RU2010357C1 - Cylindrical optical information carrier - Google Patents

Abstract

FIELD: digital video recording. SUBSTANCE: carrier has two substrates, two indicating media, two rotors, two armatures, pressure-tight container, immersion medium. EFFECT: improved reliability. 2 cl, 4 dwg

Description

 The invention relates to devices for recording and / or reproducing information with relative relative movement of the optical information carrier and the optical head and can be used in information technology, for example, digital audio recording devices, digital video recordings, and optical external computer storage devices.

 A device is known, according to which a cylindrical optical information carrier is made in the form of a substrate transparent to laser radiation, on the surface of which a recording layer is applied, and enclosed in a stationary airtight container with the possibility of rotation and axial movement [1].

 The disadvantage of this device is the low bulk density of recording and storing information due to the use of only one substrate with its recording layer.

 The closest in technical essence is the device according to which the cylindrical information carrier contains at least two concentric substrates transparent for laser radiation, on the surface of which a recording layer is applied. Moreover, these concentric substrates are placed with the possibility of individual rotation in a stationary container, on the outer surface of which is placed a stator of rotation drive common to all substrates. In the end part of the fixed container containing concentric substrates, a fixation unit of substrates is placed, which are external relative to the substrate with a recording layer, onto which recording is currently being made or from which information is being read [2].

 The disadvantage of the prototype is the low bulk density of recording and storing information due to the use of the substrate fixation unit and the rotation drive common to all substrates of the stator, due to which the thickness of the individual rotors, and therefore the thickness of the substrates, must be relatively large. But this reduces the number of substrates used and the total information capacity of the medium.

 The aim of the invention is to increase the bulk density of recording and storing information by reducing the thickness and increasing the number of substrates used, while improving operational reliability.

 The goal is achieved in that in a cylindrical optical information carrier containing at least two concentric substrates arranged individually rotatably in a fixed container, on the surface of which a recording medium is applied, each substrate is provided with an individual rotor of the electric rotation drive, and the rotors of the substrate rotation electric drives are offset relative to each other in the axial direction on the end parts of their substrates, each opposite to its stator, placed outside not odvizhnogo container.

 The goal is also achieved by the fact that in a cylindrical optical information carrier, each substrate is equipped with an individual axial displacement electric armature, and the axial disks of the electric axial displacements are axially displaced relative to each other on the end parts of their substrates, each opposite to its stator located outside the stationary container.

 The goal is also achieved by the fact that in a cylindrical optical information carrier, the internal cavity of the stationary container is filled with an immersion medium.

 In FIG. 1 shows an embodiment of the inventive cylindrical optical information carrier; in FIG. 2 is a section AA in FIG. 1; in FIG. 3 is another embodiment of the inventive cylindrical optical information carrier; in FIG. 4 is a third embodiment of the inventive cylindrical optical information carrier.

 The cylindrical optical storage medium shown in FIG. 1, 2, contains two concentric substrates transparent for laser radiation (and of glass, quartz, plastic): outer 1 and inner 2. A recording medium 3 (for example, chalcogenide) is applied to the entire inner surface of the inner substrate 2. The recording medium 4 (of the same material as the medium 3) is not completely applied to the inner surface of the outer substrate 1 (see Fig. 2), and in the cross section perpendicular to the axis, it is an open ring. In other words, in a thin film of the recording medium 4 there is a window (preferably rectangular in shape) that is completely transparent to laser radiation. At the opposite ends of the substrates 1 and 2, rotors 5 and 6 (for example, magnets magnetized perpendicular to the axis of rotation of the substrates 1 and 2) of electric rotation drives (for example, stepper) opposite their stators 7 and 8 are mounted on the outer surface of the stationary container 9. The surface of the stationary container 9 has an insert 10 made of a material transparent for laser radiation 11 (for example, glass, quartz, plexiglass). The internal cavity of the container is filled with immersion liquid (for example, distilled water, polymethylsiloxane) or a gaseous medium 12. The focused laser radiation 11 is positioned on a recording medium 3 or 4 by a movable head that is not part of the information carrier. It is conventionally depicted in the drawing by a focusing lens 13, which has the ability to move both parallel and perpendicular to the axis of rotation of the substrates 1, 2.

 Depicted in FIG. 3, the implementation of the inventive cylindrical optical information carrier contains three transparent substrates for laser radiation: outer 14, middle 15 and inner 16. The recording medium 17 is applied to the entire inner surface of the inner substrate 16. The recording medium 18 and 19 is applied to the inner surface of the middle 16 and outer 14 of the substrates not fully applied, as well as on the outer substrate 1 of the previous implementation of the inventive cylindrical optical information carrier. On the pins 20 and 21, fixed in the end parts of the inner substrate 16 by means of the caps 22 and 23, the rotor 24 of the rotation drive (for example, made in the form of a magnet magnetized in the diametrical direction) and the armature 25 of the axial movement drive (for example, made in the form axially magnetized magnet). On the hollow bushings 26 and 27, fixed in the end parts of the middle substrate 15 by means of covers 28 and 29, the rotor 30 of the rotation drive and the armature 31 of the axial movement drive are placed. The rotor 32 of the rotation drive and the anchor 33 of the axial movement drive are mounted directly on the ends of the outer substrate 14. In the covers 22, 23, 28, 20, fixed in the end parts of their substrates, holes 34 are provided for balancing the pressures in the internal cavities of all the substrates. All substrates 14-16 with individual rotors 24, 30, 32 attached individually to their ends and individual axial displacement anchors 25, 31, 33 are enclosed in a stationary container 35 (preferably sealed). In order to prevent damage to the outer surfaces of the substrates 14-16 against the inner surface of the container 35 and the substrates 14, 15, a certain relationship between their geometric dimensions is provided (for example, the diameter of the rotor 25 and the actuating movable element 24 is taken larger than the outer diameter of the outer substrate 14). An insert 36 transparent for laser radiation is provided in the side wall of the stationary container. On the side wall of the stationary container 35 are placed individual for the outer 14, middle 15 and 16 inner substrates of the rotation drives 37-39 and axial movement drives 40-41. When working with the described cylindrical optical information carrier, the same movable optical head can be used as with the previous implementation of the inventive information carrier. It is conventionally depicted in the drawing by a focusing lens 43 having the ability to move both along and perpendicular to the axis of rotation of the substrates 14-16.

 An embodiment of the inventive cylindrical optical information carrier shown in FIG. 4, previous implementations are primarily distinguished by the use of an immersion optical head, conventionally depicted by an immersion focusing lens 44, fixedly mounted on an insert 46 transparent to laser radiation 45 in the side surface of the stationary container 47, the length of which is at least twice as long as the concentric outer 48 and inner 49 substrates transparent for laser radiation 45. A recording medium 50 and 51, respectively, are deposited on the inner surface of the outer 48 and inner 49 substrates. On the end part of the outer substrate 48, a rotor of the rotation drive 52 and an anchor 53 of the axial movement drive are fixed, between which an annular insert 54 of non-magnetic material (for example, copper) is inserted. On the opposite end part of the inner substrate 49, a rotor 55 of the rotation drive and an anchor 56 of the axial movement drive are fixed, between which an insert 57 of non-magnetic material is inserted. The rotor 52 of the rotation drive and the armature drive 53 of the axial movement of the outer substrate are opposite their stators 58 and 59, respectively, which with the help of an additional drive (not shown for simplicity) can move axially relative to the stationary container 47. The rotor 55 of the rotation drive and the armature 56 of the axial displacement drive of the inner substrate 49 are opposite their stators 60 and 61, respectively, which, with the help of a second additional drive (not shown in the drawing for simplicity), move the unit in the axial direction with respect to a stationary container 47. The internal cavity of the container 47 is filled with an immersion medium 62.

 Similar nodes and elements in various implementations of the inventive cylindrical optical information carrier can be performed in a similar manner.

 Other embodiments of the inventive cylindrical optical information carrier are possible, differing in the number of recording layers on each substrate, the geometry of their placement, the number of substrates, the material of the substrates (which in the general case may be opaque), fastening of rotors of rotation drives and anchors of axial displacement drives on substrates , the design of a fixed container, the placement of stators in the inner cavity of the rotors and anchors and other features.

 A cylindrical optical storage medium operates as follows.

 In the cylindrical optical information carrier shown in FIG. 1, 2, writing or reading information from a recording medium 4 deposited on an external laser-transparent substrate 1 occurs in the usual manner. Namely, a rotation drive including a stator 7 and a rotor 5 rotates the substrate 1 with the recording medium 4. At the same time, by moving the movable optical head 13 in the axial direction, a predetermined information track is sought and held, and by moving the focusing lens 13 in the radial direction, the laser radiation 11 focuses on this track. To implement this process, any known autofocus, auto-training and positioning systems can be used. Then, in any known manner, data is recorded or read on the information tracks. In this case, both rotation (spontaneous or under the influence of its own rotation drive) and the stop of the inner substrate 2 are permissible. When recording or reading information from the recording medium 3 deposited on the inner substrate 2, the outer substrate 1 must be stopped and fixed in this position in which opposite to the detecting radiation 11 there will be a portion of the outer substrate 1 without the recording medium 4. For such a fixation of the outer substrate 1 in the stator 7 a stationary or pulsating magnetic field is created, ud alive rotor 5 from rotating. In this case, a rotating magnetic field is created in the stator 8, which rotates the rotor 6 and with it the inner substrate 2 with the recording medium 3 applied to it. Moving the focusing lens 13 in the manner described above ensures the positioning and retention of the information track, as well as the autofocus of the laser radiation 11 on it. Filling the inner cavity of the stationary container 9 with an immersion medium 12 helps to increase the transmittance of the outer substrate 1 when recording or reading information from the recording medium 3, anesennoy the inner substrate 2.

 In the cylindrical optical information carrier shown in FIG. 3, in contrast to the previous implementation of substrates transparent for laser radiation, there are already three 14-16 and the rotors 33, 31, 25 of individual rotation drives fixed to them are located at the same end of the stationary container 35 (which is not necessary). Therefore, the stators 40-42 of their respective individual drives of rotation are placed side by side on the outer surface of the stationary container 35 in the same end part thereof. The positioning and refocusing of laser radiation from one recording layer to another is carried out in the same way as in the previous implementation of the cylindrical optical information carrier as a result of the corresponding displacement (axial and radial) of the focusing lens 43. However, unlike the previous implementation, in the described embodiment for For the purposes of auto-training, individual axial displacement drives are used individually for each substrate 14-16, the anchors 32, 30, 24 of which are mounted on opposite ends of the substrates 14-16 a It is tax-free to rotors 33, 31, 25 of rotation drives. The stators 37-39 corresponding to these individual accurate axial displacement drives are fixed to the outer surface of the stationary container 35, similar to the stators 40-42 of individual rotation drives. Writing and reading information on the described medium can be carried out by any known method.

 Depicted in FIG. 4 embodiment of the inventive cylindrical optical information carrier designed to work with immersion optics. Therefore, the focusing lens 44 (conventionally shown as a focusing lens) is fixedly mounted on a laser-transparent insert 46 on the side surface of the stationary container 47 filled with immersion medium 62. Unlike previous implementations of the carrier, the recording medium 50 and 51 is deposited completely on the inner surface of the outer 48 and inner 49 concentric substrates, which in addition to rotational can also perform axial movement inside the stationary container 47, which ensures the process ionization. To implement these movements of the outer 48 and inner 49 substrates, rotors 52, 55 of rotation drives and anchors 53, 56 of the drives of precise axial movement are fixed on their opposite ends. The corresponding stators 58, 50 and 59, 61 are placed with the possibility of axial movement on the outer surface of the fixed container 47. Therefore, when moving relative to the container 47 of the stators 58, 59 due to the edge electromagnetic fields, the rotor 52 of the rotation drive and the armature 53 of the axial drive are held inside moving, as a result of which moves relative to the beam of laser radiation 45, focusing with a stationary lens 44, the outer transparent for laser radiation substrate 48 with a recording medium 50. In this case, the process rashchenija and Tracking of rotation and accurate axial movement track drive is provided same as in the previous embodiment of the claimed media manner. Similarly, by moving the stators 60, 61, the positioning of the inner substrate 49 with the recording medium 51 is ensured, and the interaction of the electromagnetic fields created by the stators 60, 61 with the rotor 55 and the armature 56 ensures the rotation of the inner substrate 49 and tracking the information track on the recording medium 51. Obviously, when recording or reading information from the recording medium 51 on the inner substrate 49, the outer substrate 48 due to the movement of the stator 58, 59 should be allocated to the end of the stationary container 47 (so as not to a discontinuity laser radiation), and vice versa. The refocusing of laser radiation 45 from one substrate to another in the described embodiment of the information carrier is provided by moving an additional focusing lens in the optical head, which is not shown in the drawing for simplicity.

 Thus, the use of concentric substrates with a recording medium deposited on them in the inventive cylindrical optical information carrier allows one to repeatedly increase the bulk density of information recording and storage with high reliability of their operation, which is due to the use of individual rotation drives for fixing non-working substrates. Therefore, it becomes possible to exclude from the design of the claimed carrier unreliable additional fixation unit for non-working substrates present in the prototype.

 (56) 1. US patent N 4829503, CL. 309-111, 1985.

 2. US Patent N 5034943, cl. G 11 B 7/08, 1986.

Claims (3)

 1. A CYLINDRICAL OPTICAL INFORMATION MEDIA, containing at least two individually arranged concentric substrates rotatable in a fixed container, the surface of which is provided with a protective environment that is equipped with a separate supply each other in the axial direction and placed on the end parts of their substrates, each contrary to its stator, located outside the stationary container.  2. The information storage medium according to claim 1, characterized in that each substrate is provided with an individual axial displacement electric drive anchor, with the axial displacement of the electrical axes being displaced relative to each other in the axial direction and placed on its other ends apart from each other. container.  3. Information carrier according to paragraphs. 1 and 2, characterized in that the internal cavity of the stationary container is filled with an immersion medium.

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