided between the pressing member and a bottom surface of the base of the semiconductor laser device and a surface of the housing portion where the mounting hole is formed. An optical pickup device, wherein a heat conducting member is sandwiched so as to come into contact with both the bottom surface of the base and the surface where the mounting hole is formed. 2. The optical pickup device according to claim 1, wherein the heat conducting member has elasticity. 3. The optical pickup device according to claim 1, wherein the heat conducting member is made of any one of silicon resin, graphite, aluminum and silver. 4. The semiconductor laser device has a lead terminal for electrically connecting an integrated circuit for driving the semiconductor laser device and the light source section, and the lead terminal is pulled out from a bottom surface of a base, The optical pickup device according to claim 1 or 2, wherein the optical pickup device is directly or indirectly connected to the integrated circuit via a wiring portion. 5. The bottom surface of the base of the semiconductor laser device is flush with the mounting hole forming surface in the mounting hole provided in the housing portion, or within a manufacturing error range from the mounting hole forming surface. 5. The optical pickup device according to claim 2, wherein the heat conducting member is mounted so as to project at, and the heat conducting member is in the form of a sheet. 6. The optical pickup device according to claim 4, wherein the heat conducting member further has electrical insulation.