JP2003168229A - Wire rod for suspension wire of optical pickup and optical pickup device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To have little changes across the ages to keep holding an actuator at home position for a long period, and to enable stable signal reading. <P>SOLUTION: The actuator 3 is loaded with an objective lens 4 for guiding a laser beam 2 emitted by a laser beam source 1 and with a driving coil for positional control. A suspension wire 5 movably supports the actuator 3 and supplies a position control signal to the driving coil. One end of the suspension wire 5 is connected by solder to the signal input terminal 6 of the driving coil of the actuator 3 while the other end to the control signal output terminal 8 of a control substrate 7. The suspension wire 5 is composed of a copper silver alloy. <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 a wire for a suspension wire of an optical pickup device and an optical pickup device.

[0002]

2. Description of the Related Art In a CD player, a CD-ROM device, etc., an optical pickup device is used for reading and reproducing information recorded on an optical disk. In this optical pickup device, the wavelength emitted from the laser light source is about 70
The signal recording surface of the optical disk is irradiated with a laser beam of about 0 nanometer, and the reflected beam reflected from the pit array having minute irregularities is detected by a photodetector and converted into an electric signal. At this time, if the laser light emitted from the laser light source is not accurately and vertically focused on the pit row, the reflected beam is distorted due to aberration or the like, and noise is mixed or a reading error occurs.

Therefore, an apparatus has been developed in which an objective lens for guiding a laser beam is prepared and the position of an actuator equipped with this objective lens is controlled by an electromagnetic force in the tracking direction and the focus direction (Japanese Patent Laid-Open No. Hei. 5-2
66507). Further, an optical pickup device has been developed in which the actuator is supported by four metal wires so that the optical axis of the laser beam is always perpendicular to the pit row forming surface by controlling the position of the actuator. (JP-A-5-266507). Since the metal wire for supporting the actuator is required to be flexible and elastic, copper beryllium alloy or phosphor bronze is used.

[0004]

By the way, the above conventional techniques have the following problems to be solved. The gravitational force of the actuator is constantly applied to the metal wire that supports the actuator, and even if it is a straight line at the beginning, the curve becomes remarkable over time, the home position changes, and the position control performance and accuracy decrease. there were. Particularly, the phosphor bronze alloy has a problem that such a tendency is remarkable as compared with the beryllium alloy.

Further, one end of the metal wire is used as an actuator,
The other end is soldered to the control board. Regarding soldering connectivity, copper beryllium alloy has poorer solderability than phosphor bronze. In order to improve the solderability, surface treatment such as silver plating is required, which causes a problem that the cost of the metal wire becomes high. Further, the copper-beryllium alloy is toxic, and there is a problem that special attention is required for management in manufacturing work, recycling treatment, and environmental impact.

Further, in recent optical pickups, the position of the lens is controlled by being supported by the electromagnetic force. This control current is supplied to the actuator via a metal wire that supports the actuator. At this time, phosphor bronze and copper beryllium alloy have a problem in that the electrical conductivity is small and the amount of heat generated is large and the device is adversely affected.

[0007]

The present invention adopts the following constitution in order to solve the above points. <Structure 1> A wire rod for a suspension wire of an optical pickup device, which is made of a copper-silver alloy.

<Structure 2> The suspension of the optical pickup device according to Structure 1, wherein the copper-silver alloy contains 0.08 to 15% by weight of silver, and the balance is copper and inevitable impurities. Wire material for wire.

<Structure 3> The suspension wire for an optical pickup device according to Structure 1 or Structure 2, wherein the copper-silver alloy is continuously cast and has a workability of 94% or more after precipitation heat treatment. Wire rod.

<Structure 4> The structure 1 is characterized in that the suspension wire is made of a stranded wire of the copper-silver alloy.
4. A wire rod for a suspension wire of an optical pickup device according to any one of items 1 to 3.

<Structure 5> An actuator equipped with a laser light source, an objective lens for guiding the laser light emitted from the laser light source, and a drive coil for position control, and a plurality of suspension wires movably supporting the actuator. The optical pickup device, wherein the suspension wire is made of a copper-silver alloy.

<Structure 6> The optical pickup device according to Structure 5, wherein the copper-silver alloy contains 0.08 to 15% by weight of silver, and the balance is copper and inevitable impurities.

<Structure 7> The optical pickup device according to Structure 5, wherein the copper-silver alloy contains 2 to 15% by weight of silver, and the balance is copper and inevitable impurities.

<Structure 8> The optical pickup device according to Structure 5, wherein the copper-silver alloy is continuously cast and has a workability of 94% or more after precipitation heat treatment.

<Structure 9> The optical pickup device according to Structure 5, wherein one end of the suspension wire is soldered to the actuator and the other end is connected to the control board side.

<Structure 10> An actuator equipped with a laser light source, an objective lens for guiding the laser light emitted by the laser light source, and a drive coil for position control, and the actuator movably supported and positioned on the drive coil. An optical pickup device, comprising: a plurality of suspension wires for supplying a control signal, wherein the suspension wires are made of a copper-silver alloy.

<Structure 11> The optical pickup device according to Structure 10, wherein the copper-silver alloy contains 0.08 to 15% by weight of silver, and the balance is copper and inevitable impurities.

<Structure 12> The copper-silver alloy is 2 to 15
11. The optical pickup device according to the constitution 10, characterized in that it contains silver by weight and the balance is copper and inevitable impurities.

<Structure 13> The optical pickup device according to Structure 10, wherein the copper-silver alloy is continuously cast and has a workability of 94% or more after precipitation heat treatment.

<Structure 14> The optical pickup device according to Structure 10, wherein one end of the suspension wire is soldered to the actuator and the other end is connected to the control board side.

<Structure 15> One end of the suspension wire is soldered to a drive coil signal input terminal of the actuator, and the other end is soldered to a control signal output terminal of the control board. 11. The optical pickup device according to the structure 10.

<Structure 16> The optical pickup device according to claim 5 or 10, wherein the suspension wire is formed by twisting three or more wires made of a copper-silver alloy.

<Structure 17> The optical pickup device according to claim 16, wherein the suspension wire has a twist pitch of not less than 5 times and not more than 15 times the core diameter.

[0024]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to specific examples. In the present invention, a copper-silver alloy is adopted as a wire material for an optical pickup device which has high flexibility, good solderability, and high conductivity. The main properties of the copper-silver alloy are disclosed in, for example, Japanese Patent Laid-Open No. 2000-199042. The price of copper-silver alloy increases as the content of silver increases. However, if the silver content is too low, the characteristics required for the optical pickup cannot be obtained.
Therefore, the present inventors have sufficient practicality, and
Developed an economical wire rod.

(Tensile Strength of Wire) FIG. 1 is an explanatory diagram showing the relationship between the silver content of the copper-silver alloy and the tensile strength. This figure shows the relationship between the Ag content and the maximum tensile strength when the cold workability is maximized. The vertical axis represents the maximum tensile strength (MPa) at the working limit, and the horizontal axis represents the Ag content (weight).

First, Cu-having various Ag contents (weight) in the range of 0.08% (weight) to 24% (weight).
A cast rod (Φ8 mm) of Ag alloy is produced. After subjecting this rod to precipitation heat treatment at 450 ° C. for 10 hours, cold working was carried out to a working limit (at least 94% or more of working ratio) at which breakage due to work hardening occurred, and wire sample was prepared for each Ag content (weight). To do. A tensile test is conducted on the sample prepared through the above steps.

As shown in FIG. 1, the Ag content is 0.08%.
From (weight) to about 15% (weight), the maximum tensile strength at the working limit increases as the Ag content increases. However, when it exceeds 15% (weight), conversely, the maximum tensile strength at the working limit decreases. That is, the Ag content is 1
In the range of 5% or less, the higher the Ag content, the higher the maximum tensile strength. At an Ag content of about 15% (weight), the maximum tensile strength at the working limit shows the maximum value. On the other hand, in the range where the Ag content exceeds 15% (weight), it becomes difficult to perform cold working, and thus it becomes difficult to obtain the effect of increasing strength by work hardening.

As the wire for the optical pickup device, one having a high tensile strength is desirable, but in consideration of the above characteristics, it is practical to use a copper-silver alloy having an Ag content of 0.08 to 15% by weight. There is also a conclusion that it is economical. That is, even if the content of silver is increased excessively, the tensile strength does not increase, which is uneconomical. Also, Ag
If the content is less than 0.08% (weight), the conductivity is not much improved as compared with copper, and the tensile strength is practically insufficient. Therefore, the Ag content of the wire for suspension wire of the optical pickup device of the present invention is set to 0.08 to 15% by weight or less.

(Flexural Breaking Strength of Wire) FIG. 2 is an explanatory view of the test result of the flexural breaking strength of the silver-copper alloy. In FIG. 2, the horizontal axis represents the tensile strength (MPa), and the vertical axis represents the number of bending breaks. The data of the test sample Ag content 3% (weight) is represented by the curve C3 (•). The data of the test sample Ag content 10% (weight) is represented by the curve C10 (◯).
The data of the test sample Ag content 14% (weight) is represented by the curve C14 (x).

As is clear from FIG. 2, the curve C3
(•), the curve C10 (∘), and the curve C14 (x), the tensile strength is 800 MPa or less, and the number of flexural fractures is 50 or less, which is sluggish. However, the tensile strength is 900 MPa
After that, the number of bending breaks increased sharply and increased almost linearly. That is, it can be said that a material having a tensile strength of 900 MPa or more is strong in bending and is practical. This property is represented by the curves C3 (•), C10 (∘), and C1.
There is not much difference in 4 (x).

FIG. 3 is an explanatory view of the principle of the swinging and repeating bending tester used for the above-mentioned bending rupture strength test. As shown in the figure, a weight 23 is attached to the tip of a test sample 22 suspended through a die 21. Wire diameter φ of test sample 22 = 0.1 mm, curvature R of die 21
= 0.5 mm, the load of the weight 23 is 35 g. The repeated test is performed by swinging the die 21 around the contact point between the die 21 and the wire. Both this device and the test method are standardized methods.

The suspension wire of the optical pickup device is required to have a strong property against repeated bending. According to the above results, it is preferable to use a copper-silver alloy having a tensile strength of at least 800 MPa or more, preferably 900 MPa or more. By comparing this result with the characteristics shown in FIG. 1, it was concluded that a silver content of 2 to 15% is more preferable for a wire for suspension wire of an optical pickup device.

(Optical Pickup Device) FIG. 4A is a perspective view showing a specific example of the optical pickup device of the present invention.
(B) is a side view of a main part for showing the operation of the suspension wire. In the figure, the laser light source 1 which is simply indicated by a broken line frame is composed of a laser diode or the like. An actuator 3 shown in the figure is provided to guide the laser light 2 emitted from the laser light source 1. The actuator 3 is equipped with an objective lens 4 and a drive coil for position control. The drive coil for position control is not shown in the figure because it is built in the actuator 3.

The actuator 3 is provided with four suspension wires 5 for supplying a signal for position control to the drive coil. One pair is used for controlling the tracking direction (direction of arrow X), and the other pair is used for position control in the focus direction (direction of arrow Y). One end of these suspension wires 5 is soldered to the drive coil signal input terminal 6 of the actuator 3. The other end of the suspension wire 5 is soldered to the control signal output terminal 8 of the control board 7.

The control board 7 is fixed to, for example, the body of a CD player, and the actuator 3 is suspended and supported right above the optical disc by four suspension wires 5. As a result, the laser light 2 emitted from the laser light source 1 is accurately focused on the pit row forming surface 11 by the objective lens.

The actuator 3 is position-controlled in the tracking direction (direction of arrow X) and the focus direction (direction of arrow Y) by the force of an electromagnet (not shown). The details of this position control mechanism are known from, for example, Japanese Patent Laid-Open No. 5-266507, and therefore, illustration and description thereof are omitted. During this position control, the suspension wire 5 that supports the actuator 3 is freely curved in a direction that allows movement of the actuator. For example, when the actuator 3 moves in the focus direction (direction of arrow Y), the suspension wire 5 bends as shown by the broken line in (b) of the figure.

In order to mechanically protect the connecting portion (fixed end portion) between the suspension wire 5 and the control board 7, a damper 9 made of rubber or the like is provided in close contact with the control board 7 side. When the electromagnetic force for position control disappears, the free single side of the suspension wire 5 returns to the solid line position again. At this time, the suspension wire 5
Is produced by using the above-mentioned wire material for an optical pickup device, so that a device with little secular change is realized.

(Processing Method for Wire Rod) The above wire rod is manufactured as follows. First, the material contains 0.08% by weight or more and 15% by weight or less of silver, and the balance is copper to produce a copper silver alloy. This copper-silver alloy is alternately subjected to cold working and heat treatment using a continuous casting machine to obtain a wire diameter of 0.1 mm.
To thin lines. In the present invention, a super-saturated eutectic structure is created by continuously casting the copper-silver alloy having the above-described structure, and precipitation heat treatment is performed to finely precipitate silver and copper in the alloy. This is further drawn into filaments by cold working.

It is desirable that this cold working is performed at a working ratio of 94% or more. By applying such high cold working, the eutectic structure is stretched into fine filaments to form a dense fiber-reinforced structure. Further, by applying high cold working after the precipitation heat treatment, the pinning effect of fine precipitates on the accumulation of dislocations due to working is exhibited,
A high tensile strength of Pa or more can be obtained. Thus, it is considered that an alloy wire having a high strength and a high conductivity can be obtained and, as will be described later, a high characteristic against sag when applied to a suspension wire. Further, since it is made of silver and copper, the soldering connectivity is extremely good. Moreover, since it is made of a binary material of silver and copper, it has excellent recyclability and environmental friendliness.

(Wire sag test) FIG. 5 is an explanatory view of a characteristic test of a suspension wire of an optical pickup device of the present invention, (a) and (b) are explanatory views of test conditions, and (c).
[Fig. 3] is an explanatory diagram showing test results. This test is made especially for the purpose of comparing the sag phenomenon of the suspension wire with the conventional one. As the sample shown in (a), a rod-shaped sample having a wire diameter of 1 mm and a length L of 200 mm was used. Each sample had one end supported by a damper 9 and the other end free, and a load F was repeatedly applied from the other end to a position W = 3 mm to make a bending motion with an amplitude H = 5 mm of 1 mm.
I went, 000,000 times. After the test, as shown in (b),
Displacement of the free end appears due to the settling phenomenon. This width Z was measured. The sagging phenomenon is a phenomenon in which the curvature becomes remarkable with the passage of time. When the sag phenomenon occurs, the optical pickup gradually shifts from the home position, and the controllability deteriorates.

The phosphor bronze alloy of the comparative example used in the test contained 6.1 wt% of tin (Sn) and 0.1% of phosphorus (P) in copper (Cu).
It contains 1% by weight. The copper-beryllium alloy contains copper (Cu) and beryllium (Be) in an amount of 1.9% by weight. The copper-silver alloy which is an example of the present invention contains copper (Cu) and silver (Ag) in an amount of 10% by weight. In the example of (c) of FIG. 1 to No. Three
Up to three tests have been conducted.

As can be seen from the results of this test, when the copper-silver alloy of the present invention was used, when compared with the phosphor bronze alloy,
Even if the bending motion is performed many times, the deviation from the home position can be sufficiently suppressed. In addition, it has better characteristics than the copper beryllium alloy.

(Soldering Connectivity of Wires) FIG. 6 shows the test results of soldering connectivity. This test shows the results of observing the surface condition when soldering was applied to the end of the sample which was exactly the same as that used in the above test. In this test, solder in which tin (Sn) and lead (Pb) were adjusted to a ratio of 50:50 was melted and the solder bath temperature was set to 25.
The one kept at 0 ° C was used. The sample was dipped in this solder bath for 1 to 4 seconds for observing the solder attached to its end. None of them have undergone any special surface treatment or pretreatment. As a result, when the immersion time was 2 seconds to 3 seconds, the copper-silver alloy of the present invention was able to make a good soldering connection, while the alloys of Comparative Examples all had a degree of partial solder adhesion. Does not show satisfactory soldering connectivity.

When the immersion time was 4 seconds, solder was uniformly applied to all the samples. However, if the immersion time in the solder bath is long, it has a great influence on other parts connected to the substrate or the like, so that 4 seconds is too long to be adopted. Therefore, it was proved that the copper-silver alloy of the present invention showing a good soldering connection property with an immersion time of 2 seconds to 3 seconds is suitable. Regarding conductivity, beryllium copper alloy has 30% IACS to 40% IA
Compared to CS, copper-silver alloy is about twice as much as 70% IACS
To 80% IACS.

As described above, according to the optical pickup device wire of the present invention, good soldering connection can be achieved in a short time without costly surface treatment or the like.

(Example Using Stranded Wire) The content described above is for the case where the wire rod for the optical pickup device selected by the present invention is used as the suspension wire, and the present invention is applied when the single wire is used. It is not limited. That is, when used as a stranded wire,
Even better results are obtained. The contents of the test using the stranded wire will be described below.

(1) Test sample The test sample is a copper-silver (Cu-Ag) alloy with a silver content of 10%, Φ 0.03 mm, 7 strands (layer core diameter 0.06 mm).
4 suspension wires and the conventionally used copper beryllium (Cu-Be) alloy, 4 suspension wires with a diameter of 0.07 mm.

(2) Test Method In the swinging and bending tester shown in FIG. 3, the weight 23 is set to 14 g, the curvature R is set to 1 mm, and the die 21 is tilted 90 degrees left and right at a bending speed of 60 times / minute. The number of fractures was measured by.

(3) Test result (Cu-Ag) 16,645 times 10,255 times 13,709 times 11,33
3 times average 12,985 times (Cu-Be) 2,116 times 1,840 times 2,157 times 1,16 times
2 times average 1,819 times

(4) Discussion As shown by the test results, the copper-silver (Cu-Ag) alloy having a silver content of 10% according to the present invention, Φ0.03 mm, and 7-strand (layer core diameter 0.06 mm) suspension wire is It can be seen that the bending performance is 7 times or more as compared with the conventional copper beryllium (Cu-Be) alloy and the suspension wire of Φ0.07 mm. Therefore, even if the content of silver is less than 2% by weight, if the content of silver is 0.08% by weight or more, the bending performance can be sufficiently put to practical use. Moreover, by keeping the silver content low, it can be made extremely economical.

(Relationship Between Twist Pitch and Layer Core Diameter) FIG. 7 is an explanatory diagram of the layer core diameter of the twisted wire. Layer core diameter D as shown
Is the distance between the centers of the strands located in the outer layer of the stranded wire. If the strand diameter is set to d, in the case of 7 strands, the core diameter D
= 2d. Therefore, the above sample (Cu-Ag) Φ
Since the core diameter of the 0.03 mm, 7-stranded wire is 0.06, the thickness is almost equal to that of the (Cu-Be) single wire Φ0.07 mm.

According to an experiment, when a twisted wire of a copper-silver alloy is used and the twist pitch is less than 5 times the layer core diameter, strong twisting of the twisted wire occurs and the suspension wire As a result, the straightness required and the formability of the shape are inferior. In addition, disconnection is likely to occur during the twisting process. On the other hand, if the twisting pitch exceeds 15 times the core diameter, the twisting tendency is hard to occur, so the twisted wire is not well organized, and the twisting is loosened at the ends and the wire is scattered. Further, if the suspension wire is formed into a stranded wire under this condition, the springback unlike a single wire is reduced, and the stability of the form is improved. Therefore, it is preferable that the wire pitch for the suspension wire of the optical pickup device has a twist pitch of 5 times or more and 15 times or less of the core diameter. If the number of twisted wires is 3 or more,
A further effect can be expected, and a 7-stranded wire is most suitable. From the above results, it can be seen that the wire rod for an optical pickup device according to the present invention can obtain a bending performance more than expected by using not only a single wire but also a twisted wire.

Although the number of suspension wires supporting the actuator is four in the above embodiment, the number may be increased or decreased as necessary. Further, since the wire rod for an optical pickup device according to the present invention has good workability, it is possible to work the suspension wire into an arbitrary shape, for example, an S shape or a Z shape. Also,
The suspension wire that supports the actuator and the signal line that supplies the control signal to the position control coil may be different. However, in the device of the present invention, since the conductivity of the suspension wire is extremely large, the cost reduction and the like can be achieved if it is also used for supplying the control signal. The wire rod for the suspension wire of the optical pickup device according to the present invention has a good workability and moldability, which enables further reduction in size and weight of the optical pickup device. Therefore, CD-R and DVD (Di
gital Versatile Disc), DVD-RAM (Digital
Versatile Disc-Random Access Memory) and other optical pick-up devices can exhibit their effects. It is also suitable for a DVD and CD shared pickup. D
Since the focal length of the pickup is different between VD and CD, the advantages of the optical pickup device of the present invention having high bending performance can be utilized.

[0054]

The wire rod for an optical pickup device according to the present invention described above has a minimum increase in material cost, and
It has good solderability, good flexibility, and high conductivity. By using a stranded wire for this wire, the flexibility is further improved. Further, the optical pickup device using the wire rod for the optical pickup device is less susceptible to aging compared with the case of using phosphor bronze or the like, and the actuator can be continuously supported at the home position for a long time. Further, this makes it possible to keep the optical axis of the objective lens mounted on the actuator always perpendicular to the pit row forming surface. Therefore, stable signal reading becomes possible.

[Brief description of drawings]

FIG. 1 is a diagram showing a relationship between a silver content rate and a tensile strength in a copper-silver alloy.

FIG. 2 is an explanatory view of a test result of flexural rupture strength.

FIG. 3 is an explanatory view of the principle of a swinging and bending tester.

FIG. 4A is a perspective view showing a specific example of the optical pickup device of the present invention, and FIG. 4B is a side view of a main part for showing the operation of the suspension wire.

5A and 5B are explanatory diagrams of a characteristic test of a suspension wire of an optical pickup device of the present invention, FIGS. 5A and 5B are explanatory diagrams of a test condition, and FIG. 5C is an explanatory diagram showing a test result.

FIG. 6 shows a test result of soldering connectivity.

FIG. 7 is an explanatory view of a layer core diameter.

[Explanation of symbols] 1 laser light source 2 laser light 3 actuators 4 Objective lens 5 suspension wire 6 Drive coil signal input terminal 7 substrate 8 Control signal output terminal 9 damper 11 Pit row formation surface

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) C22F 1/00 661 C22F 1/00 661A 685 685Z 694 694A (72) Inventor Masahiro Ichikawa Kawasaki-ku, Kawasaki-shi, Kanagawa Sakae Oda 2-1-1 No. 1 Showa Cable Denki Co., Ltd. (72) Inventor Hitoshi Shibata 2-1-1 No. 1 Oda Sakae, Kawasaki-ku, Kawasaki City, Kanagawa Prefecture F-term (Showa) 5D118 AA20 BA01 DC03 FA29

Claims (17)

[Claims] 1. A wire rod for a suspension wire of an optical pickup device, which is made of a copper-silver alloy. 2. The suspension wire of an optical pickup device according to claim 1, wherein the copper-silver alloy contains 0.08 to 15% by weight of silver, and the balance is copper and inevitable impurities. Wire rod. 3. The suspension wire for an optical pickup device according to claim 1, wherein the copper-silver alloy is continuously cast and has a workability of 94% or more after precipitation heat treatment. Wire rod. 4. The suspension wire comprises a stranded wire of the copper-silver alloy.
A wire rod for a suspension wire of the optical pickup device according to any one of 1. 5. An actuator equipped with a laser light source, an objective lens for guiding laser light emitted from the laser light source, and a drive coil for position control, and a plurality of suspension wires movably supporting the actuator. The optical pickup device, wherein the suspension wire is made of a copper-silver alloy. 6. The optical pickup device according to claim 5, wherein the copper-silver alloy contains 0.08 to 15% by weight of silver, and the balance is copper and unavoidable impurities. 7. The optical pickup device according to claim 5, wherein the copper-silver alloy contains 2 to 15% by weight of silver, and the balance is copper and inevitable impurities. 8. The optical pickup device according to claim 5, wherein the copper-silver alloy is continuously cast and has a workability of 94% or more after precipitation heat treatment. 9. The optical pickup device according to claim 5, wherein one end of the suspension wire is soldered to the actuator, and the other end is connected to the control board side. 10. An actuator equipped with a laser light source, an objective lens for guiding a laser beam emitted by the laser light source, and a drive coil for position control; and a movable coil for supporting the actuator, wherein the drive coil is for position control. An optical pickup device comprising: a plurality of suspension wires for supplying a signal, wherein the suspension wires are made of a copper-silver alloy. 11. The optical pickup device according to claim 10, wherein the copper-silver alloy contains 0.08 to 15% by weight of silver, and the balance is copper and inevitable impurities. 12. The optical pickup device according to claim 10, wherein the copper-silver alloy contains 2 to 15% by weight of silver, and the balance is copper and inevitable impurities. 13. The optical pickup device according to claim 10, wherein the copper-silver alloy is continuously cast and has a workability of 94% or more after precipitation heat treatment. 14. One end of the suspension wire is
11. The soldering connection to the actuator, the other end being connected to the control board side.
The optical pickup device described in. 15. The one end of the suspension wire is
11. The drive coil signal input terminal of the actuator is soldered and the other end is soldered to the control signal output terminal of the control board.
The optical pickup device described in. 16. The optical pickup device according to claim 5, wherein the suspension wire is formed by twisting three or more wires made of a copper-silver alloy. 17. The optical pickup device according to claim 16, wherein the suspension wire has a twist pitch of not less than 5 times and not more than 15 times the layer core diameter.