CN111050521A

CN111050521A - Sliding rail assembly

Info

Publication number: CN111050521A
Application number: CN201811187649.3A
Authority: CN
Inventors: 陈庚金; 杨顺和; 何俊毅; 王俊强
Original assignee: King Slide Works Co Ltd; King Slide Technology Co Ltd
Current assignee: King Slide Works Co Ltd; King Slide Technology Co Ltd
Priority date: 2018-10-12
Filing date: 2018-10-12
Publication date: 2020-04-21
Anticipated expiration: 2038-10-12
Also published as: CN111050521B

Abstract

The invention relates to a slide rail assembly, which comprises a first rail, a second rail, a first bracket, a second bracket, a first structure and a second structure. The first rail is provided with a first end part and a second end part; the second rail can move relative to the first rail; the first bracket is arranged adjacent to the first end of the first rail; the second bracket is movably arranged adjacent the second end of the first rail; the first structure is arranged on one of the first rail and the first bracket; the second structure is arranged on the second rail; when the second rail is at an extending position relative to the first rail, the first structure and the second structure are mutually clamped.

Description

Sliding rail assembly

Technical Field

The present invention relates to a slide rail mechanism, and more particularly, to a slide rail assembly including at least two slide rails.

Background

In a rack system, as shown in fig. 1, the rack typically has a predetermined specification. The predetermined specification is, for example, a standard rack (standard rack) specified by Electronic Industries Association (EIA).

Further, the first column 1a and the second column 1b of the rack (or cabinet) have a predetermined height, and the first column 1a and the second column 1b are usually arranged with a plurality of slide rail assemblies from top to bottom, here, the first slide rail assembly 3a, the second slide rail assembly 3b, the third slide rail assembly 3c and the fourth slide rail assembly 3d are taken as an example, but the number is not limited in the implementation. Each slide rail assembly comprises a first rail 5, a second rail 7 and a third rail 9. Wherein the first rail 5 is mounted to the first and second masts 1a and 1b through the first and

second brackets

11 and 13. And the second rail 7 of the third slide rail assembly 3c can be normally engaged with the corresponding structure of the first rail 5 and the second rail 7 in an extended position P, such as the first structure 15a and the second structure 15b, so as to temporarily hold the second rail 7 in the extended position P, thereby facilitating the maintenance operation of the slide rail assembly or the carrier 17 carried thereby. However, since the first structure 15a and the second structure 15b of the third slide rail assembly 3c are arranged at the position where they are engaged with each other at a front portion 5a of the first rail 5 (or away from the first column 1a), and due to the predetermined specification, these slide rail assemblies have a specification height h (e.g., 44.45mm) with respect to each other. In these cases, it is sometimes not easy for the user to extend his hand into the space defined by the specification height h between the two rail assemblies, and in particular, the user's hand must extend into the space by a distance K to operate and disengage the first structure 15a from the second structure 15b, which is inconvenient and may injure the relevant person walking near the rack if the second rail 7 is outside the rack in the extended position P.

In view of this, with the difference of market demands, how to develop a different slide rail product becomes an issue worth discussing.

Disclosure of Invention

The present invention provides a mechanism for preventing a slide rail from moving away from an extended position relative to another slide rail, and the mechanism is positioned to facilitate a user to release the mechanism.

According to an aspect of the present invention, a sliding rail assembly includes a first rail, a second rail, a first structure and a second structure. The second rail can move relative to the first rail; the first structure is arranged adjacent to one end of the first rail; the second structure is arranged on the second rail; when the second rail moves from a retracted position to an extended position relative to the first rail in a first direction, the first structure and the second structure are matched with each other to prevent the second rail from moving from the extended position in the first direction or a second direction; wherein, the first direction and the second direction are opposite directions.

Preferably, one of the first structure and the second structure has a hook, and the other of the first structure and the second structure is a hole for the hook to pass through, so that two hole walls of the hole are located at two sides of the hook.

Preferably, the first rail is provided with a bracket to which the first structure is attached.

Preferably, the bracket of the first rail includes a side wall, an end wall, a fastener and an elastic member, the end wall is substantially perpendicularly bent with respect to the side wall, the end wall is provided with at least one mounting member, the fastener is movably mounted to the side wall, and the elastic member provides elastic force to the fastener, so that the fastener is maintained in a locked state and a fastening portion of the fastener is adjacent to the at least one mounting member of the end wall.

Preferably, the slide rail assembly further comprises a third rail capable of moving relative to the second rail, the first rail is provided with a tripping feature, and a synchronizing member is movably mounted on the second rail, the third rail comprises a synchronization feature, the synchronization feature abuts against the synchronizing member in a predetermined state, so that the second rail and the third rail can synchronously move relative to the first rail in the first direction, and when the third rail moves to the extended position, the synchronization member is no longer in the predetermined state through the tripping feature, so as to release the synchronous displacement relationship between the second rail and the third rail.

Preferably, the synchronizing member is pivotally connected to the second rail, and the slide rail assembly further includes an elastic feature for providing an elastic force to the synchronizing member so that the synchronizing member can be maintained in the predetermined state.

Preferably, the slide rail assembly further comprises a first working member and a second working member operatively connected to the third rail, and a blocking portion is disposed adjacent to an end portion of the second rail, and when the second rail is in the extended position relative to the first rail and the third rail is displaced relative to the second rail in the first direction to a fully extended position, the first working member and the second working member are disposed on both sides of the blocking portion to prevent displacement of the third rail from the fully extended position to the first direction or the second direction.

Preferably, the first and second working members are pivotally connected to the third rail, and the slide rail assembly further includes an elastic seat disposed on the third rail, the elastic seat having a first elastic portion and a second elastic portion for providing elastic force to the first and second working members, respectively.

According to another aspect of the present invention, a sliding rail assembly includes a first rail, a second rail, a first bracket, a second bracket, a first structure and a second structure. The first rail has a front portion and a rear portion; the second rail can move relative to the first rail; the first bracket is arranged adjacent to the front part of the first rail; the second bracket is movably arranged at the rear part adjacent to the first rail; the first structure is attached to the first bracket; the second structure is arranged on the second rail; when the second rail is at an extending position relative to the first rail, the first structure and the second structure can be mutually clamped.

According to another aspect of the present invention, a slide rail assembly is adapted to a rack, the rack includes a first column and a second column, the slide rail assembly includes a first rail, a second rail, a first bracket, a second bracket, a first structure and a second structure. The first rail is provided with a first end part and a second end part; the second rail can move relative to the first rail; the first bracket is arranged adjacent the first end of the first rail for mounting the first rail to the first mast; the second bracket is movably arranged adjacent the second end of the first rail for mounting the first rail to the second mast; the first structure is attached to the first bracket; the second structure is arranged on the second rail; when the second rail is located at an extending position relative to the first rail, the first structure and the second structure are matched with each other to prevent the second rail from moving from the extending position to the first direction or the second direction; wherein, the first direction and the second direction are opposite directions.

Drawings

For further explanation of the above objects, structural features and effects of the present invention, the present invention will be described in detail below with reference to the accompanying drawings, in which:

FIG. 1 is a schematic view of a plurality of slide assemblies of the prior art mounted to a frame.

Fig. 2 is a perspective view of the slide rail assembly of the first embodiment of the present invention mounted to a rack.

Fig. 3 is a schematic view of a slide rail assembly according to a first embodiment of the invention.

Fig. 4 is an exploded view of a slide rail assembly according to a first embodiment of the invention.

Fig. 5 is a schematic view illustrating the slide rail assembly of the first embodiment of the invention mounted to two posts of a rack, and the slide rail assembly is in a folded state.

Fig. 6 is an enlarged view of the region a of fig. 5.

Fig. 7 is an enlarged view of the region B of fig. 5.

Fig. 8 is a schematic view illustrating the slide rail assembly of the first embodiment of the present invention mounted to a pillar of a rack, and the second rail and the third rail of the slide rail assembly synchronously displace in the first direction relative to the first rail.

Fig. 9 is an enlarged view of the region a of fig. 8.

Fig. 10 is a schematic view illustrating that the second rail and the third rail of the slide rail assembly of the first embodiment of the invention are continuously displaced in the first direction relative to the first rail, and the second rail is in the extended position.

Fig. 11 is an enlarged view of the region a of fig. 10.

Fig. 12 is an enlarged view of the region B of fig. 10.

Fig. 13 is a schematic view illustrating the third rail of the slide rail assembly according to the first embodiment of the invention being displaced in the first direction relative to the second rail.

Fig. 14 is a schematic view illustrating the third rail of the slide rail assembly according to the first embodiment of the invention being continuously displaced in the first direction relative to the second rail.

Fig. 15 is a schematic view illustrating the third rail of the slide rail assembly according to the first embodiment of the invention being further displaced in the first direction relative to the second rail to reach the fully extended position.

FIG. 16 is a schematic view of the first embodiment of the present invention, wherein the working member is disengaged from the second rail, and the third rail of the slide assembly is moved away from the fully extended position relative to the second rail in the first direction.

Fig. 17 is a schematic view of the second rail of the slide rail assembly according to the first embodiment of the present invention in an extended position relative to the first rail, and the third rail is detached from the second rail.

FIG. 18 is a schematic view of a plurality of slide assemblies mounted to a rack according to a first embodiment of the present invention.

FIG. 19 is a perspective view of the slide rail assembly mounted to the frame with a release member not yet operated according to the second embodiment of the present invention.

Fig. 20 is a schematic view of the slide rail assembly of the second embodiment of the present invention mounted to the frame and the release member is not yet operated.

Fig. 21 is a schematic view showing a perspective view of the slide rail assembly mounted to the frame and the release member being operated according to the second embodiment of the present invention.

FIG. 22 is a schematic view of the second embodiment of the present invention shown in another perspective of the slide rail assembly being mounted to the frame and the release member being operated.

Detailed Description

As shown in fig. 2, 3 and 4, the slide rail assembly 20 of the embodiment of the present invention can be mounted to a first column 26a and a second column 26b of a rack (rack) through a first bracket 22 and a second bracket 24.

The slide assembly 20 includes a first rail 28, a second rail 30, a first structure 32, and a second structure 34. Preferably, a third rail 36 is also included.

The first rail 28 has a first end 28a and a second end 28b, such as front and rear. Preferably, the first bracket 22 is disposed adjacent the first end 28a of the first rail 28; on the other hand, the second bracket 24 is movably arranged adjacent to the second end 28b of the first rail 28. For example, the second bracket 24 is telescopically coupled to a support base 25 at the back side of the first rail 28 via an extension bracket 24a, so that the second bracket 24 can be longitudinally adjusted in position relative to the first rail 28. The first bracket 22 and the second bracket 24 respectively include at least one mounting member, such as a plurality of first mounting members 38 and a plurality of second mounting members 40, and the first bracket 22 and the second bracket 24 respectively provide for mounting the first rail 28 to the first mast 26a and the second mast 26b via the first mounting members 38 and the second mounting members 40. Further, the first rail 28 includes a first wall 42a, a second wall 42b, and a longitudinal wall 44 connected between the first wall 42a and the second wall 42 b. The first wall 42a, the second wall 42b and the longitudinal wall 44 of the first rail 28 together define a first channel 46. Preferably, the first rail 28 is arranged with a detent-releasing feature 48, and the detent-releasing feature 48 is a ramp or a curved surface. Preferably, the first rail 28 is configured with a projection 49 on the longitudinal wall 44, and the projection 49 has the detent-releasing feature 48.

The second rail 30 is displaceable relative to the first rail 28. Preferably, the second rail 30 is mounted to the first rail 28 within the first channel 46. The second rail 30 has a first end 30a and a second end 30b, such as front and rear portions. Further, the second rail 30 includes a first wall 50a, a second wall 50b and a longitudinal wall 52 connected between the first wall 50a and the second wall 50 b. The first wall 50a, the second wall 50b and the longitudinal wall 52 of the second rail 30 together define a second channel 54. The first wall 50a, the second wall 50b and the longitudinal wall 52 of the second rail 30 are positioned to correspond to the first wall 42a, the second wall 42b and the longitudinal wall 44 of the first rail 28, respectively. Preferably, a synchronizing member 56 is movably mounted to the second rail 30, for example, the synchronizing member 56 is pivotally connected to the longitudinal wall 52 of the second rail 30 via a shaft 58, and the slide assembly 20 further includes a resilient feature 60, such as a resilient arm, for providing a resilient force to the synchronizing member 56.

The first structure 32 is disposed adjacent the first end 28a of the first rail 28. Here, the first structure 32 is disposed on the first bracket 22 as an example. Specifically, the first bracket 22 includes a side wall 62, an end wall 64, a fastener 66 and an elastic member 68. The end wall 64 is bent substantially perpendicular to the side wall 62, and the end wall 64 is provided with the first mounting member 38; the fastener 66 is movably mounted (e.g., pivotally connected) to the side wall 62, and the elastic member 68 (e.g., a spring or a leaf spring) provides elastic force to the fastener 66, so that the fastener 66 is kept in a locked state and a fastening portion 66a of the fastener 66 is adjacent to the first mounting member 38 of the end wall 64 to lock the first column 26a (as shown in fig. 2). Preferably, the side wall 62 of the first bracket 22 has an opening 70, and one end 72a of a resilient member 72 (e.g., a resilient arm) is connected to the side wall 62, and the other end 72b of the resilient member 72 is disposed with the first structure 32, and the position of the first structure 32 corresponds to the opening 70. Preferably, the first structure 32 has a hook 74, and further, the hook 74 is located toward the second rail 30 corresponding to the through hole 76 of the first rail 28.

The second structure 34 is arranged at the second rail 30. Preferably, the second structure 34 is a hole (or recess) that cooperates with the hook 74 of the first structure 32. Preferably, the second structure 34 is disposed on a longitudinal wall 52 of the second rail 30.

The third rail 36 is displaceable relative to the second rail 30. Preferably, the third rail 36 is mounted into the second channel 54 of the second rail 30. Specifically, the third rail 36 includes a first wall 78a, a second wall 78b, and a longitudinal wall 80 connected between the first wall 78a and the second wall 78 b. The first wall 78a, the second wall 78b and the longitudinal wall 80 of the third rail 36 are positioned to correspond to the first wall 50a, the second wall 50b and the longitudinal wall 52 of the second rail 30, respectively. Preferably, the third rail 36 includes a synchronization feature 82 (e.g., a protrusion) located on the longitudinal wall 80 of the third rail 36. The synchronization feature 82 is configured to cooperate with the synchronization member 56. Preferably, the slide assembly 20 further includes a first operating member 84 and a second operating member 86 operatively connected to the longitudinal wall 80 of the third rail 36, with a stop 88 disposed adjacent the first end 30a of the second rail 30. The stop 88 is disposed on the longitudinal wall 52 of the second rail 30 and projects transversely relative to the longitudinal wall 52.

Preferably, the slide rail assembly 20 further comprises a first sliding aid 90 and a second sliding aid 92. The first sliding assistance device 90 includes a plurality of first rolling members 90a (e.g., balls or rollers) rolling-supported between the first rail 28 and the second rail 30 for assisting the displacement of the second rail 30 relative to the first rail 28. On the other hand, the second sliding assisting device 92 comprises a plurality of second rolling elements 92a (such as balls or rollers) rolling and supported between the second rail 30 and the third rail 36 to facilitate the displacement of the third rail 36 relative to the second rail 30. Preferably, the first operating member 84 and the second operating member 86 are pivotally connected to the longitudinal wall 80 of the third rail 36 through a first shaft 94 and a second shaft 96, respectively, and the slide rail assembly 20 further includes a resilient seat 98 disposed on the longitudinal wall 80 of the third rail 36, the resilient seat 98 having a first resilient portion 98a and a second resilient portion 98b for providing resilient force to the first operating member 84 and the second operating member 86, respectively. Preferably, the slide assembly 20 further includes a first operating member 100 and a second operating member 102 for operating the first and second working

members

84 and 86, respectively.

As shown in fig. 5, 6 and 7, the first rail 28 of the slide rail assembly 20 is fixedly mounted on the first column 26a and the second column 26b through the first bracket 22 and the second bracket 24, and the second rail 30 is in a retracted position R relative to the first rail 28. On the other hand, the third rail 36 is folded relative to the second rail 30.

Further, the synchronizing member 56 of the second rail 30 is in a predetermined state X1. Preferably, the synchronizing member 56 is capable of remaining in the predetermined state X1 in response to the elastic force of the elastic feature 60. And the synchronization feature 82 of the third rail 36 can cooperate with the synchronization element 56 in the predetermined state X1, whereby the synchronization feature 82 of the third rail 36 can abut against the synchronization element 56 in the predetermined state X1. Wherein the synchronizing member 56 of the second rail 30 is a predetermined distance from the trip feature 48 of the first rail 28. On the other hand, the second structure 34 has a predetermined distance from the first structure 32. Wherein the first structure 32 abuts against the longitudinal wall 52 of the second rail 30, so that the elastic member 72 is in a state of accumulating elastic force.

As shown in fig. 8 and 9, when the third rail 36 is displaced in a first direction D1, the synchronization feature 82 abuts against the synchronization element 56 in the predetermined state X1, so that the second rail 30 and the third rail 36 can be synchronously displaced in the first direction D1 relative to the first rail 28 until a portion 104 of the synchronization element 56 of the second rail 30 contacts the unlatching feature 48 of the first rail 28 when the third rail 36 is displaced by a predetermined stroke. Preferably, the portion 104 of the synchronization member 56 is an inclined surface or an arc surface; on the other hand, the second structure 34 of the second rail 30 is already close to the first structure 32.

As shown in fig. 10, 11 and 12, when the third rail 36 and the second rail 30 continue to be displaced in the first direction D1 until the second rail 30 is in the extended position E, the synchronizing member 56 is no longer in the predetermined state X1 (for example, converted into another state X2 as shown in fig. 11) through the tripping feature 48, so that the synchronizing feature 82 of the third rail 36 no longer abuts against the synchronizing member 56 to release the synchronous displacement relationship between the second rail 30 and the third rail 36. In this embodiment, the synchronizer 56 generates a force through the portion 104 against the detent release feature 48 to cause the synchronizer 56 to swing at an angle from the predetermined state X1 to the another state X2. At this point, the spring feature 60 is in a state of spring force accumulation. On the other hand, when the second rail 30 is at the extended position E, the first structure 32 and the second structure 34 are matched with each other to prevent the second rail 30 from being displaced from the extended position E relative to the first rail 28 in the first direction D1 or a second direction D2 opposite to the first direction D1. In this embodiment, the first structure 32 and the second structure 34 can be engaged with each other, for example, the second structure 34 is a hole through which the first structure 32 passes the hook 74 in response to the release of the elastic force of the elastic member 72, so that two walls of the hole, for example, the first wall 35a and the second wall 35b, are located on two sides of the hook 74. According to this configuration, the second rail 30 can be prevented from being displaced from the extended position E in the first direction D1 or the second direction D2.

As shown in fig. 13, 14 and 15, the second rail 30 has been in the extended position E relative to the first rail 28. On the other hand, the first elastic portion 98a and the second elastic portion 98b of the elastic seat 98 of the third rail 36 respectively provide elastic force to the first operating member 84 and the second operating member 86, so that the first operating member 84 and the second operating member 86 are maintained in a first state S1.

Further, when the third rail 36 is displaced relative to the second rail 30 in the first direction D1 until a predetermined stroke is reached, the second operating member 86 contacts a first side of the stopping portion 88 of the second rail 30 (as shown in fig. 13). When the third rail 36 continues to displace in the first direction D1 relative to the second rail 30, the second working member 86 interacts with the stopper 88, such that the second working member 86 deflects from the first state S1 to a second state S2 (shown in fig. 14) to pass over the first side of the stopper 88, and the second spring portion 98b is in a spring force accumulation state until the third rail 36 further displaces in the first direction D1 relative to the second rail 30 to a fully extended position Y (shown in fig. 15), and the second working member 86 returns to the first state S1 in response to the release of the spring force of the second spring portion 98b, and at this time, the second working member 86 is located on a second side of the stopper 88 (shown in fig. 15); on the other hand, the first working member 84 is in the first state S1 on the first side of the blocking portion 88. In short, when the third rail 36 is in the fully extended position Y relative to the second rail 30 (as shown in fig. 15), the third rail 36 is blocked by the blocking portion 88 through the first operating member 84 and the second operating member 86 being in the first state S1 and located at the first side and the second side of the blocking portion 88, respectively, so as to prevent the third rail 36 from being displaced from the fully extended position Y to the first direction D1 or the second direction D2.

As shown in fig. 15, 16 and 17, when the third rail 36 is located at the fully extended position Y relative to the second rail 30, if the user wants to displace the third rail 36 from the fully extended position Y to the first direction D1 or the second direction D2, the user can operate the first working member 84 or the second working member 86 to be no longer in the first state S1. For example, a user can apply a force to the first operating element 100 in the first direction D1, such that a driving portion 100a of the first operating element 100 can swing the first operating member 84 from the first state S1 to another state (e.g., the second state S2, as shown in fig. 16), such that the third rail 36 can be displaced from the fully extended position Y to the first direction D1 and out of the second channel 54 of the second rail 30. In other words, the third rail 36 is detachable from the second rail 30. It should be noted that the first working member 84, the second working member 86 and the spring seat 98 are omitted from fig. 17.

As shown in fig. 18, in a rack system 106, a plurality of slide assemblies are generally arranged from top to bottom on the first tower 26a and the second tower 26b, and herein, the first slide assembly 20a, the second slide assembly 20b, the third slide assembly 20c and the fourth slide assembly 20d are taken as an example, but the number is not limited in the implementation. Each slide assembly includes a first rail 28, a second rail 30, and a third rail 36. Wherein the first rail 28 is mounted to the first and

second masts

26a and 26b via the first and

second brackets

22 and 24. It should be noted that the structural configuration and the operation principle of each slide rail assembly are disclosed in fig. 2 to 17, and for the sake of brevity, are not described herein again.

Further, the third rail 36 of each slide rail assembly can be used for carrying a carrier 108 (e.g., an electronic device). The first slide rail assembly 20a and the second slide rail assembly 20b are folded (see fig. 5), so that the bearing object 108 is located in the rack; on the other hand, the second rail 30 of the third slide rail assembly 20c is in the extended position E relative to the first rail 28, and the first structure 32 and the second structure 34 of the third slide rail assembly 20c are engaged with each other, so that a part of the rail section of the second rail 30 of the third slide rail assembly 20c is located outside the rack, and the third rail 36 of the third slide rail assembly 20c is detached from the second rail 30; in another aspect, the fourth slide rail assembly 20d is in an extended state, wherein the third rail 36 of the fourth slide rail assembly 20d is located at the fully extended position Y relative to the second rail 30, so that the load-bearing object 108 is located outside the rack.

It should be noted that, since the rack has a predetermined specification, when the slide rail assemblies are mounted on the first column 26a and the second column 26b, the slide rail assemblies have a specification height h therebetween, in this case, since the first structure 32 of the slide rail assembly 20c is arranged adjacent to the first end 28a of the first rail 28 (or adjacent to the first column 26a) to be able to catch the second structure 34 and keep the second rail 30 at the extended position E, compared to the prior art (as shown in fig. 1), the hand of the user can operate at a shorter distance L and disengage the first structure 32 from the second structure 34, so that the second rail 30 of the slide rail assembly 20c can be retracted into the rack from the extended position E relative to the first rail 28. This is characterized in that, besides allowing the user to conveniently fold the second rail 30 relative to the first rail 28 to retract the second rail 30 into the rack, and since the second rail 30 is already retracted into the rack, the related person can be prevented from walking near the rack and colliding with the second rail 30 to cause injury, thereby providing safety.

Fig. 19 and 20 show two different views of the slide rail assembly 200 of the second embodiment of the present invention mounted to the machine column of the machine frame, and fig. 19 and 20 only schematically illustrate the first machine column 26a of the machine frame. The slide rail assembly 200 of the second embodiment is substantially different from the slide rail assembly 20 of the first embodiment in that: the slide assembly 200 further includes a release member 202.

Specifically, when the release element 202 is moved from the non-manipulated state (fig. 19 and 20) to the manipulated state (fig. 21 and 22), the hook 74 of the first structure 32 is moved from the non-disengaged second structure 34 (e.g., hole) (fig. 20) to the disengaged second structure 34 (fig. 22). Further, the release member 202 is movably mounted to the first bracket 22. The releasing member 202 includes an operating portion 202a, a driving portion 202b and a connecting portion 202c arranged between the operating portion 202a and the driving portion 202 b. Preferably, the connecting portion 202c is pivotally connected to at least one lug 205 of the first bracket 22 via a pivot 204; the driving portion 202b is used for abutting against a portion of the elastic member 72 (e.g., abutting against the other end 72 b); the operating portion 202a is adjacent to the at least one mounting member 38 of the first bracket 22, where the operating portion 202a is adjacent to the first mast 26a because the at least one mounting member 38 of the first bracket 22 is mounted to the first mast 26 a. Preferably, the operating portion 202a has a pillar surface 207 with an end 203 adjacent to the first pillar 26a, or the end 203 of the operating portion 202a extends beyond the pillar surface 207 of the first pillar 26a in the first direction D1 (as shown in fig. 20). Accordingly, the user can apply a force to the releasing member 202 through the operating portion 202a to make the releasing member 202 swing at an angle (see fig. 21 and 22) so as to operate the other end 72b of the elastic member 72 to move, so that the hook 74 of the first structure 32 can be separated from the second structure 34. In other words, the user can release the first structure 32 from the second structure 34 without extending his/her hand into the housing or the second rail 30, so that the second rail 30 can be folded into the housing from the extended position E toward the second direction D2 relative to the first rail 28. Thus, the release member 202 is capable of operating the resilient member 72 to disengage the hook 74 of the first structure 32 from the second structure 34 (e.g., hole). Preferably, a return elastic member 209 is further included, and the releasing member 202 can be maintained at a predetermined position (as in the state of fig. 19) in response to the elastic force of the return elastic member 209.

Although the present invention has been described with reference to the present specific embodiments, it will be recognized by those skilled in the art that the above embodiments are illustrative only, and various equivalent changes and modifications may be made without departing from the spirit of the present invention, and therefore, it is intended to cover in the appended claims all such changes and modifications as fall within the true spirit of the invention.

Claims

1. A slide rail assembly comprises a first rail and a second rail, wherein the second rail can move relative to the first rail, and the slide rail assembly is characterized in that:

a first structure disposed adjacent an end of the first rail; and

a second structure arranged on the second rail;

when the second rail moves from a retracted position to an extended position relative to the first rail in a first direction, the first structure and the second structure are matched with each other to prevent the second rail from moving from the extended position in the first direction or a second direction;

wherein, the first direction and the second direction are opposite directions.

2. The slide rail assembly of claim 1 wherein one of the first structure and the second structure has a hook, and the other of the first structure and the second structure is a hole for the hook to pass through, such that two walls of the hole are located at two sides of the hook.

3. The slide rail assembly of claim 1 wherein the first rail is configured with a bracket and the first structure is disposed on the bracket.

4. The slide rail assembly of claim 3 wherein the bracket of the first rail comprises a side wall, an end wall, a fastener, and a resilient member, the end wall being substantially perpendicularly bent with respect to the side wall, the end wall being configured with at least one mounting member, the fastener being movably mounted to the side wall, the resilient member providing a spring force to the fastener to maintain the fastener in a locked state with a fastening portion of the fastener adjacent to the at least one mounting member of the end wall.

5. The slide assembly of claim 1 further comprising a third rail displaceable relative to the second rail, wherein the first rail is configured with a release feature and a synchronization element is movably mounted to the second rail, the third rail including a synchronization feature, the synchronization feature abutting the synchronization element in a predetermined position to synchronously displace the second rail and the third rail in the first direction relative to the first rail until the extended position is reached, the release feature releasing the synchronization element from the predetermined position to release the synchronous displacement between the second rail and the third rail.

6. The slide assembly of claim 5 wherein the synchronization member is pivotally connected to the second rail, the slide assembly further comprising a resilient feature for providing a resilient force to the synchronization member to maintain the synchronization member in the predetermined state.

7. The slide assembly of claim 5 further comprising a first working member and a second working member operably connected to the third rail and a stop is disposed adjacent an end of the second rail, the first working member and the second working member being disposed on opposite sides of the stop when the second rail is in the extended position relative to the first rail and the third rail is displaced relative to the second rail in the first direction to a fully extended position to prevent displacement of the third rail from the fully extended position in the first direction or the second direction.

8. The sliding rail assembly of claim 7 wherein the first and second operating members are pivotally connected to the third rail, and further comprising a resilient base disposed on the third rail, the resilient base having a first resilient portion and a second resilient portion for providing resilient force to the first and second operating members, respectively.

9. A slide assembly comprising a first rail having a front portion and a rear portion, a second rail displaceable relative to the first rail, a first bracket disposed adjacent the front portion of the first rail, and a second bracket movably disposed adjacent the rear portion of the first rail, the slide assembly comprising:

a first structure arranged on the first bracket; and

a second structure arranged on the second rail;

when the second rail is at an extending position relative to the first rail, the first structure and the second structure can be mutually clamped.

10. The slide rail assembly of claim 9 wherein one of the first structure and the second structure has a hook, and the other of the first structure and the second structure has a hole for the hook to pass through, such that two walls of the hole are located at two sides of the hook.

11. The slide assembly of claim 10 wherein the first bracket and the second bracket each include at least one mounting member, the first bracket and the second bracket being capable of providing the first rail to be mounted to a first column and a second column of a rack via the at least one mounting member, and the first bracket being disposed with a resilient member and the hook being disposed on the resilient member.

12. The slide rail assembly of claim 11 wherein the first bracket of the first rail comprises a side wall, an end wall, a fastener, and a resilient member, the end wall being substantially perpendicularly bent with respect to the side wall, the end wall being configured with the at least one mounting member, the fastener being movably mounted to the side wall, the resilient member providing a spring force to the fastener to hold the fastener in a locked state and a buckle portion of the fastener being capable of locking the first mast adjacent to the at least one mounting member of the end wall.

13. The slide assembly of claim 10 further comprising a third rail displaceable relative to the second rail, wherein the first rail is configured with a release feature and a synchronization element is movably mounted to the second rail, the third rail including a synchronization feature, the synchronization feature abutting the synchronization element in a predetermined position to synchronously displace the second rail and the third rail in a first direction relative to the first rail until the synchronization element is no longer in the predetermined position when displaced to the extended position, thereby releasing the synchronous displacement relationship between the second rail and the third rail.

14. The slide assembly of claim 13 wherein the synchronization member is pivotally connected to the second rail, the slide assembly further comprising a resilient feature for providing a spring force to the synchronization member to maintain the synchronization member in the predetermined state, the first rail release feature being one of a ramp and a curved surface.

15. The slide assembly of claim 13 further comprising a first and a second working member operably connected to the third rail, and a stop portion is disposed at an end of the second rail, wherein when the second rail is in the extended position relative to the first rail and the third rail is moved to a fully extended position relative to the second rail in the first direction, the first and second working members are disposed on opposite sides of the stop portion to prevent the third rail from moving from the fully extended position to the first or second direction, the first and second working members are pivotally connected to the third rail, and the slide assembly further comprises a resilient base disposed on the third rail, the resilient base having a first resilient portion and a second resilient portion for providing resilient force to the first and second working members, respectively.

16. The slide rail assembly of claim 11 further comprising a release member for operating the resilient member to disengage the hook from the aperture.

17. The slide rail assembly of claim 16 wherein the release member has an operating portion adjacent to the at least one mounting member of the first bracket.

18. The slide rail assembly of claim 16 wherein the release member has an operating portion and the operating portion is adjacent the first leg of the frame.

19. A slide rail assembly adapted for use with a frame including a first mast and a second mast, the slide rail assembly including a first rail having a first end and a second end, a second rail displaceable relative to the first rail, a first bracket disposed adjacent the first end of the first rail for mounting the first rail to the first mast, and a second bracket movably disposed adjacent the second end of the first rail for mounting the first rail to the second mast, the slide rail assembly comprising:

a second bracket movably disposed adjacent the second end of the first rail for mounting the first rail to the second mast;

a first structure arranged on the first bracket; and

a second structure arranged on the second rail;

when the second rail is located at an extending position relative to the first rail, the first structure and the second structure are matched with each other to prevent the second rail from moving from the extending position to the first direction or the second direction;

wherein, the first direction and the second direction are opposite directions.

20. The slide rail assembly of claim 19 wherein one of the first structure and the second structure has a hook, and the other of the first structure and the second structure has a hole for the hook to pass through, such that two walls of the hole are located at two sides of the hook, the first bracket includes a side wall, an end wall, a fastener and an elastic member, the end wall is substantially perpendicularly bent with respect to the side wall, the end wall is configured with at least one mounting member, the fastener is movably mounted to the side wall, the elastic member provides elastic force to the fastener, such that the fastener is maintained in a locked state and the at least one mounting member of the fastener adjacent to the end wall can lock the first column.