JP3664165B2 - Optical storage - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates generally to an optical storage device, and more particularly to an overall device structure for reducing the size and weight of an optical storage device.
[0002]
[Prior art]
Optical discs are attracting attention as a core storage medium in the rapidly developing multimedia in recent years, and are usually stored in cartridges so as to be portable.
[0003]
Then, the optical disk cartridge is loaded into the optical disk apparatus, and information access to the optical disk is performed by the optical head.
[0004]
[Problems to be solved by the invention]
Currently, an optical disk apparatus is used in a state of being externally attached to a computer via a SCSI interface. The external dimensions of the 3.5-inch magneto-optical disk drive unit taken out from the outer rocker are 1-inch height type and are approximately 25.4 (height) × 101.6 (width) × 150 (depth) mm (± The accuracy error of about 0.5 mm is taken into account), and its weight is about 470 g. Moreover, the external dimension of the state accommodated in the exterior rocker is 36 (height) × 132 (width) × 208 (depth) mm.
[0005]
Therefore, it can be applied only to a desktop type personal computer, and it is difficult to carry in a portable personal computer that is rapidly spreading at present in terms of size and weight.
[0006]
Therefore, in order to improve the user-friendliness, it is desired to install an optical disk device inside a portable personal computer to improve the usage environment, and technical development for miniaturization and weight reduction is proceeding at a rapid pace. It has been.
[0007]
Accordingly, an object of the present invention is to provide an optical storage device that is reliable, durable, and further improved as a data storage device, and that is small, lightweight, and inexpensive. Another object of the present invention is to provide an optical storage device such as a magneto-optical disk device and a phase change optical disk device having a height of about 24 mm or less and a total weight of 300 g or less. An object of the present invention is to make it possible to mount the optical storage device on a portable personal computer without changing the design.
[0008]
It is another object of the present invention to provide an optical storage device that is approximately the same size as a floppy disk device having a thickness of about 17 mm and can be inserted into an existing floppy disk unit (slot) in a personal computer or the like. Another object of the present invention is to improve the versatility by improving the connectivity of the optical storage device with the host device.
[0009]
[Means for Solving the Problems]
In order to achieve the above-mentioned object, the present invention
An optical storage device includes a drive base on which at least one mechanism for accessing an optical storage medium is disposed, and a block formed on a surface of the drive base, and is provided at an end of the drive base. A light-emitting element that emits light and a photodetector that detects return light from the optical storage medium are attached, and at least a part of the optical component for guiding the light contacts the surface of the block; Are positioned and arranged.
[0010]
Therefore, it is possible to directly place the optical component on the drive base by providing the block and contacting the optical component to improve the accuracy of the mounting surface. Further, as described in Japanese Patent Laid-Open No. 7-210878, the fixed optical head base provided separately from the conventional drive base can be eliminated, and the fixed optical unit is the size of the optical component. This makes it possible to reduce the thickness of the apparatus and reduce the number of parts to reduce the weight.
[0011]
In addition, by using the end of the drive base where other parts that are bulky are not placed, light emitting elements and photodetectors that are bulky are placed, so that the drive base can be made thinner and the device can be made thinner. It becomes possible to plan.
[0012]
In an optical storage device, a cartridge holder into which a cartridge for storing an optical storage medium is inserted, and a drive base on which the cartridge holder is mounted and recessed toward the cartridge holder mounting surface outside the portion in which the cartridge is stored And a block formed on the inner wall of the recess of the drive base, and a light emitting element that emits light and a photodetector that detects return light from the optical storage medium on the outer periphery of the recess of the drive base At least a part of the optical component for guiding light contacts the surface of the block and is positioned and arranged inside the recess of the drive base.
[0013]
Therefore, by providing the drive base outside the cartridge housing space with a recess that becomes a fixed optical head base (fixed optical unit), the height of the drive base can be realized substantially equal to the thickness of the cartridge. Can be accommodated within the height range of the drive base, and the device can be made thinner and smaller.
[0014]
Further, as described in Japanese Patent Laid-Open No. 7-210878, the fixed optical head base provided separately from the conventional drive base can be eliminated, and the fixed optical unit is the size of the optical component. Accordingly, it is possible to reduce the thickness and size of the apparatus, and it is possible to reduce the number of parts and reduce the weight.
[0015]
Further, by providing a block to improve the accuracy of the mounting surface of the optical component, the optical component can be directly arranged on the drive base.
[0016]
Furthermore, by using the outer peripheral part of the dent where the other parts whose bulk is high are not arranged outside the cartridge holder housing part, by providing a light emitting element and a photodetector, without depending on the height of the dent, The light emitting element and the photodetector can be protruded to the lower surface side of the dent, and the dent can be thinned and miniaturized to the minimum, so that the apparatus can be thinned and miniaturized.
[0017]
A shielding cover for shielding light is provided on the upper surface of the recess of the drive base.
[0018]
Therefore, it is possible to block the light inside and outside the fixed optical unit and seal it to prevent the inflow of dust, and to protect optical components that are vulnerable to dust.
[0019]
In the optical storage device, a cartridge holder receiving portion in which a cartridge holder into which a cartridge for storing an optical storage medium is inserted is disposed, and a turntable for rotating the optical storage medium is protruded to the cartridge holder side. A turntable unit housing portion in which a turntable unit for holding a turntable on the upper surface side facing the cartridge holder housing portion is disposed, and a second formed in the radial direction of the optical storage medium A moving optical unit housing portion having an opening, in which a moving optical unit for moving the objective lens in the second opening is disposed, and a first slit serving as a path for guiding light from the light emitting element to the inside of the drive base, A second slit serving as a path for guiding light to a photodetector outside the drive base, a light emitting element and an objective lens And a third slit serving as a path for guiding light between the objective lens and the photodetector, and a block having a surface for bringing the optical component for guiding the light into contact with each other and obtaining the positional accuracy of the optical component. It is characterized by comprising a formed drive base.
[0020]
Therefore, it is possible to form a fixed optical head base on the drive base by providing a slit in the portion that becomes the optical path and a block for obtaining positional accuracy in the portion where the optical component is arranged, and a high-precision optical It is possible to arrange the components and directly arrange the optical components on the drive base.
[0021]
Therefore, it is possible to reduce the thickness and size of the apparatus by minimizing the thickness and size of the drive base.
[0022]
In the optical storage device, the optical storage device has a reference surface on which at least a turntable unit for holding a turntable for rotationally driving the optical storage medium is mounted, and a recess formed so as to protrude from the reference surface toward the other surface. A drive base is provided, and a motor formed of a flat box-shaped unit is disposed in the recess.
[0023]
Therefore, by securing the motor housing space by recessing the drive base, the drive base reference surface does not require an excessive height for the eject motor on the upper surface side, and the drive base reference surface is free on the lower surface side. Space can be used, and the drive base can be made thinner and smaller. Further, by adopting a motor composed of a flat box-shaped unit, the drive base can be made thinner and smaller, and the device can be made thinner and smaller.
[0024]
In an optical storage device, a cartridge holder into which a cartridge for storing an optical storage medium is inserted, an eject motor for driving the cartridge to be ejected, and a cartridge holder mounted on the outside of the portion in which the cartridge is stored A drive base having a first housing portion and a second housing portion that protrude and are recessed toward the holder mounting surface, a block formed on a part of the inner wall of the first housing portion, and a first housing portion A light-emitting element that emits light and a photodetector that detects return light from the storage medium are attached to the outer peripheral portion, and at least a part of the optical components for guiding the light is blocked inside the first housing portion. A fixed optical unit in which an optical component is positioned and arranged in contact with the surface, and an eject motor in which an eject motor is arranged in the second housing portion Characterized by comprising a knit.
[0025]
Accordingly, a space for accommodating the fixed optical unit and the eject motor is secured by recessing the drive base, and the space is provided on the drive base outside the space for accommodating the cartridge (the cartridge holder accommodating portion). It is not necessary to secure the height on the upper surface side of the drive base, it can be accommodated within the height range of the drive base, and the height of the drive base on the upper surface side of the cartridge holder can be reduced. become.
[0026]
The eject motor is composed of a flat box-shaped unit.
[0027]
Further, by adopting an eject motor composed of a flat box-shaped unit, the drive base can be made thinner, and the device can be made thinner and smaller.
[0028]
In an optical storage device, an objective lens is mounted, and a moving optical unit that moves the objective lens in a radial direction of the optical storage medium, and a light emission in a direction perpendicular to the moving direction of the moving optical unit are arranged. The first light-emitting element, the first optical component that refracts the light from the light-emitting element and guides it to the moving optical unit, refracts the return light from the optical storage medium and guides it in the perpendicular direction, and from the optical storage medium A second optical component that separates and guides the return light into a reproduction signal component and a servo signal component; a first photodetector that detects the reproduction signal by receiving the light of the reproduction signal component; and the light of the servo signal component A fixed optical unit having at least a second photodetector that receives light and detects a servo signal.
[0029]
Therefore, the optical path can be shortened to the shortest distance by taking the arrangement of the fixed optical unit as described above, and the optical component can be simplified and miniaturized to reduce the capacity of the optical component in the fixed optical unit. This makes it possible to reduce the thickness and size of the device.
[0030]
The fixed optical unit is provided with a head base in which a drive base outside a portion in which a cartridge of an optical storage medium is accommodated protrudes toward the surface side of the cartridge accommodating portion, and the light emitting element, One photodetector and the second photodetector are directly disposed, and at least the first optical component and the second optical component are disposed directly inside the recess.
[0031]
Accordingly, the fixed optical unit is formed on the outside of the cartridge housing portion and by using an empty space on the surface side of the cartridge housing portion, and the optical component is directly arranged on the drive base, so that the cartridge housing portion of the drive base is provided. It is possible to reduce the thickness of the upper surface of the device, and to reduce the thickness and size of the device.
[0032]
The servo unit further includes a servo unit for separating the servo signal component into a plurality of signal components, and the second photodetector detects a focus signal and a track signal from the plurality of signal components.
[0033]
Therefore, by using a servo unit, two signals can be extracted without using a plurality of photodetectors, optical components can be simplified and miniaturized, and the optical path can be shortened. The storage volume of the optical components of the fixed optical unit can be reduced, and the apparatus can be reduced in thickness and size.
[0034]
An optical storage device includes a turntable unit having a turntable for rotationally driving an optical storage medium and a metal plate on which the turntable is mounted.
[0035]
Therefore, the thickness of the member that holds the turntable is made as thin as possible, and the overall height of the turntable unit is brought close to the height of the turntable alone, so that the height of the drive base turntable unit housing is made thin. Therefore, the apparatus can be reduced in size and thickness. Furthermore, the turntable can be held on the metal plate by simple processing, and the number of parts can be reduced and the cost can be reduced.
(Claim 1)
An optical storage device includes a cartridge holder for holding a cartridge in which an optical storage medium is accommodated, a wall surface facing the cartridge, and a first opening provided in the wall surface, the cartridge holder facing the wall surface. Drive base that can be mounted on both the upper and lower surfaces, a turntable that is mounted on the lower surface side of the drive base below the cartridge holder, and rotates the optical storage medium, and has a slide portion , A turntable unit comprising a metal plate for holding the turntable, and a load plate mounted on the lower surface side of the drive base and formed with a guide having an inclined surface, and the load plate moves back and forth on the drive base The slide part slides on the inclined surface of the guide and raises the metal plate of the turntable unit. And a load / unload mechanism for lowering, and when the turntable holds the optical storage medium, the turntable protrudes from the first opening of the drive base toward the cartridge holder by raising the metal plate, When releasing the engagement between the turntable and the optical storage medium, the turntable is lowered from the first opening of the drive base by lowering the metal plate. The height of the portion to be mounted is set to be substantially the same as the height of the turntable unit. (Claim 2)
In an optical storage device, a cartridge holder that holds a cartridge in which an optical storage medium is accommodated, a wall surface facing the cartridge, and a first opening provided in the wall surface, the cartridge holder facing the wall surface Drive base that can be mounted on both the upper and lower surfaces, a turntable that is mounted on the lower surface side of the drive base below the cartridge holder, and rotates the optical storage medium, and has a slide portion , A turntable unit comprising a metal plate for holding the turntable, and a load plate mounted on the lower surface side of the drive base and formed with a guide having an inclined surface, and the load plate moves back and forth on the drive base The slide part slides on the inclined surface of the guide and raises the metal plate of the turntable unit. A load / unload mechanism for lowering, and when the turntable holds the optical storage medium, the turntable protrudes from the first opening of the drive base toward the cartridge holder by raising the metal plate, When releasing the engagement between the turntable and the optical storage medium, the turntable is lowered from the first opening of the drive base by lowering the metal plate. The height of the portion to be mounted is set to be substantially the same as the higher one of the height of the turntable unit or the height of the guide.
(Claim 3)
In an optical storage device, a cartridge holder that holds a cartridge in which an optical storage medium is accommodated, a wall surface facing the cartridge, and a first opening provided in the wall surface, the cartridge holder facing the wall surface Drive base that can be mounted on both the upper and lower surfaces, a turntable that is mounted on the lower surface side of the drive base below the cartridge holder, and rotates the optical storage medium, and has a slide portion A turntable unit comprising a metal plate for holding the turntable, and a load plate mounted on the lower surface side of the drive base and formed with a guide having an inclined surface, and the load plate is moved back and forth on the drive base. By moving, the slide part slides on the inclined surface of the guide and raises the metal plate of the turntable unit. And a load / unload mechanism that raises / lowers, and when the turntable holds the optical storage medium, the turntable is raised from the first opening of the drive base toward the cartridge holder side by raising the metal plate. When the engagement between the turntable and the optical storage medium is released, the turntable is lowered by lowering the metal plate. The drive base is configured to descend from the first opening of the drive base, and the height of the portion on which the drive base turntable unit is mounted is set to be substantially the same as the maximum movement amount of the turntable unit. Features.
[0036]
Therefore, the height of the drive base on the upper surface side of the cartridge holder accommodating portion can be suppressed only to the height of the mechanism for loading / unloading the turntable unit, and the front surface of the apparatus can be made as thin as possible. It is possible to make the height of the apparatus as close as possible to the thickness of the cartridge. Therefore, it can be used as a built-in optical storage device by being inserted into a unit having a height of about 17 mm in the host system.
[0037]
  In addition, the thickness of the member that holds the turntable is reduced as much as possible, and the overall height of the turntable unit is brought close to the height of only the turntable, so that the overall rise amount of the turntable unit is suppressed, and the drive base It is possible to reduce the height of the turntable unit housing portion and to reduce the size and thickness of the apparatus.
(Claim 4)
  The metal plate of the turntable unit is characterized in that the slide part is integrally formed by a press technique.
[0038]
  Therefore, the apparatus thickness direction can be reduced as much as possible without requiring a complicated holding member for holding the slide portion, and the size and weight can be reduced. In addition, it is possible to reduce the driving torque of the load / unload mechanism (drive torque of the eject motor) by reducing the amount of lift of the turntable unit and reducing the weight of the members held by the turntable unit as much as possible. become. Furthermore, a complicated shape can be simply formed by using a press technique, and the number of parts and man-hours can be reduced to reduce the cost.
(Claim 5)
  At least a flexible printed wiring sheet for guiding a signal line for rotationally driving the turntable is mounted on the metal plate.
(Claim 6)
  The flexible printed wiring sheet is provided with a sensor for detecting write protection set in the optical disk cartridge or a cartridge-in sensor for detecting insertion of the optical disk cartridge.
(Claim 7)
Further, the drive base has a second opening at a position facing the optical storage medium, and a lens carriage on which a lens for condensing a light beam on the optical storage medium is disposed in the second opening, and the cartridge A fixed optical component for guiding the light beam to the lens carriage and a fixed optical component for guiding the reflected light from the optical storage medium to the photodetector are directly fixed on the drive base behind the holder mounting portion. It is characterized by becoming.
[0039]
Therefore, by reducing the thickness of the members held by the turntable unit as much as possible and bringing the overall height of the turntable unit close to the height of the turntable alone, the overall amount of the turntable unit can be suppressed, and the drive The base turntable unit housing can be thinned, and the apparatus can be thinned. In addition, it is possible to reduce the driving torque of the load / unload mechanism (drive torque of the eject motor) by reducing the amount of lift of the turntable unit and reducing the weight of the members held by the turntable unit as much as possible. become.
[0040]
It is provided on the load plate and rotates in conjunction with the load / unload mechanism. When the cartridge is not inserted, the lens carriage for mounting the objective lens is locked so as not to move, and the cartridge is inserted. In this case, the lens carriage further includes a lock mechanism for releasing the lock.
[0041]
Therefore, when the cartridge is not inserted, that is, when the apparatus is not used, it is possible to prevent the lens carriage from moving due to gravity or an artificial influence, and to improve the durability and reliability of the apparatus.
[0042]
An optical storage device includes a drive base on which at least one mechanism for accessing an optical storage medium is disposed, and a cover that covers at least one surface of the drive base. It is characterized by comprising a bent part bent so as to cover the periphery.
[0043]
Therefore, by making the outer periphery of the apparatus have a substantially labyrinth structure, it is possible to prevent the inflow of dust into the apparatus and improve the durability and reliability of the apparatus. Moreover, even if a thin cover is used, the strength can be ensured by the bent portion, so that the durability can be improved.
[0044]
In an optical storage device, a cartridge holder in which a cartridge for storing an optical storage medium is inserted, a drive base on which at least the cartridge holder is mounted, and a circuit component for accessing the optical storage medium are mounted on the drive. And a printed circuit board that covers the base via a cartridge holder, the printed circuit board being arranged with a tall circuit component facing the outside of the cartridge holder.
[0045]
Therefore, since the height of the cartridge housing portion is used so that tall parts of the printed circuit board are not disposed at positions facing the cartridge housing portion, the lower side of the drive base is set to the thickness of the cartridge. It is possible to reduce the thickness of the device without stopping.
[0046]
The printed circuit board is characterized in that circuit components are mounted on one side, and the mounting surface side is arranged to face the drive base.
[0047]
Therefore, the surface of the printed circuit board can be flattened, and the optical storage device can be smoothly incorporated in the host system.
[0048]
The printed circuit board is mounted with an E-IDE interface connector.
[0049]
Therefore, the connectivity of the host system interface to the connector can be improved, and it is possible to easily connect to the host system by adding a simple conversion function to the exterior case.
[0050]
An optical storage device includes a cartridge holder into which a cartridge that stores an optical storage medium is inserted, and a discharge mechanism that is provided in the cartridge holder and discharges the cartridge to the outside of the device. At least a roller portion that engages and a spring portion that urges the roller portion in the cartridge discharge direction are provided, and the roller portion includes a metal rotating shaft and a rotating portion made of a slidable material. And
[0051]
Accordingly, it is possible to prevent the roller portion from being broken due to erroneous insertion of the cartridge, and to improve the durability and reliability of the device without significantly changing the weight or structure of the device.
[0052]
In an optical storage device, a mechanism for accessing a 3.5-inch optical storage medium contained in a cartridge is disposed on the upper and lower surfaces, and a drive base is disposed on the lower surface of the drive base, and the cartridge is inserted. And a turntable for rotating the optical storage medium to the cartridge holder side through the cartridge holder and the first opening formed in the drive base facing the cartridge holder, A turntable unit that holds a turntable, a moving optical unit that holds an objective lens and moves the objective lens within a second opening of the drive base formed in the radial direction of the optical storage medium, and a cartridge are accommodated Light-emitting element that emits light to the first mounting portion of the drive base outside the portion , A photodetector for detecting return light from the optical storage medium, an optical component for guiding the light, and a surface of the first mounting portion, wherein at least a part of the optical component is brought into contact with the optical component. A fixed optical unit having at least a block for obtaining positional accuracy, and an eject motor that is disposed on the second mounting portion of the drive base outside the portion in which the cartridge is accommodated and that drives to eject the cartridge And a cover that covers one side of the drive base and a printed circuit board that covers the other side of the drive base and on which circuit components for accessing the optical storage medium are mounted. The height from the uppermost surface to the lowermost surface when the cover and the printed circuit board are fitted to the base is the storage height of the unit of 17 mm height of the host system. Characterized in that it made be made by.
[0053]
Accordingly, by configuring as described above, the drive base mounting parts can be simplified, reduced in size, reduced in thickness, and reduced in weight, and the drive base itself can be reduced in thickness and weight, and the optical storage device can be realized. It is an optical storage device that can reduce the overall weight, make the entire device thinner and lighter, and process cartridge-type optical storage media such as ISO standard 3.5-inch magneto-optical disk cartridges. However, it can be stored in a slot such as a 17 mm-high floppy disk unit of the host system, and can be carried in an ultra-thin portable PC.
[0054]
A case that covers the outermost peripheral portion of the drive base in a state where the cover and the printed board are fitted, and a first that is connected to the interface connector at a position inside the case that faces the interface connector provided on the printed board. A connector, a conversion circuit that converts information of the interface connector transmitted from the first connector into information for other interfaces, and an information provided from the conversion circuit are transmitted to the outside so as to be exposed to the outside of the case. And a second connector.
[0055]
Accordingly, by simply connecting an optical storage device having only one type of interface connector to a case corresponding to the interface of the host system, connection to a large number of host systems can be facilitated, and one optical storage device is provided. It becomes possible to improve the versatility of.
[0056]
The interface connector is for an E-IDE interface.
[0057]
Therefore, it is possible to easily connect to a large number of host systems, and the versatility of one optical storage device can be improved.
[0058]
The other interface is a SCSI interface or a PCMCIA interface.
[0059]
Therefore, the selection range of the host system can be expanded according to the use of the optical storage device, and versatility can be improved. In addition, it is possible to connect to an upper system for SCSI or PCMCIA, and it is possible to easily connect to an upper system having a high penetration rate.
[0060]
In an optical storage device, a front bezel having a door into which a cartridge containing an optical storage medium is inserted and ejected, a cartridge holder for storing a cartridge inserted from the door, and an optical storage medium are driven to rotate. A turntable having a slide portion, a turntable unit for holding the turntable, and a load plate having a guide having an inclined surface, and the slide portion is inclined by sliding the load plate. A load / unload mechanism that raises / lowers the turntable by sliding and a front bezel is mounted on the side surface, a cartridge holder is mounted on the lower surface side, and the slide portion and the guide are engaged on the upper surface side of the cartridge holder. A turntable unit and load / unload mechanism are installed. Drive base, a standing wall piece provided on the load plate, a manual eject hole provided in the front bezel or the drive base at a position facing the standing wall piece, and a covering cover that covers the manual eject hole so as to be freely opened and closed. It is characterized by.
[0061]
Therefore, by reducing the inflow of air into the apparatus as much as possible, the inflow of dust and the like can be prevented and the reliability of the apparatus (data recording / reproduction reliability) can be improved.
[0062]
The covering cover is characterized by comprising a sealing member having a radial slit at the center.
[0063]
Therefore, it is possible to mount the apparatus without projecting in the height direction or the width direction of the apparatus by simple processing while ensuring the reliability described above.
[0064]
The covering cover includes a rubber that closes the manual eject hole and a spring member that holds the rubber and is biased toward the manual eject hole.
[0065]
Therefore, it is possible to secure the strength of the covering cover with a simple structure, and even if manual insertion of the manual eject pin is repeated, it is possible to cover the manual eject hole more reliably, and the sealing performance of the device. It becomes possible to improve. Therefore, it becomes possible to improve the reliability and durability of the apparatus.
[0066]
DETAILED DESCRIPTION OF THE INVENTION
[Appearance of the device]
FIG. 1 is a front side external perspective view of an optical storage device according to an embodiment of the present invention, and FIG. 2 is a rear side external perspective view of FIG. As a specific example, a magneto-optical disk device for a 3.5-inch magneto-optical disk cartridge is shown.
[0067]
A front bezel 10 is attached in front of the optical storage device. The door 10b is rotatably attached as the optical disk cartridge is inserted or ejected, and is biased by a spring (not shown) in the direction in which the door is closed.
[0068]
The eject button 10a instructs to eject the optical disk cartridge and performs auto eject. The manual eject hole 10d is for inserting a pin or the like when the power is cut off or inspected or at the time of failure. When the pin or the like is inserted into the manual eject hole 10d, the optical disc cartridge is disengaged in the apparatus. Thus, the medium is discharged. The LED 10c indicates the operation state of the apparatus by light emission.
[0069]
The drive base 20 has a shape in which the front bezel 10 is fitted to the front of the apparatus, various ICs are mounted and various FPCs are connected, a frame 12 for adjusting the outer shape, and a peripheral portion is narrowed. A cover 13 made of a magnetic material is provided so as to cover the outer periphery thereof.
[0070]
The printed circuit board 11 is connected to the drive base 20 by screws 11a. Further, the cover 13 is formed by screws 14a, 14c, 14f, and 14h, in which the hole 13a of the cover 13, the anti-vibration rubbers 14b, 14d, 14e, and 14g, the frame 12, and a part of the drive base 20 are recessed. It is fastened through the hole 13a ′ of the attachment portion.
[0071]
In the present embodiment, the height of the 3.5-inch optical disk apparatus is determined by the height H of the housing in which the drive base 20 is fitted with the printed board 11 and the cover 13 and the height h of the front bezel 10. Here, the height of the front bezel 10 and the casing are made to be substantially the same plane, and each is set to about 17 mm. However, since the front bezel 10 and the frame 12 can be provided according to a user's request, it is not always necessary to provide them.
[0072]
Therefore, by setting the total height of the optical disk device to about 17 mm, it can be inserted into the space of a floppy disk device unit such as a personal computer and used as an alternative memory of the floppy disk device.
[0073]
In the following, a technique for reducing the size and weight of the optical disk device to about 17 mm will be described.
[0074]
FIG. 3 is an exploded view of the optical storage device shown in FIGS. 1 and 2, and FIG. 4 is a view showing the back side of FIG.
[0075]
In FIG. 3, the magneto-optical disk device is roughly configured by arranging seven main components in order, a printed circuit board 11, a cartridge holder 71, a drive base 20, a lens carriage 30, a load plate 24, a turntable unit 222, and a cover 13. Is done.
(Cartridge holder)
The drive base 20 has a housing portion 20 h for the cartridge holder 71 so that most of the surface of the cartridge holder 71 does not protrude from the end face in the thickness direction of the drive base 20. In addition, since the mounting portion 71b ′ having a screw hole of the drive base 20 to which the mounting portion 71b of the cartridge holder 71 is screwed is provided by denting a part of the drive base 20, the thickness of the drive base 20 is reduced. The attachment portion does not protrude from the end face in the direction.
[0076]
Therefore, the space from the mounting portion 71b ′ of the drive base 20 to the end surface of the drive base 20 is used to secure a space for mounting a circuit component of the printed circuit board 11 on the lowermost surface of the drive base 20, which will be described later, on one side. Yes.
[Drive base cover]
In FIG. 4, the drive base 20 is formed with openings 20a to 20f for mounting predetermined components. Also, the drive base 20 has a fixed optical unit 40 in which an optical component for guiding the light beam to the surface of the optical disk and for guiding the reflected light from the optical disk to the photodetector is integrally formed by aluminum die casting. Is formed. (In FIG. 4, the lenses and the like in the fixed optical unit 40 are omitted for simplification.) Then, a cover 40 a for dust prevention and light shielding is placed on the fixed optical unit 40.
[0077]
Further, by providing the cover 13 made of a ferromagnetic material such as stainless steel, magnetic flux leakage due to the thinning is prevented. In addition, when constructed systematically, there is no effect when a floppy disk device unit or a hard disk device unit that is weak against external magnetic flux and easily falls into a read / write failure is used in the vertical direction.
[0078]
Further, in the past, packing was provided on the inner edge of the cover as a countermeasure against dust, but in this embodiment, the cover 13 having the bent portion 13b that is bent and drawn over the entire circumference can be used. The labyrinth structure is formed so as to cover the outer peripheral edge, so that the inflow of air is blocked to prevent dust from entering the apparatus, and the strength of the cover 13 is improved.
[0079]
Further, since the attachment portion for attaching the cover 13 is formed by recessing a part of the drive base 20, the screw of the attachment portion does not protrude from the uppermost surface of the cover 13 (the uppermost surface of the device). , Enabling thinning.
[Lens carriage]
The lens carriage 30 for holding the objective lens L and moving it in the radial direction of the optical disk is integrally molded with a material such as a heat-melting resin in a state where the coil is embedded in the coil portion 32 at the end thereof. Yes. Then, a magnet is attached to the back side of the upper yoke, and the lower yoke is passed through the central openings of the coil portions 32a and 32b so that the coil portion 32 can move. Then, the end portions of the upper yoke and the lower yoke are screwed, and the magnetic circuit 33a and 33b are formed.
[Turntable unit]
The turntable unit 222 is mounted on a sheet metal 21 made of an insulating galvanized steel sheet or the like, and has slide pins 23 a and 23 b on both the left and right sides of the sheet metal 21. The turntable 22 having a diameter of 21 mm protrudes from the opening 20a of the drive base 20 toward the cartridge holder 71 side.
[0080]
Accordingly, when the optical disk cartridge is inserted into the cartridge holder 71, the optical disk hub is attracted by the magnetic body provided on the surface of the turntable 22 so that the optical disk can be held.
[0081]
The turntable 22 is connected to a spindle motor that rotates at a predetermined rotational speed.
[Eject motor]
Furthermore, an eject motor (R2DG-84 made by OMRON) 50 for ejecting the optical disk cartridge is accommodated in the eject motor housing portion 55 of the drive base 20, and the screw hole 50a of the eject motor and the screw hole 55a of the drive base 20 are connected to each other. Via a screw (not shown).
[0082]
In addition, in order to obtain the height of the predetermined dimension of the eject motor accommodating part 55, the height of the drive base 20 is needed more, Therefore The space part 20i behind the cartridge holder accommodating part 20h of the drive base 20 is utilized. The eject motor accommodating portion 55 is formed so as to protrude toward the space portion 20i. Therefore, there is no need to change the thickness of the drive base 20 and a height space (about 10.7 mm at the highest part) for accommodating the eject motor 50 within the height range of the drive base 20 (about 15.8 mm) is provided. It becomes possible to ensure, and the thickness can be reduced.
[Load board]
The load plate 24 that slides rearward of the apparatus by driving the eject motor 50 described above when ejecting the optical disk cartridge is disposed below the sheet metal 21 of the turn table 22 described above with reference to FIG. When the load plate 24 slides to the rear of the apparatus, the slide pins 23a and 23b of the metal plate 21 slide the guide 85 of the load plate 24 to raise the metal plate 21 and to raise the turntable 22a through the opening 20a. Is released and the optical disk cartridge is unloaded.
[0083]
Note that the mounting height of the load plate 24 determined by the height of the guide 85 is set to be substantially the same as the height of the turntable unit housing portion of the drive base 20, and from the uppermost end surface of the drive base 20. It does not protrude.
[0084]
Similarly, other components arranged on the drive base 20 on the side covered with the cover 13 are set so that the component height and the mounting height do not protrude from the uppermost end surface of the drive base 20. Needless to say.
[0085]
The loading / unloading of the turntable will be described later.
〔Printed board〕
FIG. 5 shows an enlarged view of the printed circuit board. A power connector 98 and an interface connector 99 are attached to the printed circuit board 11, and circuit components such as a DSP and an MPU for controlling reproduction, recording, and erasing of information on the optical disk are mounted on one side. The cartridge holder 71 is mounted on the mounting surface side of the printed circuit board 11 so as to face the mounting surface.
[0086]
Also, a short component (an IC component such as a DSP or MPU) is mounted on the cartridge holder facing part A so that the printed circuit board 11 on the side where the component is mounted is opposed to the cartridge holder 71 through a dustproof film (not shown). In addition, tall components (capacitors, connectors 98, 99, etc.) are mounted on the space 20i facing portion B so as to face the space 20i of the drive base 20, and a plurality of printed circuit boards 11 are arranged via the cartridge holder 71. The holes 11a and the drive base 20 are overlapped and connected by screws.
[0087]
Therefore, by considering the arrangement of circuit components on the printed circuit board 11 in accordance with the shapes of the drive base 20 and the cartridge holder 71, the thickness (height) of the drive base 20 is further reduced, and the overall height of the apparatus is increased. It becomes possible to make it smaller.
[0088]
The screw used in this embodiment is a screw head having a thickness of 0.3 mm or less, or a screw head having a thickness of 0.5 mm, and having a squeegee fitted to a hole in the printed circuit board 11 to reduce the thickness. I am trying.
[0089]
In addition, by soldering a washer to the mounting surface of the printed circuit board 11 on which the circuit component is mounted on one side and screwing it through the washer, the thickness of the screw head is within the thickness of the printed circuit board 11. By sinking, the surface of the printed circuit board 11 is flattened to reduce the thickness of the apparatus.
[0090]
As described above, after mounting the above-described components on the drive base 20, the frame 12 is fitted so as to cover the peripheral edge of the drive base 20, and the cover 13 formed by pressing a ferromagnetic material such as stainless steel is the printed board 11. Are screwed to the drive base 20 on the opposite side to complete the optical storage unit.
[0091]
FIG. 6 is a configuration diagram of the main part on the back side.
[FPC of optical system]
A flexible printed wiring sheet (FPC) 91 in which circuit components such as a plug-in connector 92 connected to the plug-in connector 92 ′ of the printed circuit board 11, a photodetector 52, and a head IC are mounted in the space 20i of the drive base 20 is provided. The drive base 20 is provided with a plurality of screws such as 91c and 91d.
[Lens carriage]
Mounted on the lens carriage 30 is an objective lens L and a lens actuator 60 having a magnetic circuit for driving the objective lens L. A flexible printed wiring sheet 39a that guides a signal for driving the lens actuator 60 in the focus direction or the track direction is adhered along the coil portion 32a of the lens carriage 32 with an adhesive. Further, a carriage cover 115 made of a ferromagnetic material such as stainless steel is attached around the objective lens L of the lens actuator 60.
[0092]
Subsequently, a voice coil motor (VCM) that moves the lens carriage 30 in the radial direction of the optical disk is provided on both sides of the lens carriage 30, and the voice coil motor (VCM) includes coil portions 32 a and 32 b of the lens carriage 30, and It is comprised by the magnetic circuit 33a and 33b which consists of a yoke and a magnet.
[0093]
Further, guide rails 113a and 113b that engage with bearings 31a to 31c provided on both sides of the lens carriage 30 and facilitate the movement of the lens carriage 30 are fixed while being preloaded by the leaf springs 112a, 112b, and 114, respectively. Has been.
[0094]
That is, the leaf springs 112a and 112b act as a fixing side that fixes the guide rail 113b by pressing against the engaging walls of the drive base 20 around both ends of the guide rail 113b, and the leaf spring 114 causes the guide rail 113a to be fixed to the guide rail. It acts as a preload side for applying a preload so as to be pressed toward the 113b side (perpendicular to the longitudinal direction of the guide rail). Further, the guide rails 113a and 113b and the bearings 31a to 31c have V-shaped contacts, and function to always maintain an engagement relationship with no gap.
[0095]
The carriage stoppers S1 to S3 are provided by being bonded to the drive base 20 facing both ends of the lens carriage 30 in the moving direction, and have a buffering action to alleviate the impact when the lens carriage 30 hits the drive base 20. And has a rubber material. The carriage stopper S3 is provided in close contact with the beam reflector prism 44, and closes the protective function of the beam reflector prism 44 and the gap formed between the window 41b and the beam reflector prism 44, thereby fixing optically. A sealing function for preventing dust from flowing into the unit 40 is provided.
[0096]
In FIG. 6, the carriage lock 26 provided on the load plate 24 protrudes toward the lens carriage 30, so that it is rotated from the home position so that the lens carriage 30 prevents the optical disk from moving in the radial direction. The state of doing is shown.
〔Turntable〕
A turntable unit 222 is provided on the upper surface side of the cartridge holder in which the cartridge of the drive base 20 is accommodated so that the turntable 22 is provided through an opening 20a provided at a position facing the center of the optical disk. The turntable unit housing portion of the drive base 20 on the upper surface side of the cartridge holder is set to a height (about 6.0 mm) substantially the same as the thickness (about 5.8 mm) of the turntable unit 222.
[0097]
A protrusion 22a is provided at the center of the turntable 22 protruding from the opening 20a of the drive base 20, and is engaged with the center hole of the hub of the optical disk.
[0098]
A flexible printed wiring sheet (FPC) 89 is bonded on the sheet metal 21. On this flexible printed wiring sheet (FPC) 89, a sensor 86 for detecting the write enable set in the optical disk cartridge, a sensor 87 for detecting the write protection set in the optical disk cartridge, and an insertion of the optical disk cartridge are detected. A cartridge-in sensor 88 is attached.
[0099]
The 3.5 inch magneto-optical disk cartridge is standardized by ISO / IEC10090 at 128 MB and ISO / IEC13963 at 230 MB, and is already commercially available.
[0100]
An end portion of the flexible printed wiring sheet (FPC) 89 is connected to a connector provided on a flexible printed wiring sheet (FPC) 39 that transmits a signal for controlling movement of the lens carriage 30 and the lens actuator 60. The flexible printed wiring sheet (FPC) 39 is bent around the side surface of the drive base 20 and is connected to a connector provided on the printed circuit board 11.
[0101]
Subsequently, a load plate 24 is disposed below the sheet metal 21, that is, between the drive base 20 and the sheet metal 21. When the load plate 24 moves in the front-rear direction (± Y direction) of the apparatus, the engagement pins 29 a to 29 c provided on the drive base 20 move in the plurality of grooves 24 a to 24 c provided on the load plate 24. Further, after the load plate 24 is moved rearward (+ Y direction) in response to the eject instruction and the engagement with the optical disc cartridge is released, one end is connected to the load plate 24 and the other end is connected to the engagement pins 29a and 29b. Due to the elastic force of the springs 28a and 28b, the load plate 24 moves forward (−Y direction) so as to return to the original position as soon as possible.
[0102]
The above-described eject instruction may be performed by pressing an eject button 10a provided on the front bezel 10 or by pressing a pin or the like strongly into the manual eject hole 10d. In the former case, the eject motor 50 is driven by pushing the eject button 10a, and the load plate moves to the rear of the apparatus by pulling the end 24d of the load plate 24. In the latter case, the manual eject hole 10d. When the pin P is strongly pushed into, the pin P hits the standing wall portion 10f of the load plate 24, and the load plate 24 is pushed and moved rearward of the apparatus.
[Manual eject hole]
As described above, the manual eject hole 10d is an opening provided in the front bezel 10 so that the pin P can be inserted. Similarly, the drive base 20 facing the manual eject hole 10d is provided with an opening 10d '. Accordingly, the pin P inserted from the manual eject hole 10d is formed so as to press the standing wall portion 10f of the load plate 24 through the opening space of the opening 10d '.
[0103]
However, the manual eject hole 10d and the opening 10d 'serve as an air passage, and dust from the outside may flow into the drive base 20 due to an air pressure difference when the disk rotates.
[0104]
Therefore, in the present embodiment, the cover cover 10e for sealing is provided in the manual eject hole 10d and the opening 10d '. Of course, if a covering cover is provided in both the manual eject hole 10d and the opening 10d ', the effect of preventing dust inflow is improved. However, depending on the shape of the drive base and the specifications of the front bezel, only one cover may be provided, but a sufficient sealing effect can be obtained as compared with the case without the cover.
[0105]
7A to 7C and FIGS. 8A to 8B show specific configuration examples of the covering cover 10e. In FIG. 7A, the covering cover 10e is made of a circular thin resin sheet, and is composed of a sealing member 10h in which an adhesive for adhesion is applied to the outer peripheral portion, and the central portion is divided into eight portions in a cake cut shape. The state of being cut is shown.
[0106]
7B and 7C show a state in which the pin P is inserted into the manual ejection hole 10d or the opening 10d ′ of the drive base 20, and eight sections cut into eight equal parts. 10i is pushed up to open the center, allowing the pin P to enter the front bezel 10 or the drive base 20.
[0107]
The seal member 10h may be made of a material having rubber or sponge characteristics, or a material such as an aluminum stay, in addition to resin, and a double-sided tape may be used for adhesion. Further, the shape of the sealing member 10h may be not a circle or a polygon as long as the hole can be covered, and the cutting method of the central portion is also a shape that allows the pin P to be inserted easily and easily. Any structure that can be easily closed when the pin P is removed.
[0108]
In FIG. 8A, a covering cover 10d is a plate for adhering and fixing the cover portion 10k and the cover portion 10k made of rubber for closing a hole (manual eject hole 10d or opening 10d ') and pressing the cover portion 10k against the hole side. It is comprised by the spring part 10j. The leaf spring portion 10j is fixed to the inside of the front bezel 10 or the inside of the drive base 20 with an adhesive, or a claw is provided on the leaf spring portion 10j, and the claw is fitted into a hole provided inside the front bezel 10 or inside the drive base 20. Fix by inserting.
[0109]
As shown in FIG. 8B, when the pin P is not inserted, the hole is covered with the cover portion 10k by the spring action of the leaf spring portion 10j to improve the sealing performance, and the pin P is inserted. Then, the leaf spring portion 10j is pushed and warped by the pressing force, and the pin P is allowed to enter.
[0110]
The cover portion 10k can be made of a resin or sponge material in addition to rubber to improve the close contact with the hole. The leaf spring portion 10j is not only a metal spring material but also a thin Mylar film or the like. It is also possible to reduce the weight by using a simple structure using vinyl or plastic material.
[Fixed optics]
The fixed optical unit 40 forms a head base (having a height of about 6.4 mm) that is recessed below the receiving surface of the turntable unit on the outside of the cartridge holder receiving portion 20h behind the drive base 20, The optical components described in detail below are directly disposed on the surface of the substrate.
[0111]
FIG. 9 is an enlarged view of the fixed optical unit 40. As shown in FIG. 9A, a block 41 is provided on the drive base 20, and a plurality of screw holes 41a and a plurality of positioning projections 41b are provided on the top surface thereof. 6 is configured to extend to the M lens 46 and S lens 47 side, and the collimator lens 43, the M lens 46, and the S lens 47 are elastically formed on the wall surface of the lower surface and the surface of the block 41. It engages with the protrusion 41b and is screwed through the screw hole 41a so as to be pressed and fixed by force.
[0112]
Further, a light detector 52 for detecting a reproduction data signal of the optical disk and a light detector 53 for detecting a focus servo signal and a track servo signal are driven from the return light guided from the lens carriage 30 as a moving optical unit. The base 20 is fitted in the accommodating portions 49a and 49b.
[0113]
FIG. 9B is an enlarged view of the head base on which the optical component shown in FIG. 4 is not mounted.
[0114]
As described above, the head base is formed by recessing the drive base 20 downward. And the block 411, 412-420 similar to the block 41 mentioned above is formed in the wall surface which an optical component contacts with specially high surface precision.
[0115]
That is, the collimator lens 43 contacts the block 411 on the bottom surface and performs positioning in the height direction, and contacts the block 412 on the standing wall surface and performs positioning in the front-rear direction, and is pressed against the wall surface of each block by the plate spring 111 described above. Fixed. Further, the M lens 46 comes into contact with the block 415 of the standing wall piece, performs positioning in the left-right direction, contacts with the block 416 ′ on the bottom surface, performs positioning in the height direction, and is slightly higher than the block 416 ′. Positioned in the front-rear direction by being sandwiched between the blocks 416 and pressed, they are pressed against the wall surface of each block by the plate spring 111 described above. Further, the S lens 47 comes into contact with a block (not shown) and is pressed and fixed to the wall surface of the block by the plate spring 111 described above.
[0116]
The beam reflector prism 44 is in contact with the standing wall block 413 and positioned in the left-right direction, is in contact with the bottom block 414 to determine the position in the height direction, and the block 410 is positioned in the front-rear direction.
[0117]
Further, a servo unit 48 to be described later is fixed with an end portion sandwiched in a gap formed between the blocks 417 and 418 of the standing wall piece.
[0118]
Accordingly, each optical component is directly arranged without being required to increase the overall surface accuracy of the drive base 20 by being pressed and brought into contact with the blocks 411 to 420 formed with high surface accuracy to be positioned and fixed. It becomes possible.
[0119]
Accordingly, the head base can be formed directly on the drive base 20, and the overall height of the apparatus can be reduced. In addition, a separate known head base is unnecessary, and the weight can be reduced.
[0120]
An optical system constituting the main part of the magneto-optical disk apparatus will be described. FIG. 10 is a diagram showing the arrangement of optical components arranged on the fixed optical unit. FIG. 11 is an explanatory diagram of the optical path of the light beam in the fixed optical unit 40.
[0121]
The fixed optical unit 40 is formed in a predetermined shape with high accuracy so that optical components can be arranged on the drive base 20. A light beam having a predetermined light emission power is emitted from a laser diode unit (LD unit) 42.
[0122]
In particular, the laser diode unit (LD unit) 42 is launched from a direction perpendicular to the seek direction of the lens carriage 30 and is refracted by a 45 ° raising mirror and guided to the raising mirror M in the lens carriage 30. Minimizing the optical path contributes to shortening the dimension in the apparatus depth direction.
[0123]
The emitted light beam passes through the collimator lens 43, then passes through the beam reflector prism (BR prism) 44, is guided from the window 41b to the objective lens L of the lens actuator 60 (not shown), and is focused by the objective lens L. A beam is irradiated onto the optical disc.
[0124]
Thereafter, the return light reflected from the optical disk D is guided to the window 41b through the objective lens L, and is guided to the beam splitter and wobbling prism (BW prism) 45 through the beam reflector prism (BR prism) 44. The optical signal is split into a reproduction signal, a focus signal, and a track signal. The reproduction signal (address signal and magneto-optical signal) is guided through the M lens 46 to the photodetector 52 disposed in the housing portion 49b of the drive base 20 through the slit 52S. Further, the focus signal and the track signal are guided from the beam splitter and wombling prism (BW prism) 45 to the L lens 47, and subsequently, a plurality of signal components β by the servo unit 48.₁~ Β_FourAnd is guided to the photodetector 53 disposed in the accommodating portion 49a through the slit 53S. Then, the photodetector 53 has a signal component β₁~ Β_FourFrom this, a focus signal FES and a track signal TES are generated.
[Servo unit]
12A and 12B show the structure of the compound lens of the servo unit 48. FIG. The servo unit 48 has an exit surface whose first light β out of the return light flux.₁The first emission surface 48a that emits light is formed with a right slope in the figure, and the second light β₂The second emission surface 48b that emits light is formed with a left slope in the drawing. Also, the third and fourth light β_Three, Β_FourThe third and fourth emission surfaces 48c and 48d that emit light are formed in a mountain shape.
[0125]
The first emission surface 48a is inclined in the same direction as the third emission surface 48c, and the inclination angle α₁Is the inclined surface α of the third exit surface 48c._ThreeSmaller than.
[0126]
The second emission surface 48b is inclined in the same direction as the fourth emission surface 48d, and the inclination angle α₂Is the inclination angle α of the fourth exit surface 48d._FourSmaller than.
[0127]
FIG. 12C is a diagram illustrating the photodetector 53. The return light from the optical disk D guided to the L lens 47 is transmitted by the servo unit 48 through the first to fourth lights β.₁~ Β_FourAnd is received by the photodetector 53. The photodetector 53 includes first and second light β₁ , Β₂ The first light receiving portion 53a divided into four (A to D) for receiving the light and the third light β_ThreeA second light receiving portion 53b for receiving light and a fourth light β_FourAre formed on one plane (may be separated from each other).
[0128]
Specifically, the first light β emitted from the first emission surface 48a out of the return light beam.₁Is received by the A and D regions of the first light receiving portion 53a of the photodetector 53. The second light β emitted from the second emission surface 48b₂Is received by the B and C regions of the first light receiving portion 53a. Thus, the calculation of (A + C)-(B + D) is performed by the Foucault method, and the focus error signal is detected.
[0129]
Of the return light beam, the third light β3 emitted from the third emission surface 48c is received by the second light receiving portion 53b (E region) of the photodetector, and the fourth emission surface 48d. The fourth light β emitted by_FourIs received by the third light receiving portion 53c (F region). Thereby, the calculation of (EF) is performed by the push-pull method, and the tracking error signal is detected.
[0130]
As described above, even if the Foucault method is used for focus detection and the push-pull method is used for tracking error signal detection, there is no need to divide the optical path into two, so the optical path is shortened and the volume of the entire fixed optical system is reduced. And the number of parts can be reduced.
[0131]
The specific details of the servo unit 48 are described in Japanese Patent Laid-Open No. 5-250704, etc., and are well known.
[Prism manufacturing method]
Next, the above-described BR prism and BW prism need to be miniaturized when mounted on an ultra-small optical disk apparatus having a total height of about 17 mm as in this embodiment. Taking a cube prism as an example, for example, if the width W x length L x height H is reduced from 6 x 6 x 6 mm to 5 x 5 x 5 mm, The tolerance needs to be changed from ± 0.1 mm to tolerance ± 0.08 mm so that the prism angle deviation due to accuracy is equal (tolerance / dimension = 0.1 / 6≈0.8 / 5).
[0132]
However, if the prism is reduced in size from the 6 mm type to the 5 mm type as described above, the tolerance is reduced and a considerably high mounting accuracy is required. In contrast, in this embodiment, a method for manufacturing a small prism without reducing the tolerance will be described.
[0133]
FIGS. 13A to 13C are explanatory views of a method of manufacturing a beam reflector prism (BR prism). Two long prisms 101a and 101b in the shape of a triangular prism having the same quadrangle on the opposing surface are prepared. A vapor deposition film 103a is formed on a predetermined surface of one prism 101a. The vapor deposition film 103a is opposed to a predetermined surface of the other prism 101b so that the ends of the two prisms 101a and 101b are aligned. Glue. Further, the LN Wollaston prism 101c is bonded to a predetermined surface of the prism 101b.
[0134]
The width W created in this way₁× Length L₁A prismatic prism 101d having a predetermined cutting length H₁And a predetermined number of BR prisms 101e are created.
[0135]
Similarly, a method of manufacturing a beam splitter and wombling prism (BW prism) will be described with reference to FIGS.
[0136]
A prismatic prism 102a and a prismatic prism 102b are prepared which have a quadrangle on the opposing surface. One prism 102a has a vapor deposition film 103b formed on a predetermined surface. The vapor deposition film 103b is opposed to a predetermined surface of the other prism 102b, and the ends of the two prisms 102a and 102b are aligned and bonded. To do. Further, the prism 102f is bonded to the lower surface of the prismatic prism 102b. The width W created in this way₂× Length L₂Prism 102c with a predetermined cutting length H₂Then, a predetermined number of BW rhythms 102d are created.
[0137]
The BR prism and the BW prism produced as described above have their cutting lengths H₁And cutting length H₂Are arranged as shown in FIG. 9 and FIG. 10 so as to be the length in the height (thickness) direction (Z direction) of the optical disc apparatus. That is, the length H that is likely to cause an error due to cutting.₁And length H₂By bringing the surface with a position that does not affect the mounting accuracy, that is, in the height direction, the height can be reduced, and the mounting accuracy can be improved without changing the width and depth dimensions. It is possible.
[0138]
Further, if the light beam diameter ΦD of the light beam emitted from the LD unit 42 is ΦD / H> 1.0, for example, if the height H of the prism is 5 mm, the light beam diameter ΦD is set to 0.2 mm so that the light beam is sufficiently small. Light is prevented from protruding from the surface of the prism in the height direction. Therefore, even if the prism is miniaturized, it is possible to maintain the minimum necessary accuracy.
[0139]
Needless to say, the present invention can be similarly applied to other prisms than those shown in this embodiment.
[0140]
Therefore, by using the prism manufactured in this way, sufficient mounting accuracy can be obtained even if the surface with poor surface accuracy such as the drive base formed by aluminum die casting shown in this embodiment is used as the surface of the head base. And can be directly mounted on the drive base without using a separate head base.
[Objective lens]
FIG. 15A is an enlarged perspective view of the objective lens, and FIG. 15B is a cross-sectional view of the objective lens.
[0141]
The objective lens L is provided with a flat portion F having a flat surface in the shape of a collar of a hat on the outer peripheral edge of the lens. Then, the flat surface F is attached to the end surface of the lens mounting portion 62a of the lens actuator 60 while being adjusted so that the one end surface f 'of the flat portion F and the optical axis are perpendicular to each other.
[0142]
Therefore, even if the objective lens L becomes small, there is an effect that it can be mounted on the lens mounting portion 62a with high accuracy by a simple adjustment method.
[Lens carriage]
FIGS. 16A to 16C are enlarged views of the lens carriage, showing a method for adjusting the optical axis of the objective lens on the lens carriage.
[0143]
In the central part of the lens carriage 30, a condensing lens 29 that emits and emits a light beam with respect to the fixed optical unit 40, a rising mirror M that raises the light beam from the condensing lens 129 by 45 °, and an objective lens L A space for mounting a lens actuator 60 or the like for holding the lens is formed. Details of the lens actuator 60 will be described later with reference to FIG. Further, the bearings 31 a to 31 c and the coil portions 32 a and 32 b described above are provided on both sides of the lens carriage 30.
[0144]
Next, a method for adjusting the optical axis of the objective lens L will be described.
[0145]
When the lens actuator 60 is mounted on the lens carriage 30, a jig is applied to the reference grooves 121a to 121c by using an autocollimator or the like, a preload A is applied to a predetermined position, and the objective lens L is irradiated with light. Detect tilt. The lens actuator 60 is arranged so that the flat surface F of the objective lens L and the disc mounting surface 22b of the turntable 22 are substantially parallel, that is, the optical axis l of the objective lens L is substantially perpendicular to the surface of the optical disc. The screw 122b inserted into the central portion of the coil spring 122a is closed by the driver 152 with the coil spring 122a interposed between the screw mounting portions 61a and 61b of the lens carriage 30 and the bottom surface of the lens carriage 30.
[0146]
Therefore, the inclination of the objective lens L, that is, the inclination of the optical axis l is finely adjusted by the elastic pressure of the coil spring 122a. Therefore, since there are two attachment portions of the actuator 60, there is an effect that the objective lens can be finely adjusted in two directions, that is, two-dimensionally, with two screws.
[Actuator]
FIG. 17 is an enlarged view of the lens actuator. Then, a lens holding portion 621 made of a thermosetting resin or the like that holds the objective lens L so as to be movable in the track direction or the focus direction, and a focus coil 65 that is provided by being bonded to the wall portion of the central opening of the lens holding portion 621. The track coils 66a and 66b bonded to the surface of the focus coil 65 opposite to the above-described bonded portion constitutes a movable portion of the actuator 60.
[0147]
The two track coils 66a and 66b provided on the left and right sides of the focus coil 65 are wound in a direction substantially perpendicular to the winding surface of the focus coil 65, and the end thereof is the end surface of the yoke 63 of the magnetic circuit. It protrudes to the right and left. That is, by controlling the vertical portions of the track coils 66a and 66b outside the magnetic circuit, control is performed so as not to be affected by magnetic flux and to prevent mechanical oscillation.
[0148]
Furthermore, a magnet 64 provided on the actuator base 62 so as to face the track coil 65 in the central opening of the movable lens holding portion 621, and a yoke 61c formed of a bent portion of the actuator base 61 that receives the magnetic force of the magnet 64. A magnetic circuit of the actuator 60 is constituted by a yoke 61d formed of a bent portion provided to face the yoke 61c and a U-shaped cover yoke 63 connecting the two yokes.
[0149]
Further, the four wire portions 67a, 68a, 69a (one not shown) holding the movable portion of the actuator 60 and the holes are fitted into the protrusions 62a, 62b of the lens mounting portion 62a and bonded, and the objective Terminal plates 67c, 68c, 69c (one not shown) that hold the end of the wire portion on the lens side, and terminal plates 67d, 68d that are bonded to the wire holding portion 62c fitted to the end of the actuator base 61 69d (one not shown). And the damping member 67b, 68b, 69b, 70b (one is not shown) for absorbing the vibration of a wire part is provided.
[0150]
Note that the end of the FPC 39a extends on the wire holding portion 622 and is soldered to the four terminal boards on the wire holding portion 622. Also, four lead plates on the lens holding portion 621, two lead wires each of the focus coil 65 and the track coils 66a and 66b are soldered. In this way, conduction between the focus coil 65 and the track coils 66a and 66b and the FPC 39a is achieved. Therefore, since the electrical connection can be performed without drawing the thin lead wires of each coil, there is no fear of disconnection and the reliability can be improved.
[0151]
In addition, the terminal plates on both ends of the four wire portions and each wire portion are pressed with a plate spring material or a linear spring material from a mold (a U-shape) in which the two left and right wire portions are connected. Created by processing. Then, the two left and right wire portions are attached to the wire holding portion 622 in a connected state (U-shape), and then the connecting portion is cut. Therefore, by using the wire assembly created in this way, handling and management of small parts can be facilitated, and the assembly efficiency can be improved.
[0152]
As described above, the actuator base 61 is screwed to the lens carriage 30 via the mounting portions 61a and 61b of the bent pieces of the actuator base 61 in a state where all the parts of the actuator 60 described above are mounted.
[0153]
FIG. 18 is a diagram showing the positional relationship between the focus coil 65 and the track coils 66a and 66b in the magnetic circuit of the lens actuator.
[0154]
In the track coils 66a and 66b, only the inner coil portions 66c and 66d are used as the driving force, and the outer coil portions 66e and 66f are not involved.
[0155]
However, when the outer coil portions 66e and 66f are not sufficiently far from the gap magnetic flux of the magnetic circuit, they act in the direction opposite to the original driving direction, sometimes strong and sometimes weak as the lens actuator moves. . This is because the driving force is not constant, and a force in a direction different from the original driving direction is generated, so that the movement of the lens actuator moves in a posture deviating from the control direction, which makes control difficult. is there.
[0156]
On the other hand, in this embodiment, the outer coil portions 66e and 66f that are not involved in the driving force are arranged at positions sufficiently far from the gap magnetic flux, and thus the action of the actuator as described above is prevented.
(Wire assembly)
The wire portions 67a, 68a, 69a (not shown) are bonded in order from the upper layer, a damping plate made of Kapton, Mylar film, etc., a double-sided tape for attaching the damping plate, or a non-fully curable adhesive. Layer, wire, adhesive layer, and damping plate.
[0157]
Note that FIG. 19 is a comparison diagram according to the difference in the configuration of the wire portion. FIG. 19A shows a case where only a wire is provided without a damping member, and FIG. 19B shows a case where a damping member as in the above-described embodiment is provided. In the figure, the horizontal axis represents the frequency (Hz) of the current applied to the wire, and the vertical axis represents the gain (dB) with respect to the current (i), that is, the amount of vibration.
[0158]
Comparing FIG. 19A and FIG. 19B, in the case of only the wire of FIG. 19A, a sharp peak is formed at a certain frequency, that is, it vibrates. In the case of having the damping member (b), there is no sharp peak as shown in FIG. 19 (a), indicating that the vibration is damped.
[0159]
Therefore, even if shear deformation occurs in the wire portion, the vibration in the focus direction and the track direction of the wire portion can be absorbed by covering the periphery of the wire portion with the above-described damping member such as an adhesive layer or a damping plate. The vibration can be damped to about 1/10 or less than the case of only the wire.
[Vibration control member]
As described above, the damping member is provided in the vicinity of the wire holding portion 621 of the four wire portions. The damping member has a thin plate shape, and is composed of a damping plate made of aluminum stays, Kapton, Mylar film, etc., double-sided tape, non-fully curable adhesive, etc. The vibration damping plate is adhered by the adhesive layer. In this embodiment, the damping members 67b, 68b and 69b are provided. However, since it is the adhesive layer that actually plays a major role in absorbing vibration, only the soft viscous adhesive is used. However, a sufficient damping effect can be obtained.
[0160]
FIG. 20A shows a case where an epoxy-based thermosetting adhesive is used, and FIG. 20B shows a case where a silicon-based or ultraviolet curable adhesive such as an ultraviolet curable adhesive is used. Yes. In the figure, the frequency (Hz) of the current applied to the wire, and the vertical axis indicates the gain (dB) with respect to the current, that is, the amount of vibration.
[0161]
Comparing FIG. 20A and FIG. 20B, the thermosetting adhesive of FIG. 20A has a sharp peak at a certain frequency, that is, vibrates. In the case of the non-fully curable adhesive shown in FIG. 20B, there is no sharp peak as shown in FIG. 20A, indicating that the vibration is damped.
[0162]
Therefore, even when shear deformation occurs in the wire portion, the above-mentioned adhesive layer, damping plate, etc. are provided at a location where the deformation angle of the wire portion is particularly large when the lens actuator 60 is driven or the lens carriage is moved. By providing the vibration damping members 67b, 68b and 69b, it is possible to absorb the vibration in the focus direction and the track direction of the wire portion, and to absorb the vibration to about 1/10 or less than in the case of only the wire. Can be attenuated.
[0163]
Further, since the thin plate-like damping members 67b, 68b, 69b are provided so that the plate surface is in a direction parallel to the bottom surface of the lens carriage 30, the behavior thereof does not affect the adjacent wire portion. .
[0164]
By adopting the lens actuator as described above, the lens carriage can be made high performance and thin.
[Turntable unit]
FIG. 21 is an enlarged view of the turntable unit.
[0165]
The turntable 22 is made of a magnetic material that attracts the metal portion of the hub of the optical disc, and is important for obtaining surface accuracy by contacting the projection 22a that engages with the center hole of the hub of the optical disc and the hub of the optical disc. An outer edge portion 22b that plays a role is provided.
[0166]
In addition, the sheet metal 21 includes protrusions 21a to 21b that fit into the plurality of openings 20c to 20d of the drive base 20, openings 21c to 21d that fit to the plurality of protrusions 20e to 20f of the drive base 20, and a bent curve. In order to fit slide pins 23a, 23b each having a piece 81a, 81b and having a roller at the tip, all fitting pieces 23a ', 23b' cut into strips and bent in alternate directions It is molded at once by pressing technology and has a simple structure.
[0167]
A turntable 22 is rotatably provided on the sheet metal 21 and a flexible printed wiring sheet (FPC) 89 is bonded thereto. On this flexible printed wiring sheet (FPC) 89, a sensor 86 for detecting the write enable set in the optical disk cartridge, a sensor 87 for detecting the write protection set in the optical disk cartridge, and an insertion of the optical disk cartridge are detected. A cartridge-in sensor 88 is provided.
[0168]
Further, the flexible printed wiring sheet (FPC) 89 transmits the signal of the sensor and the drive signal to the turntable 22.
[0169]
Accordingly, the turntable unit has the above-described configuration, and all the drive circuits for driving the turntable 22 are mounted on the printed circuit board 11, so that the thickness of the sheet metal in the FPC mounted state is reduced. In addition, the number of parts on the upper drive base 20 of the cartridge holder 71 can be reduced, and downsizing in the apparatus height direction is possible. That is, the upper drive base 20 of the cartridge holder 71 may be either the height of the turntable 22 or the height of the guides 82a, 82b, 83a, 83b, whichever is higher.
[0170]
In this embodiment, the shape of the guides 82a, 82b, 83a, 83b and the shape of the curved pieces 81a, 81b are devised as shown in the figure, so that the amount of ascent of the turntable unit 222 can be suppressed, and the turntable unit The height of 222 and the height of the upper drive base 20 of the cartridge holder 71 can be made substantially the same.
[0171]
Therefore, the height of the upper drive base 20 (about 6.0 mm) of the cartridge holder 71 is set so that the height of the cartridge holder 71 determined by the thickness of the cartridge and the rising amount of the turntable unit 222 (when the turntable is Since it rises from the cartridge housing portion of the drive base 20 to the turntable unit housing portion through the opening 20a, the maximum rising amount at that time, that is, the amount determined by the sum of the mounting thickness of the turntable and the mounting thickness of the sheet metal (About 5.8 mm)), and a height of about 17 mm can be realized.
[0172]
Therefore, by adopting a thinner turntable unit, the height of the drive base on the upper layer of the cartridge holder can be made smaller, so the device height of the optical storage device is almost the same as the cartridge thickness (about 5 mm). It becomes possible to approach the thickness of the.
[Load / Unload mechanism]
The unloading of the optical disk is achieved by engaging the respective components of the turntable unit 22, the eject motor unit 50, and the load plate 24 described above.
[0173]
First, the disk is manually instructed to be ejected by pressing an eject button 10a provided on the front bezel 10 or by strongly pushing a pin or the like into the manual eject hole 10d.
[0174]
In the former case, the eject motor 50 is driven by pushing the eject button 10a, and the load plate moves to the rear of the apparatus by pulling the end 24d of the load plate 24. In the latter case, the manual eject is performed. When a pin or the like is strongly pushed into the hole 10d, the pin hits the standing wall portion 10f of the load plate 24, and the load plate 24 is pushed and moved rearward of the apparatus.
[0175]
FIG. 22 is an enlarged view of the turntable unit and the load plate.
[0176]
Slide pins 23 a and 23 b that engage with the load plate are fitted on the metal plate 21 of the tar table unit 222. The load plate 24 is provided on the lower side of the sheet metal 21 and has a function of pushing up the sheet metal 21 including the turntable 22.
[0177]
More specifically, the load plate 24 engages with the slide pins 23a and 23b of the sheet metal 21, and the guide holes 84a and 84b having an inclination rising toward the front of the apparatus and the guide holes 84a and 84b are stably guided. A first guide 83a, 83b and a flat surface on which the slide pins 23a, 23b fitted in the guide holes 84a, 84b are stably guided and the slide pins 23a, 23b pulled out of the guide holes 84a, 84b ride on. Second guides 85a and 85b formed lower than these guides are provided.
[0178]
Further, the load plate 24 is provided with third guides 82a and 82b having inclined surfaces rising toward the front of the apparatus. Therefore, as the load plate 24 moves to the rear of the apparatus, the slide pins 23a and 23b of the metal plate 21 slide the second guides 85a and 85b while rotating the roller at the tip, and the curved pieces 81a and 81b slides on the inclined surfaces of the third guides 82a and 82b so that the sheet metal 21 is pushed up.
[0179]
FIG. 23A is a diagram showing a state of the apparatus when the optical disk is loaded (when inserted). FIG. 23B is an enlarged view of a main part.
[0180]
A sheet metal 21 is mounted on the load plate 24. The slide pins 29a and 29b (not shown), the projections 83c and 83d of the load plate 24, and the coil springs 28a and 28b connected at both ends thereof are provided in a contracted state (steady state).
[0181]
At this time, the slide pins 23a and 23b of the sheet metal 21 are fitted in the guide holes 84a and 84b. Further, it can be seen that the curved pieces 81a and 81b of the sheet metal 21 are located below the inclined surfaces of the third guides 82a and 82b.
[0182]
The carriage lock 26 provided on the load plate 24 protrudes toward the opening 20 b of the drive base 20. More specifically, a part of the carriage lock 26 made of plastic is pressed against the protrusion 27 by the coil spring 26 a that is biased so as to rotate in the direction of the protrusion 27 of the drive base 20, and the end of the carriage lock 26 is Protrudes toward the opening 20b of the drive base 20 and engages with the end of the coil portion 32a of the lens carriage 30 that is about to move in the radial direction of the optical disk, thereby acting to prevent the movement of the lens carriage 30.
[0183]
FIG. 24A is a diagram showing an apparatus state when the optical disk is unloaded (when not inserted). FIG. 24B is an enlarged view of a main part.
[0184]
In response to the ejection instruction described above, the load plate 24 moves to the rear of the apparatus, and along with this movement, slide pins 29a to 29c provided on the drive base 20 pass through a plurality of grooves 24a to 24c provided on the load plate 24. Moving. Further, as the load plate 24 moves, the slide pins 23a and 23b of the sheet metal 21 slide on the inclined surfaces of the guide holes 84a and 84b, and further ride on the flat surfaces of the second guides 85a and 85b, and the sheet metal 21 is pushed up. . Thereafter, the slide pins 23a and 23b of the sheet metal 21 slide by a predetermined amount and are pulled back to the guide holes 84a and 84b by the return force of the coil springs 28a and 28b.
[0185]
Similarly, with the movement of the load plate 24, the curved pieces 81a and 81b of the sheet metal 21 slide on the inclined surfaces of the third guides 82a and 82b, and the sheet metal 21 is lifted as the sheet metal 21 near the turntable 22 rises. The curved pieces 81a and 81b also rise slightly. The front side of the sheet metal 21 does not require the above-described slide pins 23a and 23b because the turntable 22 does not need to be pushed up so much for the purpose.
[0186]
Thereafter, the bending pieces 81a and 81b are also pulled back to their original positions by the return force of the coil springs 28a and 28b.
[0187]
Then, with the mechanism described above, as the sheet metal 21 is pushed up, the turntable 22 holding the optical disk rises through the opening 20a and retreats from the inside of the cartridge holder, and the optical disk is accommodated on the wall surface of the drive base 20 around the opening 29a. When the cartridge to be pressed is pressed, the engagement between the optical disk and the turntable 22 is released. Then, the cartridge is discharged outside the apparatus by a cartridge discharge mechanism of the cartridge holder 71 described later.
(Cartridge holder)
FIG. 25 is an enlarged view of the cartridge holder. The cartridge holder 71 is formed by pressing stainless steel or the like. A roller 72a that is movably fitted in the opening 71a of the cartridge holder 71, opens and closes the shutter of the optical disk cartridge, a coil spring 72b that urges the roller 72a in the cartridge discharging direction, and a rotating arm A coil transport / discharge mechanism 72 is configured by a coil spring 72d that urges 72c in the cartridge discharge direction. The rotating arm 72c has a mechanism for adjusting the ejection force of the cartridge by having a gear inside and relaxing the elastic force of the coil spring 72d so that the cartridge is not ejected vigorously when the cartridge is ejected. .
[0188]
An electromagnet unit 73 is provided in the vicinity of the center of the cartridge holder 71 at a position facing the light beam from the objective lens L. And the electromagnetic coil part consists of a copper foil slice coil of a rectangular wire (ribbon wire) shape, and is covered with the insulating seal 74a and the cover 74b. In addition, the use of a square wire (ribbon wire) coil reduces heat generation and prevents the temperature inside the apparatus from rising.
[0189]
Further, a cartridge presser 75 is provided which engages with the end of the optical disk cartridge and is urged to the inside of the cartridge holder 71 by a coil spring and presses the cartridge 400 against the other wall surface of the drive base 20.
[0190]
The cartridge holder 71 on which the above-described components are mounted is screwed to the drive base 20 through a plurality of screw holes 71a and 71b.
[0191]
The terminal 73 a of the electromagnet unit 73 configured in a leaf spring shape is exposed on the back side of the cartridge holder 71 facing the printed circuit board 11, and the cartridge is arranged so as to contact the land portion of the printed circuit board 11. The holder 71 and the printed board 11 are overlaid. And as a countermeasure against warping of the printed circuit board 11, the vicinity of the terminal 73a of the electromagnet unit 73 is screwed.
[0192]
FIG. 26 shows a state where the optical disk cartridge 400 has been normally inserted and ejected. Then, the roller 72a engages with the end surface of the slider 401 of the optical disc cartridge 400, and when the cartridge is inserted and discharged, the roller 72a moves through the opening 71a to open and close the shutter 402 connected to the slider 401.
[0193]
FIG. 27 shows a case where the cartridge 400 is inserted in the reverse direction. At that time, the roller 72a fits into the groove 403 provided in the cartridge 400, and the roller 72a cannot move in the groove 71a even if the groove 403 is pushed, and the cartridge 400 is discharged to the outside by the reaction force of the coil spring 72b. The
[0194]
However, forcibly used by the user, the cartridge 400 may be pushed in despite being erroneously inserted, and the roller 72a may be worn and damaged. If the force of the normal shutter opening / closing operation is about several tens of grams, the bending force of the roller 72a due to erroneous insertion depends on the person, but it may reach several kilograms.
[0195]
FIG. 28 shows a specific configuration of the roller 72a. The roller 72a includes a sliding portion 72f that slides while sandwiching the periphery of the groove 71a of the cartridge holder 71, a rotating portion 72g that engages with the rotation shaft 72e and the slider 401 of the cartridge 400 at the center of the sliding portion 72f. And a locking portion 72h that holds down the rotating portion 72g. In order to improve the durability of the roller 72a, the rotating shaft 72e is made of a metal material such as aluminum or stainless steel, and the other sliding portion 72f, the rotating portion 72g, and the locking portion 72h are polyacetals having good sliding properties. Molded with resin such as resin or plastic. A part of the coil spring 72b is attached between the rotating shaft 72g and the sliding portion 72f.
[0196]
In order to improve the durability of the roller 72a, parts other than the rotating shaft 72e or all parts can be made of a metal material. However, if metal is used for the sliding portion, the sliding portion (the rotating shaft 72e, sliding) Depending on the surface condition and usage frequency of the portion 72f, the rotating portion 72g, and the locking portion 72h), wear may occur, and a smooth shutter opening / closing operation may not be performed. However, it is possible to make the sliding smooth by coating the sliding part with a resin having good slipperiness such as Teflon coating or impregnating the sliding part with lubricating oil. Thus, the roller 72a can be configured.
[0197]
Therefore, the durability of the roller 72a can be improved by adopting the above configuration.
[FPC of fixed optical system]
FIGS. 29A to 29C show a flexible printed sheet (FPC) that transmits a signal of a fixed optical system. The FPC 91 is mounted with circuit components such as a head IC 95 for controlling optical system servo signals, information signals, laser diodes, and the like, and photodetectors 52 and 53.
[0198]
FIG. 29 (b) shows the back side of FIG. 29 (a). And the film and sheet | seat 93,94 which has some hardness are affixed with the adhesive agent or double-sided tape on the surface of the back side in which the plug-in connector 92 in FPC91 is provided. Therefore, when the plug-in connector 92 is connected to the connector 92 ′ on the printed circuit board 11 side, there is an effect that the plug-in connector 92 is easily pressed, the assembly workability is facilitated, and the workability is improved. FIG. 29 (c) shows the FPC 91 bent so that the plug-in connector 92 is exposed on the surface. Therefore, the mounting area of the FPC 91 can be reduced, and it can be screwed into the space portion 20i of the drive base 20 through the screw holes 91a and 91b.
[0199]
Further, the FPC 91 is arranged in the space portion 20i of the drive base 20, thereby facilitating connection to the printed circuit board 11 and contributing to improved assembly workability. In addition, by connecting a wiring for transmitting a signal related to recording or reproduction of information between the drive base 20 and the printed circuit board 11 with a plug-in connector 92 without being routed outside the drive base 20, recording or recording can be performed. It is possible to prevent external noise from being mixed in signals such as reproduction and erasure. Therefore, a more reliable device can be realized as the data storage device.
[0200]
Further, by sandwiching between the printed circuit board 11 and the drive base 20 using the plug-in connector 92 and further covering with the frame 12, a shielding effect is obtained, and further, there is an effect of preventing external noise from being mixed. Therefore, a more reliable device can be realized as the data storage device.
[Other Examples]
Another embodiment of the lens carriage and lens actuator described in FIGS. 16 and 17 will be described with reference to FIG.
[0201]
In FIG. 30, the light from the condensing lens 229 and the condensing lens 229 that emits and emits a light beam with respect to the fixed optical unit 40 are disposed at the center of the lens carriage 230 that moves the objective lens L in the radial direction of the optical disk. A space for mounting a raising mirror M for raising the beam by 45 °, an objective lens L, a lens actuator 160, and the like is formed.
[0202]
In addition, coil portions 232 a and 232 b are provided on both sides of the lens carriage 230. Then, a lens holding portion 162a made of a thermosetting resin or the like that holds the objective lens L so as to be movable in the track direction or the focus direction, and a focus coil 165 that is provided by being bonded to the wall portion of the central opening of the lens holding portion 162a. The track coils 166a and 166b that are bonded to the surface of the focus coil 165 opposite to the aforementioned bonded portion constitutes a movable portion of the actuator 160.
[0203]
The two track coils 166a and 166b provided on the left and right sides of the focus coil 165 are wound in a direction substantially perpendicular to the winding surface of the focus coil 165, and the end thereof is the end surface of the yoke 163 of the magnetic circuit. It protrudes to the outside to the left and right. That is, by controlling the vertical portions outside the magnetic gap of the track coils 166a and 166b to be outside the magnetic gap, it is controlled so as not to be affected by the magnetic flux and mechanical oscillation does not occur. Yes.
[0204]
Further, a magnet 164 provided on the actuator base 161 so as to face the track coil 165 in the central opening of the movable lens holding portion 162a, and a bent portion of the actuator base 161 receiving the magnetic force of the magnet 164. A yoke 161c, a yoke 161d formed of a bent portion provided to face the yoke 161c, and a cover yoke 163 provided on the two yokes constitute a magnetic circuit of the actuator 160.
[0205]
Further, after the six wire portions 167a, 168a, 169a, 170a, 178a (two not shown) that hold the movable portion of the actuator 160 and the holes are fitted into the protrusions 162c of the lens holding portion 162a. The terminal plates 167c, 168c, and 169c (one not shown) that are bonded and hold the end of the wire portion on the objective lens side, and the wire holding portion 162c that is fitted to the end of the actuator base 61 are bonded. Terminal boards 167d, 168d, 169d, and 170d are provided. And the damping member 167b, 169b (two not shown) for absorbing the vibration of a wire part is provided.
[0206]
However, the terminal plate 168c and the terminal plate on the opposite side of the lens holding member (connected to the wire 170a) have two wire portions on the upper and lower sides, and the two wire portions are connected to one terminal plate. Yes. Further, the wire portion may have a damping structure in which the periphery is covered with an adhesive layer, a damping plate or the like, as in the above-described embodiment.
[0207]
The end of the FPC 39a extends on the wire holding part 162b and is soldered to the four terminal boards on the wire holding part 162b. In addition, the four terminal plates on the lens holding portion 162a, and two lead wires each of the focus coil 165 and the track coils 166a and 166b are soldered. In this way, conduction between the focus coil 165 and the track coils 166a and 166b and the FPC 39a is achieved. Therefore, since the electrical connection can be performed without drawing the thin lead wires of each coil, there is no fear of disconnection and the reliability can be improved.
[0208]
Further, the six wire portions and the terminal plates at both ends of each wire portion are created by pressing a leaf spring material or a linear spring material from a mold in which the left and right wire portions are connected together. Then, the left and right wire parts are attached to the wire holding part 162b while being connected (U-shaped), and then the connecting part is cut. Therefore, by using the wire member created in this way, handling and management of small parts can be facilitated and assembly efficiency can be improved.
[0209]
Therefore, the actuator base 161 has all the parts of the actuator 160 described above mounted thereon, and the bent piece mounting portions 161a and 161b of the actuator base 161 and the lens carriage 230 are connected to the lens carriage 230 via the spring 223a. Screwed.
[Dimensions of each part of the device]
In the present embodiment, the configuration of each part for setting the optical storage device to a device height of about 24 mm or less and about 17 mm has been described above.
[0210]
According to the optical storage device that performs recording and reproduction of the 3.5-inch magneto-optical disk cartridge described in this embodiment,
(1) The thickness of the printed circuit board 11 is about 0.8mm.
(In addition, since the allowable height of the space 20i of the drive base 20 is about 4.5 mm, a circuit component having a height of about 4.5 mm at the maximum can be mounted.)
(2) Height at the highest part of the cartridge holder 71 is about 7.1 mm.
(3) The height of the highest part of the drive base 20 is about 15.8 mm.
(Height of cartridge housing is about 9.7 mm, height of turntable unit housing is about 6.0 mm, the highest part of the head base is 6.4 mm, and the highest part of the eject motor unit is about 10.7 mm / lower. (Approximately 9.7 mm, including the thickness of the drive base. The thickness is set at approximately 0.8 to 1 mm.)
(Width approximately 100.2mm, depth at the maximum part approximately 132.2mm)
(4) The center portion of the lens carriage 30 is approximately 7.0 mm thick (depth is approximately 22.2 mm), the thickness of the lens carriage 30 including the coil portion and the VCM is approximately 7.6 mm thick, and only the VCM is approximately 4.5 mm thick.
(5) Overall height of the turntable unit 222 is about 5.8 mm (only the sheet metal 21 is about 0.6 m).
(6) Cover 13 thickness 0.2mm
(7) 4.7mm at the maximum thickness of the load plate
(The above dimensions include a tolerance of ± 0.1 mm.)
The thickness of the drive base can be reduced to about 15.8 mm by taking into account the structural arrangement of each component, etc., so that the total height of the device on which the printed circuit board and the cover are mounted on the drive base is about 17 mm is achieved.
[0211]
In addition, a width of 102 mm and a depth of 140 mm including the printed circuit board and the front bezel are achieved. (Specifically, 17.2 (height) × 101.6 (width) × 140 mm (depth) was achieved.) Therefore, it was built in the slot of a thin floppy disk device having a thickness of about 17 mm, a width of 102 mm, and a depth of 140 mm. It becomes possible.
[Weight of each part of the device]
In the present embodiment, the configuration of each part for reducing the total weight of the optical storage device to about 300 g has been described above.
[0212]
According to the optical storage device that performs recording and reproduction of the 3.5-inch magneto-optical disk cartridge described in this embodiment, as described above, the device is thinned, the number of parts is reduced, the parts are simplified, etc. The weight of each major part of the device is
(1) The total weight of the printed circuit board 11 is about 40 g (including circuit components).
(2) The total weight of the cartridge holder 71 is about 50.2 g (including dustproof sheet, etc.)
(3) The total weight of the lens carriage 30 is about 36.7 g (including VCM).
(4) The total weight of the cover 13 is about 19.8 g.
(5) Total weight of the turntable unit 222 is about 18.3 g.
(6) Total weight of drive base 20 is approximately 66.5 g (including load plate, LD unit, etc.) (7) Total weight of eject motor unit 50 is approximately 10 g
Thus, the total weight of the apparatus was reduced to about 250 g.
[0213]
Further, the total weight of the apparatus when the frame 12 and the front bezel 10 are provided as an option is about 299 g.
[0214]
In this embodiment, the optical storage device for the magneto-optical disk cartridge has been described.ofNeedless to say, the technology for reducing the thickness, weight, and size of the optical storage device such as a phase change optical disk can be applied to the optical storage device such as the phase change optical disk.
[System configuration]
An embodiment in which the above-described optical storage device, particularly a magneto-optical disk device, is used in a computer system will be described.
[0215]
FIG. 31 is a system configuration diagram. The personal computer 300 mainly includes a display 2, a mouse 5, a computer main body 7, and a keyboard 6.
[0216]
The computer main body 7 is equipped with a storage device such as a floppy disk device 3, a CD-ROM optical disk device 9, and a magnetic disk device (not shown). In addition, the magneto-optical disk device 1 having the above-described configuration is inserted into the slot 4 which is a hollow portion of the computer main body 7 slightly larger than the external dimensions thereof, and the connector for the E-IDE interface of the magneto-optical disk device 1 1 a is connected to a connector (not shown) inside the slot 4.
[0217]
All the storage devices described above use portable media except for the magnetic disk device, and a part of the mechanism for inserting or ejecting the media is exposed to the outside. Such a personal computer 300 is activated when the power switch is turned on, reads an operation system and an application from a preset storage device, and executes them.
[0218]
FIG. 32 is a schematic diagram of the internal configuration of the system. A microprocessor (MPU) 301 is the heart of a personal computer and processes programs and data stored in the main memory 302. Data transfer between the MPU 301 and the main memory 302 is performed by the internal bus 303. The cache memory 304 uses a memory element that can be accessed at a higher speed than the main memory 302 and preferentially stores data that is frequently used. The bus controller 305 is connected to the internal bus 303 and exchanges data with the internal bus 307 or 308.
[0219]
Next, the internal bus 307 and a bus to which an external device can be directly connected. The internal bus 307 includes a modem 321 via an RS-232C interface 320, a display 323 via a graphic controller 322 and a video memory 324, and a floppy disk device (FDD) 326 via a floppy disk controller (FDC) 325. Each is connected via.
[0220]
Further, a magnetic disk device (HDD) 328, a magneto-optical disk device (MOD) 329, and a CD-ROM optical disk device (CD-ROM) 330 are connected to the internal bus 307 via an E-IDE adapter. The E-IDE interface is an extended version of the IDE interface and is a general standard interface.
[0221]
Subsequently, the internal bus 308 is a bus that performs interrupt control, and is connected to a timer controller 331, a keyboard controller 332 to which a keyboard 333 is connected, and an interrupt controller 334.
[0222]
FIG. 33 shows an example of a laptop computer 300 ′ having a slot 4 ′ into which a keyboard 6 ′, a floppy disk device having a height of about 17 mm, or a power supply unit can be inserted.
[0223]
Since the magneto-optical disk device 1 described above can be miniaturized as described above in the embodiment, it can be adjusted to approximately the same outer dimensions as the floppy disk device having a height of about 17 mm, and is inserted into the slot 4 'for use. Is possible.
[0224]
Here, as shown in FIG. 34A, the magneto-optical disk apparatus 1 is provided with an outer case 13 ′ on the outer periphery of the drive base 20 and the cover 13 described above so as to be substantially the same size as the slot 4 ′. To adjust the fit with the slot 4 '.
〔interface〕
Further, a case is shown in which the interface of the laptop computer 300 ′ of the present embodiment is different from the interface of the magneto-optical disk apparatus 1 of the above-described embodiment. Therefore, since both cannot be simply connected, as shown in FIGS. 34A to 34D, a conversion unit is provided inside the case 13 '.
[0225]
Specifically, the magneto-optical disk apparatus 1 of the above-described embodiment has the E-IDE connector 1a. However, since the interface of the laptop computer 300 ′ of the present embodiment is a PCMCIA type, the E-IDE Various signals output from the IDE connector 1a are converted into PCMCIA for use.
[0226]
Therefore, when the magneto-optical disk device 1 is accommodated in the case 13 ', the case 13' is provided with a connector 1b to which the E-IDE connector 1a is connected in opposition.
[0227]
Further, an FPC 1c for guiding a signal from the connector 1b is fixed by screwing to a sheet metal 1d, 1e attached to the case 13 '. Further, the signal is transmitted from the FPC 1c to the IC chip 1g containing the MPU, ROM-BUFFER, etc., where the signal for E-IDE is converted to the signal for PCMCIA and transmitted to the connector 1f on the other end side. The PCMCIA signal is converted into an E-IDE signal. The connector 1f protrudes outward from the case 13 'and can be connected to the PCMCIA type interface of the laptop computer 300'.
[0228]
Therefore, according to a user's request, the effect which enables the connection to many high-order apparatuses can be acquired by changing only the case of the optical storage apparatus of one specification.
[Examples of other interfaces]
FIGS. 35A and 35B show unit configuration diagrams of the optical storage device of the second embodiment. 35 (a), the magneto-optical disk device 1 described in FIG. 1 and the like is further housed in a case (container) 311. Two types of SCSI connectors 312a and E-IDE connectors 312b are connected to the outside of the case 311. It protrudes into
[0229]
The slide plate 314 is one in which one of the two types of connectors used is opened and the other not used is closed. And the elongate pin 313 is provided in the both sides of the slide board 314, and it is comprised so that it may move between the connectors provided up and down in the figure. If it is desired to use the upper connector, the slide plate 314 is moved upward and fixed with screws or pins (not shown).
[0230]
In FIG. 35B, the SCSI connector 312a and the E-IDE connector 312b divide the signal line for guiding the signal of the E-IDE connector 1a of the magneto-optical disk device 1 into two, and one of them is E as it is. -For IDE, the other is connected to an IC chip 331 such as MPU and ROM-BUFFER to convert the E-IDE signal to SCSI, and conversely, the SCSI signal is converted to E-IDE It is configured to convert to a signal.
[0231]
In addition, the types of connectors for cases and optical storage device interfaces are not limited to SCSI, E-IDE, and PCMCIA connectors. Can be installed.
[0232]
Therefore, by changing only the case of an optical storage device of one specification, connectivity with a host device such as a large number of types of personal computers can be improved.
[0233]
FIGS. 36A and 36B are unit configuration diagrams of the optical storage device according to the third embodiment. The magneto-optical disk device 1 has an E-IDE connector 1a. The magneto-optical disk device 1 is connected to a conversion connector (not shown) inside the case 341 by inserting it into a case 341 having a SCSI connector 342 other than the E-IDE and a PCMCIA connector 343 adapter 345. The
[0234]
An IC 346 that accommodates MPU, ROM-BUFFER, and the like, which are conversion circuits connected to the conversion connector, converts the E-IDE signal into a SCSI signal or the SCSI signal into an E-IDE signal. And can be connected to a host device 300 such as a personal computer main body 300 or a laptop computer 300 ′ via a SCSI connector.
[0235]
The signal conversion of the interface described above is based on the data of the correspondence between the signal content and terminal number for E-IDE and the signal content and terminal number for SCSI stored in the ROM-BUFFER. This is done by correspondingly converting. Also, generally known signal contents and terminal numbers of the interface connector are used.
[0236]
A simple conversion example is shown. For example, pin 1 indicates RESET in the E-IDE type, GROUND in the PCMCIA type, and GROUND in the SCSI type. Therefore, since the information differs depending on the pin number, when transmitting GROUND, the E-IDE type 2 pin signal is converted to be transmitted to the PCMCIA type 1 pin or the SCSI type 1 pin. Become.
[0237]
FIG. 37 is a unit configuration diagram of the optical storage device according to the fourth embodiment. In this embodiment, connectors 316 and 318 that can be connected to each other are provided at positions where the cases 315 and 317 face each other when the cases 315 and 317 of the two storage devices are stacked.
[0238]
Therefore, it is possible to connect the connector without interposing the cable and without routing the cable only by stacking the two storage devices vertically. In this embodiment, the optical storage device is taken as an example. However, by making the interface connectors to be connected the same, for example, the connection between the hard disk device and the magneto-optical disk device becomes possible. Data can be exchanged directly between them.
[0239]
Further, the present invention can be applied between a hard disk device other than an optical storage device and a floppy disk device.
[0240]
Further, by exposing the connector not only in the vertical direction but also in the horizontal direction, the connector can be connected between the left and right sides. Furthermore, in this embodiment, the connector is provided on the upper surface or the lower surface of the apparatus. However, it is also possible to connect two or more devices by providing the connectors on the upper and lower surfaces.
[0241]
【The invention's effect】
In an optical storage device, a cartridge holder into which a cartridge containing an optical storage medium is inserted, a turntable for rotationally driving the optical storage medium, a metal plate having a slide portion and holding the turntable, A load / unload comprising a turntable unit comprising a load plate on which a guide having an inclined surface is formed, and the slide portion slides on the inclined surface of the guide as the load plate slides to raise / lower the turntable. The mechanism and the cartridge holder are mounted on the lower surface side, and the turntable unit and the drive base on which the load / unload mechanism is mounted so that the slide portion and the guide are engaged on the upper surface side of the cartridge holder. Therefore, the height of the drive base on the upper surface side of the cartridge holder accommodating portion is characterized by Can be held only at the height of the mechanism for loading / unloading the turntable unit, the front of the device can be made as thin as possible, and the height of the device can be made as close as possible to the thickness of the cartridge. become. Therefore, it can be used as a built-in optical storage device by being inserted into a unit having a height of about 17 mm in the host system.
[0242]
In addition, the thickness of the member that holds the turntable is reduced as much as possible, and the overall height of the turntable unit is brought close to the height of only the turntable, so that the overall rise amount of the turntable unit is suppressed, and the drive base It is possible to reduce the height of the turntable unit housing portion and to reduce the size and thickness of the apparatus.
[0243]
Further, the metal plate of the turntable unit is characterized in that the slide part is integrally formed by a pressing technique, and therefore, the apparatus thickness is not required without requiring a complicated holding member for holding the slide part. The thickness direction can be reduced as much as possible, and the size and weight can be reduced. In addition, it is possible to reduce the driving torque of the load / unload mechanism (drive torque of the eject motor) by reducing the amount of lift of the turntable unit and reducing the weight of the members held by the turntable unit as much as possible. become. Furthermore, a complicated shape can be simply formed by using a press technique, and the number of parts and man-hours can be reduced to reduce the cost.
[0244]
Further, the present invention is characterized in that at least a flexible printed wiring sheet for guiding a signal line for rotationally driving the turntable is mounted on the metal plate. Further, the flexible printed wiring sheet is provided with a sensor for detecting write protection set in the optical disk cartridge or a cartridge-in sensor for detecting insertion of the optical disk cartridge.
[0245]
Therefore, by reducing the thickness of the members held by the turntable unit as much as possible and bringing the overall height of the turntable unit close to the height of the turntable alone, the overall amount of the turntable unit can be suppressed, and the drive The base turntable unit housing can be thinned, and the apparatus can be thinned. In addition, it is possible to reduce the driving torque of the load / unload mechanism (drive torque of the eject motor) by reducing the amount of lift of the turntable unit and reducing the weight of the members held by the turntable unit as much as possible. become.
[0246]
As described in detail above, the present invention can provide a compact optical storage device that is thin, small, lightweight, and has a significantly improved assembly workability.
[0247]
In addition, it is possible to provide an optical storage device that can ensure reliability and can be further improved without reducing the ability as a data storage device even if it is thinned, miniaturized, and reduced in parts.
[0248]
Therefore, the present invention makes it possible to reduce the thickness, size, and weight of the device, so that an optical storage device that can be mounted on a portable thin laptop computer or the like can be provided. Furthermore, the present invention can provide an optical storage device that can be installed in a device slot of 1 inch or less and about 17 mm in a computer system.
[0249]
Furthermore, the present invention can provide an optical storage device in which the height of the drive base is as close as possible to the thickness of the optical disk cartridge (ISO standard 3.5 inch optical disk cartridge compliant 6.0 ± 0.2 mm).
[0250]
Therefore, since the present invention can be mounted or connected to a large number of host devices, it is possible to expand the usage form of the optical storage device to a multipurpose field, and to improve the versatility of the optical storage device. Is possible.
[Brief description of the drawings]
FIG. 1 is an external perspective view of the front side of an optical storage device.
FIG. 2 is a rear external perspective view of the optical storage device.
FIG. 3 is an exploded perspective view of the front side of the optical storage device.
FIG. 4 is an exploded rear perspective view of the optical storage device.
FIG. 5 is an enlarged view of a printed circuit board.
FIG. 6 is a schematic diagram of a main part on the back side of the optical storage device.
FIG. 7 is a schematic configuration diagram of an embodiment of a covering cover. (A) Configuration diagram, (B) Operation explanatory diagram (No. 1), (C) Operation explanatory diagram (No. 2)
FIG. 8 is a schematic configuration diagram of another embodiment of the covering cover. (A) Configuration diagram, (B) Operation explanatory diagram
FIG. 9 is an enlarged view of a fixed optical unit. (A) The figure which shows the arrangement state of an optical component, (b) The figure which shows the state of a head base
FIG. 10 is a layout view of optical components of the fixed optical unit.
FIG. 11 is an explanatory diagram of an optical path in the fixed optical unit.
FIG. 12 is an explanatory diagram of a servo unit. (A) External perspective view of compound lens, (B) Plan view of compound lens, (C) Operation explanatory diagram
FIG. 13 is an explanatory diagram of a method for manufacturing a BR prism.
FIG. 14 is an explanatory diagram of a method for manufacturing a BW prism.
FIG. 15 is an enlarged view of an objective lens. (A) Perspective view, (b) Cross section
FIG. 16 is an enlarged view of a lens carriage. (A) Upper enlarged view, (b) Horizontal enlarged view, (c) Cross sectional enlarged view
FIG. 17 is an enlarged perspective view of a lens actuator.
FIG. 18 is a layout view of a focus coil and a track coil.
FIG. 19 is an explanatory diagram of a damping effect by the configuration of the wire portion.
(A) Without damping member
(B) With damping member
FIG. 20 is an explanatory view of a damping effect of the damping member.
(A) In case of thermosetting adhesive
(B) In the case of non-fully curable adhesive
FIG. 21 is an enlarged view of the turntable unit.
FIG. 22 is an enlarged view of a turntable unit and a load plate.
FIG. 23 is a diagram illustrating a device state of an optical storage device.
(When loading an optical disc)
(A) Overall view of the device, (b) Enlarged view of relevant parts
FIG. 24 is a diagram illustrating a device state of an optical storage device.
(When unloading optical disc)
(A) Overall view of the device, (b) Enlarged view of relevant parts
FIG. 25 is an enlarged view of the cartridge holder.
FIG. 26 is an operation explanatory diagram (No. 1) of the cartridge holder.
FIG. 27 is an operation explanatory diagram (No. 2) of the cartridge holder;
FIG. 28 is a schematic configuration diagram of a roller.
FIG. 29 is an enlarged view of the FPC of the fixed optical unit.
(A) Front side, (b) Back side, (c) When bent
FIG. 30 is an enlarged view of a lens carriage according to another embodiment.
FIG. 31 is a system configuration diagram.
FIG. 32 is a schematic diagram of the internal configuration of the system.
FIG. 33 is a block diagram of a laptop computer system.
FIG. 34 is a unit configuration diagram of the optical storage device according to the first embodiment;
(A) External view, (b) Internal configuration diagram, (c) Top view, (d) Block diagram
FIG. 35 is a unit configuration diagram of an optical storage device according to a second embodiment;
(A) External view, (b) Block diagram
FIG. 36 is a unit configuration diagram of an optical storage device according to a third embodiment;
(A) External view, (b) Block diagram
FIG. 37 is a unit configuration diagram of an optical storage device according to a fourth embodiment;
[Explanation of symbols]
13 Cover
10 Front bezel
11 Printed circuit board
20 drive base
24 Load board
30 Lens carriage
40 Fixed optical unit
40a shielding cover
71 Cartridge holder
222 Turntable unit

Claims (7)

A cartridge holder for holding a cartridge containing an optical storage medium;
  A wall surface facing the cartridge, a drive base having a first opening provided on the wall surface, and mounting the cartridge holder on the upper surface side so as to face the wall surface;
  A turn comprising a turntable mounted below the cartridge holder and on the lower surface side of the drive base and rotationally driving the optical storage medium, and a metal plate having a slide portion and holding the turntable. Table unit,
  A load plate mounted on the lower surface side of the drive base and formed with a guide having an inclined surface is formed, and the slide portion moves the inclined surface of the guide by moving the load plate back and forth on the drive base. A load / unload mechanism that slides to raise / lower the metal plate of the turntable unit;
With
  When the turntable holds the optical storage medium, the turntable protrudes from the first opening of the drive base toward the cartridge holder by raising the metal plate, and the turntable and the optical storage medium When releasing the engagement of the storage medium, the turntable is configured to descend from the first opening of the drive base by lowering the metal plate,
The height of the portion of the drive base on which the turntable unit is mounted is set to be substantially the same as the height of the turntable unit;
An optical storage device. A cartridge holder for holding a cartridge containing an optical storage medium;
  A wall surface facing the cartridge, a drive base having a first opening provided on the wall surface, and mounting the cartridge holder on the upper surface side so as to face the wall surface;
  A turn comprising a turntable mounted below the cartridge holder and on the lower surface side of the drive base and rotationally driving the optical storage medium, and a metal plate having a slide portion and holding the turntable. Table unit,
  A load plate mounted on the lower surface side of the drive base and formed with a guide having an inclined surface is formed, and the slide portion moves the inclined surface of the guide by moving the load plate back and forth on the drive base. A load / unload mechanism that slides to raise / lower the metal plate of the turntable unit;
With
  When the turntable holds the optical storage medium, the turntable protrudes from the first opening of the drive base toward the cartridge holder by raising the metal plate, and the turntable and the optical storage medium When releasing the engagement of the storage medium, the turntable is configured to descend from the first opening of the drive base by lowering the metal plate,
The height of the portion of the drive base on which the turntable unit is mounted is set to be approximately the same as the height of the turntable unit or the guide, whichever is higher,
An optical storage device. A cartridge holder for holding a cartridge containing an optical storage medium;
  A wall surface facing the cartridge, a drive base having a first opening provided on the wall surface, and mounting the cartridge holder on the upper surface side so as to face the wall surface;
  Mounted on the lower surface side of the drive base below the cartridge holder, A turntable unit that rotationally drives an optical storage medium, and a turntable unit that includes a slide portion and includes a metal plate that holds the turntable;
  A load plate mounted on the lower surface side of the drive base and formed with a guide having an inclined surface is formed, and the slide portion moves the inclined surface of the guide by moving the load plate back and forth on the drive base. A load / unload mechanism that slides to raise / lower the metal plate of the turntable unit;
With
  When the turntable holds the optical storage medium, the turntable protrudes from the first opening of the drive base toward the cartridge holder by raising the metal plate, and the turntable and the optical storage medium When releasing the engagement of the storage medium, the turntable is configured to descend from the first opening of the drive base by lowering the metal plate,
The height of the portion of the drive base on which the turntable unit is mounted is set to be substantially the same as the maximum movement amount of the turntable unit;
An optical storage device. 4. The optical storage device according to claim 1, wherein the metal plate of the turntable unit is formed by integrally forming the slide portion by a pressing technique. 5. The flexible printed wiring sheet for guiding a signal line for rotationally driving the turntable is mounted on the metal plate. Four The optical storage device according to claim 1. 6. The optical storage according to claim 5, wherein the flexible printed wiring sheet is provided with a sensor for detecting write protection set in the optical disk cartridge or a cartridge in sensor for detecting insertion of the optical disk cartridge. apparatus. The drive base has a second opening at a position facing the optical storage medium, and a lens carriage on which a lens for condensing a light beam on the optical storage medium is mounted in the second opening. ,
Fixed optical components for guiding a light beam to the lens carriage and fixed optics for guiding reflected light from the optical storage medium to a photodetector on the drive base behind the portion where the cartridge holder is mounted The parts are directly fixed and arranged. 6 The optical storage device according to claim 1.

Images