DE19543943A1 - Optical disc and carrier e.g. for computers - Google Patents

Abstract

An optical disc carrier includes a lower tray (8) having a first opening (10), an upper tray (30) fixed on the lower tray, at a position corresp. to this first opening, and a second opening (20). A slider (22) is movably located in the lower tray and upper tray, and a seal or lock (4) is provided on the slider (22) for locking this first opening and second opening open. A spring (26) is pretensioned in its normal direction to close the lock. A movable tray (32) is hinged, onto the upper tray (30), so that it can swivel about an axis parallel to one direction of movement of the slider (22).

Description

Background of the Invention Field of application of the invention

The present invention relates to a carrier ger for an optical disc. The one in this description The term "optical disk" used also includes magneto-optical disc.

Description of the related technology

An optical disk is considered a kind of external Storage device used for a computer. In particular In particular, a compact drive for mag is spreading neto-optical disks for operating a magneto-optical 3.5 inch disk very quickly as a storage device for a personal computer, because of interchangeability ability, portability and manageable size of the magne to-optical disc. The 3.5-inch magneto-optical Disk has a storage capacity as a single disk of 230 megabytes, and this storage capacity is sufficient for handling code data. Furthermore, this food is sufficient capacity for handling multimedia such as images data and moving images, so that for the magneto-optical Plate is believed to continue in the future will spread.

The magneto-optical disc is in a carrier (a cassette), which is essentially the same Size is like a microdisk cassette, made by ih  number has increased significantly; the thickness of the beam for a magneto-optical disc, however, is approximately 6 mm, twice as much as that of the microdisk cartridge. The carrier serves to protect the magneto-optical disk from dirt such as dust or fingerprints. In contrast to A compact disc (CD) can be the magneto-optical disc Record data, and it's against dirt when you turn it on write more sensitive than when reading. For this reason the magneto-optical disc is stored in the carrier.

The magneto-optical disc is a writable and readable memory and can also be used as a mass ver medium. The use of the magne to-optical disk as a mass distribution medium he can be sufficient by using a so-called partial ROMs, so that information can be prepackaged as a well Part of a data area of the magneto-optical disk be drawn. Such a partial ROM can be trained by training of a substrate for an optical disk very often be copied. The optical partial ROM disk is in the Carrier spent and assembled so that a complete tige cassette for an optical disc is present.

When spreading such an opti stored in the carrier partial ROM disk is a disadvantage in that the volume of the carrier is large because its thickness, like mentioned above is about 6 mm. Furthermore, the Aktua the old op table top with the previous version usually discarded together with their associated carrier, whose Weight 80% of the total weight of the cassette for an opti plate. This is uneconomical and also from Viewpoint of environmental protection undesirable. The carrier  is usually made up of an upper shell and a lower one Shell built up. Before delivery from the factory the optical plate is placed in these trays, and the Shells are then assembled using screws, so that the complete cassette for an optical disc is present. There are other parts in the carrier like a spring contain. Accordingly, such a support structure for disassembling the carrier to replace the opti unsuitable plate.

A carrier for an optical disk is for taking out an opti hard to disassemble. If that comes out would be possible to take the optical disk out of the carrier, the optical disk could be transported alone. However, it is only when the optical disc ends by Post possible that the optical disk is damaged, and because of a protruding hub in the middle of the optical disc is formed. For example it is when sending the optical put in an envelope Disk possible that the optical disk is deformed if many letters or the like stacked over the optical disc are.

Summary of the invention

Therefore, there is an object of the present invention therein, a support for an optical disk with a sol Chen structure to create an optical disc from the Carrier can be removed as desired as well as a To provide transport carriers for an optical disc, which is a deformation of an optical disk and its damage  in another way when transporting the optical disc alone through the post or the like.

According to one aspect of the present Er Invention is provided a support for an optical disc, with a lower shell that has a first opening, with an upper shell that bears on the lower shell and in a position that is essentially the same some of the first opening corresponds to a second opening has, with a slide that in the lower shell and the upper shell is slidably attached to one the slide fastened closure to close the read the first opening and the second opening transmitter way, with a spring for pretensioning in normal direction direction of the closure in its closing direction, with a movable shell, which pivots on the upper shell bar is attached so that it is parallel to one Swivel the slider direction of the slider axis bar, and with fasteners for releasable fastening movement of the movable shell on the lower shell.

The pivot axis of the movable shell is preferred from a lateral centerline of the wearer towards offset the first and second openings.

In accordance with another aspect of the present invention is a transport carrier for a optical disc for use in transporting a optical disc with a central circular hub provided of a plate with a central hole on it points that for this circular hub of the optical disc fits exactly, the plate has a thickness which is essentially same size as or greater than a height of this  Is hub and has an outer dimension that is the same size like or larger than an outer diameter of the optical Plate is.

The plate preferably has a plurality of Slits that are so educated around the central hole det are that they are in a circumferential direction of the central Hole are spaced apart. Furthermore, the Plate has a substantially rectangular outer shape. Except the plate has a portion of it that has a data record richly corresponds to the optical disc, a flat recess tion.

Since the movable shell with respect to the lower shell le can be opened, the optical plate can easily be removed from the support for an optical disk. The circular hub of the optical disk also engages when transporting the from the carrier for an optical disc removed optical plate in the central hole of the trans port carrier for an optical disc, which makes the on occur during deformation or the like of the optical disk transport is avoided.

The above and other goals, characteristics and Advantages and the way in which it is achieved the, will become clearer and the invention itself on can be best understood by reading the following the description and appended claims, namely under Reference to the accompanying drawings, the preferred Show embodiments of the invention.

Brief description of the drawings

Fig. 1 is a perspective view of a handy herkömm carriers for an optical disc;

Fig. 2 is an exploded perspective view of the conventional optical disk support shown in Fig. 1;

Fig. 3 is a perspective view of an optical disc carrier according to a first embodiment of the present invention;

Fig. 4 is an exploded perspective view of the optical disk support shown in Fig. 3;

Fig. 5 is a perspective view of an optical disc carrier in the state where a movable shell is removed;

Fig. 6 is an exploded side view of a link portion of the optical disk support;

Fig. 7 is a plan view showing a link portion u of the movable shell;

Fig. 8 is a perspective view showing fastening means for the movable shell;

Fig. 9 is a cross-sectional view of the fasteners shown in Fig. 8;

Fig. 10 is a perspective view of the first preferred embodiment, and shows a state in which an optical disc is being inserted into the optical disc carrier;

Fig. 11 is a perspective view showing an optical disk transport bracket according to a second preferred embodiment of the present invention;

Fig. 12 is a perspective view showing an optical disk transport bracket according to a third preferred embodiment of the present invention;

Fig. 13 is a cross-sectional view showing a transport carrier for an optical disk according to a fourth preferred embodiment of the present invention;

Fig. 14 is a perspective view showing an optical disk transport bracket according to a fifth preferred embodiment of the present invention; and Fig. 15 is a cross-sectional view showing an optical disk transport bracket according to the fifth preferred embodiment of the present invention.

Detailed description of the preferred embodiments

To further explain the subject matter of the present invention, the structure of a conventional optical disk support (cassette for an optical disk) 2 will now be explained with reference to FIGS. 1 and 2. The carrier for an optical disc 2 comprises a lower shell 8 and an upper shell 18 . The lower shell 8 has a first opening 10 and a flat recess 12 with a shape which essentially corresponds to the shape of an optical plate mounted in the carrier 2 .

The upper shell 18 has a second opening 20 which is smaller than the first opening 10 , and a section 6 , to which a mark is to be made. A closure 4 has a first section 4 a for closing the first opening 10 in an open manner and a second section 4 b, which is formed in one piece with the first section 4 a, for closing the second opening 20 in an open manner . The closure 4 is fastened to a slide 22 by means of screws 24 . The lower shell 8 is attached to the upper shell 18 by a plurality of screws 28 . The slide 22 is slidably mounted in the assembly from the lower shell 8 and the upper shell 18 . When the slider 22 is shifted to open or close accordingly the slider 22 fixed to the shutter 4, the first opening 10 and second opening 20th

The closure 4 is biased in the normal direction, in a Rich direction for closing the first opening 10 and the second opening 20 , by means of a spring 26 which is mounted in the assembly of the lower shell 8 and upper shell 18 . The reference number 16 designates write protection. The write protection 16 is designed for closing an opening 14 which extends through the lower shell 8 through, so that renewed writing to the optical disk can be prevented when the opening 14 is closed by the write protection 16 .

In the case of a carrier for a magneto-optical disk, the first opening 10 is provided to allow a hub of a magneto-optical disk to engage a turntable of a disk drive and a laser beam coming from an optical pickup a surface of the magneto-optical disk can be blasted while the second opening is intended to allow a bias field to act on an opposite surface of the disk. A structure or arrangement of a typical magnetic-optical disk drive is well known in the art and is described, for example, in Japanese Patent Laid-Open No. 7-210878.

FIGS. 3 and 4 show respectively a perspective view and an exploded perspective view to a first preferred embodiment of the constricting vorlie invention. In the following description of the first preferred embodiment, basically the same as the parts shown in FIGS . 1 and 2 are given the same reference numerals, and the description thereof is omitted to avoid repetition.

A movable shell 32 is so pivotally attached to an upper shell 30 with a second opening 20 that it is pivotable about an axis which runs parallel to the sliding direction of a slide 22 . The pivot axis of the movable shell 32 is offset in relation to a lateral center line of a carrier 2 A in the direction of the second opening 20 , so that it is ensured that a wide opening is determined by opening the movable shell 32 in relation to a lower shell 8 . An optical disk 34 is mounted 2 A prior to shipment from the factory in the carrier. This means that the lower shell 8 is fixed to the upper shell 30 by means of several screws 28 , with the optical plate 34 being inserted between them.

Fig. 5 shows a perspective view of the first preferred embodiment in the state where the movable shell 32 is removed, and Fig. 6 is an exploded side view of one of two linkage portions between the movable shell 32 and the upper shell 30th A pair of supports 36 are pivotally mounted on both side portions of the upper shell 30 . Each support 36 has a round through hole 38 a and an elongated through hole 38 b, which merges into the round through hole 38 a. On the other hand, as shown in FIGS . 6 and 7, the movable shell 32 is integrally formed with a pair of engaging protrusions 40 (one of which is shown). Each engaging projection 40 has a flat neck 40 a and a circular head 40 b, which is formed at the inner end of the flat neck 40 a. When attaching the movable tray 32 on the upper shell 30 of each engaging projection is first 40 of the be moveable shell 32 is inserted into the round through hole 38 a of the associated support 36 of the upper shell 30, from the outside of the support 36, and then the neck 40 a of the engaging projection 40 is pushed into the elongated through hole 38 b of the support 36 . Accordingly, the movable shell 32 is attached to the pair of posts 36 of the upper shell 30 . Since the supports 36 are pivotally mounted on the upper shell 30 , the movable shell 32 is pivotally attached to the upper shell 30 .

With respect to FIGS. 8 and 9, there is shown a preferred embodiment of fastening means for the movable tray 32. The lower shell 8 is integrally formed with an upward projection 42 , while the movable shell 32 is also integrally formed with a downward projection 44 which is in a position corresponding to that of the upward projection 42 of the lower shell 8 .

This means that the upward projection 42 of the lower shell 8 is such that it is in a releasable grip between the downward projection 44 and a side wall 32 a of the movable shell 32 comes. Consequently, the movable shell 32 is releasably attached to the lower shell 8 .

Fig. 10 shows a state in which the optical disk 34 is inserted straight into the carrier 2a. Since the movable tray can be opened wide with respect to the lower shell 8 32, the optical disk 34 can be easily inserted into the carrier A 2 or A 2 are removed from the carrier. Furthermore, the flat shape of the lower shell 8 simplifies the insertion or removal of the optical plate 34 into or out of the carrier 2 A. If an optical fixed value plate is used as the optical plate 34 , the opening 14 (see FIG. 4) the lower shell 8 closed from the start, as shown by the reference number 17 on. In this case, therefore, write protection is not required, which reduces the number of parts.

As described above, allows the use of support 2 A according to the first preferred execution form a simple removal of the optical disk 34 from the support 2 A. Accordingly, the optical disc 34 can be transported alone. When mailing the optical disk 34 alone, however, it is possible that the optical disk 34 will be damaged because a circular hub, which is formed in the central region of the optical disk 34 , protrudes from the disk surface. It is also possible while sending ge in an envelope packed optical disk 34 such that the opti cal plate 34 is bent due to their projecting hub when many programs are above the befindli surfaces in envelope optical disk 34th

To solve such problems, it is preferable to use a carrier as described below. Fig. 11 shows a preferred embodiment of the transport carrier in accordance with the present invention. As shown in Fig. 11, the transport carrier is designed as a plate 46 with a circular hole 47 which has an inner diameter which is substantially equal to the outer diameter of the circular hub 34 a of the optical plate 34 . The plate 46 is formed of paper, plastic, etc. During transport of the optical disk 34, the hub is spent 34 a of the optical disk 34 in the hole 47 of the carrier 46, whereby deformation of the optical disk is avoided rule 34th It is at least required to make the thickness of the carrier 46 equal to or larger than the height of the hub 34 a, but from the standpoint of economy, the thickness of the carrier 46 is preferably made substantially equal to the height of the hub 34 a . Moreover, it is necessary to make the outer dimension of the support 46 is greater than the outer diameter of the optical rule plate 34 o so as to damage the optical disc 34 by friction. Ä. Avoided.

The outer shape of the carrier 46 is preferably quite angular, so that a possible slipping of the carrier 46 in the circumferential direction of the optical disc 34 , which is contained in an envelope or the like, can be prevented, which also prevents damage by friction or the like.

Fig. 12 shows another preferred embodiment of the transport carrier. As shown in Fig. 12, a plurality of radially extending slots 48 are formed around the circular hole 47 of the carrier 46 A in such a manner that they are uniformly spaced from each other in the circumferential direction of the hole 47 . The formation of the slots 48 ge allows a simple deformation of the peripheral portion around the hole 47 of the carrier 46 A around. Thus, 46 A, the opti cal plate may be fixedly attached to the support 34.

Fig. 13 shows another preferred embodiment of the transport carrier. As shown in Fig. 13, an annular flat recess 49 is formed on the upper surface of a carrier 46 B at a portion thereof associated with a data area of the optical disk 34 , so that the data surface is damaged of the optical disc 34 is avoided even if a force is applied to the optical disc 34 .

FIGS. 14 and 15 again show another before ferred embodiment of the transport carrier. As shown in FIGS. 14 and 15, a carrier 46 C a sol chen raised portion 50, that the outer periphery of the optical disc is enclosed 34th The height of the raised portion 50 is preferably equal to or larger than the thickness of the optical disk 34 , thereby protecting the optical disk 34 more effectively. In addition, the thickness of the carrier 46 C as a whole can be increased in order to protect it even more effectively by the optical plate 34 . Although the raised portion 50 is formed so that it completely encloses the outer periphery of the optical plate 34 , it can also be formed from parts consisting only at the four corners of the carrier 46 C, whereby a similar effect is achieved.

According to the present invention, the optical Disk from the carrier for an optical disk as ge wishes to be taken out. Accordingly, the optical disc alone transported by post or the like without being bulky. A Verfor or other damage to the optical disk their transport by post or the like through use of the transport carrier according to the invention can be prevented.

Claims (9)

1. Carrier for an optical disk
with a lower shell ( 8 ) which has a first opening ( 10 ),
with an upper shell ( 30 ) which is fastened to this lower shell ( 8 ) and at a position which speaks essentially to that of this first opening ( 10 ), has a second opening ( 20 ),
with a slide ( 22 ) which is slidably mounted in this lower shell ( 8 ) and upper shell ( 30 ),
with a closure ( 4 ) fastened to this slide ( 22 ) for closing this first opening ( 10 ) and this second opening ( 20 ) in an open manner,
with a spring ( 26 ) for pretensioning in the normal direction of this closure ( 4 ) in its closing direction,
with a movable shell ( 32 ) which is pivotably attached to this upper shell ( 30 ) in such a way that it can be pivoted about an axis running parallel to a sliding direction of this slide ( 22 ),
and with fastening means for detachably fastening this movable shell ( 32 ) to this lower shell ( 8 )

• 2. Carrier for an optical disk according to claim 1, in which said pivot axis is offset to this movable tray (32) from a lateral center line of this support (2 A) voltage towards said first opening (10) and this second Publ (20) .

3. An optical disc carrier according to claim 1 or 2, wherein said fastening means comprises a snap fastening with a first fastening element ( 42 ) which is formed on an inner surface of this lower shell ( 8 ) and a second fastening element ( 44 ), which is formed on an inner surface of this movable shell ( 32 ). 4. Carrier for an optical disc according to one of claims 1 to 3, in which this carrier is designed for an optical disc ( 2 A) for receiving a magneto-optical disc. 5. Transport carrier for an optical disk for use when transporting an optical disk with a central circular hub, which is a plate ( 46 , 46 A, 46 B, 46 C) with a central hole ( 47 ) for this circular hub ( 34 a) this optical plate ( 34 ) fits exactly, this plate ( 46 , 46 A, 46 B, 46 C) has a thickness which is essentially the same size as or greater than a height of this hub ( 34 a ), and has an outer dimension that is equal to or larger than an outer diameter of this optical disc ( 34 ). 6. Transport carrier for an optical disc according to claim 5, in which this plate ( 46 , 46 A, 46 B, 46 C) has a plurality of slots ( 48 ) which are formed around this central hole ( 47 ) so that they are spaced apart in a circumferential direction of this central hole ( 47 ). 7. Transport carrier for an optical disc according to claim 5 or 6, in which this plate ( 46 , 46 A, 46 B, 46 C) has a substantially rectangular outer shape. 8. Transport carrier for an optical disk according to one of claims 5 to 7, in which this disk ( 46 , 46 A, 46 B, 46 C) at a portion which is assigned to a data area of this optical table ( 34 ), a flat Has recess ( 49 ). 9. Transport carrier for an optical disc according to one of claims 5 to 8, wherein said plate ( 46 , 46 A, 46 B, 46 C) outside of an outer periphery of this optical plate te ( 34 ) has a raised portion ( 50 ) with a Has height that is equal to or greater than a thickness of the water optical plate ( 34 ). 10. A method of using an optical disk having a circular hub at a central portion of the optical disk, comprising the steps of:
Holding this optical disk by inserting the circular hub into the central hole of this optical disk transport carrier according to claim 5 when the optical disk is being transported, and
Storing this optical disk in this optical disk carrier according to claim 1 when this optical disk is loaded in an optical disk drive.