JPS632998Y2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an optical information reading device that drives an objective lens in a focus direction for converging light onto a recording medium.

A conventional optical information reading device of this kind has a structure shown in FIG. In the drawing, A is a recording medium from which information can be read optically, B is an objective lens for converging the laser beam on the upper surface of the recording medium A and connecting a spot to the condensed point, and C is a magnetic circuit. The magnetic circuit C includes a pole yoke E having a cylindrical pole portion D, and a plate F.
and a magnet G, and H is a magnetic gap formed by a pole portion D and a plate F. _D1 is a sliding part formed inside the pole part D,
The objective lens B is arranged so as to be slidable on this sliding portion _D1 . I is a bobbin, and a flange portion _I1 provided at the upper end of the bobbin I is fixed to an objective lens B. Reference numeral J denotes a coil wound around the bobbin I, and the coil J is arranged within the magnetic gap H so as to be vertically movable. K is a joint portion between the coil J and the tinsel wire provided on the side surface of the flange portion _I1 .

Next, the operation of the above conventional example will be explained.
Magnetic flux is generated in the magnetic gap H by the pole yoke E, plate F and magnet G.
Now, when a signal corresponding to the focus error signal is applied to the coil J, since the coil J crosses the above-mentioned magnetic flux, it moves in the vertical direction according to the focus error signal. Therefore, the objective lens B is driven in accordance with the focus error signal, and generally, in order to miniaturize the optical pickup, it is necessary to make the magnetic circuit C thinner. However, just Magnet G
If it is made thinner, the total number of magnetic fluxes necessary to drive the objective lens B cannot be obtained in the magnetic gap H, and the amount of current flowing through the coil J must be increased. Therefore, the coil J generates heat during driving, and in extreme cases, it may burn out. Also,
Increasing the winding width and number of turns of the coil J not only increases the mass of the driven part and reduces the sensitivity, but also makes it impossible to secure the necessary width L of the joint part K for adhesively fixing the coil J and the tinsel wire. The drawback was that it disappeared.

Therefore, the present invention is an attempt to solve the above-mentioned drawbacks.The present invention is aimed at solving the above-mentioned drawbacks. By configuring the enclosed portion so that its dimensions are larger than those of the portion surrounding the coil among the members constituting the magnetic circuit, it is possible to increase the distance between the objective object and the magnetic gap without reducing the total magnetic flux of the magnetic gap. To provide an optical information reading device that aims to extend the sliding distance of a lens and secure the vertical width of a joint between a coil and a tinsel wire without increasing the vibrating mass.

Hereinafter, the present invention will be described with reference to the drawings. FIG. 2 is a longitudinal sectional view of an optical information reading device according to the present invention, and FIG. 3 is a half-cut sectional view of the same device in operation.

In the above drawings, 1 is a recording medium from which information can be read optically, and 2 is the recording medium 1.
An objective lens 3 is used to converge the laser beam on the upper surface and connect a spot to the focal point.The magnetic circuit 3 includes a pole yoke 5 having a cylindrical pole portion 4, a plate 6, and a magnet. 7, and a magnetic gap 8 is formed by the pole portion 4 and the plate 6. Moreover, the upper surface 4 of the pole part 4
a is set to be higher than the upper surface 6a of the plate 6. Reference numeral 9 denotes a sliding part formed inside the pole part 4, and the objective lens 2 is slidably disposed inside this sliding part 9. Therefore, a low-friction material 9a is coated or bonded to the inner circumferential wall.

10 is a bobbin, and a flange portion 11 is provided at the upper end of the bobbin 10, and the bobbin 10 is fixed to the objective lens 2 by the flange portion 11. Reference numeral 12 denotes a coil wound around the bobbin 10, and the coil 12 is arranged within the magnetic gap 8 so as to be vertically movable. Reference numeral 13 denotes a joint between the coil 12 and the tinsel wire provided at the upper end of the bobbin 10, and D indicates the vertical width of the joint 13.

The magnetic flux generated in the magnetic gap 8 of the magnetic circuit 3 is also distributed above the upper surface 6a of the plate 6, as shown in FIG. coil 12
are arranged so as to also cross the magnetic flux distributed above, and the number of magnetic fluxes crossed by the coil 12 is ensured in the same manner as in conventional optical reading devices.

Next, the operation of the above embodiment will be explained.
When a positional shift of the spot focused on the recording medium 1, that is, a focusing error occurs, a current according to the focus error signal flows through the coil 12, and since this coil 12 crosses the magnetic flux generated in the magnetic gap 8, the focus error signal is generated. Objective lens 2 according to
slides to correct focusing errors. At this time, the upper surface 4a of the pole portion 4 is connected to the plate 6.
Since it is higher than the upper surface 6a of the objective lens 2, the sliding distance of the objective lens 2 is extended, and therefore, lateral vibration is reduced and disturbances in the tracking direction and the tangential direction can be reduced. In addition, the joint part 13 requires a certain width D in order to adhesively fix the coil 12 and the tinsel wire, and if this width D is short, the objective lens 2 will fall to the lowest position and the bobbin will fall as shown in FIG. 10 comes close to the pole yoke 5, the joint portion 13 may enter under the plate 6 of the magnetic gap 8, and the bond between the coil 12 and the tinsel wire may come off. However, by making the upper surface 4a of the pole portion 4 higher than the upper surface 6a of the plate 6, a sufficient width D of the joint portion 13 can be ensured without increasing the vibrating mass. Furthermore, the total magnetic flux across the coil 12 remains the same, so the sensitivity of the system is not reduced.

Next, other embodiments of the present invention will be described.

In the above embodiment, an outer magnetic type magnetic circuit having a plate and a pole yoke is used, but an inner magnetic type shown in FIGS. 5 and 6 may also be used. In FIG. 5, the upper end 7a of the magnet 7 projects higher than the upper end 14a of the yoke 14, and in FIG. 6, the upper end 15a of the pole piece 17 provided on the upper part of the magnet 7
is configured to protrude above the upper end 14a of the yoke 14.

Furthermore, the optical information reading device according to the present invention includes:
It is also possible to drive an optical system such as an objective lens not only in a direction perpendicular to the information recording medium but also in a horizontal direction. FIG. 7 is an example of this, and is an example of application to the device disclosed in Utility Model Application No. 75812/1983. In this figure, driving in the focus direction perpendicular to the information recording medium is performed by a focus magnetic circuit 16 and a focus coil 17 similar to the magnetic circuit shown in FIG. Further, the information recording medium is driven in the tracking direction perpendicular to the information track by a tracking magnetic circuit 18 including a cylindrical magnet and a tracking coil 19. The optical system 20 to be driven is an objective lens or a pickup including a light source and a light receiving element. here,
The upper part 16a of the pole piece of the focus drive magnetic circuit 16 projects beyond the upper part 16b of the yoke by a distance _d1 . Further, the upper portion 18a of the pole piece of the tracking magnetic circuit 18 projects beyond the upper portion 18b of the yoke by a distance _d2 . Also in this embodiment, the focus drive coil 17 and the tracking coil 19 are the focus magnetic circuit 16 and the tracking magnetic circuit 1, respectively.
It is possible to obtain the effects of the present invention by placing it in the magnetic gap of 8.

As mentioned above, in the present invention, the portion surrounded by the coil 12 of the members constituting the magnetic circuit 3 is This optical information reading device is configured such that the dimensions of the portion of the members constituting the magnetic circuit 3 around which the coil 12 is provided are larger.

Therefore, according to the present invention, without increasing the vibrating mass,
Furthermore, a sufficient joint portion 13 between the coil 12 and the tinsel wire can be secured without reducing the total number of magnetic fluxes crossing the coil 12.

Furthermore, when the present invention is applied to an optical information reading device in which the objective lens 2 slides within the pole yoke 5, the total height of the magnetic circuit 3 can be reduced without increasing the height.
The sliding distance of the objective lens 2 is extended, and when the objective lens 2 is driven in the focus direction, lateral vibration of the objective lens 2 is reduced, and disturbances in the tracking direction and the kundiential direction can be reduced.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional view of a conventional optical information reading device, FIG. 2 is a longitudinal sectional view of an optical information reading device according to the present invention, and FIG. 3 is a half-cut sectional view of the same device in operation. FIG. 4 is a longitudinal cross-sectional view of the main part showing the distribution of magnetic flux, FIGS. 5 and 6 are longitudinal cross-sectional views of the main part showing other embodiments, and FIG. 7 is an exploded perspective view showing the state of use. DESCRIPTION OF SYMBOLS 1...Recording medium, 2...Objective lens, 3...Magnetic circuit, 4...Pole part, 4a...Top surface, 5...
Pole yoke, 6...Plate, 6a...Top surface,
7...Magnet, 8...Magnetic gap, 9...
Sliding part, 10... Bobbin, 12... Coil, 1
3...Joint part.

Claims (1)

[Scope of utility model registration request] a support member having a coil attached to its peripheral surface; a first magnetic path forming member located outside the peripheral surface of the support member; and a peripheral surface of the support member facing the first magnetic path forming member. a magnetic circuit formed by a second magnetic path forming member located inside the magnetic circuit;
The coil is located within a magnetic gap formed by the first magnetic path forming member and the second magnetic path forming member, and the supporting member is disposed so as to be movable in a direction along its central axis. An optical information reading device characterized in that an upper end portion of the second magnetic path forming member protrudes more than an upper end portion of the first magnetic path forming member in the moving direction of the supporting member.