DE3239124A1 - Optical memory with a rotating storage disk - Google Patents

Abstract

Optical memory with a rotating storage disk, having magneto-optical memory zones which are arranged in a memory area and are activated and/or scanned by a light beam. Transmitter and receiver of the light beam and the electronic elements required for activation of the memory zones are arranged in a read/write head, which embraces the storage disk from the side and can be swivelled radially and axially with respect to it. <IMAGE>

Description

Optical storage with a rotating storage disk

The invention relates to an optical memory with a rotating Storage disk on which in a storage area in circular or spiral tracks Magneto-optical storage zones for repeatable storage and retrieval of digital information is arranged and their storage states by an optical device can be activated or scanned.

Such an optical memory is disclosed in Japanese patent application 57/30 132 known. For scanning the state of the magneto-optical storage zones, placed on the rotating disk becomes a laser beam guided through the storage layer via a multiplicity of optical devices and received on the other side of the storage disk by an optical receiver and detected. There is no storage zone on the storage disk Stationary defined point understood as a result of the light beam directed at them is activated (written) by the action of temperature and magnetic field. the This point is also scanned by a light beam, but without any action of temperature and magnetic field. To now scan several memory zones one after the other or to be able to activate, the part of the laser beam going through the storage disk must either moved in parallel or pivoted by adjusting mirrors.

In order to get usable dimensions of the storage devices, the Laser beam deflected one or more times by mirror so that it can pivot of the light beam these mirrors can be used.

As can be seen from DE-OS 31 06 653, there is transparent Storage disk made of a round disc of glass or plastic material on which the storage layer with the magneto-optical storage zones is applied.

To avoid contamination or mechanical damage to this layer to avoid, it is covered with a protective layer.

It is also known, the optical scanning of digital information to be carried out on a rotating storage disk by reflecting the light beam, e.g. from DE-OS 24 03 093. For this purpose, the storage disk is also transparent. However, this is not a storage disk with electro-optical switchable memory zones but embossed and therefore no longer changeable Digital information. Such an arrangement has the opposite to the above Advantage that the optical scanning device is only on one side of the storage disk is arranged. A disadvantage is the required precise adjustment of the transmitter and receiver of the optical scanning device.

These known optical memories are very expensive, in particular due to the necessary lateral guidance of the light beam along a storage zone, which must always be exact. The pivoting of the scanning light beam above and below the storage disks can only be precisely matched to one another with great effort will.

The invention is based on the object of an optical memory to create the type mentioned, which is simple in structure, small in its external dimensions and which nevertheless has a high or higher storage capacity that of electromagnetic disk storage is equivalent to what is known as floppy disks are.

This object is achieved in that the optical device as optical write and read head is formed and arranged on a support arm, that the carrier arm mounted so that it can rotate about a stationary axis is that the optical write and read head is radial to the direction of rotation of the storage disk Can be pivoted for adjustment to the storage zones arranged in a circle or spiral is that the support arm consists of two support arm parts arranged one behind the other, which are connected to one another by a spiral spring # ystern that swivels of the support arm part carrying the optical write and read head perpendicular to the Direction of rotation of the storage disk enables (focusing).

A particularly simple pivoting of the two support arm parts can can be achieved by having a flat coil on each of the two support arm parts is attached, each of which works with a stationary magnet system in such a way that that by changing the respective magnetic field, a deflection of the support arm takes place in one direction or in the direction perpendicular to it and the stationary ones Magnet systems are designed as permanent magnet systems.

According to a further embodiment of the invention, the optical writing and read head designed so that it engages around the memory plate laterally so that the light beam transmitter in the one head part and the light beam receiver in that other headboard are housed. This ensures that the scanning of the Storage elements reached.

The storage disk itself has a diameter of 20 to 60 mm, preferably 50 mm. The width of the annular memory of the area in which the ring-shaped or spiral-shaped optical storage zones are located, is about 5 to 15 mm, preferably about 10 mm. Due to the relatively small width of the area of the storage zones is also only a slight pivoting of the optical Read and write head required, so that the storage of the support arm is constructive can be easily designed.

The clamping of the support arms can be achieved in particular by bending or Torsion springs are made.

The clamping of the optical disk can be carried out in a known manner Way. For example, the one used in magnetic disk storage Storage from a centering bearing and a Einspa onus with appropriate modification due to the smaller dimensions of the storage disk, such as e.g. for flexible magnetic disks from DE-OS 30 34 633 is known.

The invention is illustrated below using an exemplary embodiment explained in more detail. The figures show: FIG. 1 the optical write and read head with a carrier arm of the optical memory in a perspective view, FIG. 2 the storage disk in Top view and FIG. 3 shows the support arm according to FIG. 1 in side view.

In the embodiment shown in the figures are only the items absolutely necessary to understand the invention are shown. For example, the drive gear and the jig for the optical disk and automatic feed-in and feed-out devices of the storage disk not drawn. They are generally of the known drives of magnetic storage disks and can, with appropriate adaptation to the smaller dimensions of the optical storage disk can be easily adopted.

The optical storage disk 1 is made of transparent plastic and has a diameter of 50 mm. On top or on the bottom of this Storage disk 1 are known in a region 2, the width of which is a 10 mm Way magneto-optical storage zones arranged. The storage zones can be in ring-shaped or spiral be arranged in the form of tracks. In the middle of the storage disk An opening 18 can be provided for clamping in a drive which is known in the art Way consists of a centering part and a clamping cone. The clamping hole 18 has then a diameter of about 5 mm.

The storage disk 1 is supported by the head parts 4 and 5 of a writing and read head 3 encompassed. The light source is in one of these headers, e.g. 4 arranged to generate the writing and scanning beam. In the opposite Head arm, e.g. 5, is then the receiving device for the light beam. The read and write head 3 can be pivoted radially to the magnetic disk 1 (direction of the arrow P1). In addition, the read and write head 3 can be raised perpendicular to the storage disk 1 or be lowered (arrow direction P2), so that the writing and scanning beam exactly be focused on the magneto-optical storage zones arranged in area 2 can. About the pivoting of the read and write head 3 in both directions To reach P1 and P2, it is attached to a support arm, which consists of two support arm parts 10 and 11 consists. Both support arm parts 10 and 11 are supported by a spiral spring 14 connected with each other. This spiral spring 14 allows the scanning head to pivot 3 perpendicular to the storage disk 1 in the direction of the arrows P2.

The support arm part 10 is about a fixed axis which is perpendicular to the The bending plane of the spiral spring 14 is arranged, rotatably mounted, so that a radial Pivoting of the read and write head 3 in the direction of arrow P7 is possible.

The tension band spring 12, which is attached to the tension band carrier 13, serves for this purpose is attached. The strap support 13 itself is fastened to the frame 6.

Each support arm part 10 and 11 is assigned a separate magnet system, through which either the focusing or the radial pivoting of the writing and scanning beam can be controlled. For focusing the Write- and reading head .3 a flat coil 7 is provided, which is arranged on a carrier 19 which is perpendicular to the support arm part 11. The flat coil 7 is between two magnetic conductor pieces 9 are arranged, which are also perpendicular to the support arm part 11 are arranged and encompass this. There are two permanent magnets on one magnetic conductor 8 attached. The movement of the flat coil 7 takes place by current-wise control in the permanent magnetic field, so that this increases or decreases the writing and Read head 3 can be carried out exactly in the direction of arrow P2.

The same magnet system is also assigned to the support arm part 10. The flat coil 15 can either directly on the support arm part 10 or, as in the present case Example according to FIG. 3, be arranged on a special carrier 20. The flat coil 15 is also arranged here between two magnetic conductor pieces 17, one of which the two permanent magnets 16 carries. By current-wise control of the flat coil 15 the permanent magnetic field is also changed and thereby a pivoting of the support arm part 10 reached about the axis of rotation of the tension band spring 12. Since the spiral spring 14 with her flat side is arranged perpendicular to the axis of rotation of the tension band spring 12, is when the support arm part 10 is pivoted, the support arm part also inevitably 11 pivoted in the same direction.

The read and write head 3 thus becomes radial to the storage disk 1 emotional. The distance of the axis of rotation of the tension band spring 12 from the read and write head 3 and on the other hand the distance between the tension band spring 12 and the magnet system 15, 16 and 17 are chosen so that the read and write head 3 has the width a of the area 2 can sweep over with the magneto-optical storage elements.

The two magnet systems 7, 8 and 9 or 15, 16 and 17 are stationary arranged on the frame 6.

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Claims (9)

PATENT CLAIMS Optical memory with a rotating storage disk, on dgr in a memory area in circular or spiral-shaped tracks magneto-optical Storage zones for repeatable storage and retrieval of digital information are arranged and their memory states can be scanned by an optical device and can be activated, marked. that the optical device as an optical write and read head (3) formed and arranged on a support arm (10,11) that the support arm (10,11) is rotatably mounted about a fixed axis (12) in such a way that the optical writing and read head (3) radially to the direction of rotation of the storage disk (1) for the setting It is pivotable on the storage zones that the carrier arm (10, 11) consists of two one behind the other arranged support arm parts, which are connected to one another by a spiral spring system (14) are connected, which allows a pivoting of the optical write and read head (3) supporting support arm part (11) perpendicular to the direction of rotation of the storage disk (1) enabled (focusing). 2. Optical memory according to claim 1, characterized in that A flat coil (7,15) is attached to each of the two support arm parts (10, 11), each of which works with a stationary magnet system (8, 9 or 16, 17) in such a way that that by changing the respective magnetic field a deflection of the carrier arm (10,11) takes place in one direction or in the direction perpendicular to it. 3. Optical memory according to claims 1 and 2, characterized. that the levels in which the flat coils (7,15) of the support arm (10,11) each with the direction for swiveling the read and write head (3) match to which they are assigned. 4. Optical memory according to claims 1 to 3, characterized. that the fixed axis of rotation of the support arm (10,11) as a strap bearing (12) is formed. 5. Optical memory according to claims 1 to 4, characterized. that the stationary magnet systems are designed as permanent magnet systems are. 6. Optical memory according to claims 1 to 5, characterized. that the optical write and read head (3) the storage disk (1) wrapped around the side. 7. Optical memory according to claims 1 to 6, characterized. that in the storage disk (1) encompassing parts (4,5) of the optical Write and read head (3) that generates and receives the write and read beam electronic elements are arranged. 8. Optical memory according to claims 1 to 7, characterized. that the storage disk (1) encompassed by the read and write head (3) has a diameter of 20 to 60 mm, preferably 50 mm and that the on the storage disk (1) lying storage area (2) with the magneto-optical storage zones a width of about 5 to 15 mm, preferably of about 10 mm. 9. Optical memory according to claim 8, characterized in that the storage disk (1) is exchangeably mounted in a clamping device which in a manner known per se from a driven centering bearing and a pivotable one Cone part exists.