JP2008016136A - Disk tray, disk driving device, and disk changer device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To achieve miniaturization and to prevent damage to a disk recording medium during vibration. <P>SOLUTION: The disk tray is provided with a disk tray 7a into which a disk recording medium 2 is inserted from a direction parallel to the signal recording surface of the disk recording medium 2 and which supports the peripheral edge of the disk recording medium 2. This disk tray 7a has an opening where the insertion end side of the disk recording medium 2 inserted into the disk tray 7a is opened, and a slope 7h inclined at the end of a side where the opening is formed toward a direction away from the disk recording medium 2. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a disk tray for storing a disk-shaped recording medium, a disk drive device having a plurality of such disk trays, and recording and / or reproducing signals on the stored disk-shaped recording medium. The present invention relates to a disk changer device that has a plurality of such disk trays and selects and records and / or reproduces signals by selecting any one of a plurality of stored disk-shaped recording media.

  2. Description of the Related Art Conventionally, as a vehicle-mounted acoustic device, there is a so-called disc changer device that can select and reproduce an arbitrary disc-shaped recording medium from a plurality of disc-shaped recording media.

  This disc changer device has a mechanism in which a plurality of disc-shaped recording media such as compact discs (CDs) are collectively stored in a magazine case and the magazine case is mounted on the main body of the device. . For this reason, in a disk changer device, a relatively large device body is generally installed at a position different from a vehicle compartment such as a trunk, and only a portion necessary for operation is installed in the vehicle cabin. It has become. In this case, the disk cannot be exchanged in the passenger compartment, and the magazine case must be removed from the main body of the apparatus to exchange the disk, which is very troublesome.

  Therefore, a small-sized disk changer device has been proposed as a vehicle-mounted disk changer device that can store, for example, six disks in a device body that is stored in a certain standard dimension called a 1DIN size. Yes.

  In this disc changer apparatus, it is possible to install the apparatus main body in a standardized storage space provided in the center panel of the vehicle interior by storing the apparatus main body in a certain standard size without using the magazine case described above. ing. As a result, the disk can be exchanged in the passenger compartment, thereby further improving convenience.

  Specifically, as shown in FIG. 18, the disk changer apparatus has a disk storage section 202 for storing the disk 201 inside the apparatus main body 200. The disk storage section 202 includes, for example, six sheets. The trays 203 are arranged in a stacked state. Further, a disk insertion / removal port 204 is provided on the front surface of the apparatus main body 200, and the disk 201 inserted from the disk insertion port 204 is placed on the tray 203.

  The disc changer device also includes a pickup device 205 that reproduces the selected disc. The pickup device 205 includes a pair of chuck levers 206a that hold the selected disc 201 in a freely rotating manner. 206b and a pickup unit 207 on the surface of the chuck lever 206a located below on the surface facing the disc 201.

  In this disk changer device, a sufficient space is formed above and below the selected disk 201 in the stacked tray 203 so that the pair of chuck levers 206a and 206b enter. When the disc 201 is sandwiched between the pair of chuck levers 206a and 206a, the disc 201 is rotationally driven, and the pickup unit 207 reproduces a signal with respect to the disc 201.

  Further, a protective layer is provided on the disk mounting surface on which the disk 201 of the tray 203 is mounted as a cushioning material for preventing damage to the disk 2 so as not to damage the disk 201. This protective layer prevents the disk-shaped recording medium from being damaged.

  By the way, in the disk changer apparatus described above, the disk tray portion that supports the disk 201 of the tray 203 is not shaped to place the entire surface of the disk 201 from the viewpoint of miniaturization and weight reduction. The insertion end side has a shape having an open part cut out, that is, a shape that supports a part of the disc-shaped recording medium placed thereon.

  In such a disc changer device, when vibration occurs while the disc-shaped recording medium is held on the tray 203, the disc 201 may swing and collide with the notch end of the tray 203. It was. The tray 203 is provided with the above-described buffer member. However, there is a possibility that the disc-shaped recording medium may be damaged due to the collision with the end portion caused by the swinging operation of the disc.

International Publication No. 2002/086883 Pamphlet

  An object of the present invention is to provide a disc tray, a disc drive device, and a disc changer device that realize miniaturization and prevent damage to a disc-shaped recording medium during vibration.

  The disc tray according to the present invention has a disc tray portion into which the disc-shaped recording medium is inserted from a direction parallel to the signal recording surface of the disc-shaped recording medium, and supports the peripheral edge of the disc-shaped recording medium. An opening portion is formed on the portion where the insertion end side of the disc-shaped recording medium inserted into the disc tray portion is opened, and the disc-shaped recording medium is formed at the end portion on which the opening portion is formed. A disc tray in which an inclined surface portion inclined toward a separating direction is formed.

  A disk drive device according to the present invention includes a plurality of disk trays on which a plurality of disk-shaped recording media are respectively mounted, a disk storage section for storing a plurality of disk-shaped recording media, and a storage in the disk storage section. A recording and / or reproducing unit for recording and / or reproducing a signal with respect to a disc-shaped recording medium to be recorded is used, and a disk tray as described above is used as a disk tray used in this disk drive device.

  A disc changer device according to the present invention has a plurality of disc trays on which a plurality of disc-shaped recording media are respectively mounted, and a disc storage portion in which a plurality of disc-shaped recording media are stored, and is stored in the disc storage portion. Disc selection means for selecting any one of a plurality of disc-shaped recording media, and recording and / or reproduction for recording and / or reproducing signals on the disc-shaped recording medium selected by the disc selection means. Alternatively, a playback unit is provided, and the above-described disk tray used in this disk changer device is used.

  The disc tray according to the present invention has a disc tray portion in which the disc-like recording medium is inserted from a direction parallel to the signal recording surface of the disc-like recording medium and supports the periphery of the disc-like recording medium. By forming an open portion that opens the insertion end side of the inserted disc-shaped recording medium, it is possible to reduce the size and weight, and at the end portion of the disc tray portion where the open portion is formed, By providing the inclined surface portion, it is possible to prevent the disc-shaped recording medium from being damaged during vibration.

  The disk drive device and the disk changer device according to the present invention have the above-described disk tray to prevent the disk from being damaged, thereby improving the quality and realizing a reduction in size and weight.

  Hereinafter, a disc tray, a disc drive device, and a disc changer device to which the present invention is applied will be described in detail with reference to the drawings.

  As shown in FIG. 1, a disc changer device to which the present invention is applied has a disc-shaped recording medium such as six CDs (Compact Disks) in a main unit 1 of a standard size called a so-called 1DIN size. (Hereinafter referred to as “disk”) 2 is a small-sized disk changer device capable of storing 2 together. The disc changer device can select and play an arbitrary disc 2 out of the six discs 2.

  In addition, the disc changer device is installed in a standardized storage space provided in a center panel in a passenger compartment by storing the device main body 1 in a certain standard size. As a result, the disk 2 can be exchanged in the passenger compartment, and the convenience is further improved.

  Hereinafter, a specific structure of the disk changer device will be described.

  FIG. 1 is a perspective view showing an appearance of the main body 1 of the disk changer device. In addition, the apparatus body 1 is originally provided with an operation panel provided with operation buttons and the like on the front surface of the casing, and the casing itself is covered with an exterior case. The illustration of the outer case is omitted.

  As shown in FIGS. 1 and 2, in the disk changer apparatus, the apparatus main body 1 is provided with a substantially rectangular bottom plate 1a and standing upward from both side edges of the bottom plate 1a. A pair of side plates 1b and 1c formed integrally, a front plate 1d attached along the front edge of the bottom plate 1a and side plates 1b and 1c, and the bottom plate 1a, and these side plates 1b , 1c and the ceiling plate 1e attached along the upper edge of the front plate 1d constitutes a substantially box-like casing while opening the back side. FIG. 2 is an exploded perspective view showing the internal structure of the apparatus body 1.

  The apparatus main body 1 is connected to the disk storage section 3 through the disk storage section 3 for storing the disk 2 and the disk insertion / removal opening 4 provided in the front plate 1d. A disc insertion / removal device 5 for inserting / removing the disc 2 from a direction parallel to the signal recording surface, and a recording / reproduction for selecting one of the discs 2 stored in the disc storage unit 3 and reproducing a signal And / or a pickup device 6 which is a playback device.

  As shown in FIGS. 1 and 3, the disk storage unit 3 has six disk trays (hereinafter referred to as “trays”) on which the disks 2 are placed on the front side in the housing facing the disk insertion / removal opening 4. 7) are arranged in a stacked state. FIG. 3 is an exploded perspective view showing the structure of the disk storage unit 3.

  The uppermost tray 7 and the trays 7 other than the uppermost layer have different structures. However, since the uppermost tray 7 has all the configurations of the trays 7 other than the uppermost layer, first, other than the uppermost tray. The tray will be described with reference to FIG.

  As shown in FIG. 4, the tray 7 is a disc tray portion 7a formed in a flat plate shape by a metal material such as a thin aluminum plate, stainless steel, or a resin material, and a guide member attached to the upper surfaces on both sides of the disc tray portion 7a. A pair of resin members 9 and a leaf spring 11 as a spring means attached in a cantilevered state with the front side being fixed by screws or the like along the upper surfaces of the pair of resin members 9. Is formed.

  The pair of resin members 9 have substantially the same thickness as the disk 2 placed on the disk tray portion 7a, and are arranged substantially parallel to the disk tray portion 7a on the surface facing the side plates 1b and 1c. A pair of pins 10a and 10b are formed to protrude toward the side plates 1b and 1c, respectively. The pins 10a and 10b are formed on the intermediate portion and the back side of the resin member 9, the intermediate portion pin 10a is long, and the back side pin 10b is short.

  The disc tray portion 7a supports the periphery of the disc 2 by inserting the disc 2 in a direction parallel to the signal recording surface of the disc 2 in the direction of arrow D1 in FIG. The disc tray portion 7a is formed with an open portion 7j that opens the disc insertion end S1 of the disc 2 inserted into the disc tray portion 7a.

  That is, the disc tray portion 7a has a shape cut out so as to project and support one end side of the disc 2, and the disc 2 placed at a position facing the central portion of the disc 2 will be described later. A notch 7 b for chucking by the chuck lever 59 is provided. That is, the disc tray portion 7a is formed with a predetermined width over at least a portion of the peripheral edge portion of the disc 2 on the side S2 opposite to the disc insertion end side S1, and the disc 2 is supported by this portion. Here, the disc tray portion 7a is large enough to support the peripheral portion of the disc 2, and by reducing the predetermined radial width, the overall weight of the device can be reduced. It is possible to reduce the cost and to reduce the amount of a resin layer 8 to be described later as a protective member formed on the disk tray portion 7a.

  Further, the disc tray portion 7a has a first guide piece 7c formed on the disc insertion / removal port 4 side, that is, the opposite side S2 as described above, and projects in substantially the same plane as the disc tray portion 7a, and a disc insertion end side S1. A second guide piece 7d is formed at a position opposite to the first guide piece 7c so as to protrude in substantially the same plane as the disc tray portion 7a.

  As shown in FIGS. 4 and 5, the first guide piece 7 c has inclined surface portions 7 e and 7 f formed on both sides, which are formed to be inclined in a direction in which the thickness decreases toward the distal end side of the opposite side S <b> 2 described above. Is formed.

  The first guide piece 7c performs a guide when the disk 2 is inserted / discharged, and realizes smooth insertion / discharge of the disk 2. For example, as shown in FIG. 6, when the disc 2 is inserted, the height of the disc tray portion 7a on which the disc 2 is placed and the lower surface of the disc 2 are shifted. By correcting the height of the disk 2 along the inclined surface 7e of the first guide piece 7c, the disk 2 can be reliably placed on the disk tray portion 7a. Incidentally, the inclined surface portion 7f provided on the opposite side of the disc mounting surface side of the disc tray portion 7a, that is, the lower surface side, is the disc 2 inserted into the disc tray portion 7a at the lower stage of the disc tray portion 7a. It has a function as a guide at times. Even when the disk 2 is ejected, a load is applied to the disk 2 even when the disk mounting surface of the disk tray portion 7a is slightly displaced from the positions of rollers 30 and 31 for disk insertion / removal described later. It is possible to discharge smoothly without taking. Here, in order to further enhance the function as a guide, the inclined surfaces 7e and 7f are provided on both surfaces of the first guide piece 7c. However, if at least one of the inclined surfaces is provided, the above-described effects are obtained. In addition, the same effect can be obtained without providing the inclined surface portion 7f in the lowermost disc tray portion.

  As shown in FIGS. 4 and 5, the second guide piece 7 d is directed toward the front end side, which is the center side of the disk 2, and away from the disk 2 placed on the disk tray portion 7 a. It has an inclined surface portion 7g formed to be inclined.

  The second guide piece 7d performs guidance when the disc 2 is ejected, and realizes smooth ejection of the disc 2. That is, the rib 2b (see FIG. 7), which is a part for chucking the disk 2, is generally formed with a substantially conical slope, but there is no strict standard, and each disk The manufacturing error and the manufacturing line vary, and for example, this portion may be formed in a substantially cylindrical shape having a side surface orthogonal to the disk surface.

  In such a case, as shown in FIG. 7B, when the disc 2 is moved from the disc tray portion 7a in the ejecting direction, the edge portion on the side where the notch portion 7b of the disc tray portion 7a is provided. In other words, there is a case in which the inner peripheral portion is abutted and a catch occurs, and this may cause the discharge to not be performed smoothly, and further, the discharge may not be possible. FIG. 7B is a view showing a disc tray of a comparative example for comparison with the disc tray 7 to which the present invention is applied. Further, the disc tray of this comparative example is a disc tray in which the second guide piece 7d and the inclined portion 7g are not provided. The second guide piece 7d solves such a problem. As shown in FIG. 7A, the second guide piece 7d and the inclined surface portion 7g are provided on the inner peripheral side of the disc tray portion 7a, so that the disc The rib 2b protruding below 2 is guided to achieve smooth discharge. At this time, (H1 + H2), which is the sum of the height H1 of the inclined surface portion 7g and the thickness H2 of the resin layer 8 to be described later, is set to be larger than the height H3 (= 0.4 mm) of the rib 2b of the disk 2. By doing so, the disc 2 can be discharged more reliably.

  The first guide piece 7c described above also functions as a guide for the rib 2b at the time of insertion in the same manner as the second guide piece 7d described here.

  Further, on the surface of the disc tray portion 7a on which the disc 2 is placed, a softer resin layer than the disc 2 except for the first and second guide pieces 7c and 7d and the inner peripheral portion 7j of the disc tray portion 7a. 8 is formed as a protective member. The resin layer 8 is formed on the disk placement surface of the disk tray portion 7a by printing such as metal mask printing, screen printing such as silk screen printing, and tampo printing, but is not limited thereto. You may make it form by painting, sticking, etc. Furthermore, the resin layer 8 is provided as a protective member. However, the protective member is not limited to this, and may be a soft member such as rubber in consideration of slipperiness and the like. Any material having a function as a cushioning material for preventing damage may be used.

  Here, the resin layer 8 as the protective member will be specifically described. When the disk substrate is made of, for example, polycarbonate (PC), the disk 2 has a rubber hardness of 95 IRHD and a pencil hardness of B to 2B. The rubber hardness referred to here is the international rubber hardness IRHD (International Rubber Hardness Degree), and the pencil hardness is a scratch test using pencils of different hardness, and the occurrence of scratches. Hardness determined by the presence or absence.

  In this case, if a resin layer 8 having a pencil hardness of 3B or less, which is softer than that of the disk 2 made of polycarbonate, is formed, damage due to contact of the disk 2 can be prevented. More preferably, by forming the resin layer 8 having a pencil hardness of 6B or less, the occurrence of scratches or the like on the disk 2 can be reliably prevented.

  On the other hand, the rubber hardness of the resin layer 8 needs to be softer than 95IRHD. However, if the rubber hardness of the resin layer 8 is softened, the frictional resistance with the disk 2 is increased. Therefore, the rubber hardness of the resin layer 8 is preferably 60 IRHD or more that does not interfere with the operation of placing the disk 2 on the tray 7 and the operation of separating the disk 2 from the tray 7 described above. More preferably, if the rubber hardness of the resin layer 8 is in the range of 70 IRHD or more and 75 IRHD or less, the frictional resistance with the disk 2 is improved, and damage due to contact with the disk 2 is prevented. Can do.

  Further, when the resin layer 8 is formed by printing, it can be formed very thin, and the problem of peeling from the tray 7 can be avoided.

  As a printing method of the resin layer 8, for example, in the case of silk screen printing, first, the coating liquid is adjusted, and then this coating liquid is printed on the tray 7 by using a screen printing machine. The resin layer 8 is cured by irradiating the coating liquid printed on the tray 7 with ultraviolet rays using an ultraviolet irradiator.

  As a material for the resin layer 8, for example, a urethane-based ultraviolet curable (UV) resin that is softer than polycarbonate contains crosslinked rubber particles (organic crosslinked elastic filler) for imparting elasticity. Something is used. Specifically, Takelac UV-9203 (rubber hardness 70 IRHD) manufactured by Takeda Pharmaceutical is used as the urethane UV resin, and Trefil E-600 (average) manufactured by Toray Dow Corning Silicone is used as the organic cross-linked elastic filler. What knead | mixed the particle size of 3 micrometers is used as a coating liquid. In addition, an epoxy resin, an acrylic resin, etc. have the high pencil hardness of H-3H, and are unsuitable as a material of the resin layer 8 mentioned above.

  The viscosity of the coating liquid is preferably in the range of 20 Pa · s to 100 Pa · s. This is because if the viscosity of the coating liquid is lower than 20 Pa · s, it will flow after printing, making it difficult to ensure a predetermined thickness, while if the viscosity of the coating liquid is higher than 100 Pa · s, This is because it is difficult to appropriately transfer the coating liquid to the film 7.

  More preferably, the viscosity of the coating liquid is in the range of 30 Pa · s to 40 Pa · s. As a result, the texture (the wrinkle pattern) by the screen at the time of screen printing is transferred to the surface of the resin layer 8. Therefore, a large number of uneven patterns are formed on the surface of the finally cured resin layer 8, and the slipperiness at the time of contact between the resin layer 8 and the disk 2 is good due to the large number of uneven patterns. Can be. As described above, the resin layer 8 can be accurately formed on the tray 7. The resin layer 8 configured as described above can prevent the disk 2 from being damaged.

  Further, as described above, since the resin layer 8 is formed except for the inner peripheral portion 7j of the disc tray portion 7a, the disc 2 is ejected along the inclined surface portion 7g of the second guide piece 7d. In addition, it is possible to prevent adhesion of the resin layer 8 to the disk 2 due to scraping. That is, when the resin layer 8 is also formed on the inner peripheral portion 7j, when the disc 2 is discharged along the inclined surface portion 7g, the edge of the resin layer 8 near the inner peripheral portion 7j slides on the disc 2. There is a possibility that the scraped resin layer 8 may be attached to the disk 2 due to contact. In this tray 7, since the resin layer 8 is not formed in the inner peripheral portion 7j, it is possible to prevent such a problem from occurring.

  Further, as shown in FIGS. 4 and 5, the end of the disc tray portion 7a on the side where the disc 2 is projected, that is, the end portion on the side where the open portion 7j opened on the insertion end side S1 is formed. An inclined surface portion 7h that is inclined toward the tip and in a direction away from the disk 2 is formed. In other words, the inclined surface portion 7h is formed at the boundary portion between the protruding portion of the disk 2 placed so as to protrude from the disk tray portion 7a and the loaded portion. The resin layer 8 described above is also formed on the inclined surface portion 7h.

  The inclined surface portion 7h prevents the disk 2 from being damaged when the disk 2 vibrates when an impact or the like is applied to the apparatus. That is, as described above, the tray 7 is cut out so that the disc 2 protrudes from the disc tray portion 7a, thereby realizing a reduction in the size of the tray 7 in the disc insertion / removal direction. It is. However, as shown in FIG. 8B, the end portion of the disc tray portion 7a having the cut-out shape on the side where the open portion is formed is used to move the disc 2 when the disc 2 vibrates. There was a risk of damage or particles of the resin layer 8 adhering to the disk 2. FIG. 8B is a view showing a disc tray of a comparative example for comparison with the disc tray 7 to which the present invention is applied. As described above, since the disc tray portion 7a is provided with the inclined surface portion 7h at the end portion on the side where the opening portion 7j is formed, as shown in FIG. 8A, the inclined surface portion 7h. By being configured to receive the impact of the disk 2 that is vibrated by the surface, damage to the disk 2 and adhesion of particles of the resin layer to the disk 2 are prevented.

  Further, the inclined surface portion 7h prevents damage due to vibration of the disk 2 due to the structure of the tray 7 that realizes a sufficiently small size. That is, the tray 7 does not support the disk tray portion 7a over the entire surface of the disk as described above, but is formed and supported with a predetermined width over a substantially half circumference of the disk 2 on the disk insertion / removal port 4 side. As a result, the size in the disc insertion direction D1 is suppressed to reduce the size and weight, and the disc 2 placed as described later is placed from both sides of the disc tray portion 7a at positions substantially orthogonal to the disc insertion direction D1. The thickness direction of the tray 7 includes a resin member 9 as a rising portion formed so as to rise, and a pressing piece portion 11a which is provided on the resin member 9 and supports and presses the disk 2 from the side opposite to the disk tray portion 7a. If the size of the device is reduced and the function of storing it as a tray is realized, but if this structure causes an impact on the entire device It is possible to prevent damage to the disc 2 by the rocking operation of the disc 2.

  The disc tray portion 7a is formed into a desired shape having the above-described notch portion 7b and the like by punching from the material by a so-called punching press. The inclined surface portions 7e and 7f of the guide piece 7c, the inclined surface portion 7g of the second guide piece 7d, and the inclined surface portion 7h provided at the end are formed simultaneously. Therefore, this tray 7 can obtain the effects as described above by forming the inclined surface portions 7e, 7f, 7g, and 7h as described above without increasing the number of manufacturing steps. Here, the predetermined shape and the inclined surfaces are formed by press punching. However, the present invention is not limited to this, and it may be formed by only punching. In addition, the inclined surface portions 7e, 7f, 7g, and 7h described above are inclined as the inclined surface that is the C surface inclined so that the cross section thereof is linear or the R surface that is inclined so as to be curved. It may be a surface or may be formed to be curved.

  The pair of resin members 9 are provided with a pair of through holes 12 that are located on the front side and the back side in the longitudinal direction and penetrate the disc tray portion 7 a and the resin member 9. On the other hand, four guide columns 13 inserted through the through holes 12 are attached to the disk storage portion 3 in a state where the bottom plate 1a and the ceiling plate 1e are connected. The six trays 7 are stacked in a state in which the four guide columns 13 are inserted through the respective through holes 12, and are supported so as to be movable along the guide columns 13.

  Next, the leaf spring 11 used for the trays 7 other than the uppermost stage will be described. The leaf spring 11 used for the uppermost tray 7 and the leaf spring 11 used for the trays 7 other than the uppermost tray have different structures, but the leaf spring 11 used for the uppermost tray 7 is different. Since all the configurations of the leaf springs 11 used for the trays 7 other than the uppermost stage are provided, first, the leaf springs 11 used for the trays other than the uppermost stage will be described with reference to FIG. FIG. 9B shows a leaf spring 11 used for the uppermost tray 7.

  As shown in FIG. 9A, the leaf spring 11 used for the trays 7 other than the uppermost stage has one end portion on the front side in the longitudinal direction as a fixed end, and a disc tray portion 7a on the back side which is a free end. A holding piece 11a for holding the disk 2 formed to protrude toward the loaded disk side is provided. The leaf spring 11 has a bent piece portion 11b serving as a receiving portion pressed downward by a lower surface 53c of a separation cam 53, which will be described later, and a first stage provided on an upper stage of the separation cam 53, which will be described later. And a bent piece portion 11c serving as a receiving portion for receiving an upward force by the lower surface of the fitting portion 55a.

  The structure of the pressing piece portion 11a in the leaf spring 11 will be described. The holding piece 11a is formed to be bent so that the height from the disc tray portion 7a is slightly higher than the other portions, and a hook-like protruding portion that protrudes downward from the portion that contacts the upper surface of the disc 2 11d is formed. When the disc 2 is pushed onto the tray 7, the guide portion 11e is inserted so that the disc 2 is inserted below the presser piece portion 11a. The guide portion 11e rises at an inclined portion inside the presser piece portion 11a. ing. The center of the disk 2 is determined by a pair of positioning portions 9c inside the back surface of the pair of resin members 9 with which the disk 2 abuts. However, for some reason, the back side of the leaf spring 11 is lifted so that the disk 2 is above the resin member 9. The disk 2 can be moved to the back side, and the disk 2 cannot be positioned. For this reason, the back side of the leaf spring 11 is bent downward at the position of the end surface on the back side of the resin member 9 to constitute the auxiliary positioning portion 11f. An abutting portion 11g that abuts against the disc 2 is formed so as to protrude from the auxiliary positioning portion 11f to the back side, and the R portion is configured so that the disc 2 is not damaged by the leaf spring 11. A hook-shaped protrusion 11d formed on the presser piece 11a is provided at a portion that contacts the upper surface of the disk 2 and is formed to sandwich the disk 2 with the disk tray 7a.

  Next, the uppermost tray 7 will be described with reference to FIG. The uppermost tray 7 has the same configuration as that described above except that the configuration described below is different from the above-described second and subsequent trays 7. Therefore, the same reference numerals are used for detailed description. Omitted.

  The pair of resin members 9 of the uppermost tray 7 are located at both ends in the longitudinal direction, that is, further on the front side and the back side of the through holes 12 drilled in the pair of resin members 9, and downward. A substantially cylindrical spring receiving portion 9a is formed so as to protrude. As shown in FIGS. 1, 3 and 11, a coil spring 15 is inserted into the spring receiving portion 9a from the upper end opening, and the coil spring 15 is held inside. An insertion hole 9b through which the guide column 14 is inserted is formed. On the other hand, four guide columns 14 inserted through the spring receiving portions 9a are attached to the disc storage portion 3 in a state where the bottom plate 1a and the ceiling plate 1e are connected.

  The uppermost tray 7 is inserted in a state in which the coil springs 15 protrude from the respective spring receiving portions 9a, and the four guide struts 14 are inserted into the spring receiving portions 9a into which the coil springs 15 are inserted. The coil spring 15 is urged downward along the guide column 14 by the compression of the coil spring 15.

  As shown in FIG. 9B, the plate spring 11 of the uppermost tray 7 carries the upper surface side of the disk 2 placed on the uppermost tray 7 at the end on the disk insertion / removal opening 4 side. A guide portion 11j is provided. The conveyance guide portion 11j is formed integrally with the leaf spring 11 by protruding one side portion of the leaf spring 11 and bending it so as to be slightly higher than the other portions. The transport guide portion 11j functions to guide the movement of the uppermost disc 2 to a position where the tip end side of the uppermost disc 2 inserted into the uppermost tray 7 is pressed by the presser piece portion 11a.

  On the front side of the plate spring 11 of the uppermost tray 7, a through hole 11 k for inserting the guide column 13 penetrates to a position corresponding to the through hole 12 formed in the disk tray portion 7 a and the resin member 9. Is formed.

  Further, as shown in FIG. 3, the disk storage portion 3 is provided with a disk lifting / lowering base 16 positioned below the lowermost tray 7. The disk lift 16 includes a substantially rectangular horizontal plate 16a and vertical plates 16b and 16c bent upward from both side edges of the horizontal plate 16a. On the surface facing the side plates 1b and 1c, a pair of pins 17a and 17b arranged substantially parallel to the main surface of the tray 7 are formed to protrude toward the side plates 1b and 1c, respectively. Further, the disk lift 16 is provided with through-holes 18 located at each corner of the horizontal plate 16a. The disk lifting platform 16 is supported so as to be movable along the guide struts 13 together with the six trays 7 described above by inserting the four guide struts 13 described above into the through holes 18.

  The upper and lower ends of the four guide columns 14 are fixed to the ceiling plate 1e and the bottom plate 1a, and the respective guide columns 14 are inserted into the spring receivers 9a. And the lower end of the coil spring 15 as an urging means provided so as to surround the guide column 14 is in contact with the insertion hole 9b at the lower end of the spring receiver 9a.

  On the other hand, the side plates 1b and 1c are provided with a pair of vertical slits 19a and 19b corresponding to the pair of pins 17a and 17b of the disk lift 16 that moves along the guide columns 13. The disk lifting platform 16 has a pair of pins 17a and 17b inserted through vertical slits 19a and 19b formed in the side plates 1b and 1c so as to protrude outside the casing. Therefore, as the disk lift 16 moves in the vertical direction, the pair of pins 17a and 17b slide in the vertical slits 19a and 19b.

  In this disk storage unit 3, six trays 7 are stacked on the disk lifting platform 16, and coil springs 15 inserted through the four guide columns 14 are arranged on the uppermost tray 7. By being inserted into the spring receiving portion 9a, the disk elevator 16 and the six trays 7 are urged toward the bottom plate 1a.

  As shown in FIGS. 1, 2, and 12, the disk insertion / removal device 5 is disposed on a front plate 1d provided with a disk insertion / removal port 4. FIG. 12 is a perspective view of the main part of the disk insertion / removal device 5 as seen from inside the housing.

  The disk insertion / removal device 5 includes a pair of drive rollers 30 and a driven roller 31 that are disposed to face each other along the disk insertion / removal opening 4. The driven roller 31 is biased toward the driving roller 30. Here, the drive roller 30 is rotationally driven by a drive motor (not shown) and a gear group that transmits the drive force of the drive motor.

  The disk insertion / removal device 5 inserts or ejects the disk 2 through the disk insertion / removal port 4 by rotating the drive roller 30 while sandwiching the disk 2 between the pair of drive rollers 30 and the driven roller 31.

  Further, as shown in FIGS. 2 and 12, the disk insertion / removal device 5 automatically inserts the disk 2 into the housing by a predetermined amount after the disk 2 is inserted by the driving roller 30 and the driven roller 31. A disk push-in mechanism 33 that pushes into the disc is provided.

  The disk pushing mechanism 33 has a pair of vertical rollers 34 orthogonal to the pair of driving rollers 30 and the driven rollers 31 on the back side of the pair of driving rollers 30 and the driven rollers 31. The pair of vertical rollers 34 is rotatably supported by a support shaft 35 via a support member 36.

  The support member 36 is attached to the front plate 1d so as to be movable in the horizontal direction. Further, the support member 36 is provided with a coil spring 37 for urging the pair of vertical rollers 34 in a direction approaching each other, and is urged by the coil spring 37 in a direction approaching each other.

  The support member 36 and the vertical roller 34 are configured so that the disc 7 inserted by the driving roller 30 and the driven roller 31 described above is pushed into the disc storage unit 3 by a predetermined amount from a position where the disc 2 can be inserted by the roller 7. The disk 2 can be placed at an appropriate position above.

  The disk pushing mechanism 33 positions the disk 2 in the insertion / removal direction while the pair of vertical rollers 34 sandwich the disk 2. The disk 2 positioned below the pair of vertical rollers 34 is positioned by a pair of positioning rods 38 erected from the bottom plate 1a. Further, the disk 2 positioned above the pair of vertical rollers 34 is positioned from the ceiling plate 1e and positioned by a pair of positioning rods (not shown) positioned on an extension line of the pair of positioning rods 38. Has been made.

  Further, as shown in FIGS. 1 and 2, the disk insertion / removal device 5 includes a shutter mechanism 39 that opens and closes a disk insertion / removal port 4 provided in the front plate 1d.

  The shutter mechanism 39 has a substantially rectangular shutter 40 in which an opening 40a corresponding to the disk insertion / removal port 4 is formed, and is attached to the front plate 1d in a state where the shutter 40 is movable in the vertical direction. It has been. The shutter mechanism 39 raises the shutter 40 so that the opening 40a of the shutter 40 and the disk insertion / removal port 4 coincide with each other to open the disk insertion / removal port 4 while lowering the shutter 40. Then, the disk insertion / removal port 4 is closed.

  The shutter mechanism 39 includes a left and right slide plate 41 having a substantially L-shaped cross section that is movable in a direction (left and right direction) along the front plate 1d. The left and right slide plate 41 is connected to the bottom plate 1a. It is attached along the edge with the front plate 1d, and is urged in one direction (right side) by a coil spring (not shown).

  A pair of slide pins 42 project from the surface of the left and right slide plate 41 facing the shutter 40, and a pair of cam holes 43 corresponding to the pair of slide pins 42 are formed in the shutter 40 in a predetermined shape. Has been. The left and right slide plates 41 are biased in one direction, and the pair of slide pins 42 are positioned at the right end portion in the cam hole 43. Since the pair of cam holes 43 have a bent shape with the right end positioned above the left end, the shutter 40 is urged downward to close the disc insertion / removal port 4. become.

  Further, as shown in FIGS. 2 and 12, the shutter mechanism 39 includes a front and rear slide plate 46 that is movable in the direction (front-rear direction) along the side plates 1b and 1c on the left end side of the bottom plate 1a. The front / rear slide plate 46 and the left / right slide plate 41 have a substantially L-shaped connection lever 47.

  In the shutter mechanism 39, the front and rear slide plate 46 is slid to the back side as an outer slider 111 (to be described later) slides to the back side, and the left and right slide plates 41 are moved to the left side via the rotating connecting lever 47. By sliding, the shutter 40 is pushed upward to open the disc insertion / removal port 4.

  As shown in FIGS. 2 and 13, the pickup device 6 is mounted on a pickup lifting / lowering base 50 disposed on the back side of the disk storage unit 3. FIG. 13 is a perspective view of the main part showing the appearance of the pickup device 6.

  The pickup lifting / lowering platform 50 is used to move the pickup device 6 up and down, and a horizontal plate 50a and vertical plates 50b and 50c erected from both side edges of the horizontal plate 50a are integrally formed. Yes.

  In the pickup lift 50, a pair of pins 51a and 51b are provided on the vertical plates 50b and 50c, and the pair of pins 51a and 51b slides vertically in the vertical slits 52a and 52b formed in the side plates 1b and 1c. And move vertically.

  Further, the vertical plates 50a and 50b are provided with a pair of separation cams 53 made of resin, located on the surface opposite to the surface facing the side plates 1b and 1c. The pair of separation cams 53 and the vertical plates 50b and 50c have corresponding guide pins and guide grooves, and the separation cams 53 are slidable in the front-rear direction along the vertical plates 50b and 50c.

  As shown in FIGS. 2 and 3, the pair of separation cams 53 slides in the front-rear direction, so that the disc (6) selected from the six trays 7 stacked in the disc storage portion 3 is selected. Hereinafter, a space is formed above and below the selection tray 7 while holding the tray (hereinafter referred to as “selection tray”) 7 on which the “selection disk” 2 is placed.

  As shown in FIGS. 3 and 14, the pair of separation cams 53 is made of a substantially rectangular flat plate member as a whole, and of the pair of pins 10 a and 10 b provided on both sides of the tray 7 described above, the front-side pins. The surface 53a facing the pin 10a has a shape protruding forward from the surface 53b facing the pin 10b on the back side by a distance between the pair of pins 10a and 10b.

  In addition, slits 54 and 55 into which the pair of pins 10a and 10b are inserted are formed on the surfaces 53a and 53b facing the pair of pins 10a and 10b. The slits 54 and 55 are formed between the first insertion portions 54a and 55a and the first insertion portion 54a from an intermediate position of the surfaces 53a and 53b facing the pair of pins 10a and 10b to a midway portion in the longitudinal direction. , 55a and the second insertion portions 54b and 55b positioned below the second insertion portions 54b and 55b and the third insertion portions 54c and 55c positioned below the second insertion portions 54b and 55b. It is missing.

  Further, the surfaces 53a and 53b facing the pair of pins 10a and 10b are inclined surfaces whose lower end portions are positioned forward of the upper end portions. (Hereinafter, the surfaces 53 a and 53 b facing the pair of pins 10 a and 10 b are referred to as “inclined surfaces 53 a and 53 b”.) The inclined surfaces 53 a and 53 b are a pair of pins provided on both sides of the tray 7. 10a, 10b is formed at an angle at which it can be pushed up smoothly.

  Further, the lower surface 53 c of the separation cam 53 can press the tray 7 positioned at the lower stage of the selection tray 7, and the upper surface 53 d can push up the tray 7 positioned at the upper stage of the selection tray 7.

  Further, as shown in FIG. 13, the pickup device 6 includes a pair of chuck levers 59 that are disk holding members that hold the selection disk 2 in a freely rotating manner.

  The pair of chuck levers 59 includes a lower arm 60 and an upper arm 61, and a base end portion is rotatably attached to the pickup lifting / lowering base 50.

  As shown in FIG. 13, a turntable 63 on which the disc 2 is placed on the tip of the lower arm 60 is provided at the tip of the pair of chuck levers 59 to hold the disc 2 rotatably. A spindle motor 64 that rotationally drives the turntable 63 is provided.

  In contrast, a chuck plate 65 that sandwiches the disk 2 together with the turntable 63 described above and a support plate 66 that rotatably supports the outer peripheral edge of the chuck plate 65 are provided at the tip of the upper arm 61. ing.

  In the pickup device 6, the selected disk 2 is rotatably held while the pair of chuck levers 59 is sandwiched, and the spindle motor 64 rotationally drives the disk 2 sandwiched between the pair of chuck levers 59.

  Further, as shown in FIG. 13, the pickup device 6 irradiates the signal recording surface of the disk 2 with the laser beam condensed by the objective lens 67 on the surface facing the upper arm 61 of the lower arm 60. On the other hand, a pickup unit 68 is provided that reproduces a signal by reading the return light reflected and returned from the signal recording surface.

  The pickup unit 68 is movable along the radial direction of the disk 2 by a guide rail 69 formed integrally with the lower arm 60.

  Further, as shown in FIGS. 2 and 12, the pickup device 6 includes a rotating mechanism 70 that rotates the pair of chuck levers 59 by the driving force of the driving motor described above.

  The rotation mechanism 70 includes a slide bar 71 that is driven in the front-rear direction by a drive motor (not shown) and a gear train 75 that transmits the drive force of the drive motor. The rotation mechanism 70 includes a transmission switching mechanism 72 that switches transmission of the driving force of the driving motor to the slide bar 71 by moving the gear train 75. The slide bar 71 is provided with a pin 73, and the lower arm 60 of the pair of chuck levers 59 is provided with a long hole 74 through which the pin 73 is inserted.

  In the rotating mechanism 70, the slide bar 71 is slid in the front-rear direction, whereby the pin 73 engages with the elongated hole 74, and the pair of chuck levers 59 are moved to approximately the diameter of the disk 2 as shown in FIG. 15 is rotated around the support shaft 62 in the direction of arrow R in FIG.

  Further, the pickup device 6 is provided with a pinching switching mechanism 80 for switching the pinching of the pair of chuck levers 59 with respect to the disk 2, and when the pair of chuck levers 59 are rotated to a predetermined position. In addition, the upper arm 61 is set to move up and down with respect to the lower arm 60.

  As shown in FIGS. 13 and 15, the horizontal plate 50 a of the pickup lift 50 is formed between a cylindrical plate 81 formed in a part of a substantially cylindrical shape, and between the cylindrical plate 81 and the separation cam 53. A bearing plate 82 that is substantially parallel to the separation cam 53 and a restraining lever 83 that is attached to a surface of the bearing plate 82 that faces the cylindrical plate 81 are provided. A pin 84 projects from the end of the restraining lever 83 on the side of the separation cam 53 toward the separation cam 53. On the other hand, a cam groove 85 into which the guide pin 84 is inserted is formed on the surface of the separation cam 53 facing the guide pin 84 as shown in FIG.

  Here, while the separation cam 53 holds the selection tray 7, an operation for forming a space above and below the selection tray 7 and the selection disk 2 placed on the selection tray 7 by the sandwiching switching mechanism 80 are paired with a pair of chucks. The operation of holding the lever 59 will be described with reference to FIG.

  Here, the six trays 7 stacked in the disk storage unit 3 are numbered 1 to 6 in order from the top, and the second tray 7 from the top is the selection tray 7. Further, since the pair of pins 10a and 10b are pushed up along the inclined surfaces 53a and 53b of the separation cam 53 by the same operation, the rear side pin 10b is inclined to the rear side of the separation cams 54 and 55. Only the operation of being pushed up along the surface 53b will be described.

  First, at a position A in FIG. 14A, among the six trays 7 stacked in the disc storage portion 3, the inclined surface 53b is formed between the second selected tray 7 and the third tray 7. The height of the separation cam 53 is set in advance so that the lower end portion is located. Then, the separation cam 53 slides in the forward direction and moves to the position B in FIG. Note that the positioning of the separation cam 53 in the height direction is performed by a lifting / lowering operation of a pickup lifting / lowering platform 50 described later.

  Next, when the separation cam 53 moves to the position C in FIG. 14A, the pin 10b of the second selection tray 7 is pushed up to the slit 55 of the separation cam 53 along the inclined surface 53b. Further, the pin 10 b of the third tray 7 slides along the lower surface 53 c of the separation cam 53. As a result, the first tray 7 and the second selection tray 7 rise, and a space is formed between the second selection tray 7 and the third tray 7.

  Next, when the separation cam 53 moves to the position D in FIG. 14A, the pin 10b of the second selection tray 7 slides in the first insertion portion 55a of the slit 55 and the first tray. 7 pin 10 b is pushed up to the upper surface 53 d of the separation cam 53 along the inclined surface 53 b positioned above the slit 55. As a result, a space is formed between the first tray 7 and the second selection tray 7, and sufficient space is formed above and below the selection tray 7 for the pair of chuck levers 59 to enter. .

  Next, when the separation cam 53 moves to the position E in FIG. 14A, the pin 10 b of the first tray 7 slides along the upper surface 53 d of the separation cam 53 and the second selection tray 7. The pin 10b slides in the second insertion portion 55b of the slit 55. As a result, the second selection tray 7 held by the pair of separation cams 53 is lowered, and the selection disk 2 is placed on the turntable 63 of the lower arm 60.

  Next, when the separation cam 53 moves to the position F in FIG. 14A, the pin 10 b of the second tray 7 slides within the third insertion portion 55 c of the slit 55. Accordingly, the second selection tray 7 held by the pair of separation cams 53 is further lowered, and the selection tray 7 and the selection disk 2 placed on the turntable 63 are separated.

  In addition, when the separation cam 53 slides backward, an operation opposite to the above-described operation is performed.

  On the other hand, when the separation switching mechanism 80 moves in the front-rear direction of the separation cam 53, the guide pin 84 slides between the position A and the position D in the cam groove 85 of the separation cam 53 in FIG. A sufficient space is formed between the turn table 63 of the lower arm 60 and the chuck plate 65 of the upper arm 61 to allow the selection tray 7 to pass therethrough.

  The clamping switching mechanism 80 moves upward with respect to the lower arm 60 when the guide pin 84 slides between a position D and a position F in the cam groove 85 of the separation cam 53 in FIG. The arm 61 is lowered, and the center hole 2 a of the selection disk 2 is sandwiched between the turntable 63 of the lower arm 60 and the chuck plate 65 of the upper arm 61.

  The pickup device 6 configured as described above forms not only a disk changer device but also a disk drive device to which the present invention is applied together with the disk storage portion 3 having the tray 7.

  By the way, as shown in FIGS. 13 and 16, the disk insertion / removal device 5 described above removes the disk 2 by a predetermined amount when the disk 2 stored in the disk storage unit 3 is discharged from the disk insertion / removal port 4. A disk push-out mechanism 90 for pushing out toward the disk insertion / removal port 4 is provided.

  Specifically, the disc push-out mechanism 90 is located near both ends on the back side of the disc 2 placed on the tray 7 and is capable of rotating in the in-plane direction of the disc 2. And a pair of push-out plates 92 that rotate the pair of push-out levers 91 about the fixed shaft 93 toward the front side when the separation cam 53 moves to the back side. The pair of extrusion plates 92 are provided with a first bent portion 92a on the front side and a second bent portion 92b on the back side. The pair of push levers 91 is provided with an engaged portion 91a that engages with the first bent portion 92a.

  In this disk push-out mechanism 90, as the separation cam 53 moves to the back side, the separation cam 53 presses the second bent portion 92b of the push plate 92 and slides the push plate 92 to the back side. The first bent portion 92a of the push-out plate 92 presses the engaged portion 91a of the push-out lever 91, and the front end portion of the push-out lever 91 is turned to the front side. 2 is pushed out to the disk insertion / removal port 4 side by a predetermined amount.

  Further, as shown in FIGS. 1 and 2, the apparatus main body 1 includes an operation device 100 for moving the above-described pickup lifting platform 50 up and down and moving the pair of separation cams 53 in the front-rear direction. .

  Specifically, the operating device 100 includes a pair of an inner slider 101 and an outer slider 111 which are located outside the pair of side plates 1b and 1c and are movable in the front-rear direction, and are formed of a substantially rectangular flat plate member. ing.

  The inner slider 101 is formed with a pair of guide holes 102a and 102b through which the guide pins 115a and 115b provided on the side plates 1b and 1c are inserted in the front-rear direction. Further, the inner slider 101 has first slits 103a and 103b through which a pair of pins 51a and 51b provided on the pickup elevator 50 are inserted, and a pair of pins 17a and 17b provided on the disk elevator 16. Second slits 104a and 104b to be inserted are formed.

  The outer slider 111 has a pair of guide holes 112a and 112b through which the guide pins 115a and 115b of the side plates 1b and 1c are inserted, and a slit through which a pair of pins 17a and 17b provided on both sides of the disk lift 16 are inserted. 113a and 113b are formed.

  Further, the outer slider 111 has a first bent portion 111a which is located at an end on the back side and is bent inward, and extends in a vertical direction to the pair of separation cams 53 shown in FIG. Thus, the separation cam 53 can be moved in the front-rear direction and in the vertical direction as the outer slider 111 moves in the front-rear direction.

  Further, as shown in FIG. 2, the outer slider 111 has a second bent portion 111b at the lower end portion on the front side, and is engaged with the above-described front and rear slide plate 46. Then, as the outer slider 111 slides to the back side, the front and rear slide plate 46 is pressed to the back side, which is the direction of the arrow M1 in FIG. 2, and the shutter 40 is moved via the connecting lever 47 and the left and right slide plates 41. The disk insertion / removal port 4 is opened by pushing up in the direction of arrow M4 in FIG. At this time, the connecting lever 47 is rotated in the direction of arrow M2 in FIG. 2, and the left and right slide plates 41 are slid in the direction of arrow M3 in FIG.

  Further, as shown in FIGS. 1 and 2, the operating device 100 includes a slider drive mechanism 117 that slides the inner slider 101 and the outer slider 111 independently in the front-rear direction.

  Next, the overall operation of the disk changer device configured as described above will be described.

  In this disk changer device, any one of the insertion / removal mode for inserting the disk 2 into the disk storage unit 3 or discharging the disk 2 from the disk storage unit 3 and the disk 2 stored in the disk storage unit 3 is selected. There is a playback mode in which playback is performed by selecting a sheet (selected disk 2).

  In the insertion / removal mode, the operating device 100 described above slides the inner slider 101 and the outer slider 111 in the front-rear direction, so that the pair of pins 17a and 17b of the disk lifting / lowering base 16 are moved to the second slits 104a and The operation is set so as to slide in the slits 113a and 113b of 104b and the outer slider 111.

  In this insertion / removal mode, when the disk 2 is inserted into the disk storage unit 3 (for example, when the disk 2 is inserted into the second tray 7), an operation panel (not shown) provided on the front surface of the housing. For example, after pressing the “2” button, the “insert” button is pressed.

  In this case, the inner slider 101 moves backward to push up the pair of pins 17a and 17b to the second step position. As a result, the disk lift 16 is raised, and the second tray 7 is set to a height that substantially coincides with the disk insertion / removal opening 4.

  Next, when the outer slider 111 moves backward, the second bent portion 111 b presses the front and rear slide plate 46 shown in FIG. 2 toward the back side, and the shutter 40 is pushed up via the connecting lever 47. Thereby, the disk insertion / removal port 4 is opened.

  Next, when the disk 2 is inserted from the opened disk insertion / removal opening 4, a sensor (not shown) arranged at the front center of the shutter 40 senses the entry of the disk 2 and is driven by the drive motor of the disk insertion / removal device 5 described above. The roller 30 is rotationally driven in the insertion direction. As a result, the disc 2 sandwiched between the pair of drive rollers 30 and the driven roller 31 is inserted into the disc storage portion 3.

  Here, the disk 2 inserted from the disk insertion / removal port 4 is moved from the position where it can be inserted by the pair of driving rollers 30 and the driven roller 31 to the inside of the disk storage unit 3 by a predetermined amount by the disk pushing mechanism 33 described above. It is pushed. As a result, the disk 2 is placed on the second tray 7 and is held on the tray 7 by the pressing piece 11 a of the leaf spring 11.

  At this time, since the first guide piece 7c is provided in the disc tray portion 7a of the tray 7, the lower surface of the disc 2 inserted by the driving roller 30 and the driven roller 31 and the disc loading of the disc tray portion 7a. Even when the height position with respect to the placement surface is deviated, the disc 2 can be guided by the inclined portions 7e and 7f of the first guide piece 7c and can be securely and smoothly placed on the disc tray portion 7a. It becomes.

  Further, when the disk 2 is separated from the pair of drive rollers 30 and the driven roller 31, a limit switch (not shown) is operated to stop the rotational drive of the drive roller 30, and the outer slider 111 moves forward, so that the second Along with the bent portion 111 b, the front / rear slide plate 46 moves to the front side, and the shutter 40 is pushed down via the connecting lever 47. Thereby, the disk insertion / removal port 4 is closed.

  As described above, the disk 2 can be inserted into the second tray 7. An arbitrary disk 2 can be inserted into the trays 7 other than the second tray 7 by performing the same operation as described above.

  On the other hand, in the insertion / removal mode, when the disk 2 is ejected from the disk storage unit 3 (for example, when the disk 2 is ejected from the second tray 7), an operation (not shown) provided on the front surface of the housing is performed. For example, after pressing the “2” button from the operation buttons on the panel, the “discharge” button is pressed.

  In this case, first, the pair of pins 17 a and 17 b are set to a height that substantially coincides with the disk insertion / removal port 4 by raising the disk lifting platform 16 as the inner slider 101 moves backward. . Then, when the outer slider 111 moves backward, the disk insertion / removal port 4 is opened. The operation as described above is exactly the same as when a disc is inserted.

  Next, when the outer slider 111 moves backward, the separation cam 53 connected to the outer slider 111 moves backward, and the disk push-out mechanism 90 described above pushes the disk 2 toward the disk insertion / removal port 4 side by a predetermined amount.

  Here, the drive roller 30 of the disk insertion / removal device 5 is driven to rotate in the discharge direction at the same time as the “discharge” button is pressed. As a result, the disk 2 sandwiched between the pair of drive rollers 30 and the driven roller 31 is discharged to the outside of the disk storage unit 3. When a part of the back side of the disk 2 is sandwiched between the pair of driving rollers 30 and the driven roller 31, the driving roller 30 is stopped by a limit switch (not shown). Thereby, it is possible to prevent the disk 2 from being dropped when ejected.

  At this time, since the second guide piece 7d is provided at the inner peripheral edge of the disc tray portion 7a of the tray 7, the rib 2b of the inserted disc 2 is formed perpendicular to the disc surface. Even in this case, the rib 2b on the lower surface of the disk 2 can be guided by the inclined surface 7g of the second guide piece 7d, and the disk 2 can be reliably and smoothly ejected.

  Further, since the first guide piece 7c is provided on the disc insertion / removal port 4 side of the disc tray portion 7a of the tray 7, the height of the disc placement surface of the disc tray portion 7a, the driving roller 30 and the driven roller Even when the position where the disk 2 is sandwiched is shifted, the first guide piece 7c is provided with the inclined portions 7e and 7f, so that the disk 2 can be smoothly discharged without being loaded. it can.

  Next, when the disk 2 is manually extracted from the disk insertion / removal opening 4, a sensor (not shown) senses that the disk 2 has been ejected, and the outer slider 111 moves forward to close the disk insertion / removal opening 4.

  As described above, the disk 2 can be ejected from the second tray 7. An arbitrary disk 2 can be ejected to the trays 7 other than the second tray 7 by performing the same operation as described above.

  Here, switching from the insertion / removal mode to the reproduction mode is performed by moving the pair of pins 17a and 17b to predetermined positions in the slits of the inner slider 101 and the outer slider 111 as the outer slider 111 moves forward. Done.

  In the reproduction mode, the disk lift 16 is held at the lowest position. At this time, when the transmission switching mechanism 72 described above is switched, the rotation mechanism 70 can be driven by the drive motor.

  On the other hand, switching from the reproduction mode to the insertion / removal mode is performed by the reverse movement of the pair of pins 17a and 17b as the outer slider 111 moves backward.

  In the reproduction mode, only the inner slider 101 is slid in the front-rear direction with the pair of pins 51 a and 51 b of the pickup elevator 50 being inserted into the slits 103 a and 103 b of the inner slider 101, whereby the pickup elevator 50 Can be moved up and down to an arbitrary height.

  In this playback mode, when playing back the selected disk 2 placed on the selected tray 7 (for example, when playing back the disk 2 placed on the second tray 7), the front of the housing For example, a “2” button is pressed from an operation button (not shown) provided on the operation panel, and then a “play” button is pressed.

  In this case, when the inner slider 101 moves backward, the pair of pins 17a and 17b are pushed up to a predetermined position. As a result, the pickup lift 50 is raised, and the pickup lift 50 is positioned such that the lower end of the inclined surface 53b of the separation cam 53 is positioned between the second selection tray 7 and the third tray 7. The height is set.

  Next, when the outer slider 111 moves forward, the separation cam 53 connected to the outer slider 111 moves forward. Thereby, while the separation cam 53 described above holds the selection tray 7, the pair of chuck levers 59 are rotated in the radial direction of the disk 2 by the operation of forming a space above and below the selection tray 7 and the rotation mechanism 70. The operation and the operation that the pair of chuck levers 59 clamp the center hole 2a of the selection disk 2 placed on the selection tray 7 by the clamping switching mechanism 80 are performed.

  Specifically, when the separation cam 53 moves forward to the positions A to C in FIG. 12, the pins 10a and 10b of the second selection tray 7 are moved along the inclined surfaces 53a and 53b. The slits 54 and 55 are pushed up. Further, the pins 10 a and 10 b of the third tray 7 slide along the lower surface 53 c of the separation cam 53. At this time, the bent piece portions 11b of the plate spring 11 provided on both sides of the third tray 7 are pressed downward by the lower surface 53c of the separation cam 53, and the holding piece portion 11a of the plate spring 11 is pressed by the disc 2. Hold down. As a result, the first tray 7 and the second selection tray 7 rise, and a space is formed between the second selection tray 7 and the third tray 7.

  Next, when the separation cam 53 moves forward to the position D in FIG. 12, the 10a and pin 10b of the second selection tray 7 slide in the first insertion portions 54a and 55a of the slits 54 and 55, and The pins 10 a and 10 b of the first tray 7 are pushed up to the upper surface 53 d of the separation cam 53 along the inclined surfaces 53 a and 53 b positioned above the slits 54 and 55. As a result, a space is formed between the first tray 7 and the second selection tray 7, and sufficient space is formed above and below the selection tray 7 for the pair of chuck levers 59 to enter. .

  The tray 7 positioned at the lower stage of the selection tray 7 is pressed by the lower surface 53c of the separation cam 53, and the tray 7 positioned at the upper stage of the selection tray 7 is moved to the upper surface 53d of the separation cam 53 by the coil spring 15 described above. It is energized. Thereby, it is possible to prevent the tray 7 from being affected by the vibration of the vehicle.

  Further, when the separation cam 53 moves forward to a position D in FIGS. 14A and 14B, a sensor (not shown) detects this, and the drive motor is driven to rotate. Thereby, in the rotation mechanism 70, the slide bar 71 shown in FIG. 2 slides backward, so that the pair of chuck levers 59 changes from the insertion / removal mode position to the reproduction mode position, that is, the center hole of the disk 2. It is rotated in the direction of arrow R in FIG. 15 to the position 2a. Further, when the pair of chuck levers 59 are rotated to the position of the reproduction mode, a limit switch (not shown) stops the rotation drive of the drive motor.

  Next, when the separation cam 53 moves forward to the position E in FIGS. 14A and 14B, the 10a and the pin 10b of the first tray 7 slide along the upper surface 53d of the separation cam 53. At the same time, the pins 10a and 10b of the second selection tray 7 slide in the second fitting portions 54b and 55b of the slits 54 and 55, respectively. As a result, the second selection tray 7 held by the pair of separation cams 53 is lowered, and the selection disk 2 is placed on the turntable 63 of the lower arm 60.

  In synchronization with this, in the clamping switching mechanism 80, the guide pin 84 slides in the cam groove 85 of the separation cam 53, and the upper arm 61 descends with respect to the lower arm 60, and the turntables of these lower arms 60. The center hole 2 a of the selection disk 2 is sandwiched between 63 and the chuck plate 65 of the upper arm 61.

  Next, when the separation cam 53 moves forward to the position F in FIG. 14A, the pins 10a and 10b of the second tray 7 slide in the third insertion portions 54c and 55c of the slits 54 and 55. . Here, as shown in FIG. 17, the bent piece portion 11 b of the leaf spring 11 that presses the selected disk 2 is pushed up by the lower surface of the rear side of the third fitting portions 54 c and 55 c of the slits 54 and 55. Accordingly, the second selection tray 7 held by the pair of separation cams 53 is further lowered, and the selection tray 7 and the selection disk 2 placed on the turntable 63 are separated.

  Then, with respect to the selection disk 2 rotatably held by the pair of chuck levers 59, the signal is reproduced while the optical pickup unit 68 described above moves in the radial direction.

  On the other hand, in the reproduction mode, the operation of returning the pair of pins 17 and 17 to the standby position is performed by a procedure reverse to the procedure described above.

  It is to be noted that any disk 2 can be reproduced by performing the same operation as described above on the disk 2 placed on the tray 7 other than the second tray 7.

  As described above, the disc tray 7 to which the present invention is applied has the disc tray portion 7a that supports the periphery of the disc 2, and the insertion end side of the inserted disc 2 is opened to the disc tray portion 7a. By configuring so that the open portion 7j is formed, it is possible to reduce the size and weight and reduce the material, and at the end of the disc tray portion 7a on the side where the open portion 7j is formed, the inclined surface portion 7h. By providing this, it is possible to prevent the disk 2 from being damaged when the disk 2 is swung due to vibration. Further, the disk tray 7 can reduce the material of the resin layer 8 formed thereon as a buffer material by reducing the area of the mounting surface of the disk tray portion 7a. Simplification is effectively realized.

  As described above, the disk tray 7 to which the present invention is applied achieves a reduction in size and weight, and prevents damage to the disk 2 during vibration.

  Further, as described above, the disc tray 7 to which the present invention is applied has a shape of the disc tray portion 7a for realizing downsizing and preventing damage to the disc 2, and an inclined surface portion formed on the disc tray portion 7a. By simultaneously forming 7h by a punching process such as press punching, the above-described effects can be obtained without complicating the process.

  The disc tray 7 is provided on the disc tray portion 7a on which the disc 2 is placed in substantially the same plane, and is formed so as to protrude toward the side opposite to the disc insertion end side of the inserted disc 2. The first guide piece 7c is formed with inclined surfaces 7e and 7f, and the disc mounting surface of the disc tray portion 7a is used as a protective member except for the first guide piece 7c. By providing the protective layer 8, the protective member prevents damage to the disk 2, and the inclined surface portions 7e and 7f of the first guide piece 7c are used as guides for inserting and discharging the disk 2, Realizes reliable and smooth insertion and ejection of the disc 2.

  As described above, the disc tray 7 prevents the disc from being damaged and enables the disc 2 to be inserted and ejected reliably and smoothly. When used in a disc drive device or a disc changer device, the disc tray 7 has a height from the disc insertion / removal opening. Location management is advantageous.

  Further, the disc tray 7 is provided with a notch portion 7b in the disc tray portion 7a at a position facing the central portion of the disc 2 to be placed, and the end portion of the disc tray portion 7a on the notch portion 7b side, That is, a second guide piece 7d that is formed to protrude in the same plane as the disc tray portion 7a is provided at a position opposite to the first guide piece 7c on the inner peripheral edge, and the second guide piece 7d is provided on the second guide piece 7d. An inclined surface 7g is formed, and a protective layer 8 as a protective member is provided on the disk mounting surface of the disk tray portion 7a except for the first and second guide pieces 7c and 7d, so that the protective member This prevents the disk 2 from being damaged and makes the inclined surface portion 7g of the second guide piece 7d a guide when the disk is ejected, regardless of the shape of the rib 2b protruding below the disk 2. And guide ribs 2b, to achieve a reliable and smooth discharge.

  In addition, the disk drive device to which the present invention is applied has a plurality of disk trays on which a plurality of disks 2 are respectively mounted, a disk storage unit 3 in which the plurality of disks 2 are stored, and the disk storage unit 3 A pickup device 6 is provided as a recording and / or reproducing unit for recording and / or reproducing a signal with respect to the stored disk 2, and the above-described disk tray 7 is used as this disk tray, thereby damaging the disk 2. In addition to preventing it, it will be smaller and lighter.

  In the disc changer device to which the present invention is applied, the disc changer device has a plurality of disc trays on which a plurality of discs 2 are respectively mounted. A disk selecting means for selecting any one of a plurality of disks 2 to be recorded, and a recording and / or reproducing section for recording and / or reproducing a signal with respect to the disk 2 selected by the disk selecting means By using the above-described disk tray 7 as the disk tray, the disk 2 can be prevented from being damaged and reduced in size and weight.

  The present invention is not limited to the purpose of reproducing audio, such as the above-described disk changer device, and can be applied to an apparatus that records audio and an apparatus that records and / or reproduces video. It is.

It is a perspective view which shows the external appearance of the apparatus main body of the disc changer apparatus to which this invention is applied. It is a disassembled perspective view which shows the internal structure of the apparatus main body of a disk changer apparatus. It is a disassembled perspective view which shows the structure of a disk storage part. It is a top view which shows disk trays other than the uppermost stage of the disk tray which comprises a disk changer apparatus. FIG. 5 is a cross-sectional view of the disc tray taken along the line X-X ′ shown in FIG. 4. When the disc is inserted into the disc tray, the height of the disc is corrected when the height of the disc placement surface of the disc tray is shifted from the lower surface of the disc. It is sectional drawing. It is a figure for demonstrating the function of the 2nd guide piece when a disk is discharged | emitted from a disk tray, (a) is sectional drawing which shows the disk tray to which this invention is applied, (b) It is sectional drawing which shows the disk tray of the comparative example for comparing with this. It is a figure for demonstrating the function of the inclined surface part formed in the edge part by which the open part of the disk tray was formed, (a) is sectional drawing which shows the disk tray to which this invention is applied, b) is a cross-sectional view showing a disc tray of a comparative example for comparison with this. It is a figure which shows the structure of the leaf | plate spring provided in the disc tray, (a) is a perspective view which shows the leaf | plate spring provided in disc trays other than the uppermost stage, (b) is a top disc tray. It is a perspective view which shows the leaf | plate spring provided. It is a top view which shows the disk tray of the uppermost stage in the disk tray which comprises the disk changer apparatus to which this invention is applied. It is a principal part perspective view which fractures | ruptures and shows a part of uppermost tray. It is the principal part perspective view which looked at the disk insertion / extraction apparatus from the inside of a housing | casing. It is a perspective view which shows the external appearance of a pick-up apparatus. It is a figure which shows the structure of a division | segmentation cam, (a) is a side view for demonstrating the operation | movement which forms space above and below the selection tray, (b) is for demonstrating the operation | movement of a clamping switching mechanism. It is a side view. It is a figure for demonstrating the state which switches to a reproduction | regeneration mode from the insertion / removal mode of a pair of chuck lever, and is a top view which shows a pair of chuck lever in insertion / removal mode. It is a plan view showing a disk extrusion mechanism, It is a see-through | perspective side view which shows the state which the division | segmentation cam moved to the position of F. It is a perspective view which shows the conventional disc changer apparatus.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 apparatus main body, 2 disk, 3 disk storage part, 4 disk insertion / removal opening, 5 disk insertion / removal apparatus, 6 pick-up apparatus, 7 disk tray, 7a disk tray part, 7c 1st guide piece, 7d 2nd guide piece, 7e, 7f inclined surface portion, 7g inclined surface portion, 7h inclined surface portion, 8 resin layer, 9 resin member, 10a, 10b pin, 11 leaf spring, 11a holding piece portion, 11b bent piece portion, 11c bent piece portion, 11d Projecting portion, 11e guide portion, 12 through-hole, 13, 14 guide post, 15 coil spring, 16 disc lifting platform, 30 driving roller, 31 driven roller

Claims (7)

The disc-shaped recording medium is inserted from a direction parallel to the signal recording surface of the disc-shaped recording medium, and has a disc tray portion that supports the periphery of the disc-shaped recording medium,
The disc tray portion is formed with an open portion that opens the insertion end side of the disc-shaped recording medium inserted into the disc tray portion, and the disc-like shape is formed at the end portion on the side where the open portion is formed. A disc tray having an inclined surface portion inclined toward a direction away from a recording medium.   2. The disc tray according to claim 1, wherein a plurality of the disc tray portions are provided in a direction perpendicular to the signal recording surface of the disc-shaped recording medium.   2. The disc tray according to claim 1, wherein the disc tray portion is formed into a predetermined shape by punching, and at the same time, the inclined surface portion is formed.   A rising portion that is formed to rise from a mounting surface on which the disc-shaped recording medium is mounted at both ends of the disk tray portion at positions substantially orthogonal to the disk insertion direction, and the mounting surface provided on the rising portion. The disc tray according to claim 1, further comprising a pressing piece for pressing the disc-shaped recording medium from the opposite side.   2. The disc tray according to claim 1, wherein the disc tray portion is formed with a predetermined width over at least a substantially half circumference of the peripheral portion of the disc-shaped recording medium opposite to the insertion end. A disk storage unit having a plurality of disk trays on which a plurality of disk-shaped recording media are respectively mounted;
A recording and / or reproducing unit for recording and / or reproducing a signal with respect to a disk-shaped recording medium stored in the disk storage unit,
The disc tray has a disc tray portion into which the disc-shaped recording medium is inserted from a direction parallel to the signal recording surface of the disc-shaped recording medium and supports the periphery of the disc-shaped recording medium,
The disc tray portion is formed with an open portion that opens the insertion end side of the disc-shaped recording medium inserted into the disc tray portion, and the disc-like shape is formed at the end portion on the side where the open portion is formed. A disk drive device in which an inclined surface portion inclined toward a direction away from a recording medium is formed. A disk storage unit having a plurality of disk trays on which a plurality of disk-shaped recording media are respectively mounted;
A disk selection means for selecting any one of the plurality of disk-shaped recording media stored in the disk storage section;
A recording and / or reproducing unit for recording and / or reproducing a signal with respect to the disk-shaped recording medium selected by the disk selecting means,
The disc tray has a disc tray portion into which the disc-shaped recording medium is inserted from a direction parallel to the signal recording surface of the disc-shaped recording medium and supports the periphery of the disc-shaped recording medium,
The disc tray portion is formed with an open portion that opens the insertion end side of the disc-shaped recording medium inserted into the disc tray portion, and the disc-like shape is formed at the end portion on the side where the open portion is formed. A disk changer device in which an inclined surface portion inclined toward a direction away from a recording medium is formed.

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