JP3659118B2 - Disc storage case - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a case for storing a disk-shaped disk for recording data signals such as audio and video, and more particularly to a disk storage case having a mechanism that can securely hold an optical disk having a central hole and can be easily inserted and removed. .
[0002]
[Prior art]
For example, two types of storage cases for discs that record and hold a large amount of audio and video information such as digital versatile discs (hereinafter referred to as DVDs) are broadly used. One of them is a so-called compact disc (hereinafter referred to as CD) case, and the configuration is used because the shape of the disc is the same.
[0003]
However, in this case, it is difficult to distinguish it from a CD, and when a movie or the like is recorded with a small swing, there is a limit to the size of a jacket or booklet that introduces the content, so a so-called video that stores videotapes Cases with sizes close to soft cases are also used.
[0004]
In these cases, how easy it is to eject the disc is important. The standard diameter of the disc is relatively large at 120 mm, and it was difficult for a small hand such as a child to handle. In addition, since it is necessary to increase the recording capacity of a disc such as a DVD as compared to a CD, a configuration in which two discs are bonded together is adopted, and unnecessary force is applied to the disc to prevent the portion from being peeled and damaged. There is a need for locking means and removal means that are not provided.
[0005]
Therefore, various proposals have been made to provide a disc case that can be easily removed while securely holding the disc. As one of such proposals, there is a case in which an optical disc having a center hole has a circumferential rib divided into about 8 to 12 so as to match the center hole. The circumferential ribs divided into about 8 to 12 are set so that the overall length of the rib or the size of the top end is slightly larger than the inner diameter of the disc, and the disc can be held and put in and out using the spring effect of the circumferential rib. I have to.
[0006]
Therefore, if the engagement between the disc center hole and the circumferential rib is loosened so as not to apply a load to the disc during loading and unloading, there is a risk that the disc will come off the circumferential rib in the case due to impact, If the engagement is strengthened in order to prevent detachment, it becomes difficult to put in and out, and the disc may be damaged.
[0007]
In order to overcome such drawbacks, as shown in FIG. 29, the tip of two or three elastically supported arms 22 extending in the inner circumferential direction from the bottom surface 21 of the case is not a circular rib for holding the disc. A method for holding the disk center hole 26 is proposed. The arm tip 23 has a circumferential shape so as to match the disc center hole 26, and a projection 24 for preventing the disc 25 from falling off is provided at the upper end thereof.
[0008]
In this example, when the disc is loaded, as shown in FIGS. 30A to 30C, the disc center hole 26 is aligned with the two arm tip portions 23 and the disc 25 is pushed downward, thereby bringing the case into the case. The arm 22 elastically supported by the arm 22 is deformed, and the protrusion 24 is displaced to the inner peripheral side while deforming the disk center hole 25, and the protrusion 24 of the arm tip 23 is inserted into the disk center hole 26. Thereafter, when the downward pressure disappears, the arm 22 returns to its original state, and the protrusion 24 is disposed on the upper surface of the disk 25, so that the disk 25 does not fall out of the holding part.
[0009]
On the other hand, when the disc is taken out, as shown in FIGS. 31A to 31C, the two arm tip portions 23 are uniformly pressed downward so that the protrusion 24 deforms the disc center hole 26 while deforming the disc center hole 26. The clearance disk is pushed into the lower side of the center hole 26 in the circumferential direction. Thereafter, when the downward pressure is removed, the disk 25 is pushed upward with the inner circumference of the disk 25 riding on the protrusions 24. Thereby, the disk 25 can be easily removed from the holding portion.
[0010]
[Problems to be solved by the invention]
The disk case of the above-described type is not preferable because a strong load is applied to the disk center hole 26 when the disk 25 is attached or detached, and there is a risk of causing cracks or peeling of the adhesive surface in a bonded disk such as a DVD.
[0011]
Further, as shown in FIG. 32, the disc case of the above-described type is held so that the two arm tip portions 23 at the center portion can be easily pushed when taken out and the disc 25 is pushed up after the lock is released. Further, since it protrudes larger than the upper surface of the disk, when an accidental force is applied, the lock is released and the disk 25 may fall out of the holding portion. In particular, in the case of this mechanism, it is necessary to use an elastic material such as polypropylene for maintaining the elastic force of the arm 22, and when the force is applied to the vicinity of the disk holding portion from the outside of the case holding the disk, the case When the upper lid 27 is bent and deformed, the deformed case upper lid 27A pushes the arm tip 23 downward to release the lock, and the disc 25 may fall off the holding portion.
[0012]
SUMMARY OF THE INVENTION An object of the present invention is to provide a disc storage case that can easily take in and out an optical information recording disc having a center hole that can solve the above-described problems and that can be safely held and stored.
[0013]
[Means for Solving the Problems]
In order to solve the above-described problems, the present invention provides a disk storage case having the following configurations (1) to (4).
(1) A locking member that has a cover portion and a case surface and that locks in the center hole of the stored disk is provided on the case surface, and the disk can be detachably attached to the case by the locking member. A disk storage case to lock,
The locking member is
A cradle that is elastically erected on the case surface, supports the vicinity of the center of the disk, and holds the disk at a predetermined height;
The outer peripheral surface extends further upward than the cradle and has a shape that matches the center hole of the disc, and a cutout portion in which a portion of the outer peripheral surface is cut out. A cylindrical rib divided into a plurality of ribs divided by a plurality of slits in order to relieve stress applied to the inner peripheral wall of the center hole of
The disc provided on the case surface so as to be elastically deformable, facing the cylindrical rib and capable of entering the notch portion of the cylindrical rib, and engaging the cylindrical rib A lock arm provided at the tip thereof with a pressing portion for holding a part of the center hole of the disc and restricting the disc from falling off the cylindrical rib.
When the disk is removed, the pressing portion of the lock arm is pushed downward to release the engagement between the lock arm and the disk. Ruko A disc storage case characterized by
(2) The height of the cylindrical rib from the case surface is higher than the height of the upper surface position of the pressing portion of the lock arm when the pressing portion from the case surface is pressed and unlocked. The disk storage case according to claim 1.
(3) The disc storage case according to claim 1 or 2, wherein a part of the connection part connected to the case surface is formed by separating a part of the connection part.
(4) One of the connection portions corresponding to a portion between the one end of the first rib closest to the notch portion and the other end of the first rib among the plurality of pieces of the ribs of the cylindrical rib. The disc storage case according to claim 3, wherein the disc storage case is provided in a portion.
[0014]
As a specific example of the above-described means, a disk storage case having the following configurations (a) to (d) can be considered.
(A) In a case for storing an optical information recording disk having a center hole, a cylindrical rib provided perpendicularly from the bottom of the case with an external dimension that matches the diameter of the center hole of the disk in order to hold the disk in the center hole. It has a disk holding mechanism composed of one arm with a disk drop prevention lock mechanism supported elastically deformable at the bottom of the case, and the cylindrical rib for holding the disk lacks a part of its circumference In addition, the inner end of the locking arm is made up of a portion that matches the center hole of the disk to compensate for the lack of the cylindrical rib and a protrusion that prevents the disk from falling off, and the upper surface is for unlocking It has a convex shape that makes it easy to push down, and when the disc is installed in the case, push the disc center hole down along the cylindrical rib. As a result, the locking arm deforms downward and the projection that folds down on the upper end of the arm pressing pressure section passes through the center hole of the disk and then returns to the position where it presses the upper surface of the disk. A disc storage case, wherein when the arm is released after being pushed down below the unlocking position, the disc is pushed up along the cylindrical rib in such a manner that it rides on the projection at the upper end of the arm pressing pressure portion.
(B) The disc-holding cylindrical rib is set higher than the upper surface position of the pressing portion of the locking arm when the lock is released, and operates smoothly for the unlocking operation by a fingertip or the like. In case of accidental stress applied to the area larger than the outer shape of the cylindrical rib due to etc., the disk storage case is characterized in that the upper surface of the cylindrical rib serves as a stopper for the stress and does not lead to unnecessary unlocking .
(C) By providing a slit that divides the cylindrical rib for holding the disc into a plurality of portions, when a stress is applied to the center hole of the disc by the locking projection when the disc is attached or detached, the cylindrical rib is deformed in the inner diameter direction. Accordingly, the disk moves in the direction of the locking protrusion, so that the stress applied to the disk is relieved and the locking protrusion easily passes through the center hole of the disk.
(D) A disc storage characterized by having a disc cradle concentric with the cylindrical rib in the immediate vicinity of the cylindrical rib for holding the disc in order to hold the disc at the inner peripheral portion that does not affect the signal. Case.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a disk storage case of the present invention will be described in the order of (Example 1), (Example 2), (Example 3), and (Example 4) according to the drawings.
[0016]
The disc storage case 100A of the present invention has a cover portion (= case upper lid, cover side 110) and a case surface (= case bottom surface, plate 125 on the tray side 120A) as shown in FIGS. Then, a locking member (engaging portion 130A) that locks in the central hole 201 of the stored disc 200 is provided on the case surface 125, and the disc 200 can be detachably attached to the case 100A by the locking member 130A. A disk storage case to lock,
The locking member 130A is
A pedestal 160A that stands on the case surface 125, supports the vicinity of the center of the disk 200 (near the center hole 201), and holds the disk 200 at a predetermined height HH;
An outer peripheral surface 150A that extends further upward than the cradle 160A and matches the center hole 201 of the disk 200, and has a notch (notch 15A) in a part of the outer peripheral surface 150A; and A cylindrical rib 150 divided into a plurality of pieces of ribs 151A to 151F;
It is provided on the case surface 125 so as to be elastically deformable, is opposed to the cylindrical rib 150, has a shape that can enter the cutout portion 15 </ b> A of the cylindrical rib 150, and is formed in the cylindrical rib 150. A pressing portion (= arm pressing portion; disc engaging surface 142, lip 143, and the like) that holds a part of the center hole 201 of the engaged disc 200 and restricts the disc 200 from dropping from the cylindrical rib 150. The disc storage case is provided with a lock arm 141 (formed as a whole as shown in FIG. 23, which is formed with a locking portion 140) provided with a button-like portion 144).
[0017]
Further, in the disk storage case 100A of the present invention, as shown in FIG. 27 described later, the height H1 of the cylindrical rib 150 from above the case surface 125 presses the pressing portion from above the case surface 125. Then, the disk storage case is characterized by being higher than the height H2 of the position of the upper surface 144A of the pressing portion of the lock arm 140 when the lock is released.
[0018]
Further, as shown in FIGS. 23 and 28, which will be described later, the disc storage case 100A according to the present invention is a detachment in which a part of the connection part 125A is cut out of the connection part 125A of the cradle 160A with the case surface 125. This is a disk storage case in which a portion (cut 165) is formed.
[0019]
Further, in the disc storage case 100A of the present invention, the separation portion 165 is separated from one end of the first ribs 151A and 151F closest to the notch 15A among the plurality of pieces of ribs 151A to 151F of the cylindrical rib 150. The disc storage case is provided in a part 125B of the connecting portion 125A corresponding to the other end of the first ribs 151A and 151F.
[0020]
(Example 1)
First, a first embodiment of the disk storage case of the present invention will be described.
FIG. 1 is a plan view of Embodiment 1 of a disk storage case according to the present invention, and FIG. 2 is a longitudinal sectional view of a central portion viewed from the case back plate 3 when a disk is stored in the disk storage case shown in FIG. 3 is a diagram for explaining the disc holding mechanism, FIG. 4 is a diagram for explaining the operation of the disc holding mechanism when the disc is attached and detached, and FIG. 5 is a diagram for explaining the state when the case upper lid is deformed.
[0021]
The disc storage case shown in FIGS. 1 and 2 is composed of a case upper lid (cover portion) 1 and a case bottom portion (plate portion) 2 connected to the case back plate portion 3 by an integral hinge 4, and is made of an elastic material such as polypropylene. It is a storage container integrally formed of a certain material. The case bottom 2 has a disc holding mechanism 5 and a disc cradle 6 which are integrally formed substantially at the center, and four discs which are integrally formed on the entire circumference or a part corresponding to the outer circumference of the disc to be stored. A protective rib 7 is provided. Further, in order to prevent the disc 8 housed in the case from being deformed by accidental stress, four of the disc protecting ribs 7 are provided in the vicinity of the disc outer peripheral end.
[0022]
Next, as shown in FIGS. 3A and 3B, the disk holding mechanism 5 includes a cylindrical rib 9 and
And a lock arm 10. The cylindrical rib 9 has an outer dimension that substantially matches the diameter of the center hole 14 of the disk 8 in order to regulate the position of the inner peripheral surface (inner wall) of the center hole 14 of the disk 8, and from the disk cradle 6. It stands upright. The lock arm 10 has a lock mechanism that regulates the vicinity of the center hole 14 on the upper surface of the disk 8 in order to prevent the disk 8 whose position is regulated by the cylindrical rib 9 from falling, and stands up elastically from the case bottom 2. Set up.
The disk cradle 6 regulates the vicinity of the center hole 14 on the lower surface of the disk 8 on the opposite side of the vicinity of the center hole 14 on the upper surface of the disk 8 by the lock arm 10 and extends from the case bottom 2 to the cylinder. Standing up with elasticity.
[0023]
In the cylindrical rib 9 and the disk cradle 6 described above, a part of each cylindrical rib 9 (about 1/3 on the circumference) is continuously cut to form a cutout portion 15 (FIG. 3). 16 shows a range in which the cylindrical rib 9 is cut out), and the lock arm 10 (arm 10a and arm pressing portion 11) can enter the cutout portion 15. Further, the tip (upper surface) 9a of the cylindrical rib 9 has an R shape or a taper shape so that the disk 8 can be easily attached and detached. Further, the cylindrical rib 9 is provided with slits 13 for vertically dividing the cylindrical rib 9 into 4 to 8 parts in order to relieve stress applied to the inner peripheral wall of the disk center hole 14 when the disk 8 is attached and detached. What is necessary is just to set the number which divides the slit 13 in consideration of rib strength or detachability. The disk cradle 6 described above is provided concentrically with the cylindrical rib 9, and the diameter of the disk cradle 6 is larger than the diameter of the cylindrical rib 9.
[0024]
The lock arm 10 described above includes an arm 10 a, an arm pressing portion 11, and a protruding portion 12.
One end of the arm 10a is elastically formed on the case bottom 2 with a predetermined inclination. The arm pressing portion 11 to which the other end of the arm 10 a is connected has a size that matches the center hole 14 of the disk 8 in order to compensate for the notch portion 15 described above. The projecting portion 12 is provided at the upper end of the arm pressing portion 11 to which the other end of the arm 10 a is connected, and serves as a lock mechanism that regulates the vicinity of the center hole 14 on the upper surface of the disk 8.
[0025]
Usually, when the disk 8 is housed in a case, it is preferable that the disk 8 is held only at the center portion that does not affect the signal. Therefore, the disk protection rib 7 is formed on the disk 8 when stress from the outer circumferential direction of the disk 8 is applied. It functions to prevent large deformations.
[0026]
FIGS. 4 (a) to 4 (c) show a mechanism for removing and attaching the disk in such a disk holding mechanism.
When the disc is mounted on the case, the disc center hole 14 is placed along the cylindrical rib 7 as shown in FIG. 4A, and the vicinity of the disc center is pushed downward (arrow P). As a result, as shown in FIG. 4B, the locking arm 10 (arm 10a) is deformed downward, and the protrusion 12 positioned at the upper end of the arm pressing portion 11 passes through the disk center hole 14, but at this time, The cylindrical rib 9 divided by the slit 13 is bent to relieve the stress applied to the disk center hole 14. Thus, the protrusion 12 easily passes through the disk center hole 14 and returns to the position where the protrusion 12 presses the upper surface of the disk 8 as shown in FIG. And is securely held by the disk cradle 6.
[0027]
On the other hand, at the time of taking out the disc, after pushing down the arm pressing portion 11 in the reverse order of the description order of FIGS. 4A to 4C described above, the engagement between the disc 8 and the protruding portion 12 is released, The disk 8 may be taken out. Specifically, first, the arm pressing portion 11 is pushed downward. As a result, the locking arm 10 (arm 10 a) is deformed downward, and the cylindrical rib 9 is also bent, so that the protrusion 12 at the upper end of the arm pressing portion 11 passes through the disk center hole 14. In this way, the lock is released.
[0028]
Here, FIG. 4D shows a state immediately before the protruding portion 12 of the arm pressing portion 11 passes through the disc center hole 14 (the same state as FIG. 4B). When the holding mechanism 5 is in the state of FIG. 4B, the height h from the top of the case bottom 2 to the top surface of the cylindrical rib 9 is released by pressing the arm pressing portion 11 from the top of the case bottom 2. It shows that it is higher than the height H to the upper surface position of the arm pressing part 11 immediately before being performed.
[0029]
Thereafter, when the locking projection 12 completely passes through the disc center hole 14, the cylindrical rib 9 tries to return to the original position, and accordingly, the end (inner peripheral wall surface) of the disc center hole 14 is formed on the projection 12. It rides up and is pushed up along the cylindrical rib 9 in a state where the disk 8 is placed on the protrusion 12. After that, even if the pressing force is removed, the original engagement relationship is not restored. Therefore, since the disk 8 is only picked up after the engagement relationship is released, it can be easily taken out.
[0030]
In the disk holding mechanism 5 that performs such an operation, as described with reference to FIG. 4D, the above-described height h of the cylindrical rib 9 for holding the disk is equal to the upper surface position of the arm pressing portion 11 when the lock is released. It is set higher than the above-mentioned height H (h> H).
[0031]
For this reason, as shown in FIGS. 5 (a) and 5 (b), when an accidental stress is applied which is applied to an area larger than the outer diameter of the cylindrical rib 9 due to bending of the case upper lid (cover portion) 1 or the like. Even in the case of the bent case upper lid 1a, since the tip 9a of the cylindrical rib 9 has the height h, the case upper lid 1a serves as a stopper for the case upper lid 1a. Since the position is regulated by 9a, there is an effect that even if the upper end of the arm pressing portion 11 is pushed by the case upper lid 1a, the position of the upper end can be prevented from being lowered below the unlocking position H.
[0032]
The cylindrical rib 9 prevents the unnecessary unlocking as described above without hindering the unlocking operation by the fingertip or the like, and scratches, breakage, deformation, etc. of the disc due to the disc 8 falling off in the case. Can prevent accidents.
[0033]
As described above, when the disc is stored, if the disc center hole 14 is aligned with the cylindrical rib 9 and the vicinity of the disc is pushed downward, the locking arm 10 (arm 10a) is elastically deformed downward and locked. The arm 10 (projection 12) comes into contact with the upper side of the disk 8, and the disk 8 is engaged and held on the case bottom 2. During this time, the case bottom 2 is mainly configured to be deformed, so that deformation of the disk 8 at the time of storage and removal is minimized, and the signal recorded on the disk 8 or damage to the disk 8 itself is prevented. it can. Moreover, a cylindrical rib 9 having a height (height h) higher than the locking arm 10 (the upper end 11a of the arm pressing portion 11) is disposed around the locking arm 10 (FIG. 4D). When carrying, unnecessary force is applied to the central part of the case (the part facing the locking arm 10 (arm pressing part 11)), and as a result, the case is stored inside the case upper lid 1 side or the case upper lid 1 side. Printed material or the like does not push down the locking arm 10 (arm pressing portion 11). Therefore, the engagement relationship between the disk 8 and the locking arm 10 (protrusion 12) is inadvertently lost, and the disk 8 moves around in the case. As a result, the signal recorded on the disk 8 cannot be read. Can be prevented.
[0034]
The second embodiment of the disk storage case of the present invention is a detailed description of the disk holding mechanism of the first embodiment described above.
[0035]
(Example 2)
Next, a second embodiment of the disk storage case of the present invention will be described.
6 is a perspective view of Embodiment 2 of the disc storage case of the present invention, FIG. 7 is an enlarged perspective view of the engaging portion, FIG. 8 is a plan view showing the engaging portion, and FIG. 9 is a relationship between the engaging portion and the disc. FIG. 10 is a cross-sectional view showing the whole when the cover is deformed, FIG. 11 is an enlarged cross-sectional view of FIG. 10 showing the periphery of the engaging portion when the cover is deformed, and FIG. FIG. 13 is a cross-sectional view showing a stage in the middle of taking out the disc, FIG. 14 is a cross-sectional view showing a situation in which the button-like portion is pushed out in the final stage of taking out the disc, and FIG. FIG. 16 is a side view showing the final stage in which the disc is stored, FIG. 17 is a side view showing an intermediate stage when the disc is stored with a different mechanism, and FIG. Stored with further deformation than the state of FIG. FIG. 19 is a cross-sectional view showing the state of storing the disc according to the present invention, FIG. 20 is a diagram showing a stage in the middle of ejecting the disc according to the present invention, and FIG. 21 is the final operation of ejecting the disc according to the present invention. It is sectional drawing which shows the condition which pushed the button-shaped part in the step.
[0036]
The entire case is integrally formed as shown in FIG. 6 and includes a cover side (= case upper lid, cover portion) 110, a tray side (= case bottom portion, plate portion) 120 and a back portion connecting them (= case back). Plate part) 180. On both sides of the back portion 180, there are hinge portions (= hinges) 181 and 181 connected to the cover side 110 and the tray side 120, respectively. The hinge portions 181 and 181 are bent so that the cover side 110 and the tray side 120 face each other to form one case 100. The cover side 110 and the tray side 120 are provided with at least a pair of hooks 111 and 121 which are in a fitting relationship with each other. When the hinge parts 181 and 181 are bent to form a case, the hooks 111 and 121 are fitted to prevent the case from opening due to the elasticity of the hinge part 181.
[0037]
The cover side 110 is usually provided with at least one arm 112 protruding inward. In the hook 112, a booklet (not shown) in which usage and explanation of information contents recorded on the disc stored together with the disc is described is sandwiched and stored. On the other hand, the tray side 120 is provided with an engaging portion 130A for locking the disc and a disc protection rib 170 for protecting the disc 200 at the outer periphery of the disc. The protective rib 170 is used to protect (position regulation) the disc 200 from the outer peripheral direction of the disc 200 when an unnecessary force is applied from the side or the case 100 is accidentally dropped. Therefore, the disk 200 is not intended to be held or maintained at a predetermined height.
[0038]
As shown in FIG. 7, the engaging part (= disk holding mechanism) 130 holds the disk 200 in cooperation with the locking part 140 that receives the locking and releasing operations of the disk 200 and the locking part 140. A cylindrical rib 150 divided into a plurality of pieces and a cradle 160 which is located at the base of the cylindrical rib 150 and supports the disc 200 at a predetermined height.
[0039]
The locking portion 140 is continuous with the arm 141 extending from the plate 125 on the tray side 120 toward the inside of the case, the surface 142 extending upward from the tip of the arm 141 and lightly engaging the wall surface 202 of the disc center hole 201, and the engaging surface 142. The lip 143 presses the vicinity of the disc center hole 201 from above, the button-like portion 144 that receives a force to push down the locking portion 140 when the disc is removed, and the inclined surface 145 that connects the lip 143 to the button-like portion 144. Further, the locking portion 140 is formed so as to enter a notch portion 15A described later.
[0040]
On the other hand, the cylindrical rib 150 extends upward from the cradle 160 and has a cutout portion 15A as shown in FIG. 7, so that it is formed in an arc shape as a whole. The cylindrical rib 150 includes a plurality of ribs 151 and 151. The grooves 152 and 152 that partition the ribs 151 and 151 extend to the upper surface 161 of the cradle. When the disk 200 is taken out, the plurality of ribs 151 and 151 are bent toward the center of the locking portion 140. Making it easy. In this example, the cylindrical rib 150 includes six ribs 151 and five grooves 152.
[0041]
Here, as shown in FIG. 8, each of the plurality of ribs 151 and the vertical surface 142 forms an arc as a whole, and its diameter d is substantially equal to the diameter D of the center hole 201 of the disc 200 accommodated as shown in FIG. It is supposed to be the same.
[0042]
Returning to FIG. 7, the cradle 160 extends upward from the plate 125, and the diameter thereof is the same as or smaller than the no-signal portion at the center of the disk 200. The height of the cradle upper surface 161 is set so that the distance d1 between the cradle upper surface 161 and the lower surface of the lip 143 of the locking portion 140 is substantially equal to the thickness d2 of the disk 200 (FIG. 9). . Therefore, the disk 200 to be locked and stored is placed on the disk cradle 160 with its position regulated by the circular arcs of the plurality of ribs 151 of the cylindrical rib 150, and the disk 200 is also subjected to vibration and impact by the lip 143. It will be pushed (clamped) so as not to leave the locking relationship.
[0043]
By the way, since such a case 100 is made using a flexible resin, there is a possibility that the center part of the case 100 may be pushed down by mistake when carrying or handling. In such a case, as shown in FIG. 10, the cover side 110 of the case 100 is bent, and the button-like portion 144 that releases the engagement relationship with the disc 200 is pushed down directly or via an explanatory document stored on the cover 110 side. It is possible to end up. However, as shown in FIG. 11, when the cover side 110 is pushed down toward the inside of the case, the explanatory document stored inside the cover side 110 or inside the cover side 110 comes into contact with the cylindrical rib 150 first, and the button The height h1 of the cylindrical rib 150 is set so that the shape portion 144 is not pushed down to the position where the engagement relationship with the disc 200 is released. Accordingly, even when the case is carried and the like, the engagement relationship with the disc 200 is not released even if the vicinity of the locking portion 140 is pressed by mistake from the upper and lower surfaces of the case.
[0044]
Now, in order to take out the engaged disc 200 from the case 100, the button-like portion 144 is pushed downward in the storage state shown in FIG. Then, as shown in FIG. 13, the arm 141 rotates about the joint point with the plate 125 and the arm 141 also bends, and the amount of engagement between the lip 143 and the disk 200 decreases. Further, the disc 200 is pushed out in the direction of the locking portion 140 (S in FIG. 13) following the lip 143, and the rib 151 of the cylindrical rib 150 is bent in the central direction accordingly (T in FIG. 13). Thus, when the disc 200 moves horizontally and the elastic restoring force of the arm 141 wins against the frictional force between the inner wall of the disc center hole 201 and the tip of the lip 143, the tip of the lip 143 passes through the disc center hole 201, and the lip 143 Enters the lower surface of the disk 200, so that the engagement relationship is canceled. At the same time, the lateral deformation force applied to the rib 151 disappears, so that the rib 151 returns to the normal posture (FIG. 14).
[0045]
Here, when the pressing force is removed, the position of the disk 200 is regulated by the cylindrical rib 150 that has been restored to its original posture, so that the tip of the lip 143 again passes through the disk center hole 201 to return to the engagement relationship. Instead, the disc 200 is pushed up with the disk 200 placed on the button-like portion 144 including the inclined surface 145 on the lip 143. As a result, the locking relationship is completely released, so that the disc 200 can be easily picked up.
[0046]
Thus, in the above-described (Example 2), the cylindrical rib 150 is deformed during a series of disk ejecting operations, and stress applied to the disk center hole 201 is relieved. There will be no peeling. In addition, since the disk itself is not greatly bent, a large load is not applied to the entire disk.
[0047]
On the other hand, when the disc 200 is stored in the case 100, the disc 200 is set at a position substantially concentric with the engaging portion 130 as shown in FIG. At this time, when the vicinity of the lip 143 of the locking portion 130 is pushed down as shown in FIG. 16, the disc center hole 201 enters the lip 143 first while the disc 200 is tilted, and then the opposite side of the disc center hole 201 is the rib 150. (The disc moves as indicated by the arrow in the figure), and the storage is completed.
[0048]
By the way, in the above-described (Embodiment 1) shown in FIG. 1 and (Embodiment 2) shown in FIG. 6, the discs 8 and 200 cannot be sufficiently pushed down when the discs are stored. In some cases, a large load may be applied to the disk 200. In this case, the disks 8 and 200 may not be securely stored, and the disk may be damaged or the signal recorded on the disk may not be read. It was. Therefore, further details will be described below.
[0049]
In the first embodiment of the present invention, in order to store the disk 8, the disk 8 is placed on the locking arm 10 (arm pressing part 11) of the case bottom 2, and then the inner peripheral part of the disk 8 is pushed down. As a result, the locking arm 10 (arm 10a) of the case bottom 2 is elastically deformed and goes around the upper side of the disk 8. As a result, the locking arm 10 (projection 12) presses the disk 8 from above. The disk 8 is held in the case. In this case, the disk 8 needs to be pushed down further downward than the elastically deformed locking arm 10 (projection 12), but the disk 8 is further lowered because the height of the disk 8 is regulated by the disk cradle 6. Sometimes you can't do things. Therefore, when the inner peripheral portion of the disk 8 is pushed down, a portion to which the force is applied is limited.
[0050]
Further, in the above-described (Embodiment 2) of the present invention, when a pressing force is applied to a portion not in the vicinity of the lip 143 on the inner periphery of the disc, the disc 200 is first placed on the disc cradle 160 as shown in FIG. Therefore, it may not be possible to push down any further. In such a case, generation of a force acting on the disk 200 in the lateral direction is weak, and the disk center hole 201 follows the cylindrical rib 150 (which is pushed down along the shape of the cylindrical rib 150). In some cases, the disk 200 is pushed down or stopped at an intermediate position as shown in FIG.
[0051]
For this reason, it is necessary to further push down the vicinity of the lip 143 downward as shown in FIG. For this reason, it has been found that when the disc is stored, if the vicinity of the lip 143 in the inner peripheral portion of the disc is pushed down, the disc is correctly stored, but if the other portion is pushed down, it is not engaged. Further, depending on handling, there is a case where it stops at a halfway position as shown in FIG. 18. If left in this state for a long time, there is a risk of damaging the disk or case. Further, as shown by the broken line in FIG. Engagement is possible by applying a pressing force, but the amount of deformation of the disk 200 is large, and there is a possibility that the disk 200 may be damaged.
[0052]
As a result of further deliberation in order to eliminate all of these points to be improved, (Example 3) of the present invention described later was invented. The gist of the present invention is as follows. That is, as will be described later,
Cover portion (cover side) 110, plate portion (plate 125 on tray side 120), cradle 160A that supports the disc central portion and holds the disc 200 at a predetermined height, and further extends from the cradle 160A The disc has one or more ribs 151 that come into contact with the disc central hole 201 from the inside thereof, and a locking portion 140 that opposes the ribs 151 and has elasticity and can be engaged with and separated from the disc 200. In case 100A,
A part of the connecting part of the cradle 160A extending from the plate 125 is cut off, and more specifically, a part of the connecting part of the cradle 160A and the plate 125 connected to the notch 15A is cut off (cut 165). It is a structure provided with.
[0053]
As the action, when the disc 200 is pushed down from above when the disc is stored, the locking portion 140 is pushed down, and the disc cradle separated from the base (the cradle upper surface 161) by the notch 165 (unsupported to be described later) (Corresponding to the portion 164) can be similarly bent downward, so that the disc 200 is sufficiently pushed down with respect to the locking portion 140, and the engagement with the locking portion 140 is facilitated. Therefore, the range of the position to apply the pressing force for obtaining a reliable engagement relationship is expanded.
[0054]
(Example 3)
Embodiment 3 of the disk storage case of the present invention will be described below.
(Embodiment 3) of the disk storage case according to the present invention is provided with a non-supporting portion 164 on the disk pedestals 6 and 160 and a non-supporting portion as compared with the configurations of (Embodiment 1) and (Embodiment 2). This is equivalent to the one provided with the notch 165 below the support portion 164.
22 is a perspective view of Embodiment 3 of the disk storage case of the present invention, FIG. 23 is an enlarged perspective view of the engaging portion, FIG. 24 is a sectional view showing the engaging portion, and FIG. 25 shows the relationship at the start of disk storage. FIG. 26 is a cross-sectional view showing a state in the middle of the disk storage, FIG. 27 is a cross-sectional view showing a state in which the disk storage further proceeds, and FIG. 28 is a plan view of the locking portion. The same components as those described above are denoted by the same reference numerals, and description thereof is omitted.
[0055]
The entire case is integrally molded as shown in FIG. 22, and covers a side (= case top cover, cover part) 110, a tray side (= case bottom part, plate part) 120A and a back part (= case back) connecting them. Plate part) 180. The hinge portions (= hinges) 181 and 181 are bent so that the cover side 110 and the tray side 120A face each other to form one case 100A. The tray side 120A is provided with an engaging portion 130A for locking the disc 200 and a disc protection rib 170 at the outer periphery of the disc for protecting the disc. The protective rib 170 is for protecting (position regulation) from the outer peripheral direction of the disk 200 when a force is applied to the stored disk 200 from the side or the case is accidentally dropped. There is no attempt to hold or maintain the disc 200 at a predetermined height.
[0056]
As shown in FIG. 23, the engaging portion 130 </ b> A includes an engaging portion 140 that receives an operation for engaging and releasing the disc 200, and a cylindrical rib 150 that is divided into a plurality of pieces that hold the disc 200 in cooperation with the engaging portion 140. And a cradle 160A for supporting the disk 200 at a predetermined height located at the base thereof. The locking portion 140 that constitutes the engaging portion 130 has substantially the same configuration as that of the second embodiment described above, but the cradle 160A is different in configuration from the cradle 160 of the second embodiment, and the flat portion 161, the wall surface 162, and the like. A support portion 164 and a cut 165 are provided.
[0057]
That is, as shown in FIG. 24, the arm 141 extending obliquely upward from the plate 125, the vertical surface 142 in contact with the disk center hole wall surface 202 (FIG. 26), the lip 143 for pressing the disk 200 from above, and the pressing force upon release Receiving button portion 144 and an inclined surface 145 connected from the push button portion 144 to the tip of the lip 143.
[0058]
The cylindrical rib 150 and a cradle 160A that supports the disc 200 at a predetermined height are also provided in the same manner, but in the present invention, the wall surface 162 of the cradle 160A and the case (tray side 120A) are provided. Cuts 165 are provided at both end portions (part) of the connection portion with the plate 125 close to the locking portion 140. Accordingly, since the unsupported portion 164 that is not directly supported from the plate 125 by the notch 165 is connected to the other portion of the disk receiving portion 160A only by the flat portion of the receiving stand 161 and the wall surface 162, the receiving stand 161 When a force is applied from above, the connecting portion is elastically deformed and can be bent downward.
[0059]
Of the cylindrical rib 150, the rib 151 facing the locking portion 140 is provided with a convex portion 153 as shown in FIGS. 24 and 25. Since the stored disc 200 is lightly pressed from above by the convex portion 153, the disc 200 can be prevented from tilting toward the locking portion 140 in cooperation with the lip 143 when the disc is stored.
[0060]
In order to store the disc 200, as shown in FIG. 25, the disc 200 is set at a position substantially concentric with the engaging portion 130, and then the vicinity of the disc center hole 201 is pushed down with a pushing force P (FIG. 26). At this time, since the present invention uses the bending of the non-supporting portion 164 due to the notch 165 (FIG. 23), it is pushed down on the non-supporting portion 164 or in the range where there is no disk cradle 160A for reliable storage. It is desirable to apply force. As a result, the center hole 201 of the disc 200 abuts on the rib 151 and the lower surface of the disc 200 abuts on the disc cradle 161.
[0061]
When a pressing force is further applied, the pressing force acts on the non-supporting portion 164 via the disk 200, and the non-supporting portion 164 is elastically deformed downward in FIG. At this time, a force in the direction of the lip 143 is generated on the inclined surface 145 on the disk 200, and the non-supporting portion 164 is elastically deformed to generate an inclination, whereby a force in the S direction is applied to the disk 200 as shown in FIG. Works. This force elastically deforms the rib 151 in contact with the disk 200 in the direction of the lip 143 (T in FIG. 27).
[0062]
Furthermore, a force that pushes down the non-supporting portion 164 acts on the entire disc cradle 160A, and the entire disc cradle 160A is elastically deformed downward in the locking portion 140 direction. Therefore, the cylindrical rib 150 extending from above the disk cradle 160A is also elastically deformed downward in the direction of the locking portion 140, and the rib 151 is moved in the direction of the locking portion 140 in cooperation with the force S described above. Tilt. Therefore, since the disc 200 can move in the direction of the locking portion 140, the overlapping distance between the disc center hole 201 and the lip 143 of the locking portion 140 is reduced, so that the lip 143 can easily pass through the disc center hole 201. . Here, when the deformation of the rib 151 and the arm 141 progresses to the position where the tip of the lip 143 can slip through the disc center hole 201 by the elastic restoring force of the arm 141, the tip of the lip 143 slips through and the locking portion 140 is in its original posture. Return to.
[0063]
When the pressing force is released here, the rib 151 and the non-supporting portion 164 return to the original posture by the elastic force, and the disc 200 returns to the center position of the engaging portion 130A. In this way, the disk 200 can be reliably held between the disk cradle 161 and the lip 143 without applying an excessive load to the disk center hole 201. In addition, since the disk itself is not greatly bent, a large load is not applied to the entire disk.
[0064]
Here, the amount of separation between the wall surface 162 and the base 125 by the notch 165 is an amount suitable for ensuring the above-mentioned operation, and a sufficient resin flow rate to the unsupported portion 164 can be secured at the time of molding, and is not necessary after molding. It is appropriately selected in consideration of securing a connection distance such that no significant deformation occurs. In this embodiment, as shown in FIG. 28, the grooves 152A and 152F extending from the both ends of the disk receiver 160 to the cradle 161 are separated. This is because when the pressing force is applied to the disk cradle 160A, the elastic deformation is stably generated with the grooves 152A and 152F as the base shaft.
[0065]
In order to elastically deform the unsupported portion 164 in the downward direction, the structural force is secured because the cross-sectional shape of the connecting portion 125A is L-shaped. Therefore, this part is not carelessly deformed by its own weight, and the disk 200 is not sufficiently held.
[0066]
On the other hand, when taking out the disc, the button-like portion 144 is pushed downward in the storage state. Then, as shown in FIG. 27, the arm 141 rotates about the joint point with the plate 125 and the arm 141 also bends, and the amount of engagement between the lip 143 and the disk 200 decreases. Further, the disc 200 is pushed out in the S direction in FIG. 27 along the lip 143, and the rib 151 of the cylindrical rib 150 is bent in the center direction in accordance with this (T in FIG. 27).
[0067]
Further, since the disk 200 receiving the downward force via the lip 143 pushes down the non-supporting part 164, the entire disk support 160A is elastically deformed downward in the direction of the locking part 140, and as a result, extends from the disk support 160A. The deflection T toward the center of the rib 151 is increased.
[0068]
Thus, the disc 200 moves horizontally, the tip of the lip 143 passes through the disc center hole 201, and the lip 143 enters the lower surface of the disc 200, so that the engagement relationship is canceled. At the same time, the lateral deformation force applied to the rib 151 is eliminated, and further, the force to push down the non-supporting portion 164 is eliminated, so that the rib 151 returns to the normal posture (as shown in FIG. 21 described above).
[0069]
When the pressing force is removed here, the position of the disc 200 is regulated by the cylindrical rib 150 that has been restored to its original posture, so that the tip of the lip 143 does not pass through the disc central hole 201 again and return to the engagement relationship. The disk 200 is pushed up on the button-like portion 144 including the inclined surface 145 above the lip 143 (returns to the state at the start of storage shown in FIG. 15). As a result, the locking relationship is completely released, so that the disc 200 can be easily picked up.
[0070]
As described so far, it can be seen that the elastic force of the arm 141 of the locking portion 140 greatly affects the operation in the operation of storing and taking out the disc 200. Therefore, it goes without saying that when the present invention is implemented, the elastic force can be adjusted by appropriately considering the thickness of the arm 141, the reinforcing ribs to the arm 141, and the like.
[0071]
(Example 4)
Hereinafter, (Example 4) of the disk storage case of the present invention will be described.
(Embodiment 4) of the present invention has four disc protection ribs 170 provided on the tray side 120A in the configuration of the entire case 100A shown in FIG. 22 as compared with the configuration of (Embodiment 3) described above. Among them, the two disk protection ribs 170 on the cradle 160A side are simply changed to disk protection ribs 170A and 170B with additional ribs 171 and 172, which will be described later, and the other configuration is the same as that of the third embodiment. It is.
[0072]
FIG. 33 is a plan view showing the tray side of Embodiment 4 of the disk storage case of the present invention, and FIG. 34 shows a state in which a part of the disk protection rib with additional ribs shown in FIG. FIG. 35 is a cross-sectional view, and FIG. 35 is a sectional view taken along line BB ′ for explaining a state where the disk is approaching above the additional rib of the disk protective rib shown in FIG. FIG. 36 is a view of the disk protection rib with additional ribs from the direction A in FIG. 33, and FIG. 37 is an additional view shown in FIG. 33 with the disk engaged with the engaging portion. It is sectional drawing which shows the state which cut | disconnected a part of disc protection rib with a rib by line segment DD '. The same components as those described above are denoted by the same reference numerals, and description thereof is omitted. Further, since the configuration of the entire case is the same as that of the second embodiment, the illustration is omitted.
[0073]
Additional ribs 171 and 172 are respectively provided at one end portions of the disk protection ribs 170A and 170B with the additional ribs so as to face the engaging portion 130A. These additional ribs 171 and 172 pop up above the engaging portion 130A when the engagement with the engaging portion 140 is released when the disc 200 is taken out, and the outer edge portion (outermost circumference) of this disc 200 popped up. In this case, the outer edge portion of the disk 200 is restricted only at this time in order to prevent it from coming into direct contact with the tray side 120A, which is the bottom surface of the case, and being immediately picked up from the case.
[0074]
The heights of the additional ribs 171 and 172 are set lower than the height of the cradle 160A. By setting the heights of the additional ribs 171 and 172, the upper surface of the additional ribs 171 and 172 does not come into contact with the outer edge portion of the disk 200 placed on the cradle 160A immediately before the disk 200 is taken out (see FIG. 37). The outer edge of the disc 200 is restricted only when the disc 200 is taken out.
[0075]
【The invention's effect】
The disk storage case according to the present invention can be easily inserted and removed without applying a load to the stored disk, and securely holds the stored disk and prevents falling off due to accidental stress. In addition, accidents such as scratches, breakage, and deformation of the disk can be prevented. Further, according to the present invention, the disc can be easily stored in the case and can be securely locked, and the disc is not damaged. It is possible to avoid a failure in reading the signal.
[Brief description of the drawings]
FIG. 1 is a plan view of Embodiment 1 of a disk storage case of the present invention.
FIG. 2 is a longitudinal sectional view of a central portion viewed from the case back plate portion 3 side when a disc is stored in the disc storage case shown in FIG.
FIG. 3 is a diagram for explaining a disk holding mechanism.
FIG. 4 is a diagram for explaining the operation of a disk holding mechanism when a disk is attached or detached.
FIG. 5 is a diagram for explaining a state when a case upper lid is deformed.
FIG. 6 is a perspective view of a second embodiment of the disk storage case of the present invention.
FIG. 7 is an enlarged perspective view of an engaging portion.
FIG. 8 is a plan view showing an engaging portion.
FIG. 9 is a cross-sectional view showing the relationship between the engaging portion and the disc.
FIG. 10 is a cross-sectional view showing the whole when the cover is deformed.
11 is an enlarged cross-sectional view of FIG. 10 showing the periphery of the engaging portion when the cover is deformed.
FIG. 12 is a cross-sectional view showing a state in which a disc is stored.
FIG. 13 is a cross-sectional view showing a stage in the middle of taking out the disc.
FIG. 14 is a cross-sectional view showing a state in which the button-shaped portion has been pushed out in the final stage of taking out the disc.
FIG. 15 is a side view showing the relationship at the start of disk storage.
FIG. 16 is a side view showing a final stage in which a disc is stored.
FIG. 17 is a side view showing an intermediate stage when a disc is stored with a different mechanism.
18 is a side view showing a case where the disk is further deformed than the state shown in FIG.
FIG. 19 is a cross-sectional view showing a disk storage situation according to the present invention.
FIG. 20 is a diagram showing a stage in the middle of disc ejection work according to the present invention.
FIG. 21 is a cross-sectional view showing a state in which the button-like portion is fully pushed out in the final stage of taking out the disc according to the present invention.
FIG. 22 is a perspective view of Embodiment 3 of the disk storage case of the present invention.
FIG. 23 is an enlarged perspective view of an engaging portion.
FIG. 24 is a cross-sectional view showing an engaging portion.
FIG. 25 is a cross-sectional view showing the relationship at the start of disk storage.
FIG. 26 is a cross-sectional view showing a situation during disk storage.
FIG. 27 is a cross-sectional view showing a situation in which the disk storage further proceeds.
FIG. 28 is a plan view of a locking portion.
FIG. 29 is a view for explaining a holding portion of a conventional disk storage case.
FIG. 30 is a diagram for explaining a mechanism when a disc is inserted.
FIG. 31 is a diagram for explaining a mechanism when a disc is taken out.
FIG. 32 is a diagram for explaining a situation when the case upper lid is deformed.
FIG. 33 is a plan view showing the tray side of Embodiment 4 of the disk storage case of the present invention.
34 is a cross-sectional view showing a state in which a part of the disk protection rib with additional ribs shown in FIG. 33 is cut along a line segment CC ′. FIG.
FIG. 35 shows a state in which a part of a disk protection rib with an additional rib is cut along a line BB ′ in order to explain a state where the disk is approaching above the additional rib of the disk protection rib shown in FIG. It is sectional drawing shown.
36 is a view of a disk protection rib with an additional rib as viewed from the direction A in FIG. 33. FIG.
FIG. 37 is a cross-sectional view showing a state in which a part of the disk protection rib with additional ribs shown in FIG. 33 is cut along line DD ′ in a state where the disk is engaged with the engaging portion.
[Explanation of symbols]
2 Case bottom (case surface)
5 Disc holding mechanism (locking member)
8,200 discs
9,151 Cylindrical rib
10,140 Locking part, arm (lock arm)
11 Arm pressing part
12 Locking protrusion
14,201 disc center hole (center hole)
15A Notch
100,100A disk storage case
110 Cover side (cover part)
120,120A tray side
125 plate (case surface)
125A connection part
125B part
130A engaging portion (locking member)
143 Lip
144 Button-shaped part
144A Upper surface
150A outer peripheral surface
151A ~ 151F Ribs
160, 160A cradle
165 Notch (cut off part)
h, H, H1, H2, HH Height

Claims (4)

A disc having a cover portion and a case surface, and a locking member that locks in the center hole of the stored disc is provided on the case surface, and the disc is detachably locked in the case by the locking member. A storage case,
The locking member is
A cradle that is elastically erected on the case surface, supports the vicinity of the center of the disk, and holds the disk at a predetermined height;
The outer peripheral surface extends further upward than the cradle and has a shape that matches the center hole of the disc, and a cutout portion in which a portion of the outer peripheral surface is cut out. A cylindrical rib divided into a plurality of ribs divided by a plurality of slits in order to relieve stress applied to the inner peripheral wall of the center hole of
The disc provided on the case surface so as to be elastically deformable, facing the cylindrical rib and capable of entering the notch portion of the cylindrical rib, and engaging the cylindrical rib A lock arm provided at the tip thereof with a pressing portion for holding a part of the center hole of the disc and restricting the disc from falling off the cylindrical rib.
Wherein when the extraction disk, the disk storage case, wherein the benzalkonium to release the engagement between the lock arm and the disc the pressing portion of the lock arm pressed downward. The height of the cylindrical rib from above the case surface is higher than the height of the upper surface position of the pressing portion of the lock arm when the pressing portion from above the case surface is pressed and unlocked. The disk storage case according to claim 1. The disc storage case according to claim 1 or 2, wherein a part of the connection part, which is part of the connection part with the case surface, is separated. The separation portion is provided in a part of the connection portion corresponding to a portion between one end of the first rib closest to the notch portion and the other end of the first rib among the plurality of pieces of ribs of the cylindrical rib. 4. The disk storage case according to claim 3, wherein

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