JPH01251490A - Vibrationproofing rubber material and damping material for optical disk device - Google Patents

Abstract

PURPOSE:To obtain desired vibration dissipation factor and elastic modulus by containing and curing 100pts.wt. of synthetic rubber, 10-150pts.wt. of specified silica fine powder, and 3-20pts.wt. of organopolysiloxane expressed in a specific formula. CONSTITUTION:The vibrationproofing rubber material arranged so as to enclose a hinge part between the fixing part of an optical pickup device and an objective lens holder is produced by containing and curing the 100pts.wt. of synthetic rubber and the 10-150pts.wt. of silica fine powder, and the 3-20pts.wt. of organopolysiloxane expressed in the formula. And the specific surface of the silica fine powder is set at >=50m<2>/g. Where, in the formula, R<1> and R<2> represent non-substitute or substitute monovalent hydrocarbon group, and either R1 or R2 represent phenyl or alkyl group, and (m) and (n) represent integers (0-20), respectively. In such a way, it is possible to set the vibration dissipation factor tandelta at >=0.1, and the elastic modulus at 1X10<4>-1X10<9> dyne/cm<2>.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a vibration-proof rubber material for optical disk devices and a vibration-proof rubber material for optical disks, and more specifically, to a rubber material for vibration-proofing for optical disk devices, and more specifically, for vibration-proofing properties that do not change significantly with respect to temperature changes. The present invention relates to a vibration isolating rubber material for an optical disc device having excellent properties, and a vibration isolating material for an optical disc device using this vibration isolating material for an optical disc device.

[Prior Art and Problems to be Solved 1] In recent years, compact disc players as audio products, optical video disc players, and optical storage devices as OA equipment that utilizes optical discs have become popular. It is coming.

In compact disc player devices, optical video disc players, optical storage devices, etc., pits formed on an optical disc are irradiated with semiconductor laser light, the reflected light is read, digital signals are detected, and η voice information and video information are generated. is playing.

The pit has a width of about 0.5 to 0.8 m and a length of about 0.8 m.
It has extremely small dimensions of 87 to 3.18 μm and a track pitch of 1.6 pm, and is formed in a spiral shape on the surface of the optical disc, like the sound grooves on a record. The semiconductor laser beam is condensed by an objective lens within the optical pickup device and is irradiated onto the minute pit. In that case, the semiconductor laser beam must accurately follow the pits of the optical disk rotating at high speed.

Further, when the optical pickup device moves from one position to another position t on an optical disk rotating at high speed,
Even after moving, the device does not vibrate due to movement during movement, reduces sudden movements, and immediately returns to the pit.
(tamping effect).

In this way, for example, in an optical pick-up device, the ability to follow pits is not hindered by external vibrations, and even if the optical pickup device moves suddenly, it can accurately follow pits immediately after the movement. In addition, the objective lens holder that holds the objective lens is required to be kept in the middle position from the fixed part so as to be able to cope with sudden movement.

These requirements are severe and far different from those required for pickups in conventional record player devices.

In order to meet the above requirements for a serious crime optical pickup device, conventionally.

■ A method that relies on the elastic force of the metal plate or metal wire by connecting, for example, an objective lens holder that holds the objective lens with a fixed part using a thin metal plate or ultra-fine metal wire; ■ A method that relies on the elastic force of the metal plate or metal wire; A method in which a gel-like resin is attached to the base of the wire and depends on the elastic absorption rate of the gel-like resin and the elastic force of the metal. ■Also, a method that relies on the elastic absorption rate of the gel-like resin and the elastic force of the metal. ■Also, a method that relies on the elastic absorption rate of the gel-like resin and the elastic force of the metal. ■Also, use of butyl rubber, etc., which has excellent vibration absorption power on thin metal plates or metal wires. There are methods that have been put to practical use, such as coating or bonding rubber, and are there any methods that can be applied to pickup devices in acoustic record players?■ Without using metal members.

By blending silicone rubber with butyl rubber, acrylic rubber, etc., the vibration loss coefficient (tan δ) can be reduced to O51.
Vibration damping rubber member made as above (Special Publication No. 60-43865
A method of connecting a movable part and a fixed part in an optical pickup device may be considered.

However, the method (2) has a problem in that the resonance peak for l'jfi is large and it is difficult to detect a stable signal. For example, if the optical pickup device moves suddenly, the resonance of the objective lens holder continues for a long time, and the vibrations do not stop easily, making it impossible to follow the rapidly rotating pit in a short period of time. Namely.

The damping effect is poor.

The above method (2) has the problem that it is difficult to accurately inject a certain amount of gel-like resin into a predetermined complex area (low workability), and such a method is not suitable for industrial use. .

Method 0 has a large temperature dependence of the vibration loss coefficient, so it is by no means an effective means if the disk device is to be installed in a place where the temperature changes significantly.

Furthermore, in recent years, there has been a movement toward installing optical disk devices into automatic 11[. Inside the car.

Normally, the temperature inside a vehicle changes significantly, so it is an extremely urgent technical issue to ensure vibration isolation in an optical pickup device using a member that is not dependent on temperature.

Therefore, silicone rubber may be considered as a material with low temperature dependence, since conventional silicone rubber has a small vibration loss coefficient and cannot provide sufficient vibration damping performance.
It has not been possible to solve the pressing technical problems mentioned above.

Furthermore, are there any plans for a compact optical disc device that allows a person to wear the optical disc device on their body and enjoy music played from the optical disc device while walking, for example? Optical disk devices are required to have anti-vibration performance that is incomparable to conventional fixed-installation type optical disk devices.

The present invention is described above! 1 was done out of compassion.

That is, one object of the present invention is to provide a vibration-isolating rubber material for an optical disk device that has an extremely high-precision vibration-isolating function and whose vibration-isolating function hardly depends on immersion in hot water.

Another object of the present invention is to provide a vibration-damping rubber material for an optical disc device that can be suitably used in an optical disc device that requires a higher degree of vibration isolation than an acoustic record player.

[Means and effects for solving the problem] The composition of the present invention for solving the problem of serious crime consists of 100 parts by weight of synthetic rubber and 10 parts by weight of silica fine powder having a specific surface area of 50 m"/g or more.
~1501 spear moiety and the formula (in the above formula, R1 and R'' are the same or different non-substituted or substituted monovalent hydrocarbon groups, and at least one of R' and R2 is phenyl Group or carbon J: There are 2 to 10 alkyl groups, m is 1 to 20, and n is O to
3 to 20 parts of an organopolysiloxane represented by ), which is an integer of 20, is contained and vulcanized to reduce the vibration loss coefficient tanδ.
is greater than or equal to 0.1, and the elastic modulus is l X l O'
This is a vibration isolating rubber material for an optical disk device, characterized in that the vibration isolating rubber material has a vibration resistance of ~I X I 09 dyne/cm2.

The synthetic rubber is not particularly limited as long as it can exhibit rubber elasticity through a crosslinking reaction, and examples thereof include ethylene-propylene copolymer, ethylene-ethyl acrylate copolymer, ethylene-vinyl acetate copolymer, and ethylene-methacrylate copolymer. Polyolefin synthetic rubber such as polymers,
Examples include organopolysiloxane rubber.

In the present invention, since it is desired that the temperature dependence of the mechanical properties of the vibration-proof rubber material for optical disk devices is as small as possible, organopolysiloxane is preferred among the various synthetic rubbers mentioned above.

This organopolysiloxane has the following formula: Aryl groups such as tolyl groups, or 3,3.3-t-lifluoropropyl groups in which part or all of the hydrogen atoms bonded to carbon atoms of these groups are substituted with halogen atoms, cyano groups, mercapto groups, etc. The same or different unsubstituted or t-substituted 1, such as cyanopropyl group, mercaptopropyl group, etc.
j represents a hydrocarbon group, and a is a number from 1.95 to 2.05. ) The viscosity at 25°C is 1.000
cS or more, and at least 50 mol% of said R3
It is preferable to have a linear structure consisting of a methyl group or a methyl group.

This type of organopolysiloxane can be obtained by ring-opening polymerization of cyclic polysiloxane, which is well known as an oligomer, in the presence of an acid or alkali catalyst, and can also be obtained by (co)hydrolysis of organochlorosilane. It can also be obtained by polymerizing the compound in the presence of a condensation or equilibration catalyst.

The organopolysiloxane is said to be one whose molecular chain ends are capped with a silanol group, dimethylvinylsiloxy group, trimethylsiloxy group, methylphenylvinylsiloxy group, etc., or in order to give strength to this cured product, Preferably, the terminal group is a vinyl group-containing siloxy group.

Regarding the degree of polymerization of the organopolysiloxane, there is no particular restriction as long as the organopolysiloxane can be made into a rubbery product, ranging from an oily state to a raw rubbery state. As shown, the viscosity at 25°C should be less than l, 0OOcS.

As the silica fine powder, it is possible to use fumed silica, precipitated silica, etc. What is important in the present invention is that its specific surface area is 50 m''/g or more. This is because if the specific surface area is less than 50 m2/g, the anti-vibration rubber material for optical disc devices of the present invention may not exhibit a sufficient anti-vibration effect.

Furthermore, it is ffi'ff in the present invention that the amount of the fine silica powder added is 10 to 10 parts by weight, preferably 30 to 60 parts by weight, per 100 parts by weight of the synthetic rubber.

If the amount of this fine silica powder added is less than 10 parts by weight,
The anti-vibration effect of the anti-vibration rubber material for optical disc devices will be insufficient, and if it exceeds 14 parts of 100i, the physical properties of the anti-vibration rubber material for optical disc devices will deteriorate.

The organopolysiloxane in the present invention has the formula R2CH or 2 carbons
~10 alkyl groups, 1m is 1~20. n is O~2
, ), which indicates an integer of 0.

Among these organopolysiloxanes, preferred are formula % (in the formula 1, "represents an integer from 4 to 6") or formula 1 (in the formula 1, p and q are 2 to 6). represents an integer of 4,
) can be shown as

The organopolysiloxane can be obtained, for example, by hydrolyzing methylphenyldichlorosilane or (,t')phenylcyclosilane and dimethylchlorosilane.

What is important in the present invention is that this organopolysiloxane,
That is, the amount of α,ω-dihydroxyorganoborisiloxane added is 3% per 100 parts of the synthetic rubber.
-20 parts by weight, preferably 5-1011 parts.

If the blending amount of organopolysiloxane Iγ1 is less than 3 parts by weight, it will not be possible to impart a sufficient vibration damping function to the vibration-proof rubber material for optical disk devices, and even if it is blended in excess of 20 mff parts, it will not be possible to provide a sufficient vibration damping function. There is no improvement in the anti-vibration effect.

The anti-vibration rubber material for optical disc devices of the present invention requires the synthetic rubber, a specific fine silica powder, and a specific organopolysiloxane to be blended in a specific ratio and then vulcanized.

In the serious blending, the synthetic rubber, the fine silica powder, and the organopolysiloxane are mixed in two rolls, a kneader,
This can be done by mixing the wires with a Banbury mixer or the like.

At the time of this crosstalk, conventionally known additives such as titanium oxide, red iron oxide, cerium oxide as heat resistance improvers, halides and antimony oxide as flame retardants, various types of carbon funk, Narsilane, and inorganic fillers are used. Quartz powder, diatomaceous powder, etc. may be added.

Here, in the invention according to claim 2, the synthetic rubber, a specific silica fine powder, and a specific organopolysiloxane are contained in a specific ratio, and an anti-aging agent is added to 4 parts by weight of the synthetic rubber. 0. It is characterized in that it is contained in a proportion of 1 to 10 parts by weight.

If an anti-aging agent is blended with the specific ingredients in addition to the respective components constituting the anti-vibration rubber material for an optical disk device according to claim 1, the anti-vibration properties of the anti-vibration rubber material for an optical disk device can be improved. Furthermore, it can be maintained stably over a wide temperature range.

1. The anti-aging agent can be blended with all or part of the synthetic rubber, specific silica fine powder, and specific organopolysiloxane during the mixing or before kneading. .

As the anti-aging agent, conventionally known anti-aging agents can be used as long as they do not impede the object of the present invention; for example, naphthylamine-based agents such as phenyl-β-naphthylamine, N,N'-diphenylethylenecyamine, etc. diphenylamine series, p-phenylenediamine series such as N,N'-diphenyl-P-phenylenediamine: 6-ethoxy-2,2,4-trimethyl-1,2
-Hydroquinone derivatives such as dihydroquinoline: 2゜6
- Monophenols such as di-t-butyl-4-methylphenol: Polyphenols such as 2,2°-methylene-bis-(4-ethyl-6-t-butylphenol) = 4.4°-thiobis-(6 -t-phthyl-3-methylphenol) and other thiobisphenol-based 2-mercabutobenzimitazole.

Among the various types mentioned above, amine-based and phenol-based antiaging agents are preferred.

The crosslinking can be carried out by subjecting the compound or kneaded product obtained by the above blending to a curing reaction treatment using a method such as a condensation reaction using an organic peroxide or an inorganic peroxide, or sulfur vulcanization. .

Examples of the organic oxides that undergo the condensation reaction include dicumyl peroxide, t-butyl peroxide, t-phthylcumyl peroxide, and 2.5-
Dimethyl-2,5-di(t-butylperoxy)hexane, 2.5-dimethyl-2,5-di(7-butylperoxy)hexane, 1.1-bis(t-butylperoxy)3. Examples include 3.5-t-limethylcyclohexane.

Examples of the sulfur-based vulcanizing agent used in the sulfur vulcanization include +j++A, civentamethylenethiuram dehrasulfite, and the like.

Whether an elastic body can be obtained by hot mold vulcanization or not, what is particularly important in this application is that the vibration loss coefficient of the elastic body obtained as described above is 001 or more, preferably 0.
．． 2 to 1.0, and the elastic modulus is l x l O'
~l x 10"dyne/cm", preferably
This is a vibration isolating rubber material for optical disk devices with a resistance of X l O' to l X I 0 adyne/cm2.

If the vibration loss coefficient of the Otogawa anti-vibration rubber material for optical disks is less than 0.1, the vibration-isolating effect at the resonance point will decrease, and
If the elastic modulus is out of the above range, 1] the desired resonance frequency cannot be obtained.

In addition, the vibration loss coefficient a and elastic modulus are JIS K630
It is possible to measure according to 1.

The vibration loss coefficient of the anti-vibration rubber material for optical disc devices of the present invention can be adjusted by changing the amount of organopolysiloxane described in claim 11.

Furthermore, the elastic modulus of the anti-vibration rubber material for optical disc devices of the present invention can be adjusted by changing the stitching of the fine silica powder.

Since the anti-vibration rubber material for optical disc mounting of the present invention is an elastic body made of a specific material as described above, there is almost no temperature dependence of the elastic modulus and vibration loss coefficient, and the vibration loss coefficient is greater than or equal to 0.1, and the elastic modulus is 1xlo
'~1xlo' dyne/c size 2, so it has excellent vibration damping properties and excellent relaxation properties against sudden movements.

The vibration isolating rubber material for optical disk devices having such unique properties can be suitably used as a vibration damping material for optical disk devices not only in audio record player devices but also in various parts of the optical disk device.

For example, the vibration damping material for an optical disk device according to claim 3 of the present application is characterized in that the vibration-proofing rubber member according to claim 1 is formed into a rod-shaped body, and an elastic metal body is inserted into the rod-shaped body. That is.

The damping material for an optical disk device according to claim 3 is used, for example, in the following manner.

In the optical pickup device, each of the plurality of vibration damping materials for the optical disk device! They are arranged in rows f and f, and are used by connecting one end of each to a fixed part and the other end to an objective lens holder that holds an objective lens.

Here, as the metal terminating body, for example, a metal wire can be mentioned.

The diameter of this metal wire is usually 0.1 to 0.12 mm.
That's about it.

When the damping material for an optical disc device is used in an optical pickup device in this way, the following effects are produced.

In other words, if the optical backup device in the optical disk device is
The objective lens holder mounted on the optical disc 1- emits a light beam onto a minute object on the optical disk 1- and receives the reflected light, thereby capturing a minute signal from the optical disk L.
In order to read accurately, the movement in the focus force direction (movement that controls the focal length with respect to the disk surface) and the movement in the track direction (the rotation of the disk) are controlled by adjusting the Mt of the magnet driven by the magnet and the permanent magnet. Accurate displacement movement must be achieved by combining the following movements (movement in a direction that follows the deviation during signal reading that inevitably occurs due to deviation between the axis and the center axis of the track). The vibration isolating material for an optical disk device of the present invention absorbs the kinetic energy caused by the rapid displacement movement of the objective lens holder caused by the +i'ij magnet and the permanent magnet,
It is possible to reduce the speed of the rapid displacement movement. In other words, with the vibration isolating material for an optical disk device of the present invention, the objective lens holder that starts moving rapidly due to magnetic force does not stay still at a predetermined position after vibrating for a certain period of time around a predetermined position. This allows it to stop without any vibrations. Therefore, even if the entire optical pickup device is suddenly displaced in order to read the signal, the sudden displacement of the objective lens holder mounted on the optical pickup device will be alleviated within a very short time and an accurate signal will be obtained. This means that you can only read out .

Further, this vibration-proofing material for an optical disk device effectively blocks external vibrations received by the optical pickup device from being transmitted to the rotating portion.

Furthermore, since this vibration damping material for optical disk devices uses the vibration isolating rubber material for optical disk devices according to claim 1, there is no temperature dependence of the vibration loss coefficient. The anti-vibration effect will not deteriorate due to heat generation.

The restraining material for an optical disk device according to claim 4 of the present application is
The vibration-proof rubber material for an optical disc device according to claim 1,
It is characterized in that one end of the metal elastic body is inserted and is formed so as to be attached to the objective lens holder and/or the fixing part.

The damping material for an optical disk device according to claim 4 is used, for example, in the following manner.

The damping material for an optical disk device according to claim 4 is formed into a cylindrical body, for example. In the optical pilaf-up device, the optical disc device of the oil-heated cylindrical body is placed at four locations on the surface of the fixing part of the objective lens holder that holds the objective lens, with a positional relationship such that the vertices of a rectangle or square form. Attach the Kawazoe shock absorber. On the other hand, the cylindrical vibration damping material for an optical disk device is attached to the surface of the objective lens holder in a similar manner. One end of the 14 elastic body is passed through the gold and fixed to the damping material for the optical disc mounted on the objective lens holder, and the other end of the elastic body is passed through the vibration damping material for the optical disc mounted in the fixing part. and fix it. In this way, the objective lens holders are arranged in rows f and are held on the fixed part by elastic metal bodies each having a damping material for an optical disk device at its end.

Even in this case, the damping material for an optical disc device according to the fourth aspect has the same effect as the damping material for an optical disc device according to the third aspect.

The damping material for an optical disk device according to claim 5 is 111
i. The vibration-proof rubber material for an optical disk device according to claim 1,
The fixing part and the 4 part that holds the objective lens and are located in the center.
The present invention is characterized in that a rotating objective lens holder having a support shaft inserted through a through hole is used so that the serious crime rotating objective lens holder is rotatably connected to the mold temperature support shaft.

Even in this case, the damping material for an optical disc device according to the fifth aspect has the same effect as the damping material for an optical disc device according to the third aspect.

A damping material for an optical disc device according to claim 6.

In an optical pickup device in which an objective lens holder for holding a four-object lens and a fixing part are connected by a hinge mechanism, the fixing part is arranged between the fixing part and the objective lens holder, and the hinge part of the hinge mechanism is arranged between the fixing part and the objective lens holder. The vibration isolating rubber material for an optical disk device according to claim 1 is formed so as to surround at least a part of the optical disc device.

Even in this case, the damping material for an optical disc device according to the sixth aspect has the same effect as the damping material for an optical disc device according to the third aspect.

The vibration damping material for an optical disk device according to claim d. It is characterized by the fact that

The damping material for an optical disk device described above suppresses the resonance of the objective lens holder when the optical pickup device is suddenly displaced, and does not lose its damping effect even under a wide range of temperature changes.

The anti-vibration rubber material for an optical disk device according to claim 11 and claim 2 can be used, for example, in an optical disk device, for internal KB torsional vibration generated from a vibration source within the device, or external vibration generated outside the device. It is also used as a damping material for optical disc devices to effectively prevent B vibrations from being transmitted to the objective lens holder.

The vibration damping material for an optical disk device according to claim Ai8 is an optical disk in which digital information is read by irradiating the vibration isolating rubber material for an optical disk device according to claim 1 with a semiconductor laser beam onto pits formed on the optical disk. The device is characterized by being formed into a sheet shape that can be worn on the body.

The damping material for an optical disk according to claim 9.

The vibration-proof rubber material for an optical disc device according to claim 1,
It is interposed between a transformer and a substrate on which the transformer is mounted in an optical disc device that reads digital information fυ by irradiating pits formed on an optical disc with a semiconductor laser beam.

The vibration material on the output side of the optical disc device according to claim io is provided with a vibration-proof rubber material for an optical disc device according to claim 1, by irradiating the pits formed in the optical disc with a conductive laser beam. This is an optical disc device that is attached to the leg of the body to read information.

The damping material for an optical disk device according to claim 1O may be attached to the bottom surface of a leg of the body, or may be attached to the head of one of the legs, and the damping material may be attached to the head of one of the legs while being sandwiched between the body and the leg. It may be attached to the part.

The vibration damping material for an optical disk device according to claim 11 of item III is such that the vibration isolating rubber material for an optical disk device according to claim 1 is capable of transmitting digital information by irradiating pits formed on the optical disk with a semiconductor laser beam. It is used as a float ink material in the mechanical parts of optical disc devices for reading.

The damping material for an optical disk device according to claims 8 to 11 has a large vibration loss, and since the vibration loss and the elastic modulus have no temperature dependence, even if the temperature of the external environment changes greatly. , it is possible to effectively prevent vibration transmission to the objective lens holder, and to read signals with high precision from an optical disk [Example 1 (Example 1) (CHi)z S jo? 89.8 mol% of the 11th position, (
CHi ) (CH2=CH) S t O'n position is 0.2-[=le%, and (C6H5)2 S i O
io mole% of the units, f average 1
Methylphenylpolysiloxane raw rubber 100T [(14 parts) and fine silica powder [trade name:
Aerosil 200. R1 Manufactured by Aerosil Co., Ltd., Specific surface: 200 m"/g] 40 parts by volume and 10 parts by volume of dihydroxymethylphenylpolysiloxane expressed as After kneading, the mixture was further kneaded using a kneader at 150'c for 2 hours, and heat-treated.

Furthermore, dicumyl peroxide 0. "fi hE M was added to obtain a composition.

this! ! l product, lookkg/cm", 170'c
A sheet with a thickness of 2 mm was obtained by heating for 10 minutes under the following conditions.

When the vibration loss coefficient a and elastic modulus of this sheet were measured in accordance with JIS K6301, the vibration loss coefficient at 25°C was 0.4, and the elastic modulus was 5
10' dyne/c amount is 2, the vibration loss coefficient at 100°C is 0.3, and the tar property ratio is l.
x l O' dyne/ci.

(Examples 2 to 4) (CHz)2S t O medium 99.83 mol%, (CH
,)(CH2=CH)S iO units 0.15 mol%, and (C)I3)a(CH2=CH)S too5rl
io, ooo consisting of 0.02 mol%
100 parts of methyl vinyl polysiloxane raw rubber of 24:
, wrap it in a roll and add 40 parts of Aerosil 200 to it.
and 10 parts of α,ω-dihydroxymethylphenylpolysiloxane were added and uniformly kneaded to prepare a compound.

Next, this compound was heated in a kneader at 150°C for 2
After heat treatment for a period of time, 0.1 part of diphenylamine (trade name Nauger 1-445, manufactured by Koni Royal) was added (Example 2).
), 0.5 parts (Example 3), or l, 0 (Example 4)
Furthermore, 0.5 parts of 2,5-dimethyl-2,5-bis(t-butylperoxy)hexane was added and mixed uniformly.
The mixture was heated under pressure for a minute to obtain a sheet with a thickness of 2 mm.

1 Using a smoothed hardened sheet, JIS K630
When the mechanical properties and tan δ were measured based on Table 1, the results shown in Table 1 were obtained.

(Comparative Example 1) Quartz powder with a specific surface area of 19 m2/g instead of Aerosil 200 (Cristobalite VXS, @trade name manufactured by Ryumorisha)
Sheets were prepared in the same manner as in Examples 2 to 4 above, except that 1 part of 40 tl was used and Naragard 445 was not used, and various properties were measured. The results are shown in Table 1.

Table 1 (Example 5) An example of using a vibration-proofing rubber material for an optical disc device as a damping material for an optical disc is shown together with a drawing: J1171.

The damping material 1a for an optical disk device shown in FIG.
It is coated with the same anti-vibration rubber material 3 for optical disk devices as in the above.

As shown in FIG. 2, this vibration damping material 1 for optical disk device
a is attached to the fixed part 4 of the optical pickup device at one end, and the other end is attached to the fixing part 4 of the optical pickup device.

It is attached to an objective lens holder 6 that holds an objective lens 5.

The four damping materials 1a for an optical disk device are positioned parallel to each other, and the portion of each vibration damping material 1a for an optical disk device to be attached to the fixing portion 4 or the objective lens holder 6 forms the apex of a rectangle or square. ing.

The objective lens holder 6 held by the four optical disc device vibration damping members 1a is in a suspended state. This method of holding the objective lens halter with four holding members is called a four-wire one-way method.

Here, the objective lens holder 6 mounted on the optical pickup device in the optical disk device or the optical disk L is irradiated with a light beam and receives the reflected light to detect the fine particles on the optical disk L. In order to accurately read out signals, a combination of a magnet driven by zero electricity and a permanent magnet is used to perform displacement movement by combining movement in the focus direction and movement in the track direction.

The vibration isolating material 1a for an optical disk device absorbs the kinetic energy caused by the rapid displacement movement of the objective lens holder caused by the magnet and the permanent magnet, thereby reducing the speed of the rapid displacement movement. Therefore, the objective lens holder 6, which has started to move rapidly due to magnetic force due to the vibration isolating material 1a for an optical disk device, does not stay still at the predetermined position after vibrating for a certain period of time around a predetermined position, but instead remains at the predetermined position. It can be stopped with almost no vibration. Therefore, even if the entire optical pickup device is suddenly displaced for signal reading, the sudden displacement of the objective lens holder 6 mounted on the optical pickup device will be alleviated within a very short time, and an accurate signal will be obtained. can now be read.

Here, for a lens holder that weighs 1 weight j4 or 1.5 g,
The optical disc mount ffi I1 of Example 1 was attached to a phosphor bronze wire having a thickness of 0.12 mmφ and a length of 14.5 mm.
1. A case in which the lens holder is held using a 4-wire one-way system using a damping material for an optical disk device coated with a vibration-proofing rubber material, and a case in which the lens holder is held using a 4-wire one-way system using a vibration-damping material for an optical disk device coated with a vibration-proofing rubber material. When comparing the case of holding the lens holder with a 4-wire one-way system using bronze wire,
Ii? ), the resonance sharpness was 30% lower than in the latter case.

(Example 6) The damping material 1b for an optical disk device shown in FIG. 3 is 1i? 1
It is made of the same anti-vibration rubber material for optical disk devices as in Example 1, and is attached to the fixing part 4 and the objective lens holder 6 in the optical disk device, and one end of the metal wire 2 is attached to the optical disc device. It passes through and is fixed.

In this embodiment, as in the m2 embodiment 2, on the surface of the fixed part 4 facing the objective lens holder 6, the vibration damping material lb for an optical disk device is attached at a position that forms the vertex of a rectangle or square. A damping material 1b for an optical disk device is attached to the fixed part 4 in a positional relationship.

Similarly, in the objective lens holder 6, a vibration damping material lb for an optical disk device is mounted at a position corresponding to the fixing portion 4.

Then, it is fixed to the optical disc device vibration damping material 1b in the objective lens holder 6. One end and the other end of the metal wire 2 are passed through and fixed to the vibration damping material 1b for an optical disk device in the i64, so that the objective lens holder 6 is suspended in midair.

The holding method of the objective lens holder in this example is also 4.
It is a one-wire type.

(Example 7) In the fourth IA, the optical pickup device includes a cylindrical rotating objective lens holder 6a and a fixed part 4a that is disposed to face each other with the rotating objective lens holder 6a sandwiched therebetween. This rotary objective lens holder 6a has an objective lens 5, as in Examples 2 and 3 above. Further, this rotating objective lens holder 6a has a through hole 10 provided at its center, and a support shaft 11 is inserted through this through hole 10. This rotating objective lens holder 6a.

This is a rotating objective lens holder.

The vibration damping material ld for an optical disc device in this embodiment is formed of an optical disc mounting vibration damping rubber material.
As shown in the figure, the central part of the substantially elongated member is fixed to the fixing part 4a on the side, and both ends of the member are fixed on the fixed part 4a. The rotary objective lens holder 6a and the fixed part 4a are connected by fixing the ends of the elongated members to the rotary objective lens holder 6a. .

Similarly, when the center part of the elongated member is fixed to the other fixing part 4a, the two ends are bent so as to face each other, and the ends are fixed to the fixing part 4a. By this, the rotating objective lens holder 6a and the other fixed part 4
It is designed to combine with a.

In this way, the one-turn objective lens halter 6a is suspended with respect to the opposing fixed part 4a by the vibration damping material for an optical disk device, which is an elongated member.

This rotating objective lens holder 68 can be moved by a combination of a coil (not shown) and a permanent magnet within a regulated range along the spindle, or can be rotated about the spindle. It has become.

The method of holding the rotating objective lens holder in this manner is called a rotating method.

As described above, since the rotary objective lens holder 6a of this rotary type uses the optical disc device of the present invention as a recirculating material, similarly to the fifth embodiment, this pickup device as a whole can be used for signal reading. Even if the objective lens holder 6 mounted on the optical pickup device undergoes a sudden displacement, the sudden displacement is reduced to within an extremely short plane, making it possible to read out signals accurately. .

Furthermore, when external vibrations are applied to this optical pickup device, since the vibration damping material for an optical disk device, which is the elongated member, is formed of a vibration isolating rubber material for an optical disk device,
This prevents external vibrations from being transmitted to the rotating objective lens holder 6a. Therefore, only accurate signal reading can be performed without being affected by external vibrations.

(Example 8) The 5th IA connects the fixed part and the objective lens holder equipped with the objective lens to a displacement 1iT lff1 of the objective lens holder.
This is a partially cutaway perspective part showing the hinge mechanism when coupled to.

As shown in the 5th U''A, the hinge mechanism 12 is provided within the optical pickup device and connects the fixing part 4b and the objective lens holder 6b provided with the objective lens. That is,
A first support part 15 having a U-shaped cross section is provided via a vertically long first hinge part 14 provided approximately at the center of the base part 13 fixed to the fixed part 4b and capable of rotating left and right. Support part 15
A pair of horizontally aligned second support parts 17 are moved downwardly by -L through second shafts 16 that rotate up and down, which are respectively provided at the tips of a pair of protrusions 15a that protrude from the tree f. The tip of the second support i'1l17 connects to the third support part 19 fixed to the objective lens holder 6b provided with the objective lens 5 via the third hinge part 18 which can be rotated up and down (rr). It will be set up.

The damping material 1e for an optical disk device of this embodiment is as follows.

It is made of the same anti-vibration rubber material for an optical disk device as in the mold temperature embodiment 1, and is a substantially U-shaped sheet so as to substantially surround the longitudinally long first hinge portion 14 . In addition, vibration damping material 1 for optical disk devices applied to this hinge mechanism
There is no particular restriction on the shape of e, and a suitable shape can be appropriately adopted depending on various shapes of the hinge mechanism.

This method of holding the objective lens holder is called a hinge method.

In this embodiment, the hinge mechanism or the objective lens 5 is
The vibration isolating material 1e for an optical disk device suppresses the generation of vibrations caused by the shijik when the hinge portion collides with the support portion or other members due to the rotation of the hinge portion. Absorbs vibrations transmitted through the mechanism.

(Example 9) FIG. 6 is an explanatory diagram showing the objective lens holder.

As shown in No. 61211, this objective lens holder 6
c indicates the outer holder 22a and the inner holder 23b.

The external halter 22a has an internal space 2 that opens upward.
3c, and an internal holder 23 is provided in the internal space 23c.
b is placed.

The internal holder 23b has an internal space M23 (within which the external holder 2
It is held at 2a.

The vibration damping material if for an optical disc device is made of a sheet-shaped vibration damping rubber material for an optical disc device stretched on at least one side of a thin elastic metal plate.

The internal halter 23b has four optical disc device vibration damping materials 1
It is suspended in the space by f.

That is, the -
Each of the L ends is connected to the inner wall of the internal space 23c in the external holder 22a, and each of the lower ends of the vibration damping material if for an optical disk device is connected to the internal holder 23 of the flange J.
b is coupled to one end of the side surface with respect to the inner wall, and also for the other pair of optical disc device damping materials
In the same manner as above, Part 1: It is connected to the inner wall of the internal space at the end, and its lower end is connected to the upper end of the internal holder 23b. The internal holder 23 is suspended from the upper ends of the four optical disc device vibration damping materials If, and is held therein.

This type of holding method is called a plate spring method.

First, the serious external halter 22a is held against the fixed part by four optical disc device vibration damping materials IF.

That is, like the optical disc damping material If, the optical disc vibration damping material IF is made of a thin elastic metal plate with a sheet-like vibration damping rubber material for optical disc devices stretched on at least one side.

Then, one end of each of the pair of optical disk damping materials IF is coupled to the L surface of the external holder 22a with an appropriate interval, the other end of each is coupled to a fixing part (not shown), and the other Noko optical disc vibration damping material IF
By connecting one end of each to the lower surface of the external holder 22a with an appropriate distance of 1ljl, the external holder 22a is held in water. is the objective lens.

In this embodiment, +'+77 external halter 22a or
Since it is elastically held horizontally with respect to the fixed part (not shown) by the vibration damping material IF for the optical disk device,
The optical disc device vibration damping material IF absorbs vibrations in the focus direction (direction of arrow F in Figure 6) that occurs when the entire objective lens holder is suddenly displaced in the track direction (direction of arrow T in Figure 6). Also, the internal halter 23b
Or the damping material for optical disk device from the external holder 22a if
Even if the entire objective lens holder is suddenly displaced in the track direction, the vibration damping material 1f for an optical disk device effectively absorbs the sudden kinetic energy, allowing the external halter 22a and the internal holder to 23
It is possible to stop at a predetermined position without causing resonance.

Therefore, even if the entire optical pickup device is suddenly displaced for signal reading, the sudden displacement of the objective lens holder 6 mounted on the optical pickup device is alleviated within a very short time.

Only accurate signal reading is possible.

In this embodiment, the damping material if for an optical disk device may be held by suspending the internal halter 23b, or may be held by some other method.

That is, the lower end portions of the pair of damping materials If for an optical disk device are respectively coupled to the F side of the inner wall of the internal space 23c in the external halter 22a.

Further, the upper end portions of the vibration damping materials if for the optical disk device are respectively connected to the upper end portions of the side surfaces of the internal holter 23b facing the inner wall. Similarly, its lower end is connected to the lower part of the inner wall of the internal space, and its -F end is connected to the -L end of the internal holder 23b. the result,
The internal holder 23b is supported and held by the upper ends of the four optical disc device vibration damping members 1f.

(Example 10) FIG. 7 is a cross section l''A showing the body of an optical disc device.

As shown in FIG. 7, the damping material for an optical disc device in this embodiment is similar to that in the first embodiment! There are 20 sheets of l/I rubber material (tatami, thickness 0.2 to 3 mm), body 2 of the optical disc device.
It is used for the lining of 1.

The optical disc device vibration damping material in this embodiment absorbs, for example, external vibrations applied to the optical disc device, such as pressure generated from a speaker, or internal vibrations, such as vibrations transmitted from the speaker through the body, thereby producing accurate signals at the objective lens holder. Ensure reading.

(Example 11) No. 81:A is an explanatory diagram showing the installation state of a power transformer installed in an optical disc device.

As shown in FIG. 8, in this optical disk device, a sheet Ig of anti-vibration rubber material for an optical disk device similar to that in the first embodiment is attached to the power transformer 24 or the base 25.
However, the damping material (with a thickness of 0.2 to 10 mm) is used as a damping material for an optical disk device and is installed as an underlay. The power transformer 24 is fixed with a bolt 26 that is screwed through a flange provided at the base of the power transformer 24 and a base 25. In addition, in this embodiment, the bolt 26 is equipped with a sheet lh of anti-vibration rubber material similar to that used in the first embodiment of the crime, as a washer, with a thickness of 0.2 to 5 mm. It has been intervened.

Damping materials 1g and 1f for optical disk devices in this example
IF prevents the self-vibration of the power transformer 24 from being transmitted to the base and objective lens holder, and as a result,
Ensure accurate signal reading in the objective lens holder.

In this case, the loss coefficient and elastic modulus of the vibration damping materials 1g and lh for optical disk devices do not change significantly depending on the temperature, so
Even if the power transformer 24 generates heat during operation, a stable vibration damping effect is exhibited and accurate signal reading at the objective lens holder is ensured.

(Example 12) The 9th UA is ``Theory 11 indicating the leg of the optical disk device [2
It is.

As shown in FIG. 9, the damping material for an optical disk device in this example is formed of a sheet li (warped, thickness: 0.2 to 20 mm) similar to that in Example 1. , is interposed between the bottom surface of the mounting section 28 of the body 27 of the optical disk device and the installation floor surface 29.

The vibration damping material 11 for an optical disk device in this embodiment blocks various vibrations transmitted from the installation floor 29 to the optical disk device, and as a result, ensures accurate signal reading at the objective lens holder.

Note that the damping material for the optical disk device provided on the bottom surface of the leg portion 28 is not limited to the sheet described in this embodiment, but may be a molded product having an appropriate shape, and the same effects as described above can be obtained.

(Example 13) The 1θ diagram shows the mechanical part in the optical disk device 111
;4.

The mechanical part is located on the L of the base 30 of the optical disc body,
It is erected and fixed by four (two not shown) support portions 31 or screws 32 via a vibration damper 1g for an optical disk device similar to that in the eleventh embodiment.

A rope ink base 33 is provided on the support part 31.

The rope ink base 33 has four shafts 35 (for example,
Two shafts (not shown) are erected, and this shaft body 35 is
The substrate 36 is loosely fitted into a through hole 37 provided in a substrate 36, and this substrate 36 has a substantially cylindrical vibration damping material 1j for an optical disk device wrapped around the shaft body 35, and a vibration damping material 1j for an output side of the optical disk device.
It is elastically held by a coil hem 38 wound around the outer periphery of the holder.

The damping material lj for the optical disk device described in Example 1 is as follows.
It is made up of a combination of ingredients and ingredients.

This board 36 is equipped with a turntable 39, a motor 40 for rotating the same, an optical pickup device 41 containing an objective lens holder, and a linear motor 42 for moving the same in the track direction.

Note that the objective lens holder has a 17I I for optical diff device using a 4-wire one-way type, a rotation type, a hinge type, or a plate spring type, as in the above embodiment.
N material is installed.

In the mechanical part having such a configuration, the vibration damping materials 1g, li, and lj for the optical disk device transmit external vibrations generated externally from the mechanical part and transmitted through the base 30 to the objective lens holder 41. Defense: 1,
Coupled with the fact that an optical disc damping material using one of the methods described above is installed in the objective lens holder 41, this objective lens holder always remains accurate even in the presence of external vibrations or rapid displacement of the objective lens holder. It is possible to ensure that information can be read from the optical disc.

[Effects of the Invention] According to the configuration described in claim st+t, the vibration isolating rubber material for an optical disk device uses a specific original 1, has a vibration loss coefficient of 0.1 or more, and has an elastic modulus of L X l
O' ~l Since the material has a vibration loss coefficient of 0.1 or more, it has excellent vibration absorption properties, and therefore is a suitable anti-vibration rubber material for optical disc devices placed in environments with strong vibrations.Furthermore, this optical disc Since the vibration loss coefficient of the anti-vibration rubber material for devices has almost no temperature dependence, the anti-vibration rubber material for optical disk devices can be suitably applied to optical disk devices installed in automobiles where temperature changes are large. .

According to the configuration described in claim 2, J! Since the anti-corrosion agent is blended, it is possible to provide a vibration-proof rubber material for an optical disk device that has a long vibration loss coefficient a and a long-term elastic modulus.

The anti-vibration rubber material for optical disc devices according to claims 1 and 2 further allows the elastic modulus to be easily selected within a wide temperature range, has a small compressive strain, and easily exhibits anti-vibration properties. It is possible to make it flame retardant without damaging it. And this optical disc! The anti-vibration rubber material for A is cold resistant,
Excellent heat resistance, weather resistance, and ozone resistance.

According to the configurations described in claims 13 to 7, the resonant sharp lff
Even if the optical pickup device is suddenly displaced to read the signal of the optical disk L, the vibration damping material for the optical disk device attached to the objective lens holder can significantly lower the 1Q.

By absorbing the rapid kinetic energy of the optical read-up device, the objective lens holder can be stopped at an accurate information reading position with respect to the optical disc.
It is important to read information from optical discs accurately.

According to the configurations described in claims 8 to 11, it is possible to effectively prevent internal vibrations of the optical disc device or vibrations generated from an external vibration source from being transmitted to the objective lens holder.

Therefore, it is possible to provide a vibration damping material for an optical disk device which is excellent in terms of vibration damping properties and can cause the optical pickup device to accurately follow the pitch of an optical disk rotating at high speed.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing an optical disc mounting vibration damping material according to an embodiment of the present invention, and 2UA is an explanatory diagram illustrating a state in which the optical disc vibration damping material is used in an optical pickup device.
, FIG. 3 is an explanatory diagram showing a state in which a damping material for an optical disc device according to another embodiment of the present invention is used in an optical pickup device, and 41'A is an explanatory diagram showing a damping material for an optical disc device according to another embodiment of the present invention. A plan view showing the damping material! 55 [A is a partially cutaway perspective view showing another embodiment of the present invention, FIG. 6 is a partial cross-sectional perspective view showing another embodiment of an undeveloped IJ, and FIG. 7 is a partially cutaway perspective view showing another embodiment of the present invention. FIG. 8 is a partially sectional explanatory diagram showing another embodiment of the present invention, No. 9+1 is an explanatory diagram showing another embodiment of the present invention, and FIG. io is an explanatory diagram showing another embodiment of the present invention. It is an explanatory view showing an example. l a -1j...Vibration damping material for optical disc device, 2...
・Metal elastic body, 4, 4a, 4b... fixed part, 5...
Objective lens, 6.6a, 6b...Objective lens holder 110...4 holes, 11... Support shaft, 12... Hinge mechanism. Figure 1 Figure 2 Figure 3 Figure 4 11101 (j Figure 5 Figure 80 Figure 9 or

Claims (11)

[Claims] (1) 100 parts by weight of synthetic rubber and a specific surface area of 50 m^2
/g or more, 10 to 150 parts by weight of silica fine powder, and the formula ▲ mathematical formula, chemical formula, table, etc. ▼ (However, in the above formula, R^1 and R^2 are the same or different unsubstituted or substituted 1 is a valent hydrocarbon group, R^1
and at least one of R^2 is a phenyl group or an alkyl group having 2 to 10 carbon atoms, m is 1 to 20, and n
represents an integer from 0 to 20. ) by containing 3 to 20 parts by weight of an organopolysiloxane represented by
is 0.1 or more and the elastic modulus is 1×10^4 to 1×
A vibration-proof rubber material for an optical disk device, characterized in that it has a vibration resistance of 10^9 dyne/cm^2. (2) The anti-vibration rubber according to claim 1 contains an anti-aging agent,
A vibration-proof rubber material for an optical disk device, characterized in that the rubber material is contained in a proportion of 0.01 to 10 parts by weight based on 100 parts by weight of the synthetic rubber. (3) A vibration damping material for an optical disc device, characterized in that the vibration isolating rubber material for an optical disc device according to claim 1 is formed into a rod-shaped body, and an elastic metal body is inserted into the rod-shaped body. (4) The vibration isolating rubber material for an optical disk device according to claim 1 is formed such that one end of the metal elastic body is inserted thereinto and can be attached to an objective lens holder and/or a fixing part. Damping material for optical disc devices. (5) The anti-vibration rubber material for an optical disk device according to claim 1 is attached to the fixing part and the rotary objective lens holder which holds the objective lens and has a support shaft inserted into the through hole provided at the center. A vibration damping material for an optical disc device, characterized in that a rotatable objective lens holder is rotatably connected to the support shaft. (6) In an optical pickup device in which an objective lens holder that holds an objective lens and a fixed part are connected by a hinge mechanism, the optical pickup device is arranged between the fixed part and the objective lens holder, and the hinge part of the hinge mechanism is arranged between the fixed part and the objective lens holder. A vibration damping material for an optical disc device, characterized in that the vibration isolating rubber material for an optical disc device according to claim 1 is formed so as to surround at least a part of the material. (7) A system for an optical disk device, characterized in that the anti-vibration rubber material for an optical disk device according to claim 1 is stretched over at least one surface of a metal plate, and the objective lens holder and the fixing portion are connected and supported. Shaking material. (8) The anti-vibration rubber material for an optical disc device according to claim 1 is formed into a sheet that can be worn on the body of an optical disc device that reads digital information by irradiating pits formed on the optical disc with a semiconductor laser beam. A vibration damping material for an optical disk device, characterized by comprising: (9) The anti-vibration rubber material for an optical disk device according to claim 1 can be used as a transformer in an optical disk device that reads digital information by irradiating pits formed in an optical disk with a semiconductor laser beam, and a substrate on which the transformer is mounted. A damping material for optical disk devices that is interposed between the two. (10) An optical disc device in which the anti-vibration rubber material for an optical disc device according to claim 1 reads digital information by irradiating pits formed on the optical disc with a semiconductor laser beam, the optical disc being worn on a leg of the body. Damping material for equipment. (11) The anti-vibration rubber material for an optical disc device according to claim 1 is used as a floating material for a mechanical part in an optical disc device that reads digital information by irradiating pits formed on the optical disc with a semiconductor laser beam. Damping material for optical discs.