JP2015225499A - Lock device, housing device, server, housing system, and housing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lock device which makes a whole region in a slide direction of a slidable shelf body accessible, and can reduce a surrounding workspace.SOLUTION: A lock device 20 that regulates slide of a slidable shelf body (stored object A) comprises a lock part 200 and a release operation part 201. The lock part 200 regulates sliding of the stored object A at a first position where the stored object A is slid from a predetermined housing position to a first end part T1 side by a first length shorter than the entire length La in a slide direction of the stored object A. Further, the lock part 200 regulates sliding of the stored object A at a second position where the stored object A is slid to a second end part T2 side opposite from the first end part T1 by a second length being a difference between the entire length La of the stored object A and the first length.

Description

  The present invention relates to a lock device, a storage device, a server, a storage system, and a storage method.

In a storage device in which a shelf is supported so as to be slidable with respect to a support, there is a device in which the shelf can be slid in both front and rear directions.
Patent Document 1 discloses a rail fixed to a support frame, a shelf that can slide in the front-rear direction along the rail, and a forward direction of the shelf in a storage position in which the shelf is stored in the support frame. There is described a storage device having a front lock lever capable of prohibiting movement in the rear direction and a rear lock lever capable of prohibiting movement in the rear direction. Patent Document 1 describes that the front lock lever is fixed at the front position where the shelf is moved a predetermined distance in the forward direction. Furthermore, Patent Document 1 describes that the rear lock lever fixes the shelf at a rear position after moving the shelf backward by a predetermined distance.

Japanese Utility Model Publication No. 62-169638

By the way, a company or the like may have a huge number of electronic facilities such as servers and storages in order to process and store data to be handled. However, since the amount of data handled continues to increase, there is a concern that the space for installing the electronic equipment will be insufficient.
Electronic devices such as storage are often stored in a storage device having the above-described slidable shelf. In this case, the worker slides and removes the electronic device from the storage device during maintenance work or the like. Therefore, when installing the storage device, it is necessary to secure not only the installation space of the storage device itself but also a working space where the electronic device can be slid out of the storage device. However, if the work space is secured so that the worker can access all the electronic devices housed in the housing device, the number of housing devices installed in the determined floor area decreases. On the other hand, if the work space is reduced to save space, the shelf that is slid out of the storage device interferes with the housing of the surrounding storage equipment, and the shelf cannot be pulled out completely. Electronic devices that are difficult to remove from the body may come out.

  An object of the present invention has been made in view of the above problems, and is a lock device and a storage device that can reduce the surrounding work space while allowing access to the entire sliding area of a slidable shelf. It is in providing a server, a storage system, and a storage method.

According to an aspect of the present invention, the shelf body is a first position in which the shelf body is slid from a predetermined storage position to the first end side by a first length shorter than the entire length of the shelf body in the sliding direction. The shelf is slid to the second end side opposite to the first end side by a second length that is the difference between the total length and the first length. In the second position, the lock device includes: a lock portion that restricts sliding of the shelf body; and a release operation portion that releases the slide restriction of the shelf body by the lock portion.
According to such a configuration, it is possible to limit the sliding amount of the shelf body toward the first end portion side, and it is possible to limit the sliding amount of the shelf body toward the second end portion side. Furthermore, since the sum of the slidable amount to the first end side and the slidable amount to the second end side is equal to the total length of the shelf body, the entire area of the shelf body is accessed by changing the sliding direction. Can do. Further, for example, by limiting the workers that can be accessed from the first end side, it is possible to set access restrictions according to the slide area of the shelf. Furthermore, since the protruding amount of the shelf can be reduced as compared with the case where it can slide only on the first end side or the second end side, for example, the degree of freedom of arrangement of the apparatus including the shelf body can be improved. . Moreover, when returning a shelf body to an accommodation position, regulation can be easily cancelled | released by operating a cancellation | release operation part.

  Further, one aspect of the present invention is a first position in which the shelf body is slid from a predetermined storage position to the first end side by a first length shorter than the entire length of the shelf body in the sliding direction. The step of regulating the sliding of the shelf to the first end side and the second length which is the difference between the total length and the first length, the shelf to the first end side. And a step of regulating the sliding of the shelf to the second end side at a second position slid to the opposite second end side.

  According to the lock device, the storage device, the server, the storage system, and the storage method described above, the surrounding work space can be reduced while making it possible to access the entire region of the shelf in the sliding direction.

It is a figure which shows the whole structure of the accommodating apparatus which concerns on 1st Embodiment. It is a figure which shows the structure of the slide rail and locking device which concern on 1st Embodiment. (A) is a plan view of the slide rail and the lock device, (b) is a side view of the slide rail and the lock device, and (c) is a front view of the slide rail and the lock device. It is the 1st figure explaining the composition and function of the locking device concerning a 1st embodiment. It is the 2nd figure explaining the composition and function of the locking device concerning a 1st embodiment. It is the 1st figure explaining the operation effect of the locking device concerning a 1st embodiment. It is a 2nd figure explaining the effect of the locking device concerning a 1st embodiment. It is a figure which shows the structure of the locking device which concerns on the modification of 1st Embodiment. It is a figure which shows the whole structure of the locking device which concerns on other embodiment.

<First Embodiment>
Hereinafter, a lock device according to a first embodiment will be described with reference to the drawings.
The locking device according to the present embodiment is applied to a server configured by a plurality of electronic devices such as a CPU (Central Processing Unit) and storage.

FIG. 1 is a diagram illustrating an overall configuration of a storage device according to the first embodiment.
As shown in FIG. 1, the storage device 1 includes a rack 10, slide rails 11 a and 11 b (supports), and a lock device 20. The accommodation device 1 accommodates therein a plurality of stored items A (shelf) constituting the server. The storage A is configured by combining electronic devices such as a CPU (Central Processing Unit), various modules, and storage.

  The rack 10 is formed in a rectangular parallelepiped shape having long sides in the height direction (± Z direction). As shown in FIG. 1, the rack 10 has a plurality of storage items A, which are shelves formed in a rectangular plate shape, arranged in the height direction (± Z direction). The rack 10 can draw out (slide) the plurality of stored items A from a front surface S1 (a surface parallel to the YZ plane and on the + X direction side) which is one of the surfaces constituting the housing. . Thereby, the worker can access the stored item A accommodated in the rack 10 and perform maintenance and inspection. Note that the stored item A is slidable so as to protrude from the back surface S2 (the surface parallel to the YZ plane and on the −X direction side), which is the surface opposite to the front surface S1.

  The slide rails 11a and 11b are provided so as to connect both side surfaces (surfaces parallel to the XZ plane) of the storage object A, which is a shelf, and the inner wall surfaces (surfaces parallel to the XZ plane) of the rack 10. It is a support body that supports each stored item A from the rack 10 so as to be slidable forward (+ X direction) side or backward (−X direction) side. The slide rails 11 a and 11 b are attached to the storage items A that are arranged in a plurality in the height direction (± Z direction) of the rack 10. Thereby, the operator can access each desired stored item A by sliding each stored item A individually.

The lock device 20 regulates the slide of the slidable storage item A at a predetermined first position, a second position, and a storage position where all of the storage product A is stored inside the rack 10.
Here, the “first position” is a position where the stored item A is accommodated by the first length L1 shorter than the entire length La (see FIG. 2A, etc.) in the sliding direction (± X direction) of the stored item A. It is the position slid to the 1st end part side. Further, the “first end portion” is an end portion on the front S1 side of the slide rails 11a and 11b when the stored item A is in the storage position. Further, when the stored item A is in the storage position, the total length of the slide rails 11a and 11b is equal to the total length La of the stored item A in the sliding direction.
The “second position” refers to the first end portion of the stored item A by the second length L2 that is the difference between the total length La of the stored item A in the sliding direction (± X direction) and the first length L1. It is a position slid to the second end side opposite to the side. Further, the “second end portion” is an end portion on the back surface S2 side of the slide rails 11a and 11b when the stored item A is in the storage position.
In addition, the storage device 1 according to the present embodiment is configured such that the first length L1 and the second length L2 are equal. That is, the slide amount (first length L1) of the stored item A from the storage position to the first position is set to a length equal to ½ of the total length La of the slide rails 11a and 11b.

FIG. 2 is a diagram illustrating the structure of the slide rail and the locking device according to the first embodiment. 2A is a plan view of the slide rail and the lock device, FIG. 2B is a side view of the slide rail and the lock device, and FIG. 2C is a front view of the slide rail and the lock device. .
As shown in FIG. 2A, the rectangular plate-shaped container A is arranged in the rack 10 so that the long side of the flat surface (surface parallel to the XY plane) is in the sliding direction (± X direction). Has been. When the stored item A is at a predetermined storage position, the front surface (surface on the front side in the sliding direction (+ X direction) side) of the stored item A overlaps with the front surface S1 of the rack 10. Further, the back surface (the surface on the rear side in the sliding direction (−X direction) side) of the stored item A overlaps with the back surface S <b> 2 of the rack 10. That is, the total length La in the long side direction (± X direction) of the stored item A matches the distance from the front surface S1 to the back surface S2 of the rack 10.
In addition, a slide rail 11a is provided on one of the side surfaces of the containment A (a side surface parallel to the XZ plane and on the −Y direction side). Further, a slide rail 11b is provided on the other side surface of the storage object A (a surface parallel to the XZ plane and on the + Y direction side). The slide rails 11a and 11b are arranged to extend in the slide direction (± X direction) while being in contact with both side surfaces of the stored item A. At this time, the slide rails 11 a and 11 b are arranged over the entire long side of the stored item A. Therefore, in the present embodiment, the total length of the slide rails 11a and 11b is equal to the length La of the stored item A in the long side direction.

Moreover, as shown to Fig.2 (a)-(c), the slide rails 11a and 11b are provided with the outer rail 110 and the inner rail 111, respectively. The inner rail 111 is slidable in the extending direction (± X direction) while in contact with the outer rail 110.
In FIG. 2A, the outer rail 110 of the slide rail 11a is fixed to the inner wall surface (not shown) of the rack 10 arranged on the side (−Y direction side). Further, the inner rail 111 of the slide rail 11a is fixed to the side surface (the side parallel to the XZ plane and on the −Y direction side) of the stored item A disposed on the side thereof.
Similarly, the outer rail 110 of the slide rail 11b is fixed to the inner wall surface (not shown) of the rack 10 arranged on the side (+ Y direction side). Further, the inner rail 111 of the slide rail 11b is fixed to a side surface (a side surface parallel to the XZ plane and on the + Y direction side) of the containment A arranged on the side (−Y direction side).
According to the mechanism as described above, the slide rails 11a and 11b connect the both side surfaces (surface parallel to the XZ plane) of the containment A and the inner wall surface (surface parallel to the XZ plane) of the rack 10 to each other. While supporting the stored matter A. The inner rail 111 fixed to the both side surfaces of the stored item A slides forward (in the + X direction) in the extending direction with respect to the outer rail 110 fixed to the inner wall surface of the rack 10, so that the stored item A becomes the rack 10. It is pulled out so as to protrude from the front surface S1 (see FIG. 1). Further, the inner rail 111 slides backward in the extending direction (−X direction) with respect to the outer rail 110, so that the stored item A is pulled out so as to protrude from the rear surface S2 of the rack 10.

  As shown in FIGS. 2A to 2C, a lock device 20 is provided on the upper side (+ Z direction) of the slide rail 11a. One locking device 20 is disposed at each of the first end T1 and the second end T2 in the extending direction of the slide rail 11a. The lock function of the lock device 20 (the function of regulating the slide of the stored item A) will be described in detail below.

FIG. 3 is a first diagram illustrating the configuration and function of the locking device according to the first embodiment.
3 (a) to 3 (c), the slide rail 11 a shown in FIGS. 2 (a) to 2 (c) and the locking device 20 provided on the slide rail 11 a are arranged on the side on which the stored item A is arranged ( The state seen from the (+ Y direction side) is illustrated. FIG. 3A illustrates a state in which the stored item A is in a predetermined accommodation position.
As shown in FIG. 3A, the lock device 20 includes a lock unit 200 including a first lock unit 200a and a second lock unit 200b, and a release operation including a first release operation unit 201a and a second release operation unit 201b. Part 201. The lock part 200 and the release operation part 201 are located above (on the + Z direction) side of the outer rail 110 at each of the first end T1 and the second end T2 in the extending direction of the outer rail 110 (slide rail 11). It is supported via a provided axis R.

The first lock portion 200a provided on the first end portion T1 side is formed so as to extend from the first end portion T1 to the rear (−X direction) side of the stored item A. The second lock portion 200b provided on the second end portion T2 side is formed so as to extend from the second end portion T2 to the front (+ X direction) side of the stored item A.
Further, the first lock portion 200a has a convex portion 200x that projects from the first end T1 toward the center side (−X direction side) of the stored item A and then folds downward (−Z direction) side. Is formed. Similarly, the second lock portion 200b has a convex portion 200x that protrudes from the end extending from the second end T2 to the center side (+ X direction side) of the stored item A and is bent downward (−Z direction). Is formed.
Here, an opening M is formed in the outer rail 110. The opening M is provided so that the convex part 200x can be inserted downward (−Z direction). The convex portion 200x inserted through the opening M is formed so as to contact the upper surface of the inner rail 111 at the tip.
With the configuration described above, the first lock portion 200a regulates the sliding of the stored item A at the first position where the stored item A is slid from the accommodation position toward the first end T1. Similarly, the second lock portion 200b regulates the sliding of the stored item A at the second position where the stored item A is slid from the accommodation position to the second end T2 side.

The first release operation portion 201a of the locking device 20 provided on the first end portion T1 side is formed so as to protrude from the axis R to the front (+ X direction) side of the outer rail 110. That is, the 1st cancellation | release operation part 201a is provided so that the stored thing A may protrude from the 1st end part T1 of the slide rail 11a in the slide direction (+ X direction) which goes to a 1st position from an accommodation position. The 1st cancellation | release operation part 201a cancels | releases the slide regulation of the stored matter A in a 1st position by the 1st lock part 200a.
Similarly, the second release operation portion 201b of the locking device 20 provided on the second end portion T2 side is formed so as to protrude from the axis R to the rear side (−X direction) of the outer rail 110. That is, the 2nd cancellation | release operation part 201b is provided so that the stored thing A may protrude from the 2nd end part T2 of the slide rail 11a in the sliding direction (-X direction) which goes to a 2nd position from an accommodation position. The 2nd cancellation | release operation part 201b cancels | releases the slide regulation of the stored matter A in a 2nd position by the 2nd lock part 200b.

  The convex part 200x formed at the end in the extending direction of the first lock part 200a is linked to the first release operation part 201a via the axis R. Further, the convex portion 200x formed at the end in the extending direction of the second lock portion 200b is linked to the second release operation portion 201b via the axis R. Here, the shaft R of the locking device 20 is loaded with an elastic body (not shown) that can bias the convex portion 200x downward (−Z direction) with the shaft R as a rotation axis. The convex portion 200x is urged by the elastic body in the protruding direction of the convex portion 200x, and at the same time, the first release operation portion 201a and the second release operation portion 201b are urged upward (in the + Z direction).

  As shown in FIG. 3A, on the inner rail 111 of the slide rail 11a, the regulating members p1, p2 for enabling the slide of the stored item A to be regulated by the first lock portion 200a and the second lock portion 200b. , P3. The regulating members p1, p2, and p3 are provided in the extending direction of the inner rail 111 on the upper surface (the surface on the + Z direction side) of the inner rail 111, respectively. As shown in FIG. 3A, the inner rail 111 has a front end of the regulating member p1 at a position away from the first end T1 of the slide rail 11a by a predetermined length to the rear (−X direction) side. q11 (the end on the + X direction side) is located, and is arranged on the rear side (−X direction) side continuously with the regulating member p2 and the regulating member p3. The rear end q32 (the end on the −X direction side) of the regulating member p3 is located on the front (+ X direction) side by a predetermined length from the second end portion T2 of the slide rail 11a.

As shown in FIG. 3 (a), when the stored item A is in a predetermined accommodation position, the front end q11 of the regulating member p1 is the side edge t11 on the rear side of the convex portion 200x of the first lock portion 200a. -X direction side edge of the convex part 200x). Accordingly, the convex portion 200x of the first lock portion 200a fixed to the outer rail 110 functions so as to inhibit the movement of the regulating member p1 provided on the inner rail 111 to the front side, so that the first lock portion The convex part 200x of 200a regulates the slide to the front S1 side (+ X direction side, refer FIG. 1) of the stored thing A. FIG.
Similarly, when the stored item A is in a predetermined accommodation position, the rear end q32 of the regulating member p3 is the front side edge t21 of the convex portion 200x in the second lock portion 200b (on the + X direction side of the convex portion 200x). The edge). Accordingly, the convex portion 200x of the second lock portion 200a fixed to the outer rail 110 functions to inhibit the movement of the regulating member p3 provided on the inner rail 111 to the rear side, so that the second lock portion The convex part 200x of 200b regulates the slide to the back surface S2 side (-X direction side, refer FIG. 1) of the stored thing A. FIG.
Thus, the 1st lock part 200a and the 2nd lock part 200b of the locking device 20 regulate the slide of the stored matter A in the accommodation position. By doing in this way, the locking device 20 can suppress that the storage thing A unintentionally slides from an accommodation position.

  Further, the rear end q22 (−X direction side end) of the regulating member p2 and the front end q31 (+ X direction side end) of the regulating member p3 are provided apart from each other, so that the regulating member p2 and the regulating member are restricted. A recess m2 is formed between the working member p3. The width of the recess m2 in the slide direction (± X direction) is formed to be larger than the width of the protrusion 200x in the slide direction. The convex portion 200x of the first lock portion 200a is immersed in the concave portion m2 when the stored item A slides to the first position. This will be described with reference to FIGS. 3B and 3C.

FIG. 3B illustrates a state in which the stored item A has been slid by a predetermined length forward (+ X direction) from a predetermined accommodation position.
As shown in FIG. 3B, the operator moves down the first release operation portion 201a provided so as to protrude forward (+ X direction) from the first end T1 (the front surface S1 of the rack 10) ( Press down in the -Z direction). Since the convex part 200x is located on the opposite side to the first release operation part 201a with respect to the axis R, when the first release operation part 201a is lowered, the axis R serves as a fulcrum and the first lock part 200a. The convex portion 200x is lifted upward (+ Z direction). Then, the front end q11 of the regulating member p1 provided on the inner rail 111 does not come into contact with the side edge t11 of the convex portion 200x. On the other hand, the side edge t21 of the convex portion 200x of the second lock portion 200b is in contact with the rear end p32 side of the regulating member p3, but this is because the inner rail 111 slides to the front (+ X direction) side. It does not regulate. Therefore, the inner rail 111 can slide forward in the sliding direction (+ X direction). That is, when the operator pushes down the first release operation portion 201a downward, the slide restriction at the storage position of the stored item A is released (see FIG. 3B). When the operator pulls the stored item A forward (+ X direction) side while pushing down the first release operation unit 201a, the stored item A slides forward (+ X direction) side.
In the state shown in FIG. 3B, when the operator releases his / her hand from the first release operation portion 201a, the convex portion 200x of the first lock portion 200a urged downward is the regulating member p1. Alternatively, the upper surface (the surface on the + Z direction side) of the regulating member p2 is pressed downward (the −Z direction). Accordingly, the convex portion 200x of the first lock portion 200a is maintained in a state where the lower end thereof is raised to the height of the upper surface of the regulating members p1 and p2 from the initial position (see FIG. 3A). Since the convex portion 200x in this state does not restrict the sliding of the inner rail 111 in the sliding direction (± X direction), even if the operator releases his / her hand from the first release operation portion 201a, the stored item A Can be slid.

FIG. 3C illustrates a state in which the stored item A has been slid to a predetermined first position.
As shown in FIG. 3 (c), the stored item A is slid to the first position (that is, the stored item A is slid forward (+ X direction) from the accommodation position by the first length L1 = La / 2. ), The convex part 200x of the first lock part 200a urged downward (−Z direction) is immersed in the concave part m2. Then, the side edge t11 of the convex portion 200x abuts on the front end q31 (+ X direction side end) of the regulating member p3, and the side edge t12 opposite to the side edge t11 is the rear end q22 of the regulating member p2. (The end on the −X direction side) abuts. Thereby, the convex part 200x of the first lock part 200a fixed to the outer rail 110 moves to the rear side of the regulating member p2 provided on the inner rail 111, and moves to the front side of the regulating member p3. Functions to inhibit migration. In this way, the first lock portion 200a restricts the stored item A from sliding from the first position.

Although not shown, the operator moves downward (-) the second release operation unit 201b provided so as to protrude rearward (-X direction) from the second end T2 (the rear surface S2 of the rack 10). The stored item A can be slid backward (−X direction) in the sliding direction by performing an operation of pushing down in the Z direction. That is, when the second release operation portion 201b is lowered, the axis R serves as a fulcrum, and the convex portion 200x of the second lock portion 200b is lifted upward (+ Z direction). Then, the rear end q32 of the regulating member p3 provided on the inner rail 111 does not come into contact with the side edge t21 of the convex portion 200x, so that the stored item A (the inner rail 111) is on the rear side (−X direction) in the sliding direction. The slide restriction to is released.
Here, the rear end q12 (−X direction side end) of the regulating member p1 and the front end q21 (+ X direction side end) of the regulating member p2 are provided apart from each other, thereby restricting the regulating member p1. A recess m1 is formed between the regulating member p2. The convex portion 200x of the second lock portion 200b has a second length L2 = La / 2 in a state where the stored item A slides to the second position (that is, the stored item A moves backward (−X direction) from the storage position). Only slid into the recess m1. Then, the side edge t21 of the convex portion 200x abuts on the rear end q12 (end on the −X direction side) of the regulating member p1, and the side edge t22 opposite to the side edge t21 is the front end of the regulating member p2. It abuts on p21 (the end on the + X direction side). Thereby, the convex part 200x of the second lock part 200b fixed to the outer rail 110 moves to the rear side of the regulating member p1 provided on the inner rail 111, and moves to the front side of the regulating member p2. Functions to inhibit migration. In this way, the second lock portion 200b restricts the stored item A from sliding from the second position.
The recesses m1 and m2 include a slide amount (first length L1) of the storage item A from the storage position to the first position and a slide amount (second length) of the storage item A from the storage position to the second position. It is provided at a position where the length L2) is equal.

  According to the configuration as described above, the first lock part 200a and the second lock part 200b can regulate the slide of the stored item A by the engagement of the convex part 200x and the concave parts m1 and m2. Therefore, the lock part 200 can be configured with a simple structure.

FIG. 4 is a second diagram illustrating the configuration and function of the locking device according to the first embodiment.
4 (a) to 4 (c) show more specifically the structures of the locking device 20 and the slide rail 11a schematically shown in FIGS. 3 (a) to 3 (c).
FIG. 4A shows a state in which the stored item A is in the initial position (corresponding to FIG. 3A). As shown in FIG. 4A, the locking device 20 is fixedly installed on the upper side of the outer rail 110 on the first end portion T1 side with the axis R. The first locking part 200a of the locking device 20 has a convex part 200x formed so as to protrude downward from the axis R at a position extending a predetermined length rearward in the sliding direction (−X direction). . When the stored item A is in the initial position, as shown in FIG. 4A, the convex portion 200x of the first lock portion 200a is formed at the front end of the regulating member p1 provided above the inner rail 111 ( + X direction side end). Thereby, the 1st lock part 200a regulates the slide to the front (+ X direction) side of inner rail 111 (containment A).

FIG. 4B shows a state immediately after the operator pushes down the first release operation unit 201a downward from the state of FIG.
As shown in FIG. 4B, the operator pushes down the first release operation portion 201a disposed on one side of the shaft R that pivotally supports the entire locking device 20 so that the other side of the shaft R is moved to the other side. A certain first lock portion 200a is lifted upward. If it does so, since the convex part 200x will not contact | abut to the front end (end of + X direction) of the member p1 for regulation provided in the inner rail 111, the inner rail 111 can slide to the front (+ X direction) side.

FIG. 4C shows a state in which the stored item A has been slid a predetermined distance forward (+ X direction) from the initial position (corresponding to FIG. 3B).
The operator moves the inner rail 111 (contained item A) forward (+ X direction) while maintaining the state in which the convex part 200x of the first lock part 200a is lifted upward (+ Z direction) (the state shown in FIG. 4B). ) Side, the inner rail 111 slides to the front side (see FIG. 4C). At this time, the protruding end (end on the −Z direction side) of the convex portion 200x comes into contact with the upper surface of the regulating member p1 provided on the inner rail 111. The convex portion 200x in this state is not immersed in the concave portions m1, m2, etc., and the sliding direction (± X direction) does not come into contact with either the front side or the rear side. Does not restrict the sliding in the forward direction (+ X direction).

FIG. 5 is a first diagram for explaining the function and effect of the locking device according to the first embodiment.
FIG. 5A shows a state in which the stored item A is in the first position. As described above, when the stored item A is in the first position, the convex portion 200x of the first lock portion 200a is immersed in the concave portion m2 provided in the inner rail 111 and restricts the slide of the stored item A. At this time, the front end (the end in the + X direction) of the stored item A has a first length L1 = La from the first end T1 (the front surface S1 of the rack 10) of the slide rails 11a and 11b to the front (the + X direction). It protrudes by / 2. Therefore, the area A1 that occupies the front (+ X direction) side of the stored item A accommodated in the rack 10 is exposed. On the other hand, a region A <b> 2 occupying half of the stored item A on the rear (−X direction) side remains inside the rack 10. Therefore, when the stored item A is in the first position, the worker can access only the exposed front side area A1 of the stored item A.

  FIG. 5B shows a state in which the stored item A is in the second position. When the stored item A is in the second position, the convex portion 200x of the second lock portion 200b is immersed in the concave portion m1 provided in the inner rail 111 and restricts the slide of the stored item A. At this time, the rear end (the end in the −X direction) of the stored item A has a second length L2 from the second end T2 (the back surface S2 of the rack 10) of the slide rails 11a and 11b to the rear (the −X direction). It protrudes by = La / 2. Therefore, a region A2 that occupies half of the stored item A accommodated in the rack 10 on the rear (−X direction) side is exposed. On the other hand, the area A 1 occupying the front (+ X direction) side half of the stored item A remains inside the rack 10. Therefore, when the stored item A is in the second position, the worker can access only the exposed rear side region A2 of the stored item A.

As described above, the operator can access the area A1 that occupies one half of the storage A by operating the first release operation unit 201a from the front surface S1 side of the rack 10, and the rear surface of the rack 10. By operating the second release operation unit 201b from the S2 side, it is possible to access the area A2 that occupies the other half of the stored item A. Therefore, the worker can access all the areas of the stored items A accommodated in the rack 10 and perform maintenance / inspection.
In addition, at least one of the area A1 or the area A2 of the stored item A is always accommodated in the rack 10. Therefore, even if the stored item A is in the pulled-out state, the center of gravity of the entire storage device 1 is prevented from greatly fluctuating, and the entire casing formed in a rectangular parallelepiped shape can be stabilized.

Further, in the locking device 20 according to the present embodiment, the first release operation portion 201a that releases the slide restriction from the front surface S1 of the rack 10 to the front (+ X direction) side of the stored item A projects forward from the front surface S1. To be provided. Moreover, the 2nd cancellation | release operation part 201b which cancels | releases the sliding regulation from the back surface S2 of the rack 10 to the back (-X direction) side of the stored thing A is provided so that it may protrude from the said front S2 to the back side.
With such a configuration, the operator can release the restriction of sliding in the direction in which the rack 10 can slide from the front S1 side or the back S2 side from either the front S1 side or the back S2 side. That is, the worker who has accessed the stored item A from the first end portion T1 side can easily operate the first release operation unit 201a to release the slide restriction state of the stored item A. Further, the worker who has accessed the stored item A from the second end portion T2 side can easily operate the second release operation unit 201b to release the slide restriction state of the stored item A. As a result, the work efficiency of the worker can be improved.
In addition, since the first release operation unit 201a and the second release operation unit 201b are provided so as to protrude from the front surface S1 or the rear surface S2 of the rack 10, the operator can easily operate them by holding them in their hands. Thus, work efficiency can be improved.

  As mentioned above, according to the locking device 20 which concerns on 1st Embodiment, while being able to restrict | limit the sliding amount to the 1st end part T1 side of the stored thing A, the 2nd end part T2 side of the stored thing A can be limited. The amount of slide can be limited. Further, the sum of the amount slidable toward the first end T1 (first length L1) and the amount slidable toward the second end (second length L2) is the total length of the stored item A. Since it is equal to La, the operator can access the entire area of the stored item A by changing the sliding direction. Further, for example, by limiting the workers that can be accessed from the first end T1 side, it is possible to set access restrictions according to the slide area of the stored item A. Further, for example, the amount of protrusion of the stored item A can be reduced as compared with a case where the stored item A can be slid only to the first end T1 side or the second end T2 side. The degree can be improved. Further, when returning the stored item A to the storage position, the restriction can be easily released by operating the first release operation unit 201a and the second release operation unit 201b.

FIG. 6 is a second diagram illustrating the operation and effect of the locking device according to the first embodiment.
FIG. 6A schematically shows a configuration of a storage system 9 in which a plurality of storage devices 8 according to the present embodiment are arranged. Moreover, FIG.6 (b) has shown typically the structure of the accommodation system 3 formed by arranging two or more accommodation apparatuses 1 which concern on this embodiment.

  The accommodation device 8 according to the comparative example of the present embodiment is a accommodation device that allows the stored item A to be slid only from the front side S <b> 1 of the rack 10. In this case, it is necessary to be able to access the entire area of the stored item A accommodated in the rack 10. Therefore, as shown in FIG. 6A, the storage device 8 is slid from the front surface S1 by the length that the entire area of the stored item A is exposed, that is, the entire length La in the sliding direction (± X direction) of the stored item A. Configured as possible.

A storage system in which a plurality of storage devices 8 configured as described above are arranged on a predetermined floor surface (XY plane) in the slide direction (± X direction) of the stored item A and in the vertical direction (± Y direction). 9 will be described below.
As shown in FIG. 6A, when the containment system 9 is configured by arranging the storage items A on the floor (XY plane), a space necessary for the operator to perform maintenance and inspection of the storage items A is provided. It is necessary to secure. That is, in order to be able to access the entire area of the stored item A, the storage device 8 arranged in the first row and the front of the stored item A in the sliding direction (+ X direction) are arranged in the second row. The passage width (interval α1) with the storage device 8 to be stored needs to be equal to or greater than the total length La of the stored item A. In the example shown in FIG. 6A, a clearance width ΔL is provided for the purpose of preventing contact between the stored items A of the first row of storage devices 8 and the rack 10 of the second row of storage devices 8. The interval α1 is set to α1 = La + ΔL. As described above, the storage system 9 formed by arranging a plurality of the storage devices 8 in proportion to each other needs to secure a space of the interval α1 = La + ΔL for each column.

  On the other hand, as described above, the storage device 1 according to the present embodiment is a storage device that allows the stored item A to be slid by half from both the front S1 side and the back S2 side of the rack 10. Therefore, the storage device 1 can be slid from the front surface S1 and the rear surface S2 by a length that half of the area of the stored item A is exposed, that is, 1/2 of the entire length La in the sliding direction (± X direction) of the stored item A. Configured as follows.

The following is a description of a storage system 3 in which a plurality of such storage devices 1 are arranged in the slide direction (± X direction) and the vertical direction (± Y direction) of the stored item A on a predetermined floor surface (XY plane). Explained.
As shown in FIG. 6B, the accommodation device 1 arranged in the first row, and the accommodation device 1 arranged in the second row in the slide direction front (+ X direction) of the stored item A, The passage width (interval α2) must be equal to or greater than ½ of the total length La of the stored item A. In the example shown in FIG. 6B, a clearance width ΔL is further added to set the interval α2 to α2 = La / 2 + ΔL.
In this way, the operator slides from the front surface S1 of the storage device 1 arranged in the first row in the space of the interval α2 provided between the first row and the second row. Both the object A and the stored object A that slides from the back surface S2 of the storage device 1 arranged in the second row can be accessed. In addition, due to the function of the locking device 20, a slide of the storage item A from the front surface S1 of the storage device 1 arranged in the first row and a storage item from the back surface S2 of the storage device 1 arranged in the second row All slides of A are regulated at the first position or the second position where the slide amount is La / 2. Accordingly, the stored item A that slides from the front surface S1 of the storage device 1 arranged in the first row does not contact the rack 10 of the storage device 1 arranged in the second row. Similarly, the stored item A that slides from the back surface S2 of the accommodation device 1 arranged in the second row does not contact the rack 10 of the accommodation device 1 arranged in the first row.
As described above, the storage system 3 according to the present embodiment accesses the storage A of the storage device 1 in the first row and the storage A of the storage device 1 in the second row. And share the space. Therefore, if the stored items A are not pulled out simultaneously from the storage devices 1 adjacent to each other in the sliding direction (± X direction) to the sides facing each other, even if the interval in the sliding direction between the storage devices 1 is shortened, all The stored item A can be accessed. Specifically, the accommodation system 3 can reduce the interval between the first row and the second row to about ½ compared to the accommodation system 9 configured by the accommodation devices 8 that are in proportion to each other. .
As described above, according to the storage system 3 according to the present embodiment, the passage width provided on both sides in the sliding direction of the storage device can be narrowed, and more storage devices can be arranged with a predetermined floor area.

  In addition, the storage device 1 according to the present embodiment includes a slide amount (first length L1) of the storage item A from the storage position to the first position and a slide amount of the storage item A from the storage position to the second position. The second length L2 is equal to the second length L2. Accordingly, when the storage devices 1 including the slidable storage A are arranged side by side in the sliding direction, the protruding amounts of the storage A that are slid out of the storage devices 1 are equal. As a result, the intervals in the sliding direction between the plurality of storage devices 1 can be set to be the same, and the device layout can be easily determined.

  Further, by storing various electronic devices constituting the server in the accommodation device 1 according to the present embodiment, more servers can be installed with a predetermined floor area. Further, for example, in the case of a high-density server configured so that a module can be attached and detached, the recombination work of the module can be easily performed by sliding the storage A.

  As described above, according to the lock device 20, the storage device 1, and the storage system 3 according to the first embodiment, it is possible to access the entire area in the sliding direction of the slidable shelf (containment A), and the surrounding work space Can be reduced.

  The lock device 20, the storage device 1, and the storage system 3 according to the first embodiment are not limited to the above-described aspects, and can be modified as follows.

FIG. 7 is a diagram illustrating a configuration of a lock device according to a modification of the first embodiment.
As shown in FIGS. 2A to 2C, the locking device 20 according to the first embodiment includes a slide rail 11 a fixed to one side surface (a surface parallel to the XZ plane) of the stored item A. Although described as an embodiment in which one is provided at each end, the present invention is not limited to this embodiment in other embodiments. For example, the lock device 20 according to the modification is fixed to the first end T1 side of the slide rail 11a fixed to one side surface of the stored item A and the other side surface of the stored item A, as shown in FIG. One mode may be provided for each of the slide rails 11b on the second end portion T2 side. In other words, one lock device 20 is provided on each of the side surfaces of the stored item A.
In this case, the inner rail 111 of the slide rail 11a is provided with a recess m2 at a position where the stored item A can be regulated at the first position, and the stored item A is second on the inner rail 111 of the slide rail 11b. It is assumed that the recess m1 is provided at a position where the position can be regulated.
By doing in this way, one recessed part m1, m2 is provided in each of the two inner rails 111 distribute | arranged on the both sides | surfaces of the stored thing A. As shown in FIG. Therefore, for example, when the stored item A is slid forward (in the + X direction), the convex portion 200x of the first lock portion 200a is provided with the concave portion m2 provided for restriction at the first position of the stored item A. Can prevent immersion in different recesses. Thereby, an operator's working efficiency can be improved.

  Further, as shown in FIGS. 2A and 2B, the locking device 20 according to the first embodiment is provided on each of the first end T1 side and the second end T2 side of the slide rail 11a. Although described as a mode in which a total of two are provided one by one, other embodiments are not limited to this mode. For example, the lock device 20 according to another modification may have an aspect having only a single lock unit 200.

  The slide rails 11a and 11b may be provided with a mechanism (for example, a roller or the like) that smoothly slides the stored item A.

FIG. 8 is a diagram illustrating an overall configuration of a locking device according to another embodiment.
As shown in FIG. 8, the lock device 20 that regulates the sliding of the slidable shelf (contained item A) includes a lock unit 200 and a release operation unit 201. The lock part 200 is stored in the first position where the storage A is slid from the predetermined accommodation position toward the first end T1 by a first length shorter than the total length La in the sliding direction of the storage A. Regulate slide A. Further, the lock portion 200 has the second end T2 opposite to the first end T1 side by the second length that is the difference between the total length La of the stored matter A and the first length. The slide of the stored item A is regulated at the second position slid to the side.
The release operation unit 201 releases the slide restriction of the stored item A by the lock unit 200.

  According to such a configuration, it is possible to limit the amount of slide of the stored item A toward the first end T1 side, and it is possible to limit the amount of slide of the stored item A toward the second end T2 side. . Furthermore, since the sum of the slidable amount to the first end T1 side and the slidable amount to the second end T2 side is equal to the total length La of the storage A, changing the sliding direction of the storage A The entire area can be accessed. Further, for example, by limiting the workers that can be accessed from the first end T1 side, it is possible to set access restrictions according to the slide area of the stored item A. Furthermore, since the amount of protrusion of the stored item A can be reduced as compared with the case where it can slide only to the first end T1 side or the second end T2 side, for example, the degree of freedom of arrangement of the apparatus including the stored item A is improved. can do. Further, when returning the stored item A to the accommodation position, the restriction can be easily released by operating the release operation unit 201.

  As mentioned above, although some embodiment of this invention was described, these embodiment is shown as an example and is not intending limiting the range of invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the invention described in the claims and equivalents thereof, as long as they are included in the scope and gist of the invention.

1, 8 Accommodation device 10 Rack A Containment (shelf)
11a Slide rail (support)
11b Slide rail (support)
110 Outer rail 111 Inner rail 20 Lock device 200 Lock part 200a First lock part 200b Second lock part 201 Release operation part 201a First release operation part 201b Second release operation parts 3 and 9 Accommodation system

Claims (10)

While regulating the sliding of the shelf at the first position where the shelf is slid from the predetermined storage position to the first end side by a first length shorter than the total length in the sliding direction of the shelf, At the second position, the shelf is slid to the second end side opposite to the first end side by a second length that is the difference between the total length and the first length. A lock that regulates the body slide;
A release operation part for releasing the slide restriction of the shelf body by the lock part;
A locking device comprising: The release operation part is
A first release operation unit for releasing the slide restriction of the shelf in the first position;
A second release operation part for releasing the slide restriction of the shelf in the second position,
The first release operation part is provided on the first end side of the support body that supports the shelf body,
The lock device according to claim 1, wherein the second release operation unit is provided on the second end side of the support body. The first release operation unit includes:
In the first end portion of the support body, the shelf body is provided so as to protrude in a direction from the accommodation position toward the first position side,
The second release operation unit includes:
The locking device according to claim 2, wherein at the second end portion of the support body, the shelf body is provided so as to protrude in a direction from the accommodation position toward the second position side. The lock part is
The first release operation unit and the second release operation unit are respectively linked to the second release operation unit and provided with a convex portion biased in a protruding direction, and the shelf or the support body has the shelf at the first position. The locking device according to claim 2, wherein a concave portion into which the convex portion is recessed when sliding to the second position is formed. The slide amount of the shelf from the storage position to the first position is equal to the slide amount of the shelf from the storage position to the second position. The locking device as described. The lock part is
The locking device according to any one of claims 1 to 5, wherein a slide of the shelf body in the accommodation position is regulated. A shelf,
A support for slidably supporting the shelf,
The locking device according to any one of claims 1 to 6,
A storage device comprising:   A server comprising the accommodation device according to claim 7 and an electronic device accommodated in the accommodation device.   A storage system comprising the storage device according to claim 7, wherein a plurality of the storage devices are arranged in a sliding direction of the shelf. The shelf to the first end side at the first position where the shelf body is slid from the predetermined accommodation position to the first end side by a first length shorter than the total length in the sliding direction of the shelf body. Regulating the body slide;
At the second position where the shelf is slid to the second end side opposite to the first end side by a second length that is the difference between the total length and the first length, Restricting sliding of the shelf to the two end sides;
A method of storing a shelf having

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