RU1839270C - Optic-mechanic storage unit - Google Patents

Abstract

The invention relates to techniques for recording and reproducing information, in particular to nodes of optomechanical memory devices, and allows to improve the reliability of recording and storage of information and ease of operation. An axial displacement drive and / or a cylinder rotation drive is introduced into the assembly, and the cylinder is mounted in the cylindrical cavity of the container and mates with it through supports, the stator of the rotation drive being located on the container and the rotor on one or both ends of the cylinder 8 of the engine. 6 un.

Description

The invention relates to a technique for recording and reproducing information based on the relative movement of the recording medium and electromagnetic radiation source, and is intended for use with data banks, video and sound recording equipment, and other information storage and processing systems.

The aim of the invention is to increase the reliability of recording and storage of information and ease of operation.

Fig. 1 shows the device according to the invention together with a movable optical head and a modulated electromagnetic radiation source; in FIG. 2 - a device with a movable lens and a one-way recording coating; in FIG. 3 - a device with a movable lens and a double-sided recording coating; in FIG. 4 - a device with a fixed lens and an axial electric drive; in FIG. 5 - a device with a fixed lens and axial pneumatic drive; in FIG. 6 - device with an immersion lens and axial hydraulic drive.

In FIG. Figure 1 shows an example implementation of an optical-mechanical memory unit 1 optically coupled to a positioner 2 and a modulated electromagnetic radiation source 3. The node of the optomechanical storage device 1 includes a sealed cylinder 4, which is the actual information carrier, and a stationary opaque dust and moisture protection container 5. The sealed cylinder 4 consists of a transparent tube 6, on the inner surface of which a recording coating 7 is applied, and end sealing caps 8, which are supported by ball bearings 9. The end sealing caps 8 can be made of any suitable material and in any suitable way. On the inner surface of the sealed cylinder 4, rings 10 and 11 of materials with high magnetic and electrical conductivity, respectively, which form the rotor of the asynchronous rotation motor, are coaxially placed in its end part. sealed cylinder 4. The interaction of the latter with the stator 12 is provided through the walls of the container 5 from a material with low magnetic and electrical conductivity. In the side opaque wall of the container 5, which in FIG. 1 is made detachable with a threaded connection 13. An insert 14 of transparent material is provided. In particular, ZTZ

the insert can be made in the form of a cylindrical lens. Through insert 14, the radiation of a modulated electromagnetic radiation source 3 is fed through a positioner 2 to a predetermined portion of the recording coating 7. The source 3 includes a laser 15, an optical modulator 1.6 (for example, electro-optical), a polarizing beam splitter 17, the second optical output of which is coupled to a photodetector 18 , and a quarter wave plate 19.

Positioner 2 includes a reflective prism 20 and a lens 21.

5 Referring to FIG. 2, the embodiment of the proposed device differs from the previous embodiment in that, firstly, the container is made one-piece. Secondly, the container is used

0 air lubrication, i.e. an aerostatic bearing is used, and thirdly, the rotor of the rotation motor is spread on the outer end part of the sealed cylinder 4. In contrast to the previous embodiment, the container 5 with the sealed cylinder 4 is attached to the end stator 12, but not inserted into it. To organize air lubrication, annular grooves 22 are made in the container body 5, containing

0 jets 23 for supplying compressed air to the interior of the container 5. The annular grooves 22 are tightly closed from above by rings 24, in which openings 25 are provided for supplying compressed air 5 from the external line. Openings 26 with a check valve are provided for discharging the spent gas lubricant in the end part of the container body 5. Since with this arrangement of the stator 12 and the rotor formed by the coaxial rings 10 and 11 of materials with high magnetic and electrical conductivity, during operation of the electric motor, the rotor is attracted to the stator 12, in

5, the end wall of the container 5 is fixed bearing 27 of wear-resistant material. Opposite the support 27 on the sealing plug 8, the gasket 28 is also permanently fixed (for example, glued)

0 made of wear resistant material.

Referring to FIG. 3, an embodiment of the proposed optical-mechanical memory unit 1 comprises a cylindrical information carrier enclosed in an airtight container with a transparent liquid 29, which serves as a lubricant for the sliding bearing. The cylindrical optical medium is made of a transparent Cylinder, on the inner iA of the outer surface of which

thin, and therefore a translucent film of the recording coating is applied, on which a transparent film of the protective coating 30 is applied. Concentric rings 10 and 11 of materials with high magnetic and electrical conductivity serving as the rotor of an induction motor are placed (for example, glued) on the end parts of the optical cylinder, in the stators 12 of which the container body 5 is placed. A transparent insert 14 is provided in the container body 5 through which laser radiation is supplied to the recording cover 7. The transfer of laser radiation from one recording layer to another is provided by refocusing the movable lens (objective) 21.

Referring to FIG. 4, an example of the implementation of the proposed node of the optomechanical storage device 1 differs from the previous one, firstly, in that the lens 31 is fixedly mounted, for example, by using. optical glue on a transparent window 32 in the wall of the container 5, secondly, by positioning by means of an electric drive axial movement of the cylindrical carrier relative to the stationary container 5, and thirdly, by the length of the internal cavity of the container 5 s gas lubricant (not shown) is greater than or equal to twice the length of the recording coating 7 on a movable cylindrical storage medium. This embodiment of the inventive device also differs from the previous one by using a synchronous electric drive both to rotate the cylindrical mobile information carrier and to axially move it during the positioning process. Permanent magnets of the rotor 33 are fixed to the cylindrical moving information carrier, the magnetic lines of force of which are perpendicular to the axis of rotation of the cylindrical carrier, its electric motor of rotation and core 34, the magnetic lines of force of which are parallel to the axis of rotation of the cylindrical carrier, its linear axial electric motor. Accordingly, on the container body 5, stators 35 and 36 of a rotation motor and a positioning motor of a cylindrical movable storage medium are respectively arranged.

Referring to FIG. 5, an example implementation of a node of an optical-mechanical storage device comprises a cylindrical movable storage medium enclosed in a container 5. A cylindrical movable storage medium consists of

a transparent cylinder (tube) 6, on the inner and outer surfaces of which a recording coating 7 and a protective coating 30 are applied. In the end part of the transparent cylinder there is placed (for example, glued) a radial impermeable jumper 37 to which a permanent magnet is attached, the magnetic lines of force of which are perpendicular axis of the transparent cylinder, which is the rotor of the synchronous electric motor and placed on the side wall of the container 5 (for example, with vibration mounts). The positioning of the cylindrical mobile information carrier in this embodiment of the device according to the invention is carried out by means of a reverse pneumatic actuator axial movement of the cylindrical carrier relative to the stationary container 5, the length of the internal cavity of which exceeds the doubled length (in the axial direction) of the recording coating 7.

The positioning pneumatic actuator contains a reversible pneumatic pump Zb, line 39; as a piston, an information carrier, and as a cylinder, a congainer 5.

Referring to FIG. 6 is an example of the implementation of the proposed optical-fur assembly: a Czech storage device comprises a cylindrical storage medium enclosed in a container 5. The cylindrical storage medium consists of a cylinder

40, which can also be made of an opaque material, on the outer surface of which a recording 7 and a protective 30 coating are applied. A radially impenetrable jumper 41 is placed (e.g., glued) in the cylinder 40, and concentric rings 10 and 11 of materials with high magnetic and electrical conductivity that form the rotors of the electric motor are fixed on its end parts. which rotates the cylindrical movable storage medium about its axis. The stators 35 of this electric motor are located on the side wall of the container 5, in which a cylindrical information carrier is located in the immersion liquid 29. The positioner in the proposed device is an axial reversible hydraulic actuator, including a reversible hydraulic pump 42, line 43. as a piston, a cylindrical movable storage medium, as a cylinder, a container 5 and as a working fluid, an immersion fluid 44. The immersion lens 31 is stationary placed on a transparent window 32 in the wall of the container 5.

Referring to FIG. 1 device operates as follows.

In recording mode, a cylindrical movable storage medium is rotated around its axis using an asynchronous electric motor, the rotors of which are formed by rings 10 and 11 of materials with high magnetic and electrical conductivity, are placed on a cylindrical movable carrier and whose stators are placed on a container 5. made of material with low magnetic and electrical conductivity. In this case, the positioning is carried out by moving the movable optical head along the axis of rotation of the information carrier. Due to the energy impact of the electromagnetic beam emitted by the source 3 and focused (the lens of the autofocus system is not shown) to the corresponding place of the recording coating 7, information is recorded on the latter. In the read mode, the rotation of the cylindrical movable storage medium, the positioning and autofocusing of the electromagnetic beam is carried out in the same way as in the record mode. The beam emitted by the source 3 in the recording mode is not modulated, therefore, the beam reflected from the recording coating 7 appears to be modulated by the information recorded thereon. This beam in the photodetector 18 is converted into an electrical reproduction signal.

Referring to FIG. 2 node optical-mechanical storage device operates as follows.

In the recording mode by the focused lens 21, the laser beam, Modulated by the signal to be recorded in intensity or otherwise, is focused through the transparent insert 14 onto the surface of the recording coating 7 of the sealed cylinder 4. The latter is brought into rotational motion with the elements 10 mounted on it and integral with it 10 11 and 12 of the electric drive. As a result of the action of the laser beam on the recording medium, an appropriate record is formulated on it. In the reading mode, a focused laser of constant intensity reduced in comparison with the recording mode is incident on the recording coating 7 of the sealed cylinder 4 rotating around its axis. This beam when reflected from re (friction coating 7

is modulated in intensity by the recording contained therein.

Referring to FIG. 3, the device operates as follows,

In the modes of recording and reading information, the rotation of the cylindrical movable storage medium is carried out in the container 5 with a liquid transparent liquid 29 as in the previous cases.

0 In order to prevent exposure of the clear fluid 29 to the recording coating 7, a protective coating is applied to the latter. Information is recorded and read out by a laser beam focused on one of the recording coatings 7. In this case, the other recording coating 7 also receives the beam out of focus and does not interact with it. Referring to FIG. 4 device work

0 melts as follows.

In recording mode, a cylindrical movable storage medium rotates in a gas-lubricated container 5 by means of a synchronous electric motor, a stator

5 35 which is located on the container body 5, and the rotor 33 is mounted on the end part of the information carrier. Positioning in such a device is carried out as a result of the axial movement of the cylindrical movable information carrier relative to the stationary container 5 by means of a synchronous linear electric motor, the stator 36 of which is placed on the container body 5, and the core is fixed

5 on the end portion of the movable carrier. Since such a device eliminates the need for movement to position the lens 31, the latter is fixedly mounted on a transparent window 32 in the container body 5. In the reading mode, the incident laser beam is not modulated, therefore, the reflected radiation is modulated only by the recorded information.

5 Referring to FIG. 5 embodiment of the node optical-mechanical storage device operates as follows.

In recording mode, modulated

0, the laser beam is focused (the AF system lens is not shown) on one of the two recording coatings 7, on which information is currently being recorded. To another recording

5 coating 7, the beam arrives already defocused and therefore does not interact with it. In this case, the cylindrical storage medium is rotated by means of a synchronous electric motor. and its positioning is carried out using a pneumatic actuator. In the read mode, the rotation and positioning of the cylindrical mobile information carrier is carried out in the same manner as in the write mode. In contrast to the recording mode, the incident beam is not modulated, therefore, the beam reflected from the cylindrical carrier is modulated only with the information contained therein.

Referring to FIG. 6 node optical-mechanical storage device operates as follows,

In the recording mode, a cylindrical movable storage medium rotates around its axis by an asynchronous electric motor and moves along the axis with a hydraulic actuator, whereby the recorded information is addressed. In this case, the modulated laser beam through the immersion lens 31 enters the recording coating 7, on which information is recorded. In read mode, addressing is performed in the same manner as in write mode. The read beam is modulated by information recorded on the recording coating. This optical signal is converted to electrical by a photodetector (not shown).

(56) Copyright certificate of the USSR No. 1086957, cl. G 11 C 13 / 04.19982.

Claims (9)

1. NODE OF THE OPTICAL-MECHANICAL REMEMBERING DEVICE, comprising a base in the form of a transparent cylinder, on the inner part of the side surface of which a working layer is applied, which is rotatably supported in supports, characterized in that, with aim to increase the reliability of the recording and for storing information and ease of operation, an axial displacement drive and / or a cylinder rotation drive is inserted into it, and the cylinder is mounted in the cylinder cylinder and connected to it 5 through supports, the stator of the rotation drive being located on the container and the rotor on one or both ends of the cylinder 2. The node according to claim 1, characterized in that in a stationary lens of the lens is placed on the side wall of the container. 3. The node according to claim 1 or 2, characterized in that the working layer is applied to the outer ny part of the side surface of the transparent cylinder, J 4. An assembly according to claim 1, 2 or 3, characterized in that the surface of the working layer contains a protective coating. 5. An assembly according to claim 1, 1,2,3 or 4, characterized in that the axial displacement drive is viy. complete in the form of a linear electric motor, the stator of which is located on the container, and measles - on one or both ends of the transparent cylinder. 6. An assembly according to claim 1, 2, 3 or 4. characterized in that at least one radial jumper is placed in the cylinder. 7. The assembly according to claim 6, characterized in that the axial displacement drive is hydraulic. l 8. An assembly according to claim 5 or 7, characterized in that the cavity of the container is filled with immersion liquid. 9. The assembly according to claim 6, characterized in that the axial displacement drive is pneumatic and the supports are in the form of gas lubricant between the cylinder and the container. and 9-l 467 U e t JI --- .. IXX-C I 1 , - :. Y S / / S f /. /// // .. -E-i I 13 fie. 4 Fig. 5 about IL l / jfy , aZ auezza i-jc