JPS6161447B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a multidimensional driving device such as a condenser lens used for recording and reproducing an optical information medium.

When recording or reproducing an optical information medium such as an optical video disk, a laser beam is focused and irradiated onto the surface of the information recording medium. In this case, since the position of the reading coordinates generally changes as the information recording medium is regularly scanned, it is necessary to make the focal point of the laser beam follow this fluctuation.

Conventionally, in order to meet the above requirements, a movable coil is fixed to a condensing lens, this movable coil is disposed in a magnetic gap, and the condensing lens is driven by supplying a control current to the movable coil. A device that tracks changes in the focus direction was used.

In such a case, a movable mirror is provided in the optical path between the light source and the condensing lens, and the optical axis is swung within the field angle of the condensing lens, so that it is perpendicular to the focus direction. It was customary to move the focal point within the plane.

However, in the above-mentioned device,
In addition to having to use a condensing lens with a large angle of view, it also required the installation of a movable mirror, which resulted in disadvantages such as an expensive and complicated configuration.

On the other hand, as shown in Figures 1 and 2,
A multidimensional drive device has been proposed that eliminates the need for a movable mirror and allows the use of a condensing lens with a small angle of view.

Figure 1 is a plan view of a conventional multidimensional drive device;
The figure is a sectional view thereof.

In the figure, 1 is a condensing lens with a small angle of view, 2
are permanent magnets supporting the condensing lens 1; 3a;
3b is a fixed coil provided on the left and right sides with a distance from the permanent magnet 2, and 4 is the fixed coil 3a, 3.
5a and 5b are parallel plate springs that support the permanent magnets 2, and 6 is a spring substrate that supports the parallel plate springs 5a and 5b.

7 is a bobbin supported by the spring board 6; 8 is a moving coil provided at the lower end of the bobbin 7; 13 is a housing; 9a and 9b are bobbin 7
A spring 11 with a wave-like cross section provided in the X-axis direction between and the housing tube 13 supports the housing tube 13,
and a first yoke provided at a position facing the movable coil 8; 10 a permanent magnet provided below the first yoke 11; 12 a permanent magnet provided below the permanent magnet 10 to support it; This is the second yoke installed in the second yoke.

As is clear from the figure, the condenser lens 1 is supported in the optical path by parallel leaf springs 5a and 5b via a permanent magnet 2 that is magnetized in the vertical direction. Therefore, by supplying a predetermined control current to the fixed coils 3a and 3b arranged on the upper surface of the coil substrate 4 provided in the housing tube 13, the condenser lens 1 can be driven in the direction of the arrow X.

In addition, the bobbin 7 attached to the spring board 6 supporting the parallel plate springs 5a, 5b is elastically movable in the Z-axis direction with respect to the spring board 6 by two upper and lower springs 9a, 9b each having a wave-shaped cross section. I support it.

A movable coil 8 provided at the bottom of the bobbin 7 is connected to a cylindrical permanent magnet 10 magnetized in the vertical direction and a yoke 1.
1 and 12 in the magnetic gap of the magnetic circuit. By supplying a predetermined control current to the movable coil 8, the condenser lens 1
is driven in the Z-axis direction (focus direction).

However, in the above-mentioned device,
Although it is possible to use a condensing lens with a small angle of view,
The structure is rather complicated, and there are disadvantages in that it is extremely difficult to drive the condenser lens in three directions: the X-axis, Y-axis, and Z-axis.

Furthermore, since the condenser lens and the permanent magnet are driven via the parallel plate springs, there is a drawback that harmful resonance of the parallel plate springs occurs at high frequencies.

An object of the present invention is to improve the structure of a multidimensional drive device, thereby eliminating the above-mentioned drawbacks, making it possible to use a condensing lens with a small angle of view, and preventing the occurrence of resonance at high frequencies. The purpose is to provide a dimensional driving device.

In order to achieve the above object, the present invention provides a condenser lens in a magnetic gap formed by a vertical drive permanent magnet and first and second yokes that contact the vertical drive permanent magnet. The condenser lens is configured to be driven in the focus direction by arranging a movable coil coaxially fixed to the bobbin which is arranged separately from the bobbin holding the condenser lens, and the condenser lens is driven in the focus direction. The condenser lens is configured to be driven in a horizontal plane by a horizontal drive permanent magnet that is slidably supported, and a tracking coil and a jitter coil that are fixedly arranged to drive the horizontal drive permanent magnet in a horizontal plane. , the horizontal drive permanent magnet and the condenser lens, first and second yokes,
The feature is that each gap between the tracking coil and the jitter coil is filled with magnetic fluid.

Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIGS. 3 and 4 are a plan view and a sectional view, respectively, of an embodiment of the present invention.

In the figure, 1 is a condensing lens, 7 is a bobbin provided to hold the condensing lens, 14 is a coil holder fixed to the middle of the bobbin 7, and 8 is an outside of the coil holder 14. A movable coil 20 provided at the end so that the winding axis direction coincides with the Z-axis direction is magnetized in the Z-axis direction,
It is a permanent magnet for vertical drive installed in an annular shape.

11 and 12 are first magnets provided above and below so as to contact each of the magnetized surfaces of the permanent magnet 20.
and a second yoke 13 on the outside of the bobbin 7,
The casing 17a and 17d are installed in a cylindrical shape so as to be substantially coaxial with the casing 13, and an upper regulating plate and a lower regulating plate are provided perpendicularly to the upper and lower ends of the casing 13, facing inward. Reference numeral 17b is a disk-shaped regulating plate provided at a distance opposite to the upper regulating plate 17a, and the lower surface thereof is in contact with the upper surface of the first yoke 11; This is a disc-shaped regulating plate provided so as to be in contact with the lower surface of the second yoke 12.

15a, 15b, 15c, and 15d are between the upper regulating plate 17a and the disc-shaped regulating plate 17b,
A pair of tracking coils are disposed between the disk-shaped regulating plate 17c and the lower regulating plate 17d so that the respective winding axes thereof are in the Z-axis direction.

16a, 16b, 16c, and 16d are between the upper regulating plate 17a and the disc-shaped regulating plate 17b,
A pair of jitter coils are disposed between the disc-shaped regulating plate 17c and the lower regulating plate 17d so that the respective winding axes thereof are in the Z-axis direction.

22a denotes the bobbin 7, the tracking coil pair 15a and 15b, and the jitter coil pair 16.
a and 16b are horizontal drive permanent magnets arranged in the gap between the upper regulating plate 17a and the disc-shaped regulating plate 17b and magnetized in the Z-axis direction.

Further, 22b is magnetized in the Z-axis direction in the gap between the bobbin 7, the tracking coil pair 15c and 15d, the jitter coil pair 16c and 16d, the disk-shaped regulating plate 17c, and the lower regulating plate 17d. This is a horizontal drive permanent magnet arranged in the same direction.

18a is a magnetic fluid filled to fill a gap around the horizontal drive permanent magnet 22a;
b is a magnetic fluid filled so as to fill the gap around the horizontal drive permanent magnet 22b.

The movable coil 8 is connected to the first yoke 11 and the second yoke.
It is placed in the magnetic gap formed by the yoke 12.

Here, the magnetic fluid is one in which fine particles of magnetite (FeO.Fe ₂ O ₃ ) with a particle size of about 100 Å are uniformly dispersed in a solvent using a surfactant. As the solvent, diester oil, fluorocarbon, ponyferryl ether, etc. are generally used in consideration of evaporability.

The gap between the holes of the horizontal drive permanent magnets 22a and 22b and the outer diameter of the bobbin 7 is about 10 to 15 μm, and the strong center holding action of the magnetic fluids 18a and 18b allows the bobbin 7 to become a horizontal drive permanent magnet. magnet pair 2
It is held at the center of the holes 2a and 22b. Therefore, the bobbin 7 has horizontal drive permanent magnets 22a, 2.
Although it is slidable in the Z-axis direction with respect to 2b, movement in the X and Y planes (horizontal planes) is restricted because the distance between the two is narrow.

Further, the gaps between the upper and lower surfaces of the horizontal drive permanent magnets 22a, 22b and the regulating plates 17a, 17b, 17c, 17d are approximately 20 to 50 μm, and the outer surfaces of the horizontal drive permanent magnets 22a, 22b and the tracking coils are approximately 20 to 50 μm. Pairs 15a to 15d and jitter coil pair 16
Since the gap between the horizontal drive permanent magnets 22a and 22b is about 1 to 2 mm, the movement of the horizontal drive permanent magnets 22a and 22b in the Z-axis direction is regulated by the regulation plates 17a, 17b, 17c, and 17d. It is slidable within the plane.

Using a multidimensional drive device configured as described above,
When the condensing lens 1 is driven multidimensionally, it is performed as follows.

By supplying a focus control current to the movable coil 8, the condenser lens 1 is driven in the Z-axis direction (focus direction). Further, by supplying a tracking control current to the tracking coils 15a, 15b, 15c, and 15d, the horizontal drive permanent magnets 22a and 22b are driven in the X-axis direction.
As a result, the bobbin 7 - i.e. the condenser lens 1
Driven in the axial direction.

Similarly, jitter coil pairs 16a, 16b,
By supplying jitter compensation currents to 16c and 16d, the condenser lens 1 is driven in the Y-axis direction.
Here, the X-axis direction and Y-axis direction are, for example, the radial direction and tangential direction of the video disc, respectively.

The present invention includes a bobbin that holds a condensing lens in a magnetic gap formed by a vertical drive permanent magnet and first and second yokes that contact the vertical drive permanent magnet as described above. A condensing lens is configured to be driven in a focus direction by arranging a movable coil that is arranged in isolation and coaxially fixed thereto, and the condensing lens is supported slidably in the focus direction. A condenser lens is configured to be driven in a horizontal plane by a horizontal drive permanent magnet, and a fixedly arranged tracking coil and jitter coil pair that drive the horizontal drive permanent magnet in a horizontal plane, and the horizontal drive Since the gaps between the permanent magnet and the condenser lens, the first and second yokes, the tracking coil, and the jitter coil are filled with magnetic fluid, it is possible to use a condenser lens with a small angle of view. With,
Since parallel plate springs are not required, there is a great advantage in that resonance at high frequencies can be prevented from occurring.

[Brief explanation of the drawing]

1 and 2 are a plan view and a sectional view of a conventional multidimensional drive device, and FIGS. 3 and 4 are a plan view and a sectional view of an embodiment of the present invention. 1... Condensing lens, 7... Bobbin, 8... Moving coil, 11, 12... Yoke, 15... Tracking coil, 16... Jitter coil, 17... Regulating plate, 18... Magnetic fluid, 20... Permanent magnet for vertical drive, 22... Permanent magnet for horizontal drive.

Claims (1)

[Scope of Claims] 1. A non-magnetic bobbin that holds a condensing lens; a movable coil that is arranged separately from the bobbin and coaxially fixed thereto, and whose winding axis direction is the long axis direction of the bobbin; a vertical drive permanent magnet arranged in isolation on the outer periphery of the bobbin; a yoke connected to both poles of the vertical drive permanent magnet to generate a magnetic flux passing through the movable coil in a radial direction; a horizontal drive permanent magnet arranged in isolation on the outer periphery and magnetized in the longitudinal direction of the bobbin; and a horizontal drive permanent magnet located in substantially the same plane as the horizontal drive permanent magnet;
a pair of tracking coils and a pair of jitter coils, each of which is on a straight line passing approximately through the center of the bobbin, and is arranged so as to sandwich the horizontal drive permanent magnet therebetween, with each winding axis oriented in the longitudinal direction of the bobbin; and a magnetic fluid filled in the magnetic gap between the bobbin and the horizontal drive permanent magnet, and in which the tracking coil pair and the jitter coil pair are arranged. 2. The above-mentioned claim further comprises regulating plates that sandwich and fix the tracking coil pair and the jitter coil pair from above and below, and horizontal drive permanent magnets are arranged at intervals between these regulating plates. The multidimensional drive device according to item 1.