JP2005135508A - Disk device having a clamp mechanism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a disk device for preventing generation of noise by a boss which is moved in a cam groove when clamping or unclamping is performed, in the disk device having a clamp mechanism which is elevated to clamp a disk mounted on a turntable, by loosely fitting the boss provided on the tip of a traverse unit into the cam groove of a slide cam and by sliding the slide cam. <P>SOLUTION: A slit groove 33 is formed in the axial direction in the boss 29 to divide it into a plurality of boss pieces 34a and 34b, and the impact generated when the boss 29 is moved in the cam groove 30 is reduced. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a disc device characterized by a clamp mechanism that prevents noise from being generated when a disc carried into a reproduction position is mounted and clamped on a turntable, and conversely, when the clamp is released. .

  The disc placed on the tray moves to the reproduction position as the tray is carried in, and the traverse unit is raised here so that the disc is mounted on the turntable and then clamped. On the other hand, when the reproduced disc is taken out, the disc mounted on the traverse unit descends is placed on the tray and carried out together with the tray.

  FIG. 10 shows a cross-sectional view of the side surface of the disk device. In FIG. 10A, the traverse unit 2 is lowered obliquely with the tray 1 being carried out. Therefore, if a disk is placed on the tray 1 and carried into the apparatus, the traverse unit 2 is raised and the disk is mounted on the turntable 3 and is sandwiched and clamped by the clamper 4.

  A boss 5 is provided at the tip of the traverse unit 2, and the boss 5 is fitted in the cam groove 7 of the slide cam 6. When the slide cam 6 slides left and right (in FIG. 10, it slides in the depth direction). The traverse unit 2 can be moved up and down. FIG. 11 is a schematic view showing a case where the tip boss 5 of the traverse unit 2 is fitted in the cam groove 7 on the slide cam 6. In the cam groove 7, both horizontal grooves are formed continuously with the inclined groove. Therefore, if the slide cam 6 slides to the left and right, the boss 5 can move up and down and the traverse unit 2 can move up and down.

  When the slide cam 6 slides and the boss 5 passes between the inclined groove and the horizontal groove, noise is generated by an impact. Since this noise is heard by a person who operates the disk device, it becomes annoying. This is a noise that must be eliminated, especially for high-end disk devices.

  In the “disk device” according to Japanese Patent Application Laid-Open No. 2003-223762, a movable body that is guided by a cam groove of a cam plate disposed at a position facing the free end of the drive chassis and is moved up and down is made of a second vibration-proof rubber. The free end of the drive chassis is connected via a buffer. In other words, a shaft body, which is a hollow cylindrical cap-type synthetic resin molded body, is externally fitted to a protrusion projecting at the center in the width direction of the free end of the drive chassis. The joined cylindrical second buffer is interposed in a press-fitted state. The shaft body is held by the protrusion in a non-contact state with respect to the protrusion and the free end of the drive chassis via the second buffer body.

When the shaft body fits into the cam groove and the slide cam slides, the drive chassis moves up and down. At this time, the second buffer body is compressed and deformed to reduce the impact, and the generation of noise based on the impact can be suppressed. . However, the cost becomes high by making the form of the boss into such a complicated structure.
“Disk device” according to Japanese Patent Application Laid-Open No. 2003-223776

  As described above, the boss loosely fitted in the cam groove of the slide cam in order to move the traverse unit up and down has the above-described problems. The problem to be solved by the present invention is this problem, and provides a disk device having a very simple structure and capable of mounting and clamping the disk by moving the traverse unit up and down without causing noise.

  The basic structure of the disk apparatus of the present invention is the same as that of the prior art, and the traverse unit is raised in order to mount the disk carried into the apparatus on the turntable. A slide cam is provided as an elevating means of the traverse unit, a boss protruding from the tip of the traverse unit is loosely fitted in the cam groove of the slide cam, and a slit groove is formed in the boss and divided into a plurality of boss pieces. It is easy to bend.

  Therefore, the boss piece is bent and deformed with respect to the impact, and the impact force can be reduced. Here, the width and length of the slit groove are arbitrary, and the direction and number of the slit grooves with respect to the boss are not limited. Sometimes it is possible to increase the length of the boss piece by forming a recess in the holder surface at the tip of the traverse unit and raising the boss from the bottom of the recess, which can further promote the bending deformation of the boss piece. .

  The clamp mechanism of the disc device according to the present invention is provided with a plurality of boss pieces by forming slit grooves in the tip boss of the traverse unit. Therefore, the boss loosely fitted in the cam groove of the slide cam is bent and deformed as the slide cam slides, and the impact is alleviated. Therefore, the generation of noise due to the impact is prevented, and the disc clamping operation and the unclamping operation performed by the raising and lowering of the traverse unit are performed gently.

  The slit groove of the boss is integrally formed with the holder of the traverse unit, and there is almost no burden of manufacturing cost compared to the boss without the slit groove, and is adopted in the “disc device” according to Japanese Patent Laid-Open No. 2003-22376. The production is simple compared to the boss. On the other hand, when forming a boss having a slit groove, the slit groove can be formed by modifying a conventional mold, and it is not necessary to manufacture a new mold.

  FIG. 1 is an external view showing a disk device. A tray 11 for loading and unloading the disc is projected at the center of the front, and is provided with a plurality of push buttons 12a, 12b,. Here, the functions of the push buttons 12a, 12b,... Are not particularly limited. For example, in the case of a disk device, 12a is a playback button, 12b is a fast forward button, 12c is a fast reverse button, 12d is a skip button, and 12e. Can function as a tray open button.

  The push buttons 12a, 12b,... Can be arranged freely and are designed as one of the appearance elements of the front panel. Here, a decorative plate 13 is attached to the front surface of the disk device, and this decorative plate 13 has the same size as the cabinet 14 as shown in FIG. The design improves the front design of the device.

  FIG. 2 is a plan view showing the internal structure of the disk device of the present invention, and shows a state in which the tray 11 is open. A circular shallow groove is formed on the upper surface of the tray 11, and a disk is set in the groove. A tray rack 15 is provided on the lower surface side in the front-rear direction, and a substantially L-shaped tray guide groove 16 is provided along the tray rack 15. A tray opening / closing gear 17 meshes with the tray rack 15, and a cam rod boss 18 is loosely fitted into the tray guide groove 16.

  The tray opening / closing gear 17 is rotationally driven by a feed motor 19, and the tray opening / closing gear 17 rotates to retract and close the tray rack 15 and the tray 11. The tray 11 is opened and closed by moving forward and backward a predetermined distance. The substantially L-shaped tray guide groove 16 is in parallel with the vertical guide groove 20 and the tray rack 15 that are parallel to the tray rack 15. The vertical guide groove 21 includes a vertical guide groove 21 and a corner guide groove 22 formed between the vertical guide groove 20 and the horizontal guide groove 21. Further, the rear end portion of the vertical guide groove 20 extends in a curved manner.

  Therefore, when the tray 11 moves forward to open, the tray 11 stops when the cam rod boss 18 loosely fitted in the vertical guide groove 20 reaches the curved portion 23. When the tray 11 moves backward to close, the cam rod boss 18 loosely fitted in the vertical guide groove 20 reaches the corner guide groove 22 to stop the tray 11. That is, the cam rod boss 18 moves along the tray guide groove 16, and the slide cam 24 also moves along the tray guide groove 16.

  FIG. 3 shows a state in which the tray 11 is retracted and closed, and the cam rod boss 18 is positioned in the corner guide groove 22 of the tray guide groove 16. Accordingly, the slide cam 24 moves to the right, and the tray opening / closing gear 17 removed from the tray rack 15 meshes with the slide cam rack 25 provided at one end of the slide cam 24. If the tray opening / closing gear 17 continues to rotate, the cam rod boss 18 slides along the lateral guide groove 21 to send the slide cam rack 25 to the right and the slide cam 24 to move to the right.

  4 and 5 show the relationship between the slide cam 24 and the traverse unit 28. FIG. FIG. 5A shows the case where the traverse unit 28 is raised, the disk is mounted on the turntable and is in a clamped state, and FIG. 5B shows the case where the traverse unit 28 is lowered and the tray 11 is carried out. is there.

  By the way, the slide cam 24 can be slid in the lateral direction by the rotation of the tray opening / closing gear 17 meshing with the slide cam rack 25. The boss 29 moves up and down along the cam groove provided in the slide cam 24, and the traverse unit 28 can be moved up and down. A cam rod boss 18 projects upward, and has a slide cam rack 25 at one end. The cam groove is formed with a step in the vertical plane.

  FIG. 6 is a schematic view of the slide cam 24. The slide cam 24 is formed with a cam groove 30. Horizontal grooves 32a and 32b are continuously formed at both ends of the inclined groove 31, and provided at the tip of the traverse unit 28. The boss 29 is loosely fitted in the cam groove 30, and the boss 29 can move up and down as the slide cam 24 slides.

  By the way, as shown in (b) of the enlarged sectional view of the boss 29, the slit groove 33 is horizontally cut and divided into boss pieces 34a and 34b. Therefore, when the slide cam 24 slides, the boss 29 moves in the cam groove 30. When the boss 29 reaches the boundary between the inclined groove 31 and the horizontal grooves 32a and 32b, the thin boss pieces 34a and 34b are bent and deformed. The shock is relieved. And generation | occurrence | production of the noise accompanying an impact can be suppressed.

  FIG. 7 shows the relationship between the amount of deformation of the boss 29 and the load. (a) is the conventional boss | hub, (b) represents the case of the boss | hub 29 which provided the slit groove | channel 33 as shown in FIG. As described above, by providing the slit groove 33, the amount of bending deformation of the boss is large in a region where a low load is applied, and generation of abnormal noise can be prevented by appropriately deforming when the cam groove 30 is moved.

  In the region where the impact acts, the slit groove 33 is closed by the bending deformation of one boss piece 34a, and can be brought into contact with the other boss piece 34b to be bent and deformed together. Therefore, the strength is the same as the conventional boss without the slit groove 33. As described above, by providing the slit groove 33 in the boss 29, it is possible to have both “a region where bending is easy” and “a region where strength is high”. In the curve (b) of the figure, point A is the case where one boss piece 34a is deformed and abuts against the other boss piece 34b, and thereafter the load is caused by deformation of both boss pieces 34a and 34b. Get up big.

  FIG. 8 shows another embodiment of the boss 29, in which a recess 35 is formed at the base of the boss 29 and extends from the bottom of the recess. Accordingly, the length of the boss 29 is increased, and the boss 29 is easily bent and deformed correspondingly. That is, in order to reduce the size of the disk device, when the protrusion length of the boss 29 from the front end surface 36 is restricted, the concave portion 35 is formed on the front end surface 36 and the boss 29 is raised from the bottom of the concave portion. I can do it.

  Here, the slit groove 33 shown in the embodiment forms a horizontal plane, but it can be freely changed to an appropriate direction according to the shape of the cam groove 30. In addition, it is possible to divide into four boss pieces by forming two slit grooves.

  FIG. 9 shows a disc clamping mechanism in which slit grooves are formed in the boss, and shows another structure of FIG. A cam groove 30 is formed in the slide cam 24, and horizontal grooves 32 a and 32 b are continuously formed at both ends of the inclined groove 31. A boss 29 provided at the tip of the traverse unit 28 is loosely fitted in the cam groove 30. The point that the boss 29 can be moved up and down with the sliding movement of the slide cam 24 is the same as in the above embodiment.

  By the way, as shown in the enlarged cross-sectional view of the boss 29 in (b), the slit grooves 37a, 37b, 37c are cut perpendicular to the protruding direction and divided into boss pieces 38a, 38b, 38c. . Accordingly, when the slide cam 24 slides, the boss 29 moves in the cam groove 30. However, when the boss 29 reaches the boundary between the inclined groove 31 and the horizontal grooves 32a, 32b, the boss pieces 38a, 38b, 38c are bent and deformed. Shock is reduced. And generation | occurrence | production of the noise accompanying an impact can be suppressed.

  That is, by providing the slit grooves 37a, 37b, and 37c, the amount of bending deformation of the boss is large in a region where a low load is applied, and generation of abnormal noise can be prevented by appropriately deforming when the cam groove 30 is moved. In the region where the impact acts, the slit grooves 37a, 37c, or 37b are blocked by the bending deformation of the boss 29, and can withstand a large load.

FIG. The internal structure figure of a disk apparatus. The internal structure figure of the disc apparatus at the time of retreating a tray. The relationship between the traverse unit and slide cam. The relationship between the traverse unit and slide cam. A disc clamp mechanism with slit grooves in the boss. Boss deflection curve. Other specific bodies of bosses with slit grooves. Another disc clamping mechanism with slit grooves in the boss. Sectional drawing of a disc apparatus. Conventional disc clamp mechanism.

Explanation of symbols

11 Tray
12 Push button
13 veneer
14 Cabinet
15 Tray rack
16 Tray guide groove
17 Tray opening / closing gear
18 Cam rod boss
19 Feed motor
20 Vertical guide groove
21 Horizontal guide groove
22 Corner guide groove
23 Curved section
24 Slide cam
25 Slide cam rack
28 Traverse unit
29 Boss
30 Cam groove
31 Inclined groove
32 Horizontal groove
33 Slit groove
34 Boss pieces
35 recess
36 Tip surface
37 Slit groove
38 Boss pieces

Claims (7)

In the disc device provided with a clamp mechanism for loosely fitting a boss provided at the tip of the traverse unit into the cam groove of the slide cam, and ascending by sliding the slide cam to clamp the disc mounted on the turntable, the boss A disk device provided with a clamp mechanism characterized in that a slit groove is formed on the disk. 2. A disk device provided with a clamp mechanism according to claim 1, wherein the slit groove is formed in the axial direction of the protruding boss. 2. A disk device having a clamp mechanism according to claim 1, wherein the slit groove is formed perpendicular to the axial direction of the protruding boss. 2. A disk device comprising a clamp mechanism according to claim 1, wherein a plurality of the slit grooves are formed alternately and perpendicularly to the axial direction of the protruding boss. 2. A disk device having a clamp mechanism according to claim 1, wherein a plurality of slit grooves are formed on the same side perpendicular to the axial direction of the protruding boss. 6. A disk device comprising the clamp mechanism according to claim 1, 2, 3, 4, or 5, wherein the outer shape of the boss is a substantially cylindrical shape or a substantially spherical shape. The clamp mechanism according to claim 1, 2, 3, 4, 5, or 6, wherein a recess is provided on a front end surface of the traverse unit in which the boss extends, and the boss extends from the bottom of the recess. Provided disk unit.

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