1. Field of the Invention
This invention relates to foldable support legs for tables, chairs, portable staging, risers, or other similar portable equipment requiring foldable legs for supporting a surface. More particularly, the present invention relates to an improved locking mechanism for folding legs which is simpler and stronger than other similar mechanisms.
2. Related Art
Portable tables, chairs, risers, etc. having foldable legs are well known. Such devices typically comprise a support surface of some kind having a plurality of support legs hingedly attached to the underside. The legs are rotatable from a folded position against the underside of the support surface, to an extended position where they are generally perpendicular to the support surface. When in the extended position, the support legs are typically locked into place by means of a lock arm, a catch, a linkage, or some other similar locking mechanism. The most common of these mechanisms typically involve hinged angular supports and sliding collars, or spring loaded catches.
To be functional and safe, these locking mechanisms must hold the legs firmly in place, without wobbling or twisting. However, they must be easy to lock and unlock, particularly for novices who are unfamiliar with the mechanism. Accordingly, it is preferable that such devices be lightweight, simple, and intuitive to use. Unfortunately, some prior leg locking mechanisms have relatively low strength, and are susceptible to failure. For example, hinged angular supports can easily buckle if a locking collar is not properly placed, possibly resulting in collapse of the legs and the support surface. Some prior leg locking mechanism can also be in the way of one's knees when sitting at the table. Others are complicated, expensive, and sometimes not very durable. Many of them are also quite heavy, and noisy, thus reducing the desirability, portability, and practicality of the support device.
It has been recognized that it would be advantageous to develop a locking mechanism for folding legs which is strong and durable, simple in construction and operation, and is relatively lightweight.
It has also been recognized that it would be advantageous to provide a locking mechanism for folding legs which eliminates or reduces potential hazards to one's knees, and which also provides for a wide range of leg styles.
The invention advantageously provides a locking mechanism for a support leg hingedly attached to a support surface. The locking mechanism includes a base, attached to the support surface, with a plurality of angularly spaced, radial teeth, and a coupler, attached to the support leg, having a plurality of angularly spaced, radial teeth configured to mate with the teeth of the base. A selectively releasable engagement mechanism is configured to engage and disengage the teeth of the base with the teeth of the coupler to allow selective rotation of the support leg from an extended position to a folded position, and to lock the leg in place in the folded and the extended position.
In accordance with a more detailed aspect of the present invention, the locking mechanism may include a pair of oppositely oriented bases attached to the support surface, each having a support leg connected thereto, and the pair of support legs being mechanically connected, the selectively releasable engagement mechanism further comprising an oppositely directed spring force built into each of the connected pair of legs, such that the natural position of the legs provides force to engage the teeth. A flexible tension member may be provided for countering the force of the engaging means to allow the tops of the legs to be drawn together, thus drawing the teeth out of engagement, allowing the legs to be rotated from the extended position to the folded position, and vice versa.
In accordance with another more detailed aspect of the present invention, the selectively releasable engagement mechanism may further comprise a biasing spring configured for biasing the counter-locking side of the coupler away from the locking side of the base, and a cam associated with the coupler, configured for creating a biasing force for biasing the counter-locking side of the coupler toward the locking side of the base, the biasing force of the cam being greater than the biasing force of the biasing spring. A release is associated with the cam, configured to release at least part of the biasing force of the cam, to allow the biasing spring to disengage the teeth of the base and the coupler, and allow rotation of the support leg when the release is actuated by a user.
Additional features and advantages of the invention will be apparent from the detailed description which follows, taken in conjunction with the accompanying drawings, which together illustrate, by way of example, features of the invention.
a is a pictorial view of the coupler and base of
b is a close-up, cross-sectional view of the interlocked teeth of
a is a pictorial view of one embodiment of a leg locking mechanism shown in
b is a pictorial view of the leg locking mechanism of
a is an exploded pictorial view of the leg locking mechanism of
b is an exploded pictorial view of the leg locking mechanism of
For the purposes of promoting an understanding of the principles of the invention, reference will now be made to the exemplary embodiments illustrated in the drawings, and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended. Any alterations and further modifications of the inventive features illustrated herein, and any additional applications of the principles of the invention as illustrated herein, which would occur to one skilled in the relevant art and having possession of this disclosure, are to be considered within the scope of the invention.
Viewing
Referring to
A circular hole 34 is provided in the coupler 18 at the center of the circular face 26, and a corresponding shaft 36 extends from the center of the circular face 32 of the base 20 to provide a rotational axle for the opposing faces 26 and 32. A biasing means is disposed around the shaft 36 between the circular faces, and is configured to push the coupler and base away from each other. This biasing means may comprise a spring washer (similar to spring washer 108 shown in
The teeth 28 and 30 are flat-topped and non-uniform in width so that the coupler 18 and base 20 will lock together only at desired angular orientations, as mentioned above.
Because the teeth 28 and 30 are non-uniform in width, they will engage only when appropriately sized valleys are disposed opposite appropriately sized ridges around the entire circular face. For example, in the embodiments shown in the drawings, there are two sizes of teeth. When rotating, the larger (wider) teeth ride on the flat tops of the smaller (narrower) teeth until the large teeth become disposed opposite large valleys which allow them to slide into locking position. The different sized teeth in conjunction with the flat tops are what allow smooth rotation between locking positions. Without different tooth sizes, the mechanism only rotates to the next tooth before locking again. With such a configuration proper functioning of the mechanism could be provided using a smaller number of uniform teeth with slots disposed only at positions corresponding to desired locking locations. However, larger numbers of teeth are desired to provide a larger interlocking surface area, and thus increased interlocking strength. It will be apparent that when engaged, the rotational strength of the rotary coupler is dependent in part upon the number of teeth which are interlocked. A larger number of uniform teeth would provide a strong connection, while also creating an interlocking position at each tooth. With non-uniform teeth, a few interlocking positions are possible while still providing many teeth which interlock, making the mechanism stronger.
Viewing
Naturally, too much taper will increase reliance on frictional forces, and may also create wedge action which tends to push opposing teeth away from each other, thus tending toward disengagement. Through experimentation, the inventors have found that teeth having a taper α (
The tapered sides of the teeth also minimize the effects of wear due to repeated usage over time. As the leg locking mechanism is used, the teeth may tend to deform slightly because of the large forces imposed upon them. This may cause an individual tooth or valley to change shape, possibly resulting in less than full contact between the teeth, and thus lower coupling strength and/or creating sloppiness in engagement. However, the tapered configuration of the teeth helps accommodate this deformation because the tapered sides are more likely to keep full contact even when deformed than are vertically-sided teeth.
Similarly, the tops 50 of the teeth may gradually wear down due to repeated sliding over each other, as indicated by the wear line 51 in
Referring back to
Other methods for biasing the couplers and bases in the engaged position are also possible. For example, the table leg assembly 12 may be configured such that the legs 14 are attached to the crossbar 16 at a slight angle, such that the tops of the legs must be deflected inwardly to fit between the bases, thus providing a normally outwardly directed biasing force, which is released by deflecting the compression rod 38 or by pulling on a flexible tension member 42 connected therebetween, as shown in
In an alternative embodiment, shown in
At the top of the single vertical leg 84 is a vertical slot 94, forming forked ends 96. The slot allows the legs to deflect inwardly, allowing the teeth to disengage. In this embodiment, the forked ends 96 are formed to be biased away from each other, so as to provide the engaging force to engage the teeth of the oppositely oriented bases 20. A buckling rod 98 is disposed between the forked ends to allow a user to deflect the forked ends toward each other, allowing the biasing means to push the locking and counter-locking faces away from each other, allowing the leg to be rotated. Alternatively, a cam or toggle mechanism (not shown) could be provided in the slot 94 to perform the same function.
Referring now to
Disposed on the base 102 is a circular hub 112 (seen best in
The invention advantageously incorporates a cam mechanism for biasing the counter-locking side of the coupler toward the locking side of the base, for engaging the teeth of the base and the coupler. Viewing
Returning to
The first interlocking tabs 140 have outwardly directed interlocking bevels 148 at their distal extremity. These outwardly directed bevels are configured to deflect and slide past a corresponding set of inwardly directed interlocking bevels 150 disposed at the ends of a second annular set of interlocking tabs 152 connected to the cam cylinder 106. The interlocking tabs 140 and 152 include oppositely oriented vertical locking faces 154 and 156, respectively. Because the tabs are resilient, and the diameters of their respective annular groupings are complementary, the oppositely oriented bevels push the tabs apart when the sets of tabs are pushed together, allowing the ends of the tabs to slide past one another, then snap back to their original position, engaging the locking faces. Additionally, the tabs 140 are different sizes (i.e. different widths measured radially) from the tabs 152 to prevent catching during rotation. This ensures that there is engagement of the locking faces of the tabs around the full perimeter at all times during rotation, yet helps prevent the edges of tabs from catching on each other because the edges of tabs are only encountered one at a time during rotation. The interlocking tabs thus lock with each other, yet allow sliding movement (i.e. rotation of the cam cylinder relative to the base) when pressed against each other. The engaged locking faces 154 and 156 of the interlocking tabs are shown in
To assemble the leg locking mechanism, the spring washer 108 is placed over the first set of interlocking tabs 140, and pushed toward the base 142 of the first interlocking tabs, such that it is roughly against the inner portion 144 of the locking side of the base. The 118 aperture of the coupler 104 is then aligned with the first interlocking tabs, and the coupler is slid into place with its counter locking side disposed near the locking side of the base, and the inner side 122 of the depression slidingly mated with the outer side 124 of the hub 112. The torsion spring 110 may then be inserted through the coupler aperture 118, and into the torsion spring recess 126 in the base. To hold the coupler in place, the cam cylinder 106 is inserted into the cam aperture 128, with the cam cylinder cam lobes 134 disposed toward the cam ridges 130 of the coupler and the torsion spring aligned with the cam cylinder torsion spring recess, until the second interlocking tabs 152 slide past and engage the first interlocking tabs 140.
Once assembled in this way, the torsion spring tends to hold the cam cylinder in a position wherein its cam lobes press against the cam ridges of the coupler, so that the teeth of the coupler and base will be engaged. The elongate torsion spring 110 is disposed with its long axis substantially coincident with the axis of rotation of the folding leg, and, being affixed at one end to the base and at the other end to the cam cylinder, resists rotation of the cam cylinder. The torsion spring may comprise a solid elongate piece of elastomeric material, such as polyurethane, extruded thermoplastic rubber, or other resilient materials. One suitable material for the torsion spring is Santoprene™, manufactured by Advanced Elastomers of Akron, Ohio. It will be apparent to one skilled in the art, however, that many other suitable configurations and materials for the torsion spring could be conceived for providing the same function. For example, the torsion spring could be a coil spring, and could be formed of metal.
The torsion spring 110 may be prismatic in shape, having a constant cross-section, as shown in
The torsion spring 110 is configured to hold the cam cylinder 106 with its cam surfaces engaged against the cam surfaces of the coupler, and thereby keep the flat-topped teeth 114 and 116 engaged, with sufficient force to overcome the oppositely directed force of the spring washer 108. To disengage the teeth, a user rotates the cam cylinder against the force of the torsion spring by pushing the release lever 138, to rotate the cam lobes into alignment with the cam valleys 132 of the coupler. This releases lateral force on the coupler, allowing the spring washer to push the coupler away from the base, thus separating the locking and counter-locking faces of the base and coupler, respectively, allowing free rotation of one relative to the other. The operation of the spring washer and the releasable cam cylinder thus create a selectively releasable engagement mechanism configured for selectively locking the leg in an extended position and a folded position, or any other desired position, depending on the configuration of the teeth.
Once the teeth disengage, the flat-topped teeth of the base and coupler may slide over one another as the leg is rotated, as described above, until the teeth reach a subsequent interlocking position. After releasing the teeth and beginning rotation, the user may let go of the release lever, allowing the cam to rotate with the coupler, until reaching the subsequent interlocking position. At that point, under the force of the torsion spring, the cam cylinder will tend to rotate back to a position in which the cam lobes of the cam cylinder press against the cam ridges of the coupler, thus pushing the coupler 104 toward the base 102 and engaging the teeth. The torsion spring also provides the added benefit of providing slight resistance to rotation of the leg, which gives the leg locking mechanism a feel of strength and quality, and may also prevent injury during its use, such as from sudden unexpected motion, etc.
In an alternative embodiment, the torsion spring 110 may be inserted after the cam cylinder 106 is put into place, depending upon the configuration of the torsion spring recesses 126 and 136. For example, as shown in
Viewing
Alternatively, referring to the upper left side of
Viewing
The individual parts of the leg locking mechanism may be formed of a variety of materials. It is desirable that the parts be strong and tough, yet lightweight, abrasion resistant, and dimensionally stable. Inherent lubricity is also desirable for slidingly engaged parts. Materials which the inventors have found to be suitable include injection molded polymers, such as acetal plastic (particularly for the cam cylinder) and glass-filled polypropylene (particularly for the coupler). Other parts, such as the spring washer 108 and the base 102 may be made of metal.
As described, the invention thus comprises a two-position mating lock which is attached to a table and a leg, and is configured for selectively locking the leg in an extended position and a folded position. The lock has a biasing member configured for biasing the mating lock in a disengaged position, and a selectively releasable spring member configured for biasing the mating lock in an engaged position, with the selectively releasable spring member providing a force greater than the disengaging force of the biasing member.
Referring now to
The embodiment of
The coupler 204 has a counter-locking side with a set of flat-topped teeth, generally designated at 216, disposed in a ring around the center of a circular aperture 218 and configured to mate with the teeth 214 of the base. These radially spaced flat-topped teeth are generally configured as described above, with a few exceptions as noted below. As with the embodiment of
The coupler 204 includes a cam aperture 228 which is configured to slidingly receive a cam cylinder 206. Disposed within the cam aperture and located at its periphery are a pair of curved cam ridges 230, with cam valleys 232 therebetween (only one of each of which are visible in
Protruding from the center of the hub 212 are a set of resilient interlocking tabs 240 arranged in an annular configuration, concentric with the angularly spaced, radial teeth 214. The base 242 of the tabs forms a circular shaft or axle about which the spring washer 208 is placed. The spring washer abuts against an inner portion 244 of the locking side of the base 202, and against an inner rim 246 of the aperture 218 of the coupler, as described above.
The interlocking tabs 240 have outwardly directed interlocking bevels 248 at their distal extremity, which are configured to deflect and slide past a corresponding set of inwardly directed interlocking bevels 250 disposed in the cam cylinder 206. The interlocking bevels push the interlocking tabs 240 inwardly when they are pushed into the cam cylinder, allowing the ends of the tabs to engage the inwardly directed interlocking bevels.
As with the other embodiments described above, the interlocking tabs 240 may be configured with radial widths that are different than the radial width of the interlocking bevels 250, so as to promote smooth rotation. One way of doing this is to provide different numbers of interlocking bevels on the base 202 and cam cylinder 206, respectively. For example, the embodiment depicted in
The leg locking mechanism depicted in
The glide ring slot 280 corresponds to a discontinuous glide ring 282 disposed around the perimeter of the circular hub 212 of the base 202. The glide ring interconnects the outer extremity of discrete groups of the radially spaced teeth 214 of the base around the perimeter of the hub, but leaves a tooth gap 284 corresponding to the location of each long tooth 216b of the coupler. When the teeth are disengaged and the coupler and base are rotated with respect to each other, the glide ring rides upon the flat top surfaces of the long teeth until it reaches the next location where the long teeth can slide into the tooth gap, allowing all teeth to interlock.
In the embodiment shown in
It is to be understood that the above-described arrangements are only illustrative of the application of the principles of the present invention. Numerous modifications and alternative arrangements may be devised by those skilled in the art without departing from the spirit and scope of the present invention and the appended claims are intended to cover such modifications and arrangements. Thus, while the present invention has been shown in the drawings and fully described above with particularity and detail in connection with what is presently deemed to be the most practical and preferred embodiment(s) of the invention, it will be apparent to those of ordinary skill in the art that numerous modifications, including, but not limited to, variations in size, materials, shape, form, function and manner of operation, assembly and use may be made, without departing from the principles and concepts of the invention as set forth in the claims.
This application is a continuation-in-part of U.S. patent application Ser. No. 09/859,919 filed on May 17, 2001 entitled LOCKING MECHANISM FOR FOLDING LEGS, now U.S. Pat. No. 6,598,544 which issued on Jul. 29, 2003.
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Number | Date | Country | |
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20050247243 A1 | Nov 2005 | US |
Number | Date | Country | |
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Parent | 09859919 | May 2001 | US |
Child | 10629440 | US |