Patent Grant
8317278
The present disclosure relates generally to slide assemblies having at least one releasable locking position. More specifically, the present disclosure relates to slide assemblies having telescopic slide members and a releasable latch system that provides for locking in an open position, a closed position or both of the opposed open and closed positions. In some instances, such slide assemblies are used in cabinet or desk structures to support and permit opening and closing movements of a drawer, in which case they are commonly referred to as drawer slides. However, such slide assemblies can be used in alternative environments, as desired.
It is common for slide assemblies to be configured for relatively free movement between opposed open and closed positions, although some include apparatus to assist in achieving an open or a closed position. Nevertheless, it has been recognized as advantageous for some applications to have the slide assemblies be releasably lockable exclusively when in an open, fully extended position, or exclusively when in a closed, fully retracted position, or when in either an open, fully extended position or when in a closed, fully retracted position. Indeed, there are slide assemblies with such locking open and closed positions, which may otherwise be known as having a lock-out position, a lock-in position, or both lock-out and lock-in positions. However, such known slide assemblies tend to be complex and/or have release mechanisms that permit or require operator inputs in directions that are not intuitive and convenient with respect to the intended direction of movement of the slide assembly.
In a first aspect, the present disclosure includes a slide assembly having an open locking position, a closed locking position, or both open and closed locking positions, while merely requiring an actuation force of intuitive pulling on a handle toward an open position to both unlock and move the slide assembly from a closed position to a locked open position, and/or an actuation force of intuitive pushing on the handle toward a closed position to both unlock and move the slide assembly from an open position to a closed position. The slide assembly further employs a releasable latch system having a compact and efficient design with the components mounted between the slide members, so as to achieve these advantageous features within a configuration that is seen as a normal slide assembly.
In a second aspect, the disclosure includes a slide assembly that includes a plurality of slide members connected in a linear telescoping configuration, a handle assembly connected to one of the slide members and a latch system configured to releasably lock the slide members with respect to each other. The latch system is configured to be unlocked and to allow movement of the slide members when an actuation force is applied to the handle assembly in the direction of the intended linear movement of the slide members.
In a further aspect, the disclosure provides a slide assembly having a first slide member, a second slide member and a third slide member, the slide members being slidably connected in a telescoping configuration, and further including a handle assembly connected to the first slide member, and having a latch system configured to releasably lock the slide members with respect to each other. The latch system is configured to be unlocked and to allow movement of the slide members when an actuation force is applied to the handle assembly in the direction of the intended movement of the slide members.
These and other aspects of the present slide assemblies will become apparent from the following detailed description of the structure of the slide assemblies and the method of using them, when considered in conjunction with the accompanying drawings.
While the drawings depict a slide assembly having both open and closed locking positions, it will be appreciated by one of skill in the art that consistent with this disclosure, a slide assembly may include only an open locking position, only a closed locking position, or both open and closed locking positions, but virtue of which components are included in the latching system and slide members.
Although the following discloses an example slide assembly having releasable lock-in and lock-out positions, such as for use in supporting a drawer from a cabinet or other structure, persons of ordinary skill in the art will appreciate that the teachings of this disclosure are in no way limited to the specific structure of the example. On the contrary, it is contemplated that the teachings of this disclosure may be implemented in alternative configurations and environments. Indeed, it will be appreciated that a slide assembly may be constructed to have only a lock-in position when closed, without locking in the fully extended, open position, or to have only a lock-out position when open, without locking in the fully retracted, closed position. Also those having ordinary skill in the art will readily recognize that the example slide assembly may be used for supporting and translating other structures relative to each other, and other configurations and constructions could be employed to accommodate the specific needs of a user. Accordingly, while the following describes an example slide assembly and methods of operating such a slide assembly, persons of ordinary skill in the art will readily appreciate that the disclosed example is not the only way to implement such a slide assembly within the scope and spirit of the appended claims.
As illustrated in
The slide members 10, 20 and 30 are configured for telescopic sliding motion and are preferably of metal construction, such as steel or other suitable materials. Thus, the first slide member 10 telescopically slides relative to the second slide member 20, such as by use of first bearing assemblies 90 having first bearing retainers 91 and associated bearings, such as ball bearings (not shown), while the second slide member 20 further telescopically slides relative to the third slide member 30, such as by use of second bearing assemblies 92 having second bearing retainers 93 and associated bearings, such as ball bearings (not shown). The bearing retainers are preferably constructed of molded plastic but may be of plastic or metal construction. It will be appreciated that the sliding engagement between the respective slide members could be achieved with suitable structures other than ball bearings, which typically would be constructed of hardened steel or other suitable materials. Also, the reference to telescoping is not intended to mean that the slide members must be configured to have each successive slide member be located within the next slide member. Rather, telescoping is intended to be used to mean any configuration in which each successive slide member extends some distance further than an adjacent slide member when in an open position.
In the illustrated example, the first slide member 10 includes opposed flanges 11 and a web 12 therebetween. The front end 13 of the first slide member 10 includes an aperture 14 in the web 12 that receives a pivot of the first latch assembly 60, and an aperture 15 in a flange 11 that receives an end of a spring of the first latch assembly 60. The web 12 further includes apertures 16 for mounting the first slide member 10 to another structure, such as a drawer (not shown). Proximate a central region of the first slide member 10 are apertures 17 and 18 that receive respective pivots for the second latch assembly 70. The flanges 11 slidably receive a portion of the handle assembly 40 on a portion of their inner surface 11′ while engaging the first bearing assemblies 90 on their outer surfaces 11″. The flanges 11 also include bearing retainer stops 19 that are formed in this example as projections at the rear end 13′ of the first slide member 10 and that act as stops for the first bearing retainers 91.
The second slide member 20 includes opposed flanges 21 and a web 22 therebetween. The front end 23 of the second slide member 20 includes an opening 24 in the web 12, with a stop 24′ that is formed in this example as a tab extending from the web 12 for engagement with the second latch assembly 70 and bearing retainer stops 25 that are formed in this example as projections at the front end 23, and that act as stops for the first bearing retainers 91. The web 22 further includes apertures 26 proximate a central region for access to other fasteners. Proximate the rear end 23′ of the second slide member 20, the web 22 has an aperture 27 for a pivot of the third latch assembly 80, an opening 28 which permits access by the third latch assembly 80 to the third slide member 30, and an aperture 29 that receives an end of a spring of the third latch assembly 80. The flanges 21 engage the first bearing assemblies 90 on their inner surfaces 21′ and engage the second bearing assemblies 92 on their outer surfaces 21″.
The third slide member 30 includes opposed flanges 31 and a web 32 therebetween. Proximate the front end 33 of the third slide member 30, the web 32 includes a front stop 34 that is formed in this example as a tab, for engagement with the first latch assembly 60. The flanges 31 include bearing retainer stops 35 that are formed in this example as projections at the front end 33, and that act as stops for the second bearing retainers 93. The flanges 31 engage the second bearing assemblies 92 on their inner surfaces 31′. The web 32 includes apertures 36 for mounting the third slide member 30 to another structure, such as a cabinet (not shown). The web 32 further includes a rear stop 37 that is formed in this example as a tab and that is located in a central region of third slide member 30 for engagement with the third latch assembly 80. At the rear end 33′ of third slide member 30, the web 32 has a central stop 38 that is formed in this example as a large tab and that acts as a rear stop for the second slide member 20.
The flanges 21 of the second slide member 20 also include apertures 21′″ to receive a fastener 94, such as a press fit steel roll pin, or other suitable fastener, and the outer ends of the fastener 94 act as bearing retainer stops for the second bearing retainers 91. The fastener 94 also is used to connect a resilient block 95 to the second slide member 20. The resilient block 95 preferably is made of a foam rubber or other suitable material and acts as a bumper by providing a cushioned stop for the first slide member 10 against the front side 95′, as well as a cushioned stop of the second slide member 20 as the rear side 95″ stops against the central tab 38 of the third slide member 30. It will be appreciated that the resilient block 95 could be connected to the second slide member 20 separately or in other ways if such integrated cushioned stopping is desired, or cushioned stopping could be provided by other suitable structures.
The handle assembly 40 of the slide assembly 1 of the illustrated example includes a handle 41, which is connected to a slider 42, both of which preferably are of metal construction, such as steel, although other suitable materials could be used. In this example, the handle 41 has a right-angled bend to permit easy grasping by a user at its front end while permitting easy connection to the flat slider 42 at its rear end. The handle 41 includes a partial cover 41′ that is constructed of plastic, rubber or other suitable materials for more comfortable gripping. The slider 42 has apertures 43 at its front end to receive fasteners 44 used to connect the handle 41 to the slider 42. The slider 42 also includes an aperture 45 that receives a pin 46, preferably constructed of steel or other suitable material, and that is connected to the slider 42, such as by press fit, welding or by other suitable methods of connection. The slider 42 has elongated openings 47 along its length to permit access to mounting fasteners that are installed through the apertures 16 in the first slide member 10. A further elongated aperture 48 is located proximate the front end of the slider 42. A post that serves as a pivot for the first latch assembly 60 passes through the elongated aperture 48 in a manner that holds the slider 42 to the web 12 of the first slide member 10, while permitting the slider 42 to slide relative to the first slide member 10, as will be discussed herein in more detail. The rear end of the slider 42 has a stepped surface 49 that selectively engages a latch body of the second latch assembly 70.
Turning to the structures of the releasable latch system, the slide assembly 1 includes a releasable latch system 50 having a compact and efficient design with the components mounted between the slide members. In this particular example, the releasable latch system 50 allows the slide assembly 1 to achieve releasable lock-in and lock-out positions within a configuration that is otherwise seen as a normal slide assembly. The releasable latch system 50 is configured to be unlocked and to allow linear movement of the slide members 10, 20, 30 when the handle assembly 40 is subjected to an actuation force in the direction of the intended linear movement of the slide members. The slide assembly 1 includes a releasable lock-in position when the slide members are in a closed, fully retracted position and a releasable lock-out position when the slide members are in an open, fully extended position. The releasable latch system includes latches that are configured so that they will automatically lock the slide assembly 1 in the lock-out position when the handle assembly 41 receives a linear actuation force in the direction of extending the slide assembly to an open, fully extended position, and will automatically lock the slide assembly 1 in the lock-in position when the handle assembly 41 receives a linear actuation force in the direction of retracting the slide assembly to a closed, fully retracted position. It will be appreciated that the slide assembly could be constructed with a latch system having fewer components and which provides only a lock-out position or only a lock-in position, as discussed further herein.
Within the releasable latch system 50 of the example slide assembly 1 having both lock-out and lock-in positions, the first latch assembly 60 includes a first latch 61, a post 62 and a resilient element 63. In this example, the first latch 61 preferably is constructed of metal, such as steel or other suitable materials, and the resilient element 63, in this example, is preferably constructed as a coiled torsion spring made of spring steel, however, other configurations and/or suitable materials could be used. The first latch 61 and resilient element 63 are pivotally movable about the post 62 which is preferably constructed of metal, such as steel or other suitable materials, and the post 62 is connected to the first slide member 10 at the aperture 14 therein, such as by press fit, welding or other suitable methods.
The first latch 61 has a main planar portion 64 that lies adjacent the slider 42 and includes a locking member 65 formed as a tab at its rear and that extends generally perpendicular to the main planar portion 64. The first latch 61 also includes an upstanding lever 66. The locking member 65 includes a small groove 67 that receives a first end 63′ of the resilient element 63 with a second end 63″ of the resilient element 63 being received in the aperture 15 in the flange 11 of the first slide member 10. The resilient element 63 in the illustrated example biases the first latch 61 to rotate to a neutral position where an edge of the main planar portion 64 engages the inner surface 11′ of a flange 11 on the first slide member 10. This position permits locking in the closed position of the slide assembly 1 when the locking member 65 comes to rest behind the front stop 34 on the third slide member 30, as will be described further herein. Thus, a slide assembly could be made to have only a lock-in position if it includes just a latch assembly such as the first latch assembly 60.
It will be appreciated that the first latch 61 may be automatically rotated against the biasing force of the resilient element 63 when the locking member 65 contacts the front stop 34 and rides up and over the stop 64 as the slide assembly 1 nears the fully closed position and regardless of whether or not the handle assembly 40 is being pushed in route to the closed position, as best seen in the sequence of
Further, when opening the slide assembly 1 from a fully closed position, it will be understood that the first latch 61 may be rotated against the biasing force of the resilient element 63 when the handle assembly 40 is pulled, causing the slider 42 and its pin 46 to drive forward the lever 66 of the first latch 61 relative to the post 62, as the slider 42 slides relative to the first slide member 10 until the end of the elongated slot 48 engages the post 62. This causes the locking member 65 to be lifted over the front stop 34 on the third slide member 30 to unlock the first slide member 10 from the third slide member 30 when pulling on the handle assembly 40 to extend the slide assembly 1 from its fully closed position toward an open, extended position, as best seen in the sequence of
Turning to the second latch assembly 70, there is a second latch 71, a first post 72, a resilient element 73 and a second post 74. The first post 72 is connected to the second slide member 20 at aperture 17 for pivotal connection of the second latch 71 to the second slide member 20. The second post 74 is connected to the second slide member 20 at aperture 18 for pivotal connection of the resilient element 73 to the center slide member 20. The construction materials and basic connection of the second latch 71, the first post 72, the resilient element 73, and the second post 74 to the second slide member 20 are similar to that which was described above for the components of the first latch assembly 60, but need not necessarily be similar.
The second latch 71 has a main planar portion 75 that lies adjacent the second slide member 20 and further includes an offset portion 76, a locking member 77 in the form of a secondary planar portion that is substantially parallel to the main planar portion 75, and a tab 78 at its rear that extends generally perpendicular to the secondary planar portion 77. The locking member 77 includes a locking surface 77′ that selectively engages the respective stop 24′ on the front end 23 of the second slide member 20. The second latch 71 also includes an upstanding lever 75′ that is an upward extension of the main planar portion 75. The tab 78 includes a small groove 79 that receives a first end 73′ of the resilient element 73 with a second end 73″ of the resilient element 73 engaging the inner surface 11′ of a flange 11 on the first slide member 10.
The resilient element 73 in the illustrated example biases the second latch 71 to rotate to a neutral position where the lever 75′ engages the stepped surface 49 at the rear end of the slider 42, when the first latch assembly 60 also is in its above-described neutral position, as best seen in
When the slide assembly 1 is in the fully extended, lock-out position, it will be appreciated that the second latch 71 may be rotated against the biasing force of the resilient element 73 when the handle assembly 40 is pushed so as to move the slide assembly 1 toward a closed position, thereby causing the stepped surface 49 on the rear end of the slider 42 to push the lever 75′ rearward relative to the post 72 on the second slide member 20. This causes the release of the second latch assembly 70 as the stop 24 rides up and over the locking surface 77′ of the locking member 77, as best seen in stepping from
Further, when the slide assembly 1 is in the fully retracted, lock-in position, the second latch 71 may be automatically rotated against the biasing force of the resilient element 73 when the handle assembly 40 is pulled, causing the slider 42 to slide forward relative to the first slide member 10 until the elongated slot 48 engages the post 62, thereafter causing the handle assembly 40 to pull the first slide member 10 toward an extended position relative to the second slide member 20. As best seen in the sequence of
Turning to the third latch assembly 80, there is a third latch 81, a post 82 and a resilient element 83. The post 82 is connected to the second slide member 20 at aperture 27 for pivotal connection of the third latch 81 and the resilient element 83 to the second slide member 20. The construction materials and basic connection of the third latch 81, the post 82, and the resilient element 83 to the center slide member 20 are similar to that which was described above for the components of the first and second latch assemblies 60, 70, but need not necessarily be similar.
The third latch 81 has a main planar portion 84 that lies adjacent the second slide member 20 and further includes an offset portion 85 that extends through the opening 28 in the web 22 of the second slide member 20, and a locking member 86 in the form of a secondary planar portion that is substantially parallel to the main planar portion 84. The locking member 86 includes a locking surface 86′ that selectively engages the rear stop 37, which is located in the central region of the third slide member 30. The third latch 81 also includes an engagement surface 87 along an outer edge that is configured to be engageable by the inner surface 21′ of a flange 21 on the second slide member 20. The main planar portion 84 includes an aperture 84′ that receives a first end 83′ of the resilient element 83 with a second end 83″ of the resilient element 83 received by the aperture 29 in the web 22 of the second slide member 20.
The resilient element 83 in the illustrated example biases the latch body 81 to rotate to a neutral position which is shown in
It will be appreciated that the third latch 81 may be rotated against the biasing force of the resilient element 83 when the slide assembly 1 has been unlocked and is moving toward a closed position, with the above-described release of the second latch assembly 60, thereby allowing the first and second slide members 10, 20 to be moved rearward. As the rear end 13′ of the first slide member 10 engages the engagement surface 87 on the third latch 81, the engagement surface 87 rides up and into engagement with the inner surface 11′ of the first slide member 10, rotating the third latch 81, as is about to occur in
Further, the third latch 81 may be automatically rotated against the biasing force of the resilient element 83 when the slide assembly 1 is moved toward an open position, such that the first slide member 10 moves toward an extended position relative to the second slide member 20, eventually reaching the locked position of the second latch assembly 70 shown in
Having set forth the structures and some of the basic movements of components within the slide assembly 1, the operation of the slide assembly 1 can be described more fluidly. For instance, the slide assembly 1 is shown in an open, fully extended and locked out position within
Turning to
Then, as the second slide member 20 extends toward an open, fully extended position, the third latch 81 of the third latch assembly 80 engages the rear stop 37, located in a central region on the third slide member 30. This sequence of movements is shown in
One will appreciate that the releasable latching system 50 of the illustrated example results in a device which does not require one to learn how to operate the slide assembly 1, despite its capabilities to provide releasable lock-in and lock-out positions.
While the present disclosure shows and demonstrates an example of a slide assembly that may be adapted for use with releasable lock-in and lock-out positions, the example is merely illustrative and is not to be considered limiting. It will be apparent to those of ordinary skill in the art that various alternatives may be constructed without departing from the scope or spirit of the present disclosure. Indeed, one of skill in the art will appreciate that if it is desired to have a slide assembly having only a lock-in position, then a latch system could include the first latch assembly 60 that is connected to the first slide member 10, while if it is desired to have only a lock-out position, then a latch system could include the second latch assembly 70 that is connected to the first slide member 10 and the third latch assembly 80 that is connected to the second slide member 20.
Thus, although an example method and apparatus have been described herein, the scope of coverage of this patent is not limited thereto. On the contrary, this patent covers all methods, apparatus and articles of manufacture fairly falling within the scope of the appended claims either literally or under the doctrine of equivalents.
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