JP2006099818A - Disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a disk device compatible with each disk. <P>SOLUTION: Pickup devices 10 and 20 capable of reading/writing data in a disk 400 by applying a laser beam to the disk 400 are provided, and a plurality of pickup devices 10 and 20 are disposed in a disk device main body 150 which houses the disk 400. The two of the pickup devices 10 and 20 are arranged in the disk device main body 150. The plurality of pickup devices 10 and 20 are set to be first and second pickup devices 10 and 20. The first and second pickup devices 10 and 20 are movable in the radial direction of the disk 400. When the disk device main body 150 is seen from a plane, the moving direction of the second pickup device 20 is set different from that of the first pickup device. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a disk device that can be installed in, for example, a personal computer.

  FIG. 3 shows an embodiment of a conventional disk device.

  The disk device 600 is used to read data on a disk (not shown). The disk device 600 is used to record data on a disk (not shown). A pickup device 510 that emits laser light when data recorded on the disk is read is used. In addition, a pickup device 510 that emits laser light is used when recording data on a disc. Examples of the disc include a CD (compact disc) and a DVD (digital versatile disc / digital video disc). “CD” is an abbreviation for “Compact Disc”. “DVD” is an abbreviation for “Digital Versatile Disc” or “Digital Video Disc”.

  A tray 800 that can be freely moved in and out of the housing 620 constituting the disk device 600 is used, and the disk is accommodated in the disk device 600. In addition, a disk drive device 530 that rotates a disk is housed in a housing 620 constituting the disk device 600. In addition, a pickup device 510 that reads data from a disk and records data on the disk is provided in a housing 620 constituting the disk device 600. A cover 630 is attached to the housing 620, and the disk device 600 is assembled.

  As a disk, for example, a read-only disk such as a CD-ROM or DVD-ROM, a write-once disk such as a CD-R or DVD ± R, or a write / write such as a CD-RW, DVD ± RW, or DVD-RAM. Examples include erasable and rewritable discs.

  “ROM” of “CD-ROM” or “DVD-ROM” is an abbreviation of “Read Only Memory”, and CD-ROM or DVD-ROM is dedicated to data reading. In addition, “R” of “CD-R” or “DVD ± R” is an abbreviation of “Recordable”, and CD-R or DVD ± R can write data. Further, “RW” of “CD-RW” or “DVD ± RW” is an abbreviation of “ReWritable”, and CD-RW or DVD ± RW can be rewritten. “DVD-RAM” is an abbreviation of “Digital Versatile Disc Random Access Memory”, and data can be read / written / erased.

Further, as related to the conventional disk device, for example, there is no loss of light amount when the light beam incident on the objective lens is switched, the beam can be easily switched, and one objective lens is driven without any change in angle. There is an optical pickup that uses an apparatus and can easily handle a plurality of types of optical disks (see, for example, Patent Document 1).
Japanese Patent Laid-Open No. 9-17005 (pages 1, 4 and FIGS. 1 to 21)

In recent years, disc standards tend to be diversified. As described above, examples of the disk include various disks such as CD-ROM, CD-R, CD-RW, DVD-RAM, DVD-RW, and DVD + RW. Discs such as HD-DVD and Blu-ray Disc have also been proposed.

  “HD-DVD” is an abbreviation for “High Definition DVD”. “HD-DVD” is compatible with the conventional DVD series and has a larger storage capacity than the conventional DVD series disks. Conventional CDs and DVDs use a red laser. When data recorded on an HD-DVD disc is read, a blue-violet laser is used. “Blu-ray” means a blue-violet laser employed for realizing high-density recording, compared to a red laser used for reading and writing signals in conventional CDs and DVDs.

  However, when the types of discs are diversified as described above, it is difficult to configure a single pickup device (510) corresponding to all types of discs. In addition, the single pickup device (510) corresponding to all types of discs is difficult at the present time in terms of design, manufacture, etc., and therefore tends to be expensive. For this reason, there is a concern that when a high-priced pickup device (510) is installed in the disk device (600), the disk device (600) is expensive.

  Further, in order to increase the functionality of the disk device 600, the pickup device 510 constituting the disk device 600 is required to have higher performance. For example, a laser diode (not shown) that constitutes the pickup device 510 when data is written to or rewritten from a disk such as a CD-R, CD-RW, DVD ± R, or DVD-RAM. A high-power laser beam is emitted from. At this time, the temperature of a laser diode (not shown) constituting the pickup device 510 rises.

  For example, when data is recorded on the disc at a speed as fast as 8 ×, 12 ×, 16 ×,... Relative to the normal data reading speed for the disc, a high energy laser beam is emitted from the laser diode. At this time, when the temperature of the laser diode rises, laser light having a wavelength different from the predetermined wavelength of the laser light is emitted from the laser diode. When this occurs, there is a concern that low quality data recording is performed on the disc.

  Further, when the disk device 600 is used and data recorded on the disk is read, there is a strong demand from the market that no data read error occurs in the disk device 600. For this reason, for example, a disk device 600 in which measures against vibration are taken is required from the market. Further, there is a demand for miniaturization of the disk device 600 from the market. In recent years, there has been a demand from the market for a disk device 600 having a trick playback function such as variable speed playback and reverse playback. Furthermore, a disk device 600 with higher added value is being demanded from the market.

  The present invention is to solve the above-described problems. The present invention has been made in view of the above points, and an object of the present invention is to provide a disk device that can handle each disk.

  In order to achieve the above object, a disk apparatus according to claim 1 of the present invention includes a pickup device that is capable of reading and writing data from and to a disk by irradiating the disk with laser light. A plurality of pickup devices are mounted on a disk device main body in which a disk is accommodated.

With the above configuration, a disk device that can handle each disk is configured. Since a plurality of pickup devices are installed in the disk device main body in which the disk is accommodated, it is avoided that many functions are integrated into one pickup device. Accordingly, each function is distributed to each pickup device. For example, a disk device corresponding to a plurality of disks is configured by mounting a plurality of single-wavelength pickup devices in the disk device. This provides a disk device that can handle each disk. In addition, since the disk device is provided with a plurality of pickup devices, it is easy to prevent the wavelength of the laser light emitted from the pickup device from being changed due to, for example, heat generated from the pickup device. Become. Since the disk device includes a plurality of pickup devices such as one pickup device and another pickup device, for example, the temperature of one pickup device in use rises, and laser light having a wavelength different from a predetermined wavelength is picked up by one pickup device. When it is going to be emitted from an apparatus, a laser beam is emitted from another pickup apparatus that is not used. Accordingly, laser light having a predetermined wavelength is emitted from another pickup device. As a result, a disk device capable of high-quality recording is provided. Further, since the disk device includes a plurality of pickup devices, for example, even if a data error occurs on the disk, the data error can be easily recovered. For example, when one pickup device is used to read data on a disc, even if a data read error occurs in one pickup device, data can be read by another pickup device. Therefore, a reading error in one pickup device is recovered by another pickup device. In addition, since the disc device includes a plurality of pickup devices, the disc device can execute trick playback such as variable speed playback and reverse playback. Further, since the disk device is provided with a plurality of pickup devices, it is possible to perform a large amount of data processing on the disk substantially simultaneously. In addition, since the disc device includes a plurality of pickup devices, data for many channels on the disc can be used.

  A disk device according to a second aspect is the disk device according to the first aspect, wherein the two pickup devices are disposed in the main body of the disk device.

  With the above configuration, it is possible to provide a disk device with a reduced price. A single pickup device compatible with all types of discs is difficult in terms of design and manufacturing, and therefore tends to be expensive. However, when three or more pickup devices are installed in a disk device, it is difficult to keep the price of the disk device low because the number of parts increases. By disposing the two pickup devices in the disc device main body, a disc device that is compatible with various discs is configured, and a disc device that is inexpensive is provided. In addition, since the two pickup devices are arranged in the disk device main body, for example, a disk device capable of simultaneously performing twice the data processing as compared with a disk device including only one pickup device. . In addition, since the disc device includes two pickup devices, for example, data for two channels recorded on the disc can be used simultaneously.

  The disc device according to claim 3 is the disc device according to claim 1 or 2, wherein the plurality of pickup devices are a first pickup device and a second pickup device, the first pickup device, and the second pickup device. The pickup device is movable along the radial direction of the disc. When the disc device main body is viewed in plan, the movement direction of the second pickup device is relative to the movement direction of the first pickup device. It is characterized by being set in different directions.

With the above configuration, the disk device is prevented from being greatly increased in size, and the size of the disk device is maintained as a reduced size. When the disk device main body is viewed in plan, the degree of freedom in designing the disk device is improved by setting the movement direction of the second pickup device to be different from the movement direction of the first pickup device. Thereby, it is avoided that the size of the disk device is significantly increased, and a disk device having a predetermined size is configured. In addition, by doing so, it is expected that, for example, an air flow generated when the disk is rotated is easily circulated in the disk device main body.

  A disk device according to a fourth aspect is the disk device according to the first or second aspect, wherein the plurality of pickup devices are a first pickup device and a second pickup device, the first pickup device, and the second pickup device. The pickup device is movable along the radial direction of the disc. When the disc device main body is viewed in plan, the movement direction of the first pickup device and the movement direction of the second pickup device are: 3. The disk device according to claim 1, wherein the disk devices are set in the same direction.

  With the above configuration, harmful vibrations transmitted to the disk are reduced. When the moving direction of the first pickup device and the moving direction of the second pickup device are set in the same direction when the disk device main body is viewed in plan, for example, a disk drive device that rotates the disk is The layout structure is located substantially at the center between the one pickup device and the second pickup device. By doing so, the arrangement structure of the pickup devices in the disk device main body is balanced. Therefore, it is possible to provide a disk device in which measures against vibration are taken.

  As described above, according to the first aspect of the present invention, a disk device that can handle each disk is configured. Since a plurality of pickup devices are installed in the disk device main body in which the disk is accommodated, it is avoided that many functions are integrated into one pickup device. Therefore, each function can be distributed to each pickup device. For example, a disk device corresponding to a plurality of disks is configured by mounting a plurality of single-wavelength pickup devices in the disk device. As a result, it is possible to provide a disk device that can handle each disk. In addition, since the disk device is provided with a plurality of pickup devices, it is easy to prevent the wavelength of the laser light emitted from the pickup device from being changed due to, for example, heat generated from the pickup device. Become. Since the disk device includes a plurality of pickup devices such as one pickup device and another pickup device, for example, the temperature of one pickup device in use rises, and laser light having a wavelength different from a predetermined wavelength is picked up by one pickup device. When it is going to be emitted from an apparatus, a laser beam is emitted from another pickup apparatus that is not used. Accordingly, laser light having a predetermined wavelength is emitted from another pickup device. As a result, a disk device that enables high-quality recording can be provided to an assembly manufacturer of the disk device, a user of the disk device, and the like. Further, since the disk device includes a plurality of pickup devices, for example, even if a data error occurs on the disk, the data error can be easily recovered. For example, when one pickup device is used to read data on a disc, even if a data read error occurs in one pickup device, the data can be read by another pickup device. Therefore, a reading error in one pickup device can be recovered by another pickup device. Further, since the disk device includes a plurality of pickup devices, the disk device can also perform trick playback such as variable speed playback and reverse playback. Further, since the disk device is provided with a plurality of pickup devices, a large amount of data processing on the disk can be performed substantially simultaneously. In addition, since the disc device includes a plurality of pickup devices, data for many channels on the disc can be used.

  According to the second aspect of the present invention, it is possible to provide a disk device with a reduced price. A single pickup device compatible with all types of discs is difficult in terms of design and manufacturing, and therefore tends to be expensive. However, when three or more pickup devices are installed in a disk device, it is difficult to keep the price of the disk device low because the number of parts increases. By disposing the two pickup devices in the disk device main body, it is possible to configure a disk device that is compatible with various types of disks and to provide a disk device with a reduced price. Further, since the two pickup devices are disposed in the disk device main body, for example, a disk device capable of performing twice the data processing simultaneously as compared with a disk device having only one pickup device. In addition, since the disc device includes two pickup devices, for example, data for two channels recorded on the disc can be used simultaneously.

  According to the third aspect of the present invention, it is avoided that the disk device is significantly increased in size, and the size of the disk device is maintained as a reduced size. When the disk device main body is viewed in plan, the degree of freedom in designing the disk device can be improved by setting the movement direction of the second pickup device to be different from the movement direction of the first pickup device. . As a result, the size of the disk device can be prevented from being greatly increased, and a disk device having a predetermined size can be configured. In addition, by doing so, it is expected that, for example, an air flow generated when the disk is rotated can be easily circulated in the disk device main body.

  According to the fourth aspect of the present invention, harmful vibrations transmitted to the disk are reduced. When the moving direction of the first pickup device and the moving direction of the second pickup device are set in the same direction when the disk device main body is viewed in plan, for example, a disk drive device that rotates the disk is The layout structure is located substantially at the center between the one pickup device and the second pickup device. By doing so, the arrangement structure of the pickup devices in the disk device main body is balanced. Therefore, it is possible to provide a disk device in which measures against vibration are taken.

  Embodiments of a disk device according to the present invention will be described below in detail with reference to the drawings.

  FIG. 1 shows a first embodiment of a disk device according to the present invention.

  The disk device 100 is used to reproduce data such as information recorded on the disk 400. Also, data such as information is recorded on the disk 400 using a disk device. As a disk, for example, a read-only optical disk such as a CD-ROM, a DVD-ROM, a write-once optical disk such as a CD-R, a DVD-R, a DVD + R, a CD-RW, a DVD-RW, a DVD + RW, a DVD-RAM. , HD-DVD, Blu-ray Disc, etc., and write / erase and rewritable optical discs.

As described above, “CD” is an abbreviation for “Compact Disc”. “DVD” is an abbreviation for “Digital Versatile Disc” or “Digital Video Disc”. Further, “ROM” of “CD-ROM” or “DVD-ROM” is an abbreviation of “Read Only Memory”, and CD-ROM or DVD-ROM is dedicated to data reading. In addition, “R” in “CD-R” or “DVD-R” or “DVD + R” is an abbreviation of “Recordable”, and CD-R, DVD-R, or DVD + R can write data. Has been. “RW” in “CD-RW” or “DVD-RW” or “DVD + RW” is an abbreviation for “ReWritable”, and CD-RW, DVD-RW, or DVD + RW is rewritable data. Has been. “DVD-RAM” is an abbreviation of “Digital Versatile Disc Random Access Memory”, and data can be read / written / erased.

  “HD-DVD” is an abbreviation for “High Definition DVD”. “HD-DVD” is compatible with a conventional DVD series and has a larger storage capacity than a conventional DVD series disk. Conventional CDs and DVDs use a red laser. When data recorded on an HD-DVD disc is read, a blue-violet laser is used. “Blu-ray” means a blue-violet laser used to achieve high-density recording, compared to the red laser used to read and write signals on conventional CDs and DVDs. It is said that.

  An optical disk apparatus 100 shown in FIG. 1 is an optical disk drive apparatus 30 that rotates an optical disk 400, and an optical pickup apparatus 10 that can read and write data from and to the optical disk 400 by irradiating the optical disk 400 with laser light. , 20.

  The optical disk drive device 30 is configured to include at least a spindle motor (not shown) that rotationally drives the optical disk 400 and a turntable 35 that is attached to the spindle motor and on which the optical disk 400 is mounted.

  An optical disk 400 provided with information such as data is detachably attached to the turntable 35. A chucking portion 36 is provided on the turntable 35 so that the optical disc 400 can be easily attached and detached when the optical disc 400 is attached to and detached from the turntable 35. The optical disk 400 mounted on the turntable 35 using the chucking unit 36 is rotated by a spindle motor (not shown) provided with the turntable 35.

  The optical pickup devices 10 and 20 irradiate the optical disc 400 with laser light, thereby allowing the optical pickup main body 1 to read / write data from / to the optical disc 400 and the optical pickup main body 1 along the radial direction of the optical disc. And a pair of guide shafts 9I and 9II that can be moved with high accuracy.

  The optical pickup body 1 constituting the optical pickup devices 10 and 20 can read information such as data recorded on the optical disc 400 by an optical signal or the like. Further, the optical pickup body 1 constituting the optical pickup devices 10 and 20 can record information such as data on the optical disc 400.

  The optical pickup main body 1 includes a lens 5 for condensing laser light emitted from a laser diode (not shown) on the optical disc 400, a lens holder 4 for holding the lens 5, and a focus direction or tracking of the lens 5 with respect to the disc 400. A connector 7 for inputting / outputting electricity and signals for driving the lens holder 4 in the direction, the laser diode, the lens 5, the lens holder 4, and the housing 2 equipped with the connector 7 are provided. It is configured as a provision.

The optical pickup main body 1 constituting the optical pickup devices 10 and 20 is moved along a pair of guide shafts 9I and 9II constituting the optical pickup devices 10 and 20 by a feed motor (not shown). The optical pickup body 1 constituting the optical pickup devices 10 and 20 is driven along the radial direction of the optical disk by a motor such as a stepping motor (not shown). Further, the lens holder 4 of the optical pickup main body 1 constituting the optical pickup devices 10 and 20 is operable with respect to the optical disc 400 in the focus direction and tracking direction of the lens 5.

  Each guide shaft 9I, 9II is formed as a straight cylindrical column made of metal. The first guide shaft 9I and the second guide shaft 9II are arranged in parallel. The first guide shaft 9I and the second guide shaft 9II are arranged in parallel with high accuracy.

  Corresponding to the pair of metal guide shafts 9I and 9II, a pair of guide portions 2I and 2II are provided in the metal housing 2 constituting the optical pickup main body 1. A first guide shaft 9I is aligned with the first guide portion 2I of the housing 2 constituting the optical pickup body 1. The second guide shaft 9II is aligned with the second guide portion 2II of the housing 2 constituting the optical pickup body 1.

  The optical disk drive main body 150 is configured by housing the optical disk drive device 30 and the optical pickup devices 10 and 20 in a substantially rectangular box-shaped synthetic resin casing 120. The optical disk 400 is provided in a tray (not shown) that can enter and exit the optical disk apparatus main body 150 and is accommodated in the optical disk apparatus main body 150.

  Corresponding to a plurality of standard optical disks, a plurality of optical pickup devices 10 and 20 are mounted on an optical disk apparatus main body 150 in which an optical disk 400 is accommodated.

  As a result, an optical disc apparatus 100 that can handle each standard optical disc is configured. Since the optical disc apparatus main body 150 in which the optical disc 400 is accommodated is equipped with the plurality of optical pickup devices 10 and 20, it is avoided that many functions are concentrated in one optical pickup device. Therefore, each function can be distributed to each optical pickup device 10, 20.

  For example, by mounting a plurality of single-wavelength optical pickup devices (10, 20) in the optical disc device (100), an optical disc device (100) corresponding to the plurality of optical discs (400) is configured. For example, a single-wavelength optical pickup device (10, 20), which is considered to be low cost, is combined and mounted in the optical disc device main body (150), whereby the optical disc device (100) that realizes multi-drive is configured. Will be. As a result, the optical disk device (100) that can support each standard optical disk can be provided to an assembly manufacturer of the optical disk device (100), a user of the optical disk device (100), and the like.

  Further, since the optical disc apparatus 100 includes a plurality of optical pickup devices 10 and 20, the optical pickup device is caused by heat generated from a laser diode (not shown) of the optical pickup devices 10 and 20, for example. It is also easy to prevent the wavelength of the laser light emitted from the laser diodes 10 and 20 from changing.

Since the optical disk device 100 includes a plurality of optical pickup devices 10 and 20 such as one optical pickup device 10 and another optical pickup device 20, for example, the temperature of the one optical pickup device 10 in use increases and is determined. When a laser beam having a wavelength different from that of the optical pickup is about to be emitted from the laser diode of the one optical pickup device 10, the emission of the laser light from the optical pickup device 10 is interrupted, and another optical pickup device that is not used. Laser light is emitted from 20 laser diodes. Accordingly, laser light having a predetermined wavelength is emitted from the laser diode of the other optical pickup device 20. The laser light is switched from the laser diode of one optical pickup device 10 to the laser diode of the other optical pickup device 20 and continues to be emitted.

  Next, when the temperature of the other optical pickup device 20 in use rises and a laser beam having a wavelength different from the predetermined wavelength is about to be emitted from the laser diode of the other optical pickup device 20, the other optical pickup The emission of the laser beam from the apparatus 20 is interrupted, and the laser beam is emitted from the laser diode of the one-optical pickup apparatus 10 that is suspended. Therefore, a laser beam having a predetermined wavelength is emitted from the laser diode of the one optical pickup device 10. The laser light is switched from the laser diode of the other optical pickup device 20 to the laser diode of the one-optical pickup device 10 and continues to be emitted. Such a process is repeated, and laser light is emitted alternately from the optical pickup devices 10 and 20.

  The optical pickup devices 10 and 20 are alternately used and in a rest state. After the laser diodes of the heated optical pickup devices 10 and 20 are cooled, the resting optical pickup devices 20 and 10 are used again. By doing so, the optical disc apparatus 100 capable of high-quality recording can be provided to an assembly manufacturer of the optical disc apparatus 100, a user of the optical disc apparatus 100, and the like.

  In addition, since the optical disc device 100 includes a plurality of optical pickup devices 10 and 20, even if a data error occurs in the optical disc 400, for example, the data error can be easily recovered. For example, even if a data reading error occurs in the one optical pickup device 10 when the optical pickup device 10 is used to read data on the optical disc 400, the other optical pickup device 20 Therefore, the reading error in the one optical pickup device 10 can be recovered by the other optical pickup device 20.

  Even if another optical pickup device 20 is used to read data on the optical disc 400, even if a data read error occurs in the other optical pickup device 20, the one optical pickup device 10 is used. Thus, it is possible to read data in the other optical pickup device 20, so that the one optical pickup device 10 can recover the reading error. As described above, the plurality of optical pickup devices 10 and 20 assist each other, thereby recovering the data reading error when the data reading operation of the optical disc 400 is being performed.

  Further, since the optical disc device 100 includes a plurality of optical pickup devices 10 and 20, the optical disc device 100 can perform trick playback such as variable speed playback and reverse playback. In addition, since the optical disc device 100 includes a plurality of optical pickup devices 10 and 20, a large amount of data processing on the optical disc 400 can be performed substantially simultaneously. Further, since the optical disc apparatus 100 includes a plurality of optical pickup devices 10 and 20, data for many channels in the optical disc 400 can be used.

  Two optical pickup devices 10 and 20 are disposed in the optical disc apparatus main body 150.

By making the number of the optical pickup devices 10 and 20 two, the optical disc device 100 with a reduced price can be provided to an assembly manufacturer of the optical disc device 100, a user of the optical disc device 100, and the like. A single optical pickup device compatible with all types of optical discs is currently difficult in terms of design, manufacture, and the like, and is likely to be expensive. However, when three or more optical pickup devices are installed in an optical disk device, it is difficult to keep the price of the optical disk device low because of an increase in the number of parts.

  By providing the two optical pickup devices 10 and 20 in the optical disc device main body 150, it is possible to configure the optical disc device 100 that is compatible with various optical discs, and the optical disc device 100 is reduced in price. Can be provided to an assembly manufacturer of the optical disc apparatus 100, a user of the optical disc apparatus 100, and the like.

  In addition, since the two optical pickup devices 10 and 20 are disposed in the optical disc apparatus main body 150, it is possible to simultaneously perform twice the data processing as compared with, for example, an optical disc apparatus having only one optical pickup device. The optical disc device 100 is obtained. In addition, since the optical disc device 100 includes the two optical pickup devices 10 and 20, for example, data for two channels recorded on the optical disc 400 can be used simultaneously.

  The plurality of optical pickup devices 10 and 20 are a first optical pickup device 10 and a second optical pickup device 20. The first optical pickup device 10 and the second optical pickup device 20 are movable along the radial direction of the optical disc 400. When the interior 160 of the optical disc apparatus main body 150 is viewed in plan, the movement direction of the second optical pickup device 20 is set to be different from the movement direction of the first optical pickup device 10.

  More specifically, when the inside 160 of the optical disc apparatus main body 150 is viewed in plan, the movement direction of the second optical pickup apparatus 20 is set to be substantially orthogonal to the movement direction of the first optical pickup apparatus 10. Yes. More specifically, the moving direction of the first optical pickup device 10 and the moving direction of the second optical pickup device 20 are substantially V-shaped when the inside 160 of the optical disc apparatus main body 150 is viewed in plan. The first optical pickup device 10 and the second optical pickup device 20 are disposed in the optical disc apparatus main body 150.

  Further, when the inside 160 of the optical disc apparatus 100 is viewed in plan, the turntable 35 of the optical disc drive apparatus 30 that rotationally drives the optical disc 400 is biased to the front side from the substantially central portion 190 of the optical disc apparatus main body 150. It is said that.

  As described above, the optical pickup devices 10 and 20 and the optical disc drive device 30 are arranged in the optical disc device main body 150, so that the optical disc device 100 is prevented from being greatly increased in size. The size is maintained as a miniaturized size. When the interior 160 of the optical disk apparatus main body 150 is viewed in plan, the movement direction of the second optical pickup apparatus 20 is set to be different from the movement direction of the first optical pickup apparatus 10, thereby designing the optical disk apparatus 100. The degree of freedom increases. Thereby, it is avoided that the size of the optical disc apparatus 100 is significantly increased, and the optical disc apparatus 100 having a predetermined size is configured. In addition, by doing so, it is expected that, for example, an air flow generated when the optical disk 400 is rotated is easily circulated in the optical disk apparatus main body 150.

  The optical disk device can be installed in various personal computers (not shown) such as a desktop personal computer and a notebook personal computer. The desktop computer is a desktop computer and can be used on a desk, but is not of a type that can be easily carried.

In contrast to desktop personal computers, notebook personal computers
Since light weight and light weight are required, the structure is provided with a disk device equipped with a slim type drive. A notebook personal computer has a structure different from that of a desktop personal computer. A notebook personal computer has a structure in which a display and a personal computer main body are integrated, and the display is folded with respect to the personal computer main body, so that the laptop personal computer has a thin size. The notebook personal computer is a general-purpose personal computer having a size of about A4 or smaller when viewed in plan, and is also called a book-type personal computer.

  The optical disc apparatus main body 150 with a tray (not shown) removably attached can be installed in a desktop personal computer (not shown). Since the housing 120 of the optical disc apparatus main body 150 for desktop personal computers has a certain amount of space in the interior 160, the layout of each component in the casing 120 of the optical disc apparatus main body 150 can be adjusted to adjust the casing. A plurality of optical pickup devices 10 and 20 can be accommodated in 120.

  If the optical disk apparatus 100 having such a structure is configured, it is possible to provide the optical disk apparatus 100 for a desktop personal computer that is compatible with disks of various standards. Further, the optical disk device 100 for desktop personal computer capable of correctly and quickly executing reading and writing of data with respect to the optical disk 400 can be provided to an assembly manufacturer of the optical disk device 100, a user of the optical disk device 100, and the like.

  FIG. 2 shows a second embodiment of the disk device according to the present invention.

  With respect to FIG. 2, detailed description of the same components as those described in FIG. 1 is omitted.

  The optical disc apparatus 200 includes an optical disc drive device 80 that rotates the optical disc 400, and optical pickup devices 60 and 70 that can read and write data from and on the optical disc 400 by irradiating the optical disc 400 with laser light. It is supposed to be equipped with.

  The optical disk drive device 80 is configured to include at least a spindle motor (not shown) that rotationally drives the optical disk 400 and a turntable 85 that is attached to the spindle motor and on which the optical disk 400 is mounted.

  An optical disk 400 provided with information such as data is detachably attached to the turntable 85. A chucking portion 86 is provided on the turntable 85 so that the optical disk 400 can be easily attached and detached when the optical disk 400 is attached to and detached from the turntable 85. The optical disk 400 mounted on the turntable 85 using the chucking unit 86 is rotated by a spindle motor (not shown) provided with the turntable 85.

  The optical pickup devices 60 and 70 irradiate the optical disc 400 with laser light, thereby allowing the optical pickup main body 51 to read and write data to the optical disc 400, and the optical pickup main body 51 along the radial direction of the optical disc. And a pair of guide shafts 59I and 59II that can be moved with high accuracy.

The optical pickup main body 51 constituting the optical pickup devices 60 and 70 can read information such as data recorded on the optical disc 400 by an optical signal or the like. Further, the optical pickup body 51 constituting the optical pickup devices 60 and 70 can record information such as data on the optical disc 400.

  The optical pickup main body 51 includes a lens 55 that condenses laser light emitted from a laser diode (not shown) on the optical disc 400, a lens holder 54 that holds the lens 55, and a focus direction or tracking of the lens 55 with respect to the disc 400. A connector 57 for inputting / outputting electricity and signals for driving the lens holder 54 in a direction, the laser diode, the lens 55, the lens holder 54, and a housing 52 equipped with the connector 57. It is configured as a provision.

  The optical pickup main body 51 constituting the optical pickup devices 60 and 70 is moved along a pair of guide shafts 59I and 59II constituting the optical pickup devices 60 and 70 by a feed motor (not shown). The optical pickup main body 51 constituting the optical pickup devices 60 and 70 is driven along the radial direction of the optical disk by a motor such as a stepping motor (not shown). Further, the lens holder 54 of the optical pickup main body 51 constituting the optical pickup devices 60 and 70 is operable with respect to the optical disc 400 in the focus direction and tracking direction of the lens 55.

  Each guide shaft 59I, 59II is formed as a straight cylindrical column made of metal. The first guide shaft 59I and the second guide shaft 59II are arranged in parallel. The first guide shaft 59I and the second guide shaft 59II are arranged in parallel with high accuracy.

  Corresponding to the pair of metal guide shafts 59I and 59II, a pair of guide portions 52I and 52II are provided in a metal housing 52 constituting the optical pickup body 51. A first guide shaft 59I is aligned with the first guide portion 52I of the housing 52 that constitutes the optical pickup body 51. The second guide shaft 59II is aligned with the second guide portion 52II of the housing 52 that constitutes the optical pickup body 51.

  The optical disk drive main body 250 is configured by housing the optical disk drive device 80 and the optical pickup devices 60 and 70 in a substantially rectangular box-shaped synthetic resin casing 220. The optical disk 400 is provided in a tray (not shown) that can enter and exit the optical disk apparatus main body 250 and is accommodated in the optical disk apparatus main body 250.

  A plurality of optical pickup devices 60 and 70 are mounted on an optical disc apparatus main body 250 in which the optical disc 400 is accommodated, corresponding to a plurality of standard optical discs.

  As a result, an optical disc apparatus 200 that can handle each standard optical disc is configured. Since the optical disc apparatus main body 250 in which the optical disc 400 is accommodated is equipped with a plurality of optical pickup devices 60 and 70, it is avoided that many functions are concentrated in one optical pickup device. Therefore, each function is distributed to each optical pickup device 60, 70.

For example, by mounting a plurality of single-wavelength optical pickup devices (60, 70) in the optical disc device (200), an optical disc device (200) corresponding to the plurality of optical discs (400) is configured. For example, a single-wavelength optical pickup device (60, 70), which is considered to be a low cost, is combined and mounted in the optical disc device main body (250), so that an optical disc device (200) that realizes multi-drive is configured. Will be. As a result, an optical disc device (200) that can handle optical discs of each standard is provided to an assembly manufacturer of the optical disc device (200), a user of the optical disc device (200), and the like.

  Further, since the optical disk device 200 includes a plurality of optical pickup devices 60 and 70, the optical pickup device is caused by, for example, heat generated from a laser diode (not shown) of the optical pickup devices 60 and 70. It is also easy to prevent the wavelength of the laser light emitted from the laser diodes 60 and 70 from changing.

  Since the optical disk device 200 includes a plurality of optical pickup devices 60 and 70 such as the one optical pickup device 60 and the other optical pickup device 70, the temperature of the one optical pickup device 60 in use increases and is determined, for example. When a laser beam having a wavelength different from the wavelength of the light is about to be emitted from the laser diode of the one optical pickup device 60, the emission of the laser light from the optical pickup device 60 is interrupted, and another optical pickup device that is not used. Laser light is emitted from 70 laser diodes. Accordingly, laser light having a predetermined wavelength is emitted from the laser diode of the other optical pickup device 70. The laser light is switched from the laser diode of one optical pickup device 60 to the laser diode of another optical pickup device 70 and continues to be emitted.

  Next, when the temperature of the other optical pickup device 70 in use rises and a laser beam having a wavelength different from the predetermined wavelength is about to be emitted from the laser diode of the other optical pickup device 70, the other optical pickup device The laser light is emitted from the laser diode of the one-optical pickup device 60 that is suspended and stopped from emitting the laser light from the device 70. Therefore, a laser beam having a predetermined wavelength is emitted from the laser diode of the one optical pickup device 60. The laser light is switched from the laser diode of the other optical pickup device 70 to the laser diode of the one optical pickup device 60 and continues to be emitted. Such a process is repeated, and laser light is emitted alternately from the optical pickup devices 60 and 70.

  The optical pickup devices 60 and 70 are alternately used and in a rest state. After the heated laser diodes of the optical pickup devices 60 and 70 are cooled, the resting optical pickup devices 70 and 60 are used again. By doing so, the optical disc device 200 capable of high-quality recording is provided to an assembly manufacturer of the optical disc device 200, a user of the optical disc device 200, and the like.

  Further, since the optical disc device 200 includes a plurality of optical pickup devices 60 and 70, even if a data error occurs in the optical disc 400, for example, the data error can be easily recovered. For example, even if a data reading error occurs in the one optical pickup device 60 when the one optical pickup device 60 is used to read data on the optical disc 400, the other optical pickup device 70 is informed. Therefore, the reading error in the one optical pickup device 60 is recovered by the other optical pickup device 70.

  Even if another optical pickup device 70 is used to read data on the optical disk 400, even if a data read error occurs in the other optical pickup device 70, the one optical pickup device 60 is used. Since the data can be read at the same time, the reading error in the other optical pickup device 70 is recovered by the one optical pickup device 60. As described above, the plurality of optical pickup devices 60 and 70 assist each other, thereby recovering the data reading error when the data reading operation of the optical disc 400 is being performed.

In addition, since the optical disc device 200 includes a plurality of optical pickup devices 60 and 70, the optical disc device 200 can perform trick playback such as variable speed playback and reverse playback.
It becomes. Further, since the optical disc device 200 includes a plurality of optical pickup devices 60 and 70, a large amount of data processing on the optical disc 400 can be performed substantially simultaneously. In addition, since the optical disc device 200 includes a plurality of optical pickup devices 60 and 70, data for many channels on the optical disc 400 can be used.

  Two optical pickup devices 60 and 70 are disposed in the optical disc apparatus main body 250.

  By making the number of the optical pickup devices 60 and 70 two, it is possible to provide the optical disc device 200 with a reduced price to an assembly manufacturer of the optical disc device 200, a user of the optical disc device 200, and the like. A single optical pickup device compatible with all types of optical discs is currently difficult in terms of design, manufacture, and the like, and is likely to be expensive. However, when three or more optical pickup devices are installed in an optical disk device, it is difficult to keep the price of the optical disk device low because of an increase in the number of parts.

  By arranging the two optical pickup devices 60 and 70 in the optical disc device main body 250, an optical disc device 200 that can cope with various optical discs is configured, and an optical disc device 200 with reduced price is provided. It will be provided to an assembly manufacturer of the optical disc apparatus 200, a user of the optical disc apparatus 200, and the like.

  Further, since the two optical pickup devices 60 and 70 are disposed in the optical disc apparatus main body 250, it is possible to simultaneously perform twice the data processing as compared with an optical disc apparatus having only one optical pickup device, for example. The optical disc device 200 is obtained. Further, since the optical disc device 200 includes two optical pickup devices 60 and 70, for example, data for two channels recorded on the optical disc 400 can be used simultaneously.

  The plurality of optical pickup devices 60 and 70 are a first optical pickup device 60 and a second optical pickup device 70. The first optical pickup device 60 and the second optical pickup device 70 are movable along the radial direction of the optical disc 400. When the interior 260 of the optical disc apparatus main body 250 is viewed in plan, the moving direction of the first optical pickup device 60 and the moving direction of the second optical pickup device 70 are set in the same direction. More specifically, when the inside 260 of the optical disc apparatus main body 250 is viewed in plan, the moving direction of the first optical pickup device 60 and the moving direction of the second optical pickup device 70 are substantially straight and substantially I. A first optical pickup device 60 and a second optical pickup device 70 are arranged in the optical disc apparatus main body 250 so as to have a letter shape.

  In addition, an optical disc drive device 80 that rotates the optical disc 400 is installed between the first optical pickup device 60 and the second optical pickup device 70. The turntable 85 of the optical disk drive device 80 that rotationally drives the optical disk 400 when the inside 260 of the optical disk apparatus 200 is viewed in plan is positioned at a substantially central portion 290 of the optical disk device body 250.

Thus, the harmful vibrations transmitted to the optical disc 400 are reduced by arranging the optical pickup devices 60 and 70 and the optical disc drive device 80 in the optical disc apparatus main body 250. When the interior 260 of the optical disc apparatus main body 250 is viewed in plan, the moving direction of the first optical pickup device 60 and the moving direction of the second optical pickup device 70 are set in the same direction, and the first optical pickup device In the optical disc apparatus main body 250, the first optical pickup device 60 and the second optical pickup device 60 are arranged so that the movement direction of the second optical pickup device 70 and the movement direction of the second optical pickup device 70 are substantially straight. When the optical pickup device 70 is provided, the optical disc drive device 80 for rotating the optical disc 400 includes a first optical pickup device 60 that is a first traverse mechanism and a second light that is a second traverse mechanism. The layout structure is located substantially at the center of the pickup device 70. By doing so, the arrangement structure of the optical pickup devices 60 and 70 in the optical disc apparatus main body 250 is balanced. Therefore, it is possible to provide the optical disk device 200 with vibration countermeasures to an assembly manufacturer of the optical disk device 200, a user of the optical disk device 200, and the like.

  The optical disk device can be installed in various personal computers (not shown) such as a desktop personal computer and a notebook personal computer.

  The optical disc apparatus main body 250 on which a tray (not shown) is detachably mounted can be installed in a desktop personal computer (not shown). Since the housing 220 of the optical disk apparatus main body 250 for desktop personal computers has a certain amount of space in the interior 260, the layout of each component in the housing 220 of the optical disk apparatus main body 250 can be adjusted to adjust the housing. A plurality of optical pickup devices 60 and 70 can be accommodated in the body 220.

  If the optical disk apparatus 200 having such a structure is configured, it is possible to provide the optical disk apparatus 200 for a desktop personal computer that is compatible with disks of various standards. Further, the optical disk device 200 for a desktop personal computer that can correctly and quickly execute data reading / writing with respect to the optical disk 400 can be provided to an assembly manufacturer of the optical disk device 200, a user of the optical disk device 200, and the like.

  The disk device can be installed in, for example, a personal computer such as a notebook personal computer or desktop personal computer, an audio device such as a CD player, or an audio / video device such as a DVD player. In addition, the optical disk apparatus can be adapted to a plurality of media such as a CD optical disk and a DVD optical disk. The disk device of the present invention is not limited to the illustrated one. The thing of this invention can be changed variously in the range which does not deviate from the summary.

It is explanatory drawing which shows 1st embodiment of the disc apparatus which concerns on this invention. It is explanatory drawing which shows 2nd embodiment of the disc apparatus which concerns on this invention. It is a perspective view which shows one form of the conventional disc apparatus.

Explanation of symbols

1,51 Optical pickup body (Pickup body)
2,52 Housing 2I, 52I First guide part (guide part)
2II, 52II 1st guide part (guide part)
4,54 Lens holder 5,55 Lens 7,57 Connector 9I, 59I First guide shaft (guide shaft)
9II, 59II Second guide shaft (guide shaft)
10, 60 First pickup device (Pickup device)
20, 70 Second pickup device (pickup device)
30, 80 Optical disk drive device (disk drive device)
35,85 Turntable 36,86 Chucking unit 100,200 Optical disc device (disc device)
120, 220 Case 150, 250 Optical disk device main body (disk device main body)
160, 260 Inside 190, 290 Central part 400 Optical disc (disc)

Claims (4)

By irradiating the disk with a laser beam, it is equipped with a pickup device capable of reading and writing data on the disk,
A disk device comprising a plurality of pickup devices mounted on a disk device main body in which the disk is accommodated.   2. The disk device according to claim 1, wherein the two pickup devices are disposed in the disk device main body. The plurality of pickup devices are a first pickup device and a second pickup device,
The first pickup device and the second pickup device are movable along the radial direction of the disc,
3. The moving direction of the second pickup device is set to be different from the moving direction of the first pickup device when the disk device main body is viewed in plan. Disk unit. The plurality of pickup devices are a first pickup device and a second pickup device,
The first pickup device and the second pickup device are movable along the radial direction of the disc,
3. The moving direction of the first pickup device and the moving direction of the second pickup device are set in the same direction when the disk device main body is viewed in plan. Disk unit.

Images