JPWO2004107337A1 - Optical information storage device and optical information storage system - Google Patents

Abstract

The present invention provides a medium storage unit that stores a plurality of optical storage media, an information reproduction unit that reproduces information from the optical storage medium, and moves the optical storage medium between the medium storage unit and the information reproduction unit. In an optical information storage device with a built-in medium moving unit and a high storage capacity and a compact device size, the optical storage medium stored in the medium storage unit can be appropriately cleaned with a simple configuration. It is an object of the present invention to provide an optical information storage device that can be performed, and an optical information storage system in which a plurality of optical information storage devices are integrated. A cleaning unit that removes unnecessary materials on the optical storage medium 13 is disposed on a path along which the medium moving unit 15 moves the optical storage medium 13. While the optical storage medium 13 is moved from the medium storage unit 12 to the information reproduction unit 16, unnecessary matters on the optical storage medium 13 are removed, and it is possible to prevent a problem in which unnecessary items are mixed into the information reproduction unit 16. it can.

Description

  The present invention relates to an optical information storage device that reproduces information on an optical storage medium in which at least information reproduction is performed by light, and also cleans the optical storage medium, and light that is formed by integrating a plurality of optical information storage devices. The present invention relates to an information storage system.

The amount of data such as transaction information and homepage data transmitted over communication networks such as the Internet will explode in the near future in view of the rapid development of the information and communication industry in recent years. It is predicted. In addition, virus problems and crimes continue to increase on the communication network, and log recording and the like are becoming obligatory on the Internet and the like. Although there is a strong demand for a large capacity information storage device for such current and future predictions, a hard disk, which is a type of large capacity information storage device capable of reading and writing information at high speed, requires a lot of expansion. Currently, information that exceeds the capacity of the hard disk is unavoidably discarded due to the cost. In addition, a magnetic tape storage device, which is a kind of large-capacity information storage device, can realize a large capacity exceeding the hard disk at low cost, but because magnetic tape is a sequential medium that reads and writes information sequentially, There is a difficulty in the input / output speed of information, and it is currently used only for the purpose of long-term storage of information.
In order to cope with the explosive increase in the amount of data expected in the near future, it is not enough to simply store a large amount of data. For example, data that finds trends in consumption from a large amount of information such as sales information. The field of mining, the field of experimental data analysis related to atomic physics, the field of collation technology using fingerprints and DNA information, the field of patent information search, the field of banking / securities, the field of electronic medical records, the IDC In the field of (Internet Data Center) and the like, in order to ensure high searchability and the like, it is desired to achieve both petabyte-class information amount accumulation and high-speed access within a few seconds (so-called near-line access) at low cost.
Optical information storage devices that store information on hard disks and magnetic tapes having these disadvantages using optical storage media such as MO and DVD are capable of reading and writing information at high speed, and are blue laser diodes. And the development of surface recording methods, etc., can be expected to dramatically increase the capacity in the near future, and it is also expected to realize a storage capacity comparable to magnetic tape storage devices. It is attracting attention as a device.
Furthermore, the latest technology includes a magazine that stores a plurality of optical storage media, a drive that reads and writes information from and to the optical storage medium, and a changer that moves the optical storage medium between the magazine and the drive. An optical information storage device that has been compactly housed in a housing has been devised (hereinafter, such an optical information storage device is referred to as a multi-media storage device). By using such a multi-media storage device, the capacity can be easily expanded by increasing the number of optical storage media or arranging a plurality of multi-media storage devices. Maintenance can also be easily performed by replacement.
Normally, information is recorded on the optical storage medium by irradiating light from the head, or reflected light reflected on the optical storage medium is received by the head and recorded on the optical storage medium based on the reflected light. The information that is being played is done. Therefore, when dust such as dust or dirt such as cigarette tar adheres to the head, information cannot be read and written correctly, and the performance of the optical information storage device may be degraded.
As a method for solving this problem, a method of directly cleaning the head by mounting a cleaning medium on the optical information storage device (see, for example, Patent Document 1, Patent Document 2, Patent Document 3, Patent Document 4, and Patent Document 5). ), Or a method of cleaning the optical storage medium with a cleaning drive provided separately from the recording / reproducing drive to prevent unnecessary objects from being brought into the recording / reproducing drive (for example, Patent Document 3). , Patent Document 4 and Patent Document 6) have been devised.
JP 2000-93121 A Japanese Patent Laid-Open No. 5-54513 JP-A-5-74127 Japanese Patent Laid-Open No. 5-114155 JP 7-235120 A JP 11-45489 A

However, in the cleaning method using the cleaning medium, the cleaning medium is rotated in the drive, so that dust or dust is scattered or the cleaning medium itself becomes dirty due to repeated cleaning. There is a risk that unwanted objects will re-attach to the head. In addition, when applied to a multi-media storage device in which a plurality of optical storage media are stored, the number of optical storage media that can be stored is reduced by the amount of the cleaning medium mounted, and the storage capacity of the entire multi-media storage device is reduced There is also the problem of doing.
These problems can be solved by cleaning the optical storage medium using the above-described cleaning drive and preventing unnecessary objects from being brought into the recording / reproducing drive. In addition to the reproducing drive, it is necessary to provide a cleaning drive, which causes a problem that the apparatus is increased in size and complexity.
In any of the above-described methods, for example, an operator gives an instruction to start cleaning or an instruction to perform cleaning by detecting contamination of the head or the optical storage medium, etc. Heads can be kept clean if operations and complicated mechanisms are required, or if the frequency of cleaning is increased, but on the other hand, the time required for the original operation as a storage device is reduced due to the time taken for cleaning. Development of an optical information storage device that can be appropriately cleaned with a simpler mechanism is desired.

In view of the above circumstances, the present invention provides an optical information storage device that can be appropriately cleaned with a simple mechanism in an optical information storage device in which components and a plurality of optical storage media are built in a housing, and a plurality of optical information storage devices An object of the present invention is to provide an optical information storage system in which optical information storage devices are integrated.
An optical information storage device of the present invention that achieves the above object includes a box-shaped housing,
A medium storage unit in which a plurality of disk-shaped optical storage media that are arranged at one end in the case and at least information is reproduced by light are stored;
An information reproducing unit for reproducing information from an optical storage medium, which is disposed in the housing at a distance from the medium storage unit;
A medium moving unit arranged between the medium storing unit and the information reproducing unit, for moving the optical storage medium between the medium storing unit and the information reproducing unit;
The medium moving unit includes a cleaning unit that is disposed on a path for moving the optical storage medium and removes unnecessary materials on the optical storage medium.
According to such an optical information storage device of the present invention, since unnecessary objects attached to the optical storage medium are removed before the optical storage medium is loaded into the information reproducing section, unnecessary objects are mixed into the information reproducing section. Problems can be prevented in advance. Further, according to the optical information storage device of the present invention, since it is not necessary to provide a cleaning drive for cleaning the optical storage medium, it is possible to suppress the enlargement of the device and the cleaning frequency is high. Does not affect the operation time.
Further, in the optical information storage device of the present invention, the medium storage unit stores the optical storage media side by side with a gap therebetween, and when the optical storage medium is taken in and out of the gap. A mode in which a cleaning member that contacts an optical storage medium and wipes off unnecessary objects on the optical storage medium is also used as the above-described cleaning unit is a preferable mode.
For example, by disposing a cleaning member such as a sheet as described above, unnecessary materials on the optical storage medium are wiped off by the cleaning member each time the optical storage medium is taken in and out of the medium storage unit. Therefore, it is possible to automatically perform cleaning with a simple mechanism without requiring an explicit operation or a complicated mechanism for cleaning.
Further, in the optical information storage device of the present invention, the medium moving unit includes a cleaning member that contacts the optical storage medium and wipes unnecessary materials on the optical storage medium when the optical storage medium is moved. A mode in which the cleaning unit is also used is a preferable mode.
By providing the medium moving unit as described above, every time the optical storage medium is moved between the medium storage unit and the information reproducing unit, the unnecessary material on the optical storage medium is wiped off by the cleaning member.
In the optical information storage device of the present invention, it is preferable that the cleaning member is a sheet.
By applying such a cleaning member, dust adhering to the optical storage medium can be entangled and dirt can be wiped off.
In the optical information storage device of the present invention, it is also preferable that the cleaning member is a brush.
By applying a brush as the cleaning member, dust such as cotton dust or hair that easily collects in the housing can be swept away.
Furthermore, the optical information storage device of the present invention is
The medium storage unit is detachably disposed at one end of the housing,
The housing includes a medium storage unit, a medium moving unit, and an information reproducing unit arranged in a row inside, and integrally holds the medium storing unit, the medium moving unit, the information reproducing unit, and the cleaning unit. Yes,
It is preferable that a system housing in which a plurality of the optical information storage devices are mounted further includes a connection portion for detachably connecting the optical information storage devices.
According to such an optical information storage device of the present invention, the medium storage unit, the information reproducing unit, and the medium moving unit are compactly housed in the housing, and the number of optical storage media is increased and a plurality of optical information storage devices are arranged. Thus, the capacity can be easily expanded, and maintenance can be easily performed by attaching / detaching or replacing a medium storage unit or an optical storage medium arranged at one end in the housing.
Furthermore, an optical information storage system of the present invention includes a box-shaped housing, a medium storage unit in which a plurality of disk-shaped optical storage media that are disposed at one end of the housing and at least information is reproduced by light are stored, An information reproducing unit that reproduces information from an optical storage medium disposed at a distance from the medium storage unit in the housing, and a medium storage unit that is disposed between the medium storage unit and the information reproducing unit. A medium moving unit that moves the optical storage medium to and from the information reproducing unit; and a cleaning unit that is disposed on a path along which the medium moving unit moves the optical storage medium and removes unnecessary materials on the optical storage medium. A plurality of optical information storage devices;
A system housing in which a plurality of optical information storage devices are detachably mounted;
And a control unit that controls recording and / or reproduction of information in each of the plurality of optical information storage devices mounted on the system housing.
According to such an optical information storage system of the present invention, a plurality of optical information storage devices in which a medium storage unit, a recording / reproducing unit, and a medium moving unit are compactly housed in a housing are provided, and a compact and large-capacity storage device is provided. A system can be constructed, and the optical storage media stored in each of these optical information storage devices can be appropriately cleaned with a simple mechanism. Further, the capacity can be easily expanded by increasing the number of optical storage media and optical information storage devices, and maintenance can be easily performed by attaching and detaching and replacing the medium storage unit and the optical information storage device.

FIG. 1 is an external view showing each embodiment of the optical information storage system and the optical information storage device of the present invention.
FIG. 2 is a diagram illustrating a hardware structure of the blade device.
FIG. 3 is a functional block diagram showing the functional structure of the blade.
FIG. 4 shows the internal structure of the magazine.
FIG. 5 is a diagram showing the structure near the head of the drive.
FIG. 6 is a flowchart showing a series of processes for reading / writing information from / to the MO disk.
FIG. 7 is a view showing the MO disk and the sheet when the MO disk is taken out from the magazine.
FIG. 8 is a diagram showing the inside of the magazine according to the second embodiment of the present invention.
FIG. 9 is a diagram showing the inside of the magazine according to the third embodiment of the present invention.
FIG. 10 is a diagram illustrating a hardware structure of a blade device according to the fourth embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described.
FIG. 1 is an external view showing each embodiment of the optical information storage system and the optical information storage device of the present invention.
FIG. 1 shows a blade device 10 corresponding to an embodiment of an optical information storage device of the present invention using a magneto-optical (MO) disk as an example of an optical storage medium according to the present invention, and a plurality (10 in this figure) A collective system 20 corresponding to an embodiment of the optical information storage system of the present invention in which a blade device 10 is incorporated is shown.
The casing 11 of the blade device 10 has a length that is more than 2.5 times the diameter of the MO disk, a width slightly larger than the diameter of the MO disk (height in this figure), and is significantly smaller than the diameter of the MO disk. A magazine 12 in which a plurality of MO disks are stored is detachably disposed at one end of the housing 11. The housing 11 corresponds to an example of the housing according to the present invention, and the magazine 12 corresponds to an example of a medium storage unit according to the present invention.
A plurality of blade devices 10 are detachably mounted on the housing 21 of the collective system 20, and the magazine 12 of each blade device 10 is in a state where the blade device 10 is inserted into the housing 21 of the collective system 20. It is removable. The collective system 20 is also provided with a control device 22 that controls the recording and reproduction of information in each of the plurality of blade devices 10.
Such a collective system 20 is a compact and large-capacity storage system in which a plurality of blade devices 10 are housed compactly in a casing 21. Further, the capacity can be easily expanded by increasing the number of MO disks and blade devices 10, and maintenance can be easily performed by attaching and detaching and replacing the magazine 12 and blade device 10.
FIG. 2 is a diagram illustrating a hardware structure of the blade device.
The blade device 10 also shown in FIG. 1 includes the above-described magazine 12 and a drive 16 for recording and reproducing information with respect to the MO disk 13 in the housing 11. Between them, a changer 15 for moving the MO disk 13 between them is provided. The drive 16 corresponds to an example of an information reproducing unit according to the present invention, and the changer 15 corresponds to an example of a medium moving unit according to the present invention.
One end of the blade device 10 opposite to the magazine 12 is provided with an interface connector 17a for transferring data between the blade device 10 and the outside, and the blade device 10 has a housing of the collective system 20 shown in FIG. When inserted into the body 21, the connector 17a is joined to the connector on the collective system 20 side. The connector 17a corresponds to an example of a connection portion according to the present invention.
FIG. 3 is a functional block diagram showing the functional structure of the blade.
As described above, the blade device 10 includes the magazine 12, the changer 15, and the drive 16, and further corresponds to the control unit 18 that controls the changer 15 and the drive 16, and the connector 17a shown in FIG. An interface 17 responsible for data transfer between the apparatus 10 and the outside is also provided. The interface 17 is selected from well-known high-speed serial interfaces such as IEEE 1394, USB, and serial ATA, and will not be described in detail.
The drive 16 includes a spindle motor 16a that holds and rotates the MO disk 13, and a head 16b that records and reproduces information by irradiating the MO disk 13 with laser light. Two are provided for each of the first surface (front surface) and the second surface (back surface) of the MO disk. The drive 16 also includes a read / write channel 16c for each of the first and second surfaces, and a first-in first-out (FIFO) memory 16d that functions as a buffer.
Further, the magazine 12 is provided with an FRAM 14 in which a disk number of the MO disk 13 stored, address information where the MO disk 13 is stored, and the like are stored.
When specific information specifying the MO disk is designated from outside the apparatus through a path (not shown) via the interface 17, the control unit 18 specifies the MO disk 13 indicated by the specific information based on the information stored in the FRAM 14. And the changer 15 is instructed to the found MO disk 13. The changer 15 takes out the MO disk 13 designated by the control unit 18 from the magazine 12 and loads it into the drive 16.
Further, the blade device 10 is provided with an access path 19 for accessing the FRAM 14 from outside the blade device 10 by bypassing the control unit 18 and the blade device 10 is turned off. However, the information stored in the FRAM 14 can be confirmed from the outside via the access path 19.
The blade device 10 is connected to the collective system 20 shown in FIG. 1 basically as described above.
Next, details of the components that constitute the blade device 10 will be described.
FIG. 4 is a diagram showing the internal structure of the magazine 12.
The magazine 12 also shown in FIGS. 2 and 3 is provided with a plurality of guide projections 12a for holding a plurality of MO disks 13, and a sheet 40 made of nonwoven fabric is provided on one side of each guide projection 12a. Is pasted. The MO disks 13 are arranged one by one on each guide projection, and are stored side by side with a gap therebetween. One side (the back side in this example) of each MO disk 13 is in contact with the sheet 40. Yes. The magazine 12 corresponds to an example of a medium storage unit according to the present invention, and also serves as an example of a cleaning unit according to the present invention. The sheet 40 corresponds to an example of a cleaning member according to the present invention and corresponds to an example of a sheet according to the present invention.
The changer 15 shown in FIGS. 2 and 3 has a function of inserting / removing the MO disk 13 with respect to the magazine 12, a function of moving the MO disk 13 in the vertical direction in the figure, and loading and releasing the MO disk 13 with respect to the drive 16. It has a function.
FIG. 5 is a diagram showing the structure near the head of the drive.
The drive 16 shown also in FIGS. 2 and 3 is provided with two heads 16b, and FIG. 5 shows the structure in the vicinity of the two heads 16b. The two heads 16b are arranged with the MO disk 13 held and rotated by the spindle motor 16a interposed therebetween, and each head 16b incorporates a laser diode, a light detection element, various optical elements, and the like, and performs recording and reproduction. The fixed assembly 32 responsible for generating the laser beam and detecting various signals to be described later, and moving on a predetermined rail, irradiating the MO disk 13 with the laser beam at a desired position, and being reflected by the MO disk 13 A moving assembly (carriage) 31 that returns light to the fixed assembly 32 and a control unit (not shown) that controls each element of FIG. 5 are configured. Further, the moving assembly 31 includes a carriage base 33, a rising mirror 34 that reflects the laser light, a condensing lens 35 that condenses the laser light on the MO disk 13, and a lens actuator 36 that moves the condensing lens 35. I have.
Here, the various signals detected by the fixing assembly 32 will be described once apart from the description of the components constituting the blade device 10.
Although not shown, the fixed assembly 32 includes a beam splitter and a prism. In the fixed assembly 32, the reflected light reflected by the MO disk 13 is used for focus control, track control, and MO signal. Split into two lights.
The focus control light is used for focus control that keeps the distance between the condenser lens 35 and the MO disk 13 constant. Since the MO disk 13 is rotated at high speed by the spindle motor 16a, the distance to the condenser lens 35 is likely to fluctuate. When the distance between the condensing lens 35 and the MO disk 13 deviates from the in-focus distance, the laser light condensed by the condensing lens 35 is emitted to a position other than the desired position on the MO disk 13. There is a problem that information cannot be read and written correctly. In the fixed assembly 32, a signal (FES: focus error signal) indicating how much the distance between the MO disk 13 and the condenser lens 35 deviates from the in-focus distance is detected from the focus control light. In the lens actuator 36 of the optical lens 35, the position of the condenser lens 35 is corrected according to the FES.
The track control light is light used for track control in which the position of the laser beam condensed by the condenser lens 35 is moved to a position for reading and writing information on the MO disk 13 and maintained. The focus control is an operation for controlling the position of the condenser lens 35 in the height direction, whereas the track control is an operation for controlling the position of the condenser lens 35 in the lateral direction. For example, if the light beam is not focused on the center of the track on the MO disk 13 because the MO disk 13 is swung to the left or right due to the high speed rotation of the MO disk 13, an error on the MO disk 13 may occur. There is a risk of reading and writing information to the location. In order to prevent such a problem, a signal (TES: track error signal) representing an error between the position of the laser beam condensed by the condenser lens 35 and the center of the track on the MO disk 13 from the track control light. Is detected, and the lens actuator 36 corrects the position of the condenser lens 35 in accordance with TES.
From the MO signal light, an MO signal representing information read from and written to the MO disk 13 is detected. Based on the MO signal, information recorded on the MO disk 13 is read.
Here, if dust or dirt adheres to the drive 16 shown in FIG. 5, particularly near the condenser lens 35, the reflected light from the MO disk 13 cannot be received sufficiently, and the focus control and track control described above are performed. May not be performed correctly, or information may not be read from or written to the MO disk 13.
FIG. 6 is a flowchart showing a series of processes for reading / writing information from / to the MO disk in the blade device of this embodiment. In the following, a series of processes for reading and writing information to and from the MO disk 13 after cleaning unnecessary materials attached to the MO disk 13 will be described using the flowchart of FIG.
The MO disk 13 stored in the magazine 12 shown in FIGS. 2 and 4 is taken out from the magazine 12 by the changer 15.
FIG. 7 is a view showing the MO disk and the sheet when the MO disk is taken out from the magazine.
As shown in FIG. 4, the MO disk 13 stored in the magazine 12 is in contact with the sheet 40 on one side. The changer 15 moves the MO disk 13 toward the drive 16 while keeping the MO disk 13 and the sheet 40 in contact with each other. At this time, unnecessary substances attached to the surface of the MO disk 13 in contact with the sheet 40 are wiped off (step S1 in FIG. 6).
The MO disk 13 is transported to the drive 16 as it is and mounted on the drive 16. The MO disk 13 that has been mounted has previously removed unnecessary objects, so that it is possible to prevent the inconvenience of unnecessary objects entering the drive 16. The MO disk 13 mounted on the drive 16 is held and rotated by the spindle motor 16a of FIG.
When the MO disk 13 is rotated, laser light is generated in the fixed assembly 32, and the laser light is condensed at a predetermined position on the disk by the condenser lens 35 of the moving assembly 31 (step S2 in FIG. 6). ).
The laser light condensed by the condenser lens 35 is reflected on the disk, and the reflected light is transmitted from the moving assembly 31 to the fixed assembly 32. In the fixed assembly 32, the transmitted reflected light is split into light for focus control, track control, and MO signal, and FES, TES, and MO signals are detected from these lights.
The detection of the signal is continuously performed at regular intervals while the MO disk 13 is rotating. First, the above-described series of focus control is performed using FES among these signals (step S3 in FIG. 6), and the distance between the condenser lens 35 and the MO disk 13 in FIG. 5 is kept constant. Be drunk.
Subsequently, the above-described track control is performed using the TES among the detected signals (step S4 in FIG. 6), and the light is condensed by the condenser lens 35 in FIG. 5 at the center of the track on the MO disk 13. The light beam is followed.
When focus control and track control are performed, information is read from and written to the MO disk 13 based on the MO signal detected in that state (step S5). By such a series of operations, information can be correctly read from and written to the MO disk 13.
As described above, in the blade device of this embodiment, every time the MO disk 13 is taken out of the magazine 12, unnecessary objects attached to the MO disk 13 are wiped off. Cleaning is appropriately performed with a simple mechanism without requiring a mechanism.
Here, an example in which only the MO disk 13 is stored in the magazine 12 has been described. However, a conventional cleaning disk that cleans the head 16b by being mounted on the drive 16 and rotating is referred to as the MO disk 13. May be stored in the magazine 12. By storing the cleaning disk in the magazine 12 in this way, the head 16b can be directly cleaned to keep the head 16b clean, and dirt adhering to the cleaning disk is removed by the sheet 40. The cleaning disk can be used repeatedly.
Above, description of 1st Embodiment of this invention is complete | finished, and 2nd Embodiment of this invention is described next. In order to avoid duplication, in the following description, elements having the same configurations as those in the first embodiment will be denoted by the same reference numerals, and will be described with a focus on differences from the first embodiment.
The second embodiment has the same configuration as that of the first embodiment shown in FIG. 2, but the position of the sheet attached inside the magazine is different from that of the first embodiment.
FIG. 8 is a diagram showing the inside of the magazine according to the second embodiment of the present invention.
Unlike the first embodiment shown in FIG. 4, the magazine 12 of the second embodiment shown in FIG. 8 has sheets attached to both sides of the guide projection 12 a as well as one side of the guide projection 12 a.
By applying the magazine 12 of the present embodiment shown in FIG. 8 in place of the magazine 12 of the first embodiment shown in FIGS. 2 and 4, for example, when removing the MO disk 13 from the magazine 12, the MO disk When the MO disk 13 is moved in contact with the sheet 41a and the MO disk 13 is stored in the magazine 12, the both surfaces of the MO disk 13 are moved by moving the lower surface of the MO disk 13 in contact with the sheet 41b. Can be cleaned.
Above, description of 2nd Embodiment of this invention is complete | finished and 3rd Embodiment of this invention is described. The third embodiment has the same configuration as that of the first embodiment shown in FIG. 2, but the position of the sheet attached inside the magazine is different from that of the first and second embodiments. is doing.
FIG. 9 is a diagram showing the inside of the magazine according to the third embodiment of the present invention.
In the magazine 12 of the third embodiment shown in FIG. 9, unlike the first embodiment shown in FIG. 4 and the second embodiment shown in FIG. 8, a sheet 42 having a thickness substantially the same as the thickness of the guide protrusion 12a, Attached so as to be connected from the guide protrusion 12a.
The magazine 12 of this embodiment is applied in place of the magazine 12 shown in FIGS. 2 and 4. For example, when the MO disk 13 is taken out from the magazine 12, the upper surface of the MO disk 13 is brought into contact with the sheet 42. When the MO disk 13 is stored in the magazine 12, both surfaces of the MO disk 13 can be cleaned with a small number of cleaning members by moving the lower surface of the MO disk 13 in contact with the sheet 42. it can.
Above, description of 3rd Embodiment of this invention is complete | finished and 4th Embodiment of this invention is described. In the first, second, and third embodiments described above, the cleaning member is attached to the inside of the magazine. However, in this embodiment, the cleaning member is attached to the changer.
FIG. 10 is a diagram illustrating a hardware structure of a blade device according to the fourth embodiment of the present invention.
The blade device 10 according to the present embodiment shown in FIG. 10 has substantially the same configuration as the blade device according to the first embodiment shown in FIG. 2, but the blade device 10 according to the present embodiment has a brush 50 on the changer 15. Is provided. The changer 15 corresponds to an example of a medium moving unit according to the present invention, and also serves as an example of a cleaning unit according to the present invention. The brush 50 corresponds to an example of the cleaning member according to the present invention and corresponds to an example of the brush according to the present invention.
The brush 50 is fixed on the changer 15 at a position where it comes into contact with the MO disk 13 when the MO disk 13 is removed from the magazine 12. When the changer 15 takes out the MO disk 13 from the magazine 12, the MO disk 13 is moved in the lateral direction and carried to the drive 16 while the MO disk 13 and the brush 50 are in contact with each other. At this time, the dust adhering to the MO disk 13 is swept away by the brush 50, and the trouble that the dust enters the drive 16 is prevented beforehand.
Thus, instead of the magazine, the changer may be provided with a cleaning member.
Above, description about embodiment of this invention is complete | finished.
In the above, an MO disk is shown as an example of the optical storage medium according to the present invention, but the optical storage medium according to the present invention may be a DVD or the like.
In the above description, the optical information storage device that can simultaneously access both sides of the MO disk has been described. However, the optical information storage device of the present invention may access only one side of the optical storage medium.
In the above description, an example in which a non-woven sheet or brush is used as the cleaning member according to the present invention is shown. However, the cleaning member according to the present invention may be, for example, a sponge.
Further, in the above, an example is shown in which a cleaning unit that wipes unnecessary materials on an optical storage medium with a cleaning member such as a sheet or a brush is used as the cleaning unit in the optical information storage device of the present invention. The cleaning unit in the optical information storage device may include, for example, an air ejector that ejects clean air and blows away unnecessary objects on the optical storage medium.

[Claims]
    1. A box-shaped housing;
  A medium storage unit in which a plurality of disk-shaped optical storage media that are arranged at one end in the housing and at least information is reproduced by light are stored;
  An information reproducing unit for reproducing information from the optical storage medium, which is disposed in the casing at a distance from the medium storage unit;
  A medium moving unit disposed between the medium storage unit and the information reproduction unit, the medium moving unit moving the optical storage medium between the medium storage unit and the information reproduction unit;
  An optical information storage device comprising: a cleaning unit disposed on a path through which the medium moving unit moves the optical storage medium to remove unnecessary materials on the optical storage medium.
    2. The medium storage unit stores optical storage media arranged with a gap therebetween, and contacts the optical storage medium when the optical storage medium is taken in and out of the gap. The optical information storage device according to claim 1, wherein the cleaning unit is also used as a cleaning unit in which a cleaning member for wiping off unnecessary objects on the optical storage medium is disposed.
    3. The medium moving unit also serves as the cleaning unit, which includes a cleaning member that contacts the optical storage medium and wipes unnecessary materials on the optical storage medium when the optical storage medium is moved. The optical information storage device according to claim 1, wherein:
    [Claim 4] The medium storage unit is detachably disposed at one end of the housing,
  In the housing, the medium storage unit, the medium moving unit, and the information reproducing unit are arranged in a row inside, and the medium storing unit, the medium moving unit, the information reproducing unit, and the cleaning unit are integrated. Is to hold
  2. The optical information storage device according to claim 1, further comprising a connection unit that detachably connects the optical information storage device to a system housing in which a plurality of the optical information storage devices are mounted.
    [Claim 5] A box-shaped casing, a medium storage section in which a plurality of disk-shaped optical storage media that are arranged at one end in the casing and at least information is reproduced by light are stored, and a distance from the medium storage section in the casing An information reproducing unit for reproducing information with respect to the optical storage medium, and the medium storing unit and the information reproducing unit arranged between the medium storing unit and the information reproducing unit A medium moving unit that moves the optical storage medium between the optical storage medium, and a cleaning unit that is disposed on a path along which the medium moving unit moves the optical storage medium, and removes unnecessary materials on the optical storage medium. A plurality of optical information storage devices,
  A system housing in which the plurality of optical information storage devices are detachably mounted;
An optical information storage system comprising: an overall unit that controls recording and / or reproduction of information in each of a plurality of optical information storage devices mounted in the system casing.

Claims (7)

A box-shaped housing;
A medium storage unit in which a plurality of disk-shaped optical storage media that are arranged at one end in the housing and at least reproduce information by light are stored;
An information reproducing unit for reproducing information with respect to the optical storage medium, disposed in the casing at a distance from the medium storage unit;
A medium moving unit arranged between the medium storage unit and the information reproducing unit, for moving the optical storage medium between the medium storing unit and the information reproducing unit;
An optical information storage device comprising: a cleaning unit that is disposed on a path through which the medium moving unit moves the optical storage medium and removes unnecessary materials on the optical storage medium. The medium storage unit stores optical storage media side by side with a gap therebetween, and contacts the optical storage medium when the optical storage medium is inserted into or removed from the gap. 2. The optical information storage device according to claim 1, wherein a cleaning member for wiping off unnecessary objects on the medium is also used as the cleaning unit. The medium moving unit also serves as the cleaning unit including a cleaning member that comes into contact with the optical storage medium and wipes unnecessary materials on the optical storage medium when the optical storage medium is moved. The optical information storage device according to claim 1. 4. The optical information storage device according to claim 2, wherein the cleaning member is a sheet. 4. The optical information storage device according to claim 2, wherein the cleaning member is a brush. The medium storage unit is detachably disposed at one end of the housing,
In the housing, the medium storage unit, the medium moving unit, and the information reproducing unit are arranged in a row inside, and the medium storing unit, the medium moving unit, the information reproducing unit, and the cleaning unit are integrated. Is to hold,
2. The optical information storage device according to claim 1, further comprising a connection unit that detachably connects the optical information storage device to a system housing in which a plurality of the optical information storage devices are mounted. A box-shaped casing, a medium storage section in which a plurality of disk-shaped optical storage media that are arranged at one end in the casing and at least information is reproduced by light are stored, and a distance from the medium storage section in the casing An information reproducing unit for reproducing information with respect to the optical storage medium, and the medium storing unit and the information reproducing unit arranged between the medium storing unit and the information reproducing unit A medium moving unit that moves the optical storage medium between the optical storage medium, and a cleaning unit that is disposed on a path along which the medium moving unit moves the optical storage medium, and removes unnecessary materials on the optical storage medium. A plurality of optical information storage devices,
A system housing in which the plurality of optical information storage devices are detachably mounted;
An optical information storage system comprising: an overall unit that controls recording and / or reproduction of information in each of a plurality of optical information storage devices mounted in the system casing.

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