JP2011092259A - Slide rail unit, rack cabinet, removal implement, and removal method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a slide rail unit, rack cabinet, removal implement, and removal method that can minimize the workspace needed for removing a travel rail from a middle rail and that can enhance stability of a mount. <P>SOLUTION: The slide rail unit is provided with: a slide rail 2 including an outer rail 4 (fixed rail) that can be mounted on the strut of a rack cabinet 100, a middle rail 5 drawably supported by the outer rail 4, and an inner rail 6 (travel rail) drawably supported by the middle rail 5; and a stopper 3 that practically restrains drawing of the middle rail 5 from the outer rail 4 while drawing of the inner rail 6 from the middle rail 5 is permitted. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a slide rail unit, a rack cabinet, a removal tool, and a removal method, and more particularly to a technique for removing a moving rail from an intermediate rail.

  As this kind of technology, Patent Document 1 discloses a fixed rail fixed to a gantry, an intermediate rail supported so as to be able to be pulled out with respect to the fixed rail, and a moving rail supported so as to be able to be pulled out with respect to the intermediate rail. The slide rail comprised from these is disclosed. A mounting table is attached to the moving rail, and a gas analyzer unit is mounted on the mounting table. The moving rail can be removed from the intermediate rail so that the analyzer unit can be freely carried along with the mounting table.

  Specifically, in normal use conditions, a lock mechanism is provided between the moving rail and the intermediate rail to prevent the analyzer unit from being accidentally pulled out of the intermediate rail and falling. It has been. This locking mechanism is configured by a lock pin provided on the intermediate rail and a spring stopper provided on the moving rail. In this configuration, when the analyzer unit is pulled out from the gantry, the intermediate rail is pulled out to the maximum with respect to the fixed rail, and the moving rail is pulled out from the intermediate rail. Eventually, when the locking mechanism is activated, further pulling of the moving rail with respect to the intermediate rail is prevented.

  When carrying from this state, first, the mounting table is further pulled out while releasing the lock by the lock mechanism. At this time, the intermediate rail is pulled out to the maximum with respect to the fixed rail. In other words, the intermediate rail is held by the fixed rail. When the moving rail is completely pulled out from the intermediate rail, the analyzer unit can be freely carried along with the mounting table and the moving rail.

JP 2000-236970 A

  However, the above-described slide rail of Patent Document 1 has the following problems. That is, in order to fully pull out the moving rail from the intermediate rail during the above-mentioned carrying, the intermediate rail has already been pulled out to the maximum with respect to the fixed rail, so a considerable working space on the front side of the gantry. It was necessary to ensure.

  In addition, when the moving rail is completely pulled out from the intermediate rail when carrying the above, the center of gravity of the entire gantry moves further to the front side of the gantry, so there is room for improvement in terms of the stability of the gantry. .

  An object of the present invention is to provide a slide rail unit, a rack cabinet, a removal tool, and a removal method that can solve the above-described problems.

  According to the first aspect of the present invention, a slide rail unit configured as follows is provided. That is, the slide rail unit includes a fixed rail that can be attached to a column of a rack cabinet, an intermediate rail that is supported so as to be drawable with respect to the fixed rail, and a movable rail that is supported so as to be drawable with respect to the intermediate rail. , And a drawer restraining means that substantially prevents the middle rail from being pulled out from the fixed rail while allowing the drawer of the moving rail from the middle rail.

  According to the 2nd viewpoint of this invention, the rack cabinet comprised as follows is provided. That is, a support, a fixed rail that can be attached to the support, an intermediate rail that is supported so as to be able to be pulled out with respect to the fixed rail, a moving rail that is supported so as to be able to be pulled out with respect to the intermediate rail, and the intermediate rail And a drawer restraining means for substantially inhibiting the withdrawal of the intermediate rail from the fixed rail while allowing the drawer of the moving rail from the stationary rail.

  According to the 3rd viewpoint of this invention, the removal tool comprised as follows is provided. That is, the remover includes a fixed rail that can be attached to a column of a rack cabinet, an intermediate rail that is supported so as to be able to be pulled out with respect to the fixed rail, and a moving rail that is supported so as to be able to be pulled out with respect to the intermediate rail. , For removing the moving rail from the intermediate rail. The removal tool substantially prevents the intermediate rail from being pulled out from the fixed rail while allowing the moving rail from being pulled out from the intermediate rail.

  According to the fourth aspect of the present invention, a fixed rail that can be attached to a column of a rack cabinet, an intermediate rail that is supported so as to be drawable with respect to the fixed rail, and a pullable support that is supported with respect to the intermediate rail. The following method is employed when the moving rail is removed from the intermediate rail among the slide rails including the moving rail. That is, the moving rail is pulled out from the intermediate rail while substantially pulling out the intermediate rail from the fixed rail.

  According to the present invention, a slide rail unit, a rack cabinet, a detachable tool, and a detachable unit that can reduce the work space required to remove the moving rail from the intermediate rail and can further improve the stability of the gantry. A method can be provided.

The perspective view of the slide rail unit which concerns on 1st embodiment. The perspective view of the rack cabinet which concerns on 2nd embodiment. Front view of the slide rail unit according to the second embodiment The perspective view of the control mechanism provided in the slide rail unit which concerns on 2nd embodiment. FIG. 5 is a cross-sectional view taken along line VV in FIG. The disassembled perspective view of the removal tool which concerns on 2nd embodiment The figure which shows the 1st state and 2nd state of the said removal tool Operation explanatory diagram of the slide rail unit Operation explanatory diagram of the slide rail unit Operation explanatory diagram of the slide rail unit

<First embodiment>
Hereinafter, a first embodiment of the present invention will be described with reference to FIG.

  The slide rail unit 1 is configured to include a slide rail 2 and a stopper 3 that is a removal tool serving as a drawer restraining means. The slide rail 2 includes an outer rail 4 as a fixed rail attached to the column 101 of the rack cabinet 100, an intermediate rail 5 supported so as to be drawable with respect to the outer rail 4, and a drawer with respect to the intermediate rail 5. And an inner rail 6 as a movable rail that is supported. The inner rail 6 is attached to a supported device 7 such as various measuring devices, computer devices, or server devices.

  Specifically, the outer rail 4 is fixed to the column 101 of the rack cabinet 100 through the bracket 8 so as to be substantially horizontal. Further, balls (not shown) are sandwiched between the outer rail 4 and the intermediate rail 5 and between the intermediate rail 5 and the inner rail 6, respectively.

  Moreover, the stopper 3 is being fixed to the outer rail 4 through said support | pillar 101 and the bracket 8 in order. With this configuration, the stopper 3 is substantially in the state shown in FIG. 1 while allowing the inner rail 6 to be pulled out from the intermediate rail 5 and substantially preventing the middle rail 5 from being pulled out from the outer rail 4. Yes.

  According to the slide rail unit 1 according to the present embodiment, the inner rail 6 can be removed from the intermediate rail 5 at a position close to the outer rail 4.

  Therefore, the work space on the front side of the rack cabinet 100 that is required when the inner rail 6 is removed from the intermediate rail 5 can be made compact. From another point of view, when removing the inner rail 6 from the intermediate rail 5, the center of gravity of the entire rack cabinet 100 is excessively moved to the front side of the rack cabinet 100 as compared with the configuration of Patent Document 1 described above. Therefore, the rack cabinet 100 is excellent in stability.

<Second embodiment>
Next, a second embodiment of the present invention will be described with reference to FIGS. Note that components that correspond to the components described in the first embodiment are given the same reference numerals in principle.

(Rack cabinet 100)
A rack cabinet 100 shown in FIG. 2 includes a bottom plate 102 provided with casters (not shown) on four sides, four support columns 101 provided on the bottom plate 102, and a top plate 103 facing the bottom plate 102 with the support columns 101 interposed therebetween. And as a main configuration. The supported device 7 is supported by the support column 101 via the slide rail 2.

  FIG. 2 shows three states of the supported device 7. That is, in the upper stage of the rack cabinet 100, the accommodation state of the supported device 7 in which the supported device 7 is completely accommodated in the rack cabinet 100 is shown. Similarly, in the middle stage of the rack cabinet 100, the supported device 7 is pulled out from the rack cabinet 100 to the front side, and a normal maintenance state of the supported device 7 is shown in which the upper surface and side surfaces of the supported device 7 can be maintained. ing. In the lower part of the rack cabinet 100, the supported device 7 is detached from the rack cabinet 100 and the supported device 7 is removed.

  Here, terms used in the present specification are defined. In FIG. 2, a direction in which the supported device 7 is pulled out from the rack cabinet 100 is hereinafter simply referred to as a “drawing direction” and is indicated by a symbol PU. Similarly, the direction in which the supported device 7 is accommodated in the rack cabinet 100 is hereinafter simply referred to as “accommodating direction” and is indicated by the symbol AC. That is, the pull-out direction PU and the accommodation direction AC are in an opposite relationship.

  For example, as shown in FIG. 8, each support column 101 includes a frame portion 101 a lacking a part in plan view, a first support portion 101 c having a first mounting surface 101 b perpendicular to the pull-out direction PU, and a pull-out direction. And a second support portion 101e having a second mounting surface 101d parallel to the PU. The first mounting surface 101b of the first support portion 101c is formed with a large number of mounting holes 101f arranged in the vertical direction. By using these mounting holes 101f, the front surface of the supported device 7 shown in FIG. The panel 7 a can be screwed to the first support portion 101 c of the support column 101.

(Slide rail unit 1)
In the present embodiment, as shown in FIG. 2, the slide rail unit 1 includes a slide rail 2 and a stopper 3 that is a removal tool as a pull-out restraining unit as main components. As shown in the figure, the slide rail unit 1 is provided as a pair so as to sandwich the supported device 7. Since each slide rail unit 1 is left-right symmetric when viewed from the front side of the rack cabinet 100, in the following description, among the pair of slide rail units 1, the slide rail unit 1 that is the front side in FIG. Only the description will be given, and the other description will be omitted.

(Slide rail 2)
As shown in FIG. 3, the slide rail 2 includes an outer rail 4 as a fixed rail attached to the support column 101, an intermediate rail 5 that is supported so as to be able to be pulled out with respect to the outer rail 4, and the intermediate rail 5. And an inner rail 6 as a moving rail supported so as to be drawable. In the front view of FIG. 3, the outer rail 4 has a relationship for accommodating the intermediate rail 5, and the intermediate rail 5 has a relationship for accommodating the inner rail 6. Further, the outer rail 4, the intermediate rail 5, and the inner rail 6 all have substantially the same length in the pull-out direction PU shown in FIG. Further, as shown in FIG. 2, the slide rail 2 is attached substantially horizontally to the support column 101. In this configuration, the inner rail 6 is fixed to the side surface 7b of the supported device 7 as shown in FIG.

  Specifically, as shown in FIG. 3, the outer rail 4 is fixed to the second support portion 101 e of the support column 101 (see also FIG. 8) via a bracket 8. Ball grooves 4 a are formed above and below the outer rail 4. Similarly, ball grooves 6 a are formed above and below the inner rail 6. A first ball groove 5 a that faces the ball groove 4 a of the outer rail 4 and a second ball groove 5 b that faces the ball groove 6 a of the inner rail 6 are formed above and below the intermediate rail 5. With this configuration, a plurality of balls (not shown) are sandwiched between the ball groove 4 a of the outer rail 4 and the first ball groove 5 a of the intermediate rail 5, so that the intermediate rail 5 can be smoothly pulled out from the outer rail 4. It has been realized. Similarly, a plurality of balls (not shown) are sandwiched between the second ball groove 5b of the intermediate rail 5 and the ball groove 6a of the inner rail 6, so that the inner rail 6 can be smoothly pulled out from the intermediate rail 5. Has been.

(Regulatory structure of slide rail 2)
Next, with reference mainly to FIGS. 4 and 5, a restriction structure R as a restriction means for restricting the inner rail 6 from being pulled out from the intermediate rail 5 by a predetermined amount or more will be described. In the present embodiment, the restricting structure R includes a disconnect spring 9 as an elastic member attached to the inner rail 6 as shown in FIG.

  Specifically, the disconnect spring 9 is attached to a vertical surface 6 b as a surface of the inner rail 6 that is substantially vertical and faces the intermediate rail 5. The disconnect spring 9 is formed by bending a stainless steel plate. The disconnect spring 9 extends in the accommodating direction AC. The disconnect spring 9 includes a mounting portion 9a, a first inclined portion 9b, a claw holding portion 9c, and a second inclined portion 9d in order along the accommodating direction AC.

  The attachment portion 9a is fixed to the vertical surface 6b of the inner rail 6 by spot welding. As shown in FIG. 5A, the first inclined portion 9b is inclined so as to be separated from the vertical surface 6b of the inner rail 6 as the distance from the attaching portion 9a is increased. As shown in FIG. 4, a pair of upper and lower claws 9e is formed on the claw holding portion 9c. As shown in FIG. 5A, the claw 9 e protrudes from the claw holding portion 9 c toward the intermediate rail 5. A vertical edge 9f as a first edge substantially perpendicular to the claw holding portion 9c in the cross-sectional view of FIG. 5A is formed at the end of the claw 9e on the attachment portion 9a side. On the other hand, an inclined edge 9g as a second edge inclined with respect to the claw holding portion 9c is formed at the end of the claw 9e on the second inclined portion 9d side. 9 d of 2nd inclination parts incline so that it may approach with respect to the vertical surface 6b of the inner rail 6 as it leaves | separates from the nail | claw holding | maintenance part 9c.

  On the other hand, the vertical surface 5c as the surface of the intermediate rail 5 that is substantially vertical and faces the inner rail 6 accommodates at least a part or all of the claw 9e as an accommodating portion. A pair of holes 5d is formed as shown in FIG. As shown in FIG. 5B, the edge 5 e of the accommodation hole 5 d is substantially perpendicular to the vertical surface 5 c of the intermediate rail 5.

  With the above configuration, the restriction structure R operates as follows. FIG. 5A shows a state immediately before the restriction by the restriction structure R is exhibited, and FIG. 5B shows a state in which the restriction by the restriction structure R is exhibited. . In the state of FIG. 5A, the claw 9 e of the disconnect spring 9 is pressed against the vertical surface 5 c of the intermediate rail 5 by the self-elastic restoring force of the disconnect spring 9. In this state, when the inner rail 6 is further pulled out from the intermediate rail 5 in the pull-out direction PU, the claw 9e reaches the accommodation hole 5d, and the claw 9e is accommodated in the accommodation hole 5d by the self-elastic restoring force of the disconnect spring 9. . Subsequently, when the inner rail 6 is further pulled out from the intermediate rail 5 in the pull-out direction PU, as shown in FIG. 5B, the vertical edge 9f of the claw 9e abuts against the edge 5e of the accommodation hole 5d. Here, since the vertical edge 9f of the claw 9e of the disconnect spring 9 and the edge 5e of the receiving hole 5d of the intermediate rail 5 are both substantially perpendicular to the pull-out direction PU, the state shown in FIG. In addition, pulling out the inner rail 6 from the intermediate rail 5 is regulated.

  On the other hand, when the inner rail 6 is pushed into the accommodation direction AC with respect to the intermediate rail 5 from the state of FIG. 5B, first, the vertical edge 9f of the claw 9e of the disconnect spring 9 is the edge of the accommodation hole 5d of the intermediate rail 5. Leave 5e. Next, due to the presence of the inclined edge 9g of the claw 9e, the disconnect spring 9 is pushed away toward the vertical surface 6b of the inner rail 6. As a result, the state of FIG. 5B is shifted to the state of FIG. In short, the restriction by the restriction structure R operates only when the inner rail 6 is pulled out from the intermediate rail 5 in the pull-out direction PU, and when the inner rail 6 is pushed into the accommodating direction AC with respect to the intermediate rail 5. Does not work.

(Stopper 3)
Next, the stopper 3 will be described with reference to FIGS. 6 and 7. The stopper 3 is a removal tool as a drawer restraining means that substantially allows the inner rail 6 from being pulled out from the outer rail 4 while allowing the inner rail 6 from being pulled out from the intermediate rail 5. As shown in FIGS. 2, 3, 7, and 8, the stopper 3 is fixed to the first mounting surface 101 b of the first support portion 101 c of the support column 101. Furthermore, as shown in FIG. 3, the stopper 3 is attached to the support column 101 at a position close to the slide rail 2. As shown in FIG. 2, the slide rail 2 and the stopper 3 constituting the slide rail unit 1 are aligned so as to be at substantially the same height position in the height direction of the rack cabinet 100. And as shown in FIG. 6, the stopper 3 is equipped with the base 10 as a base, and the knob 11 as a rotation member as a main structure.

  The base 10 is a pedestal for stably attaching the knob 11 to the support column 101, and includes a slightly thin first pedestal portion 12 and a slightly thick second pedestal portion 13. The first pedestal portion 12 and the second pedestal portion 13 are formed with countersunk holes 12 a and 13 a as attachment holes for fixing the base 10 to the first support portion 101 c of the support column 101. The interval between the countersink 12a and the countersink 13a is substantially the same as the interval between the mounting holes 101f shown in FIG. With this configuration, the base 10 can be fixed to the first support portion 101c of the support column 101 using the countersunk screw 14 shown in FIG.

  The first pedestal portion 12 is further formed with a shaft hole 12b for rotatably attaching the knob 11 to the base 10. The central axis C of the shaft hole 12b substantially defines the rotation axis of the knob 11.

  The knob 11 includes a knob body 15 in which a through hole 11a is formed, and a knob portion 16 as a grip portion that can be gripped by a finger. The knob body 15 extends in a direction away from the through hole 11a, and the knob portion 16 is integrally formed with the knob body 15 at a position away from the through hole 11a. With this configuration, the shaft 11 is inserted into the through hole 11a of the knob 11, and the tip of the shaft 17 is screwed into the shaft hole 12b of the first pedestal 12, so that the knob 11 has a base as shown in FIG. 10 is freely rotatable. In the present embodiment, the central axis C as the rotation axis of the knob 11 shown in FIG. 6 is substantially parallel to the pull-out direction PU of the inner rail 6 as shown in FIG. In addition, the knob 11 is approximately 90 degrees on both sides with respect to the longitudinal direction of the first pedestal portion 12 due to the presence of interference with the step formed between the first pedestal portion 12 and the second pedestal portion 13. It can be rotated. Furthermore, the knob 11 is configured to be able to hold the standing position shown in FIG.

  With the above configuration, the stopper 3 is configured to be switchable between a first state shown in FIG. 7A and a second state shown in FIG. 7B.

  The first state is a state where the knob 11 of the stopper 3 is erected as shown in FIG. At this time, the knob 11 does not overlap at all with respect to any of the bracket 8, the outer rail 4, the intermediate rail 5, and the inner rail 6 when viewed from the front side of the rack cabinet 100. Therefore, in the first state, the tip 11b of the knob 11 is inaccessible from the drawing side to the drawing side end 5f (see FIG. 8) of the intermediate rail 5. Therefore, when in the first state shown in FIG. 7A, as shown in FIG. 8, the inner rail 6 is pulled out from the intermediate rail 5, and the intermediate rail 5 is pulled out from the outer rail 4. Both are permitted.

  In the second state, as shown in FIG. 7B, the knob 11 of the stopper 3 is tilted 90 degrees toward the slide rail 2 side. At this time, the knob 11 is in an overlapping relationship with the bracket 8, the outer rail 4, and the intermediate rail 5 as viewed from the front side of the rack cabinet 100, while it does not overlap with the inner rail 6 at all. There is a relationship. Therefore, in the second state, the tip 11b of the knob 11 can come into contact with the drawer side end 5f (see FIG. 8) of the intermediate rail 5 from the drawer side. Therefore, in the second state shown in FIG. 7B, as shown in FIG. 9, the inner rail 5 from the outer rail 4 is allowed to be pulled out while allowing the inner rail 6 to be pulled out from the intermediate rail 5. Withdrawal is virtually deterred.

(Disabling regulations)
Next, a mechanism for invalidating the above restriction by the restriction structure R will be described. In this embodiment, when the stopper 3 is in the second state shown in FIGS. 7B and 9, the restriction by the restriction structure R is performed as shown in FIGS. 10A to 10D. The function to disable can be demonstrated. This invalidation is caused by the interference between the stopper 3 in the second state and the disconnect spring 9 constituting the regulating structure R as shown in FIGS. 10 (b) and 10 (c). It has been realized. Furthermore, this interference starts to occur before the regulation by the regulation structure R is exerted as shown in FIG. Hereinafter, a mechanism for invalidating the restriction by the restriction structure R will be described with reference to FIGS.

  The state shown in FIG. 10A corresponds to the state shown in FIG. That is, in the state of FIG. 10A, the claw 9 e of the claw holding portion 9 c of the disconnect spring 9 is pressed against the vertical surface 5 c of the intermediate rail 5 by the self-elastic restoring force of the disconnect spring 9. . In this state, when the inner rail 6 is further pulled out from the intermediate rail 5 in the pulling direction PU, the claw 9e is partially accommodated in the accommodating hole 5d of the intermediate rail 5 once, but as shown in FIG. As shown, the interference between the first inclined portion 9b of the disconnect spring 9 and the tip 11b of the knob 11 starts immediately. By this interference, the first inclined portion 9b, the claw holding portion 9c, and the second inclined portion 9d are pushed away in a direction away from the vertical surface 5c of the intermediate rail 5. Here, as shown in FIG. 10B, the vertical edge 9f of the claw 9e of the claw holding portion 9c of the disconnect spring 9 is in the state closest to the edge 5e on the stopper 3 side of the accommodation hole 5d of the intermediate rail 5. The length of the knob 11 is set so that the claw 9e is completely removed from the accommodation hole 5d. Therefore, the regulation of the regulation structure R realized by the contact between the vertical edge 9f of the claw 9e of the claw holding part 9c of the disconnect spring 9 and the edge 5e of the accommodation hole 5d of the intermediate rail 5 is never exhibited. Then, the state shifts to the state of FIG. In other words, before the regulation by the regulation structure R is exerted, the regulation by the regulation structure R is invalidated.

  When the inner rail 6 is further pulled out from the intermediate rail 5 in the pulling direction PU from the state of FIG. 10B, the first inclined portion 9b of the disconnect spring 9 and the tip 11b of the knob 11 of the stopper 3 interfere with each other. Thus, the first inclined portion 9b gets over the tip 11b of the knob 11 as shown in FIG. At this time, the pair of claws 9e of the claw holding portion 9c of the disconnect spring 9 is formed with a sufficient interval so as not to contact the knob 11 of the stopper 3 in the second state. (See also FIG. 4 and FIG. 7B.) As shown in FIG. 10C, the climbing operation of the first inclined portion 9b of the disconnect spring 9 with respect to the tip 11b of the knob 11 is performed without any problem. It has become.

  When the inner rail 6 is further pulled out from the intermediate rail 5 in the pulling direction PU from the state of FIG. 10C, the claw holding portion 9c and the second inclined portion 9d of the disconnect spring 9 get over the tip 11b of the knob 11 in order. . When the second inclined portion 9d of the disconnect spring 9 completely leaves the tip 11b of the knob 11, the disconnect spring 9 is moved to the vertical surface of the inner rail 6 by self-elastic restoring force as shown in FIG. Large displacement in the direction away from 6b.

(Working from the housed state to the normal maintenance state)
Based on the above description, in order to switch the state of the supported device 7 from the housed state (upper stage in FIG. 2) to the normal maintenance state (middle stage in FIG. 2), the stopper 3 is the first shown in FIG. After confirming that this is the state, the supported device 7 may be pulled out to the front side of the rack cabinet 100. Then, as shown in FIG. 8, the intermediate rail 5 is pulled out from the outer rail 4 by a predetermined amount, and the inner rail 6 is pulled out from the intermediate rail 5 by a predetermined amount. The Due to this restriction, the supported device 7 is not likely to fall out of the rack cabinet 100.

(Work from normal maintenance state to storage state)
On the other hand, in order to switch the state of the supported device 7 from the normal maintenance state (middle stage in FIG. 2) to the housed state (upper stage in FIG. 2), the stopper 3 is in the first state shown in FIG. After confirming that the device is supported, the supported device 7 may be pushed into the rack cabinet 100. Then, due to the presence of the inclined edge 9g of the claw 9e of the claw holding portion 9c of the disconnect spring 9 shown in FIG. 5 (b), the claw 9e of the claw holding portion 9c of the disconnect spring 9 is connected to the vertical surface 6b of the inner rail 6. Pushed to the side. By this pushing-out operation, the operation of accommodating the inner rail 6 in the accommodating direction AC with respect to the intermediate rail 5 is performed without any problem.

(Working from the housed state to the removed state)
In order to switch the state of the supported device 7 from the housed state (upper stage in FIG. 2) to the removed state (lower stage in FIG. 2), the stopper 3 is in the second state shown in FIG. 7B. The supported device 7 may be pulled out to the front side of the rack cabinet 100 after confirming the above. Then, as shown in FIG. 9, the withdrawal of the intermediate rail 5 from the outer rail 4 is substantially inhibited by the knob 11 of the stopper 3. Further, as shown in FIG. 10, the restriction by the restriction structure R is invalidated. Therefore, the device 7 to be supported can be detached from the rack cabinet 100 at a position very close to the rack cabinet 100 as shown in the lower part of FIG. it can. In other words, as shown in FIG. 9, the inner rail 6 can be removed from the outer rail 4 at a position very close to the outer rail 4.

(Working from the removed state to the stowed state)
In order to switch the state of the supported device 7 from the removed state (lower stage in FIG. 2) to the accommodated state (upper stage in FIG. 2), the stopper 3 is in the first state shown in FIG. 7 (a). After confirming the above, the supported device 7 may be pushed into the rack cabinet 100. Then, the second inclined portion 9 d of the disconnect spring 9 shown in FIG. 4 interferes with the intermediate rail 5, so that the disconnect spring 9 is pushed away to the vertical surface 6 b side of the inner rail 6 as a whole. By this pushing-out operation, the disconnect spring 9 is inserted between the intermediate rail 5 and the inner rail 6 without any problem, and the operation of accommodating the inner rail 6 in the accommodating direction AC with respect to the intermediate rail 5 is problematic. Will be done without.

(Work from normal maintenance state to removal state)
In order to switch the state of the supported device 7 from the normal maintenance state (middle stage in FIG. 2) to the removed state (lower stage in FIG. 2), the state of the supported device 7 is once switched from the normal maintenance state to the housed state. After confirming that the stopper 3 is in the second state, the supported device 7 may be pulled out to the front side of the rack cabinet 100.

<Summary>
(1) As described above, the slide rail unit 1 according to the present embodiment includes the outer rail 4 that can be attached to the column 101 of the rack cabinet 100 and the intermediate rail 5 that is supported so as to be drawable with respect to the outer rail 4. And an inner rail 6 supported so as to be able to be pulled out with respect to the intermediate rail 5, and an intermediate rail from the outer rail 4 while allowing the inner rail 6 to be pulled out from the intermediate rail 5. The drawer 5 is provided with a stopper 3 for substantially deterring. According to the above configuration, the inner rail 6 can be removed from the intermediate rail 5 at a position close to the outer rail 4.

  Therefore, the work space on the front side of the rack cabinet 100 that is required when the inner rail 6 is removed from the intermediate rail 5 can be made compact. From another point of view, when removing the inner rail 6 from the intermediate rail 5, the center of gravity of the entire rack cabinet 100 is excessively moved to the front side of the rack cabinet 100 as compared with the configuration of Patent Document 1 described above. Therefore, the rack cabinet 100 is excellent in stability.

(2) The slide rail unit 1 is further configured as follows. That is, the stopper 3 has a first state (see FIG. 7A) that allows both the inner rail 6 to be drawn from the intermediate rail 5 and the intermediate rail 5 to be drawn from the outer rail 4. 5 is configured to be switchable between a second state (FIG. 7B) in which the inner rail 6 is allowed to be pulled out from the outer rail 4 while the middle rail 5 is not substantially pulled out from the outer rail 4. The

  According to the above configuration, since the stopper 3 can be switched between the first state and the second state, the intermediate rail 5 can be moved from the outer rail 4 to the intermediate rail 5 only by switching the state of the stopper 3. The normal maintenance performed by pulling out the inner rail 6 from the intermediate rail 5 and pulling it out can be performed without any problems.

  In this embodiment, the stopper 3 is switched between the first state and the second state by using the rotation of the knob 11 as shown in FIGS. 7 (a) and 7 (b). However, the present invention is not limited to this, and the following configurations are also conceivable.

  First, the above-described switchable configuration may be realized by using attachment / detachment of the stopper 3 to / from the support column 101. That is, if the stopper 3 shown in FIG. 7B is simply removed from the support column 101 without raising the knob 11, it is said that the removal has switched the second state to the first state. be able to.

  Secondly, in the second embodiment, the knob 11 shown in FIG. 7B can be rotated around the central axis C, and the above switching is realized by using this rotation. Instead, the knob 11 shown in FIG. 7B may be configured to be slidable in the left-right direction on the paper surface, and the above switching may be realized by using this slide.

  Third, the rotation mode of the knob 11 may be varied by making the rotation axis (center axis C) of the knob 11 shown in FIG. 7B parallel to the longitudinal direction of the column 101.

(3) The slide rail unit 1 is further configured as follows. That is, a restriction structure R that restricts the inner rail 6 from being pulled out from the intermediate rail 5 by a predetermined amount or more is provided. The stopper 3 has a function of invalidating the restriction by the restriction structure R as shown in FIGS. 10A to 10D in the second state shown in FIG. According to the above configuration, when removing the inner rail 6 from the intermediate rail 5, it is not necessary to be aware of the release of the restriction by the restriction structure R, so that the slide rail unit 1 that is easy to handle is realized.

  As the restriction structure R, an elastic member attached to the inner rail 6 is adopted, and the disconnect spring 9 is used as the elastic member in the embodiment. The disconnect spring 9 is formed by bending a stainless steel plate. However, instead of this, the disconnect spring 9 may be made of resin. In this case, the disconnect spring 9 can be attached to the inner rail 6 by, for example, vibration welding.

  Further, in the above embodiment, the vertical surface 5c of the intermediate rail 5 is formed with the accommodation hole 5d for accommodating the claw 9e of the claw holding portion 9c of the disconnect spring 9, but it is accommodated instead of the accommodation hole 5d. A groove may be formed.

(4) The above slide rail unit 1 is further configured as follows. That is, the invalidation of the regulation by the regulation structure R is realized by interference between the stopper 3 in the second state shown in FIG. 7B and the disconnect spring 9 that is a component of the regulation structure R. . According to the above configuration, invalidation of the regulation by the regulation structure R is realized by a simple phenomenon of interference. Therefore, compared with the case where the invalidation is realized by a complicated mechanism, the repetition stability of the invalidation is excellent.

  In the above embodiment, the disconnect spring 9 is attached to the vertical surface 6b of the inner rail 6 by the attachment portion 9a as shown in FIG. 10 (a). It is good also as a free end on the side opposite to the nail | claw holding | maintenance part 9c across the 2 inclination part 9d. In any configuration, the disconnect spring 9 is elastically deformed toward the inner rail 6 due to interference between the first inclined portion 9b of the disconnect spring 9 constituting the regulating structure R and the tip 11b of the knob 11 constituting the stopper 3. It does not prevent you from doing.

(5) The slide rail unit 1 is further configured as follows. That is, the interference starts to occur before the regulation by the regulation structure R is exerted. According to the above configuration, the regulation by the regulation structure R is already invalidated before it is exhibited as shown in FIG. Smooth removal is realized.

(6) The slide rail unit 1 is further configured as follows. That is, the stopper 3 includes a knob 11 that is attached to the outer rail 4 and has a rotation axis that is substantially parallel to the pull-out direction PU of the inner rail 6. In the first state shown in FIG. 7A, as shown in FIG. 8, the knob 11 is unable to contact the drawer side end portion 5f of the intermediate rail 5 from the drawer side. In the second state shown in FIG. 7B, as shown in FIG. 9, the tip 11b of the knob 11 can come into contact with the drawer side end portion 5f of the intermediate rail 5 from the drawer side. According to the above configuration, the stopper 3 having the above switching function can be configured with a simple configuration. Moreover, since it is a simple structure, the stopper 3 can be manufactured cheaply.

  In the above embodiment, the stopper 3 is indirectly attached to the outer rail 4 via the support column 101 or the bracket 8. Instead, the stopper 3 is directly attached to the outer rail 4. It may be fixed. In short, any configuration can be adopted as long as it does not cause a change in the relative position of the stopper 3 with respect to the outer rail 4.

DESCRIPTION OF SYMBOLS 1 Slide rail unit 2 Slide rail 3 Stopper 4 Outer rail 5 Intermediate rail 6 Inner rail 7 Supported apparatus 8 Bracket 9 Disconnect spring 100 Rack cabinet 101 Post

Claims (9)

A slide rail including a fixed rail that can be attached to a rack cabinet column, an intermediate rail that is supported to be able to be pulled out with respect to the fixed rail, and a movable rail that is supported to be able to be pulled out with respect to the intermediate rail;
A drawer restraining means for substantially inhibiting the withdrawal of the intermediate rail from the fixed rail while allowing the withdrawal of the moving rail from the intermediate rail;
A slide rail unit comprising: The slide rail unit according to claim 1,
The drawer restraining means is
A first state that allows both the withdrawal of the moving rail from the intermediate rail and the withdrawal of the intermediate rail from the fixed rail;
A second state in which the withdrawal of the moving rail from the intermediate rail is allowed, while the withdrawal of the intermediate rail from the fixed rail is substantially inhibited;
Configured to be switchable between,
Slide rail unit. The slide rail unit according to claim 2,
A restricting means for restricting a predetermined amount or more of the moving rail from the intermediate rail is provided;
The drawer restraining means has a function of invalidating the regulation by the regulating means in the second state.
Slide rail unit. The slide rail unit according to claim 3,
The invalidation of the regulation by the regulating means is realized by interference between the drawer suppressing means in the second state and the regulating means.
Slide rail unit. The slide rail unit according to claim 4,
The interference starts to occur before the regulation by the regulation means is exerted.
Slide rail unit. The slide rail unit according to any one of claims 2 to 5,
The drawer restraining means is configured to include a rotating member attached directly or indirectly to the fixed rail and having a rotation axis substantially parallel to the pulling direction of the moving rail,
In the first state, the rotating member is inaccessible from the drawing side to the drawing side end of the intermediate rail,
In the second state, at least a part of the rotating member can come into contact with the drawer side end of the intermediate rail from the drawer side.
Slide rail unit. Struts,
A fixed rail attachable to the support;
An intermediate rail supported so as to be able to be pulled out with respect to the fixed rail;
A moving rail supported so as to be able to be pulled out with respect to the intermediate rail;
A drawer restraining means for substantially inhibiting the withdrawal of the intermediate rail from the fixed rail while allowing the withdrawal of the moving rail from the intermediate rail;
Rack cabinet with. A slide rail including a fixed rail that can be attached to a column of a rack cabinet, an intermediate rail that is supported so as to be drawable with respect to the fixed rail, and a movable rail that is supported so as to be drawable with respect to the intermediate rail. A removal tool for removing the moving rail from the intermediate rail,
The removal tool allows substantially no withdrawal of the intermediate rail from the fixed rail while allowing the withdrawal of the moving rail from the intermediate rail;
Remover. A slide rail including a fixed rail that can be attached to a column of a rack cabinet, an intermediate rail that is supported so as to be drawable with respect to the fixed rail, and a movable rail that is supported so as to be drawable with respect to the intermediate rail. , When removing the moving rail from the intermediate rail,
Pulling out the moving rail from the intermediate rail while substantially preventing the middle rail from being pulled out from the fixed rail,
Removal method.

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