JPH04195854A - Disk loading device - Google Patents

Abstract

PURPOSE:To prevent the surface of a disk from being flawed by providing roller rotation driving mechanisms, a roller transfer mechanism which positions rollers near to and apart from the disk, a disk guide mechanism, and eject mechanisms. CONSTITUTION:The rollers 28, 29 are brought into proximity to the supplied disk 32 by the roller transfer mechanism and the rollers come into contact with the outer peripheral surface of the disk. Since the rollers 28, 29 rotate, the disk 32 is transferred in the prescribed direction by the rotational driving force thereof. The outer peripheral surface of the disk 32 is pressed and the disk is ejected by the eject mechanisms 46, 47 coupled to the rotation driving mechanisms of the rollers 28, 29 when the reproducing of the disk 32 ends. Disk loading is executed by driving the outer peripheral surface of the disk 32 without allowing the rollers, etc., to come into contact with the surface of the disk 32 in such a manner and the disk is ejected by pressing its outer peripheral surface with pins 48, 49. The surface of the disk 32 is prevented from flawing in this way.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a disc loading device used in compact disc players and the like.

BACKGROUND ART FIGS. 8 and 9 show a conventional disk loading mechanism. In Fig. S and Fig. 9, 50° 51 is a rubber roller arranged in parallel;
By rotating the disk 51 with the rotational driving force of a motor, the disk 52 was transferred in the direction of the arrow.

However, in the above conventional example, the rubber rollers 50, 51
Since the disc 52 is brought into contact with the surface of the disc 52 for D-ding, there is some slippage that may damage the disc surface during disc loading.

The present invention solves the above conventional problems and provides a disc loading device that does not damage the surface of the disc.

Means for Solving the Problems In order to achieve the above object, the present invention provides a roller rotation drive mechanism that rotates a roller, a roller movement mechanism that moves the roller toward and away from the disk transport direction, and a roller rotation drive mechanism that rotates the roller, a roller movement mechanism that moves the roller toward and away from the disk transport direction, and The present invention is characterized by comprising a disc guide mechanism for guiding the disc along the disc, and an eject mechanism connectable to the roller rotation drive mechanism.

Operation The present invention has the above-described configuration, and the roller moves closer to the supplied disk by the roller moving mechanism, and the roller comes into contact with the outer peripheral surface of the disk. Since the rollers are rotating, the disk is transported in a predetermined direction by the rotational driving force of the rollers. Further, when the playback of the disc is completed, the outer circumferential surface of the disc is pushed by an eject mechanism coupled to the roller rotation drive mechanism, and the disc is ejected.

Embodiment FIG. 1 shows a disk loading device in one embodiment of the present invention. In FIG. 1, 1 is a board, in which an arc-shaped kite hole 2°3 is formed. 4 is a reversible motor attached to the back of the board 1, and 5 is a motor 4. 6 is a helical gear rotatably supported on the base plate 1 and meshes with the worm gear 5; 7 and 8 are floats rotatably supported on the base plate; The gear 7.8 meshes with the small gear portion 6a of the helical gear 6. 9 is the base plate 1
The gear 9 is rotatably supported by the gear 9, and the gear 9 meshes with the gear 8. ], 0.1.1 are gears rotatably supported on the substrate 1, and the gears 10.1.1 mesh with the gears 7.9, respectively. 12.13 is axis 1 on board 1
4. Arm rotatably supported in 15, 1G, 1
7 is the shaft 14. , 1.5, and this clutch gear 16.17 meshes with the pinion portion 102.11a of the gear 10.11. 18.19 connects the clutch gear 16.17 to the above 7'-
12. Spring that presses on 13 (see Figure 2)
, 20, 21. ．． 22 is a gear rotatably supported by the arm 12, 23, 24.25 is a gear rotatably supported by the arm 13, and 26.27 is a gear rotatably supported by the arm 12.13. Rubber rollers 28, 29 are attached to one end of the gears 26, 27. The rubber rollers 28, 29 pass through the kite holes 2.3 of the substrate 1 and protrude from the top surface of the substrate 1. 4.0 and 4.1 are gears rotatably supported on the substrate 1;
0,411i7-412.1.3 rotate and are farthest from each other, gear 21. ．． It meshes with 24. 42.43 is a clutch gear rotatably supported on a shaft 44.45;
6.47 is an eject arm 4G that rotates around a shaft 44.4.5.

At the tip of 47 are provided bins 48, 4.9.

The clutch gears 42, 43 are pressed against the eject arm 46, 47 by an elastic body such as a spring.

Figure YS2 shows the clutch gear 16 portion. In FIG. 2, 12 is an arm rotatably supported on the substrate 1 by a shaft 14, 36 is a resin plate attached to the arm 12, and a cylindrical shaft 37 is integrally formed in the center of this resin plate 36. ing. 38 is a ring-shaped felt; 16 is a clutch gear rotatably supported on the cylindrical shaft 37;
18 is a spring; 39 is a ring-shaped retaining plate fixed to the end of the cylindrical shaft 37; the spring 18 is interposed between the retaining plate 39 and the clutch gear 16; The clutch gear 16 is pressed by the spring 18, and a felt 38 is held between the clutch gear 16 and the resin plate 36.

In FIG. 1, the rotational driving force of the motor 4 is as follows: worm gear 5 → helical gear 6 → gear 7 → gear 10 → gear 16 →
Rubber roller 28 via gear 20 → gear 21 → gear 22
is transmitted to the gear 26 equipped with
The rotational driving force of
Gear 7 - Gear 10 - Gear 16 → Seedling wheel 20 - Tooth pattern 2l-a
It is transmitted to the clutch gear 42 via the l wheel 40. Further, the rotational driving force of the motor 4 is as follows: worm m115 - helical gear 6 = r & tun 8 - gear 9 -> gear 11 - gear] 7 -
Rubber roller 2 via gear 23-l village wheel 24-gear 25
The rotational driving force of the motor 4 is transmitted to the gear 27 equipped with a worm gear 5, a helical gear 6, and a rubber roller 29 to rotate the rubber roller 29 counterclockwise or clockwise.
It is transmitted to the clutch gear 43 via gear 8 - gear 9 - gear 11 - gear 17 → gear 23 - gear 24 - gear 41. Reference numeral 30 denotes an optical sensor for detecting insertion of a disc, and the output of the sensor 30 is sent to a control circuit 31. When the optical sensor 30 detects the insertion of a disc, the control circuit 31 causes the motor 4 to rotate.

Next, the operation of the above embodiment will be explained. FIG. 3 shows a state in which a large diameter disk (12 cm CD) 32 is inserted through the disk insertion hole. When the insertion of the disk 32 is detected by the optical sensor 30, the control circuit 31 starts the motor 4.
starts rotating in the first rotation direction. The rotational driving force of this motor 4 is as follows: worm gear 5 - helical gear 6 -> gear 7
→Gear 10 = Gear 16 - Gear 20 → Gear 21 → Gear 22
is transmitted to the gear 26 equipped with the rubber roller 28, and rotates the rubber roller 28 clockwise.
Arm 12 rotates clockwise about shaft 14.

Further, the rotational driving force of the motor 4 is transmitted to the gear 27 equipped with a rubber roller 29 via the worm gear 5 - helical gear 6 = gear 8 -> gear 9 -> gear 11 - 4 - gear 17 - gear 23 -> gear 24 -> gear 25. This is transmitted and rotates the rubber roller 29 counterclockwise, and the arm 13 rotates counterclockwise about the shaft 15. When the motor 4 rotates in the first rotational direction in this manner, the arms 12.13 rotate toward each other, and the rubber rollers 28.
29 rotate in opposite directions. Due to the rotation of the arm 12.13, the rotating rubber rollers 28.29 come into contact with the outer peripheral surface of the inserted disk 32 and move the disk 32 in the direction of the arrow ()'. FIG. 4 shows the state immediately before the loading in the arrow (Y) direction is completed. When the disk 32 is transferred to a predetermined position by the loading mechanism, the power to the motor 4 is cut off, the rotation of the arms 1, 2, and 130 is stopped, and the rubber roller 2
8 and 29 also stop rotating. Note that when the disk 32 is transferred to a predetermined position, the disk 32 is clamped to the turntable by the clamp mechanism, the disk 32 is rotationally driven, and the playback operation fT is started. When the eject switch is operated in the disc playback state shown in FIG. 4, the motor 4 begins to rotate in the opposite direction. For this reason, the arms 12.1.3 pivot about the axes 14-, 15 in directions away from each other. When the arms 12.13 reach the ends of the guide holes 2, 3, the gears 21.+24 are replaced by the gears 40. /11 meshes. Therefore, the rotational driving force of the motor 4 is transmitted to the gear 40.41 via the gear 21.24, and further transmitted to the clutch gear 42.43, the tarlatch gear 42 rotates counterclockwise, and the clutch gear 43
rotates clockwise. As the clutch gear 4-2, 43 rotates, the eject arm 46 rotates counterclockwise about the shaft 44, and the eject arm 47 rotates clockwise about the shaft 45. Therefore, the pins 48.4-9 provided at the tips of the ejecting arms 46, 47 push the disk 32, and the disk 32
is ejected toward the disc insertion slot.

5 and 6 show the case where a small diameter disk (8 cm CD) 33 is inserted. When a small-diameter disk 33 is inserted into the disk insertion slot, the optical sensor 30 detects the disk 3.
3 is detected, the motor 4 starts rotating in the first rotation direction by the control circuit 31, and the small diameter disk 33 is moved in the direction of the arrow ()" by an operation similar to the movement of the large diameter disk 32. When the large-diameter disk 32 and the small-diameter disk 33 (! It is only necessary to change the stop position at which the transfer of the disk in the arrow (Y) direction is stopped based on the diameter determination result.The operation for ejecting the small diameter disk 33 is the same as the ejecting operation for the large diameter disk described above. It is.

In addition, in the two-legged embodiment, even if a large-diameter disk or a small-diameter disk is not inserted at the center of the disk insertion slot, but is inserted toward the left or right side of the disk insertion slot,
The disk can be moved in the direction of the center line by rotating the arm and rotating the rubber roller.

In this embodiment, as in the case of the disk 32, 3
3, the outer circumferential surface of the disk is driven without contacting the surface of the disk with rollers, etc. to load the disk, and pins 48 and 49 are used to press the outer circumferential surface of the disk to eject the disk, so the surface of the disk is not scratched. can be prevented.

In the above embodiment, two sets of mechanisms operate symmetrically with respect to the center line, but as shown in FIG. Arm 12
．． Rubber roller 28. Gear 40. Clutch gear 42. It is also possible to remove the eject arm 46 etc. and use only one mechanism to load and eject the disc; in this case, the disc is mounted on the guide surface 35.
transported along.

Effects of the Invention The present invention has the above-described configuration, and according to the present invention, since loading and ejecting are performed using only the outer peripheral surface of the disk, there is no possibility of scratches on the surface of the disk during disk loading and ejecting operations. This has the advantage that there is no need to attach it. Furthermore, since the present invention performs the ejecting operation using a part of the loading mechanism, the ejecting mechanism can be particularly simplified.

[Brief explanation of the drawing]

Fig. 1 is a top view of a disk loading device according to an embodiment of the present invention, Fig. 2 is a side view of the clutch gear portion of the same device, Figs. 3 to 6 are explanatory diagrams of the operation of the device, and Fig. 7 9 is a top view of another embodiment of the present invention, FIG. 8 is a top view of a conventional disk loading device, and FIG. 9 is a front view of the same device. DESCRIPTION OF SYMBOLS 1... Board, 2.3... Guide hole, 4... Motor, 5... Worm gear, 6... Helical gear, 7,
8,9,10.1.1...gear,]2,13...arm, 14. ．． 1.5...Shaft, 16.17...Clutch gear, 18.19...Spring, 20.21,
22, 23, 24, 25, 26° 27...gear, 28
．． 29... Rubber roller, 30... Optical sensor, 31.
...Control circuit, 32, 33...Disk, 34...
Gear, 35... Guide surface, 36... Resin plate, 37.
... Cylindrical shaft, 38 ... Felt, 39 ... Retention plate, 4.0.41 ... Gear, 42.43 ... Clutch gear, 44.45 ... Shaft, 46.47. ...Eject arm, 4, 8, 4.9...pin. Name of agent: Patent attorney Akira Okaji and two others Figure 1
. r-1--'-, -1111--11--11--Fig. 3 Fig. 4! Figure 6! / Figure 7/'

Claims (6)

[Claims] (1) a roller rotation drive mechanism that rotates a roller; a roller movement mechanism that moves the roller toward and away from the disk in the disk transfer direction; and a disk guide mechanism that guides the disk along the disk transfer direction; an eject mechanism connectable to the roller rotation drive mechanism, the outer peripheral surface of the disk is brought into contact with the roller and the disk guide mechanism, the disk is transferred by the rotational driving force of the roller, and the ejection mechanism transports the disk. A disc loading device characterized by ejecting. (2) The disk loading device according to claim 1, wherein the roller moving mechanism and the ejecting mechanism are driven by the rotational driving force of the roller rotation driving mechanism that rotates the roller. (3) an arm rotatably supported; a clutch gear coaxially supported with the rotation axis of the arm; a motor mechanism for rotationally driving the clutch gear; and a rotational driving force for the clutch gear. 2. The disk loading device according to claim 1, further comprising a rotational driving force transmission mechanism that transmits a rotational driving force to the roller supported by the arm, forming a roller rotational driving mechanism and a roller moving mechanism. (4) A roller rotation drive mechanism that rotates a pair of rollers in opposite directions, a roller movement mechanism that moves the pair of rollers toward and away from each other, and an ejection mechanism that moves a pair of ejection arms toward and away from each other. A disk loading device, characterized in that the roller is brought into contact with the outer circumferential surface of the disk, the disk is transferred by the rotational driving force of the roller, and the ejecting arm pushes the outer circumferential surface of the disk to eject the disk. (5) a pair of rotatably supported arms, a pair of clutch gears supported coaxially with the rotation axis of the arms, a motor mechanism for rotationally driving the pair of clutch gears, and each of the above 5. The disk according to claim 4, wherein the roller rotation drive mechanism and the roller movement mechanism are constituted by a pair of rotation drive force transmission mechanisms that transmit the rotation drive force of the clutch gear to each roller supported by each of the arms. Loading device. (6) a pair of gears that can mesh with the roller rotation drive mechanism; a pair of eject arms rotatably supported;
2. The disk loading device according to claim 1, wherein the eject mechanism includes a pair of clutch gears supported coaxially with the rotating shaft of the eject arm and meshing with the gear.