KR100201638B1 - Disc holding device - Google Patents

Abstract

The present invention relates to a disk loading apparatus for reducing the number of operations for a disk loading by increasing the disk holding permissible area in relation to the disk size in a loading apparatus and a boss coupled to the disk loading plate And a disc holding portion for holding a disc contact portion between the upper holder and the lower holder. The disk holding portion comprises a lower holder for holding the disc, a lower holder for holding the upper holder and a lower portion of the lower holder.

Description

Disk holding device

One of the oldest technologies of disk loading devices is to put the disc on the tray and move it to the destination while playing the prepared tray.

There are a tray drive unit and a pickup drive unit for loading / unloading a disc. Each drive unit has an interlocking relationship that controls the position of the disc in accordance with the selection mode. In the case of loading, It is known that there is not a big malfunction such as a deviation from the path even when it is removed. Therefore, the possibility of damage or jamming of the disk is mechanically managed by the tray.

However, in order to load / unload the disc, the operation of the tray must precede the operation of the tray. In case of loading the disc, the tray is taken out, then the tray is loaded thereon and then the tray is loaded again. And thus unnecessary operations are repeated.

The disc ejecting structure disclosed in U.S. Patent No. 5,136,570 has a structure in which a transverse roller 2 is provided in the interior of the interior disc housing 1 as shown in Figs. 1 and 2, A plurality of detecting elements 4 (4a) for sensing the position are accommodated from a disk having a large radius to a disk having a small radius.

The apparatus compensates for the disadvantages of using a disk loading apparatus that uses a tray for loading / unloading a disk.

That is, when the disc 3 is pushed into the prepared disc port 5 without depending on a member such as a tray, the disc 3 is moved to the destination and landed on the turntable 6 as it is.

Even in the case of unloading, the ejection of the disk is advanced by the ejector of the disk guide mechanism part 7, and the disk is ejected by the rotational friction of the transverse roller 2 at the next time.

However, this device is adapted to utilize the frictional force of the transporter 2 at any time in the loading / unloading mode of transporting the disk 3, so that the disk 3 ) There are disadvantages.

Another "disk loading device" of U.S. Patent No. 5,255,255 is similar to the direct loading method of pushing the disk 3 into the disk port 5, which is a feature of the roller method, and the disk loading method.

4 is a direct disk loading apparatus in which disk loading rollers 8 and 8a have a predetermined moving area from the inside of the disk housing 1 and are dependent on the position of the disk 3, The main part includes left and right rollers 8 and 8a which come into close contact with the side surface of the disc 3 and guide rails 9 for guiding the movement of the rollers 8 and 8a. Left and right symmetrical drive gear groups 11 and 11a meshed with a plurality of gears to rotate the rollers 8 and 8a by the rotational force of the loading motor 10, And controls the loading motor 10. [0050]

The disc loading in the apparatus detects the position of the disc 3 when the disc 3 is inserted and transmits the detected position to the control unit. The control unit controls the loading motor 10 to determine the rotating direction of the rollers 8 and 8a, The loading motor 10 is stopped in the previous step.

Unloading is performed such that when the driving signal is inputted to the loading motor 10, the loading motor is rotated in the direction opposite to the loading direction, and the interlocking gears are extended in both directions and the rollers 8, The disc 3 is released by the rotational friction of the rollers 9 and 9a.

Here, the positions of the rollers 8 and 8a vary depending on the size and position of the disc 3 along the rails 9 and 9a.

Therefore, even in this case, it is possible to load the disc 3 without any other transportation mechanism necessary for loading the disc, but there is a disadvantage that the wear of the roller is repeatedly used for repeated use of the disc.

The disk loading apparatus shown in FIGS. 5 and 6 has a special type of holding apparatuses 20L and 20R for holding disks on both sides of the disk 21 to load the disks.

In carrying the disc 3, the apparatus is mounted on a moving plate 23 that slides through the holding devices 20L and 20R without moving the disc by surface contact of a friction member such as a roller to move the disc Such as damage to the disc or inability of the disc to be transported due to wear of the roller.

In this apparatus, the disk 3 is held in a precise state so as to prevent the disk from slipping or floating in the moving plate 23 by providing a certain amount of adhering force to the disk through the holder without giving any special frictional force to the disk 3, And how the holder can be held with respect to a disc having a variable width of the holder and thus a receiving area of the disc size is set to a predetermined size so that the disc is out of the disc fixing area by the holder This is a problem.

[Object of the invention]

The present invention increases the disk holding allowable area in relation to the disk size in a loading device for reducing the number of operations for disk loading, and keeps the fixing state of the disk properly.

The present invention relates to a disc holding apparatus that can stably maintain pick-up centering after completing loading while supporting disc size defects exceeding a prescribed size in a disc loading apparatus that does not use a tray.

FIG. 1 (a) shows a conventional disk ejecting apparatus, and FIG. 1 (b) shows a disk loading progress.

FIG. 2 shows a disk ejecting apparatus of FIG. 1; FIG.

FIG. 3 is a view showing another example of another conventional loading apparatus.

4 shows a disc loading device of Fig. 3; Fig.

FIG. 5 shows an interior housing of another disc loading apparatus, wherein (a) is an external view and (b) is a sectional view.

FIG. 6 shows a configuration example of a loading device of FIG. 5; FIG.

7 (a), 7 (b), and 7 (c) illustrate an example of a disc holding apparatus according to the present invention.

Fig. 8 is a plan view showing a structure of an upper holder according to the present invention. Fig. 8 (a) is a plan view and Fig. 8 (b) is a side view of Fig.

9A is a plan view of a lower holder according to the present invention. FIG. 9A is a plan view and FIG. 9B is a sectional view taken along line A-A of FIG.

FIG. 10 is a partial sectional view of FIGS. 8 and 9; FIG.

FIG. 11 shows another embodiment of the present invention. FIG.

DESCRIPTION OF THE REFERENCE NUMERALS

1: Disk housing 5: Disk port

20L, 20R: holding device 21: base plate

22L, 22R: Indian groove 23L, 23R: Loading plate

24: Boss 25: Upper holder

26: Lower holder 27:

28: tongue piece 29: elastic action space

30: flow space 31: elastic member

32: Boss guide home

The disk holding apparatus of the present invention is divided into parts in the disk loading apparatus as in the seventh aspect and is mounted on both side faces of the disk port 5 of the loading plates 23L and 23R carrying the disk 3 on the base plate 21 Respectively.

The main parts of the holding devices 20L and 20R include an upper holder 25 having a boss 24 to be coupled to the loading plates 23L and 23R as shown in Figs. 8 and 9, A lower holder 26 for forming a disk guiding groove 22L by mating the upper holder 25 through a guide groove 32 fitted to the upper boss 25 and the lower holder 25, And a disk-shaped elastic portion 27 for urging the side contact surface of the disk,

The disk lobe portion 27 forms a resilient force action space 29 for forming a resilient force piece 28 about the resilient piece 28 while forming the resilient piece 28 in the molding step on the upper holder 25 side And the side of the lower holder 26 secures the flow space 30 at a position corresponding to the upper end 25 of the upper holder 25 so as to guide the flange 28. [

The disk chest portion 27 is constituted by providing a resilient member 31 made of a permanent material on the inner side surface of the lead groove 22L formed between the upper holder 25 and the lower holder 26 as shown in FIG. do.

In the position setting step of the holding device, the above-mentioned elastic portion 27 is adjusted to a condition for maintaining the contact relation with the side surface of the disk 3 by making the reference disk size smaller than the reference disk size width.

The disk holding device having the elastic portion 27 is symmetrically installed on the left and right sides, and can be installed on one side.

The disk holding apparatus of the present invention corresponds to the rigid disk holding apparatus having the loading plates 23L and 23R as shown in FIG.

The role of the holding devices 20L and 20R in the presence of the moving plates 23L and 23R is to move the disc 3 through the disc port 5 and to move the disc 3 In a stable state.

Therefore, in the disc loading apparatus having the loading plates 23L, 23R, the holding apparatus guides and loads the disc 3, and at the time of ejecting, the disc is held again and is sent out.

The holding device applied to this type of disk loading device is not adapted to accommodate disks of all sizes and is adapted to hold only prescribed disks.

For example, when the standard disk size is 120 mm, the widths of the two side holders are set to be about 120 mm and the both sides of the disk 3 are guided to the loading plates 23L and 23R in a holding state.

If the disc size is out of the standard, the disc will be poorly held. For example, if the disc size is too small to hold the disc, the disc will flow. If the disc size is too large, disc holding is difficult.

Also, even in the case of a size conforming to the standard, there is a disk flow in the process of loading the loading plates 23L and 23R.

The disc holding apparatus according to the present invention is capable of disc holding with respect to the disc 3 passing through the disc port 5.

The disc holding apparatus of the present invention as shown in FIGS. 8 and 9 has a disc guide groove 22L formed by separating the upper and lower holders 25 and 26 into the form of a tenth form, So as to guide both sides of the disc 3 in a resilient manner through the elastic portion 27. [

When the disc 3 passes through the disc port 5 on the side of the disc housing 1 and reaches the holding devices 20L and 20R, the disc 3 is guided to the disc guiding grooves 22L and 22R, The elastic piece 28 formed on the disc 3 is pushed in the horizontal direction outside the elastic force action space 29 at the moment when it comes into contact with the side surface of the disc 3 and keeps the side surface of the disc 3 in close contact.

At this time, the elastic piece 28, which is deformed in the horizontal direction through the elastic action space 29, is guided to the flow space 30 on the side of the lower holder 26.

The pressing force of the disk side surface by the flange portion 28 immediately suppresses lifting or flow of the disk and induces a correct movement of the disk. The torsion force of the disk side surface can be provided at the same time in the left / right direction, It is possible to offer it from one side alternatively.

For example, one of the holders is provided with the lug portion 27 and the other lug is not provided with a lug portion, so that the lug is held in a form in which the lug is not in the side having the lug portion.

The above disk holding apparatus is applicable to the case where the elastic portion of the material is formed by using the elastic displacement of the material during the molding of the upper holder 25 and the lower holder 26. However, It is possible to obtain an equivalent tooth surface structure of the disc by inserting and inserting the disc 31.

When the standard disk size is 120 mm in the disk holding apparatus of the present invention, the left / right width of the holding devices 20L and 20R needs to be set smaller than 120 mm.

This is to provide a resilient holding state with respect to the disc not exceeding 120 mm. If the disc exceeds 120 mm, the disc side surface can push the elastic part laterally and insert the disc when passing through the disc, When the width of the holding devices 20L and 20R is matched to 120 mm, there is no obstacle to the loading, which helps to compensate for the fact that elastic holding is impossible for smaller size discs.

Thus, the disc holding apparatus of the present invention provides a resilience to the side surface of the disc so as to catch the flow generated in the disc moving step, and the disc can not be held due to the disc size defect.

The present invention provides a disc loading apparatus that can vary the storage width of the disc on the side of the holding device in accordance with the actual size of the disc, thereby enlarging the storage area for defective disc size, It is possible to accurately induce the centering of the picture after the completion of loading.

Claims (5)

A lower holder which is fitted to the upper holder side boss to form a disk guiding groove and a disk ridge portion which rides on the side contact surface of the disk guided between the upper holder and the lower holder, Wherein the disk holding device comprises: 2. The disc holding apparatus according to claim 1, wherein the disc-like portion comprises an elastic piece formed in an upper holder-side forming step and a resilient force action space for guiding displacement of the elastic piece about the elastic piece. The disc holding apparatus according to claim 1, wherein the lower holder side has a fluid space for guiding the elastic piece at a position corresponding to the upper holder side resilient piece. 2. The disk holding apparatus according to claim 1, wherein the disk-shaped portion is provided with an elastic member on the inner surface of the guide groove formed between the upper holder and the lower holder. The disc holding apparatus according to claim 1, wherein a disc width of the holding apparatus having the elastic member is set to be smaller than a reference disc size width.