The present invention generally relates to folding table assemblies. More particularly, the present invention relates to a lifting assist assembly for a folding table and a means for maintaining the location or position of the folding table when in an unfolded and operative or use position.
Folding roll-away tables having seating structures are know in the art, for example as disclosed in U.S. Pat. Nos. 6,223,661 and 3,075,809, the disclosures of both of which are hereby incorporated by reference. Such foldable tables have lifting assist mechanisms intended to assist an operator during the folding of a folding table from an unfolded use position to a folded storage or moving position. Existing lifting mechanisms typically use one or more torsion bars for providing lifting assistance to the operator. Two to four torsion bars are employed in a typical torsion bar lifting assist mechanism. The torsion bars are typically attached to the table frame on one end of the torsion bar and attached to a hinge tube of a leg assembly at the other end of the torsion bar. Each torsion bar stores energy that will be used to fold the table assembly. Torsion bar holders are attached to the table frame and have a hexagonal hole configuration that solidly accepts and locks one end of the torsion bar to the table frame assembly. In this manner, the attached torsion bar end is solidly positioned and not allowed to twist with respect to the table frame at this point. The opposite end of the torsion bar is solidly attached to the hinge tube of a leg assembly with a second hexagonal torsion bar holder. With this end of the torsion bar firmly attached to the leg assembly, the torsion bar will twist as the leg assembly rotates with respect to the table frame when the folding table assembly is unfolded between the storage and use positions. In existing foldable tables, the torsion bars typically twist or rotate throughout a range of ninety degrees (90°) during the unfolding or folding operation. Other lifting assist mechanisms using torsion bars may twist through a greater or lesser angular range depending on the torsion bar construction.
During the unfolding process of existing foldable table assemblies from a folded or storage position to an open unfolded use position, the operator unfolds the foldable table and thereby stores potential energy in the torsion bars. The operator-applied force and the force of gravity acting on the table assembly overcomes the natural tendency of the torsion bars to remain in an untwisted state as the table unfolds. As the table assembly unfolds, the free ends of the torsion bars are twisted through ninety (90) degrees as the table legs swing out to an open position and thereby store enough energy in the torsion bars to later release the stored energy to fold the table.
To initiate the folding process from an unfolded or use position to a closed or folded storage position, a small input force is required from the operator. The initial operator input force is necessary since the folding table tends to want to fold due to the stored energy in the torsion bars. The folding table assembly needs a locking mechanism to keep the folding table in a flat and unfolded use position. Typical foldable table designs, such as those described in U.S. Pat. Nos. 6,223,661 and 3,075,809, require a small operator input force of about ten (10) to twenty (20) pounds of force vertically applied at the midpoint of the foldable table assembly near the center hinge point to initiate the folding sequence.
Existing lifting assist torsion bar designs, however, have drawbacks associated with them. For example, the amount of force needed to close the table varies as it closes, so that more force is needed, either from the operator or the torsion bars, when the table begins to fold away from its unfolded use position than when it approaches the fully folded storage position. Existing designs attempt to provide the required force by attempting to balance the amount of torque induced by the torsion bars with the weight of the table as it is being folded or unfolded. However, if too much force is added near the top of the table's travel, the table will snap shut causing a potential safety hazard as well as unnecessary wear and tear. Further it would be difficult to pivot the two halves of the tables as an operator starts to unfold the table. If there is insufficient force near the top of the table's travel, the table will “feel” heavy as the operator tries to fold it. Thus, additional lifting force would be beneficial in assisting the operator at the beginning of the folding process but is not necessary at the end of the folding process as the table approaches its folded position.
Existing mobile folding tables typically have stool-style seat structures with wheeled casters positioned directly underneath the stool seat post of the end leg assembly, for example as disclosed in U.S. Pat. No. 3,075,809. In this end leg configuration, the casters always maintain contact with the floor irrespective of whether the folding table assembly is folded, unfolded or in a position therebetween. The tendency of the lifting assist torsion bar assembly is to fold the table from an unfolded position, thus the center legs will tend to rise off the floor. When the center legs rise and lose contact with the floor, so too do the gripping pads at the base of the seating stool tubes. This results in the weight of the table being shifted mostly to the wheeled caster which further results in movement or wandering of the unfolded table from its original location.
Additionally, if weight is concentrated near or at the ends of the folding table assembly or directly over the wheeled casters, the center legs also tend to rise off the floor, also resulting in movement or wandering of the unfolded table from its original location. Existing folding tables, having wheeled casters on the end leg assemblies are prone to shift or wander in the unfolded use position, especially on hard floor surfaces. This can be a significant problem in certain use environments such as in school cafeterias and the like where hard flooring surfaces such as vinyl tile is common. Further, manufacturing tolerances, clearances, and the inherent flexibility in the table structure increases the likelihood that the table will deviate or wander from its original unfolded location on the floor.
There is thus a need for a folding table assembly with a lifting assist mechanism that will provide an assist lifting force primarily during the beginning of the folding process of the foldable table assembly from an unfolded use position to a folded storage position. There is also a need for a mechanism that will assist in maintaining an unfolded table assembly in a stationary position and to prevent the unfolded table from wandering or deviating from its original location on the floor.
The present invention provides a folding table assembly for assisting in the transition of a folding table between an open position and a closed position. The folding table assembly includes a center torsion bar mechanism having a clutch mechanism and a center torsion bar coupled to the folding table such that the folding table folds about the center torsion bar as the table is moved between the open and closed positions. The center torsion bar is preferably fixed to the folding table at a first end and moveably coupled to the folding table at an opposite second end via the clutch mechanism. The clutch mechanism engages the center torsion bar at a first semi-folded position as the table is unfolded from the closed position. The center torsion bar stores folding potential energy between the first semi-folded position and the open position as the folding table continues unfolding to the open position. The center torsion bar is adapted to provide a lifting force between the open position and a second semi-folded position as the folding table is folded from the open to the closed position. In one embodiment, the first semi-folded position and the second semi-folded position are identical table positions. The lifting force is provided via release of the stored folding potential energy in the center torsion bar until the clutch mechanism disengages the center torsion bar at the second semi-folded position as the table continues to fold to the closed position. There lifting assist mechanism provides an assist lifting force during the beginning of the folding process of the foldable table assembly from an unfolded use position to a folded storage position.
The folding table assembly can further include a lift off caster assembly that assist in maintaining the unfolded table assembly in a stationary position and preventing the unfolded table from wandering or deviating from its original location on the floor. The lift off caster assembly has a plurality of lift-off rollers coupled to table end leg assemblies. The plurality of rollers are adapted to support the folding table and facilitate folding of the folding table. The plurality of rollers are also adapted to lift-off from a table supporting structure when the folding table reaches the open position enabling the center and end table leg assemblies to land and support the folding table. The plurality of rollers also contact the floor and lift the center and end table leg assemblies from the supporting structure, e.g., the floor, as the folding table is folded from the open to the closed position.
In one aspect of the present invention a center torsion bar for a foldable table assembly provides lifting assistance to an operator during the beginning of the folding process from an unfolded use position to a folded storage position.
In another aspect of the present invention a mechanism is provided to assist in maintaining an unfolded table assembly in a stationary position.
In an additional aspect of the present invention a mechanism is provided to prevent the unfolded table from “wandering” or deviating from its original location on the floor.
In still a further aspect of the present invention a graduated torsion bar assist mechanism increases the efficiency of the torsion assist mechanism throughout the folding table's range of motion while lifting the caster wheels off the floor when the table assembly is opened and unfolded.
In another aspect of the present invention a center torsion bar assembly matches efficiently the amount of energy provided by the torsion bars to the amount of force actually needed during the table's travel from fully folded to fully unfolded and vice versa.
In a further aspect of the present invention a center torsion bar assembly provides lifting assistance to an operator for folding the table assembly using a reduced number of torsion bars used in the lifting assist assembly.
The following drawings and description set forth additional advantages and benefits of the invention. More advantages and benefits will be obvious from the description and may be learned by practice of the invention.
The present invention may be better understood when read in connection with the accompanying drawings, of which:
The short drive links 8A and 8B connect the table frame assembly 20A and 20B to the nearest center leg assembly 200 at a center tube yoke 508A and 508B, shown in
The short drive link 8A and 8B and a second connecting center drive link 40A and 40B are pinned at the center leg open yoke 240 on the central-most center leg assemblies 200. The total number of center leg assemblies 200 used in the mobile folding table 100 will determine the length of the second center drive link 40A and 40B. If a second or third center leg assembly 200 is required on a table section 5A and 5B, the second center drive link 40A and 40B will horizontally connect the additional center leg assemblies 200 to the central-most leg assemblies 200. All of the center leg assemblies 200 are preferably identical in construction and therefore the center leg yoke points are all identical and will pass horizontally through the open yokes 240 on each center leg assembly 200. As a result, each of the center leg assemblies 200 will pivot in synchronization with its twin center leg assembly 200 on the opposite table section 5A and 5B of the folding table 100 and will rotate through the same number of degrees, at the same rate, as any other center leg assembly 200 immediately inboard of it.
As the table is being folded, for example from an unfolded position shown in
The end leg assemblies 300 are identical to each other and comprise a stool post 315 and tubular structure 310 to connect two stools 202 to the linkage points and pivot points 23A, 23B, 29A and 29B on the table frame structure 20A or 20B, and the undercarriage of the mobile folding table 100. The end leg assemblies 300 are connected to the table frame structure 20 or 20B at their respective pivot locations 23A, 23B, 29A and 29B, and are also connected to end leg drive links 45A or 45B, shown in
The end leg assemblies 300 are connected to the mid or central-most center leg assemblies 200 by an end leg drive link 45A or 45B, shown in
End leg assembly 300 comprises a pair of stool posts 315 that extend completely to the floor and caster wheels 30 that are located above the floor when folding table 100 is in the unfolded position as shown in
The end leg casters 30 are preferably mounted to caster tubular spur extensions 320 of the stool post 315 on each end leg assembly 300. The caster tube 320 preferably has a rectangular or square cross-section and is mounted at an angle 324 to the stool post 315. The caster tube angle 324 of the caster tube 320 to the stool post 315 is preferably such that, in the unfolded table position, the caster wheel 322 does not touch or only slightly contacts the floor irrespective of the position that the caster wheel 322 may be rotated on its stem 326. The caster tube angle 324 between caster tube 320 and the stool post 315 is preferably determined by the folded position of the mobile table when it is locked for normal maneuvering and storage. The casters 30 are preferably mounted such that the caster tube 320 is parallel to the floor and the hole drilled for the caster stem 326 is perpendicular to the floor since it is easiest to maneuver a set of casters 30 when the axis of rotation of the caster stem 326 is perpendicular to the ground. The caster wheels 322 will then freely follow a travel path as intended by an operator as he or she maneuvers the folded mobile table 100.
The cross-section of the caster tube 320 is preferably rectangular in order to facilitate the easy and stable mounting of the caster 30 to the end leg assembly 300. A round caster mounting tube 320 could be used, but may cause a caster stem 326 to bend about the axis of the caster tube 320 thereby shortening the life of the caster and increasing the likelihood of failure of the caster 30. The caster stem 326 is fastened through a hole placed in the caster tube 320 at a distance along the caster tube 320 away from the stool post 315. The hole is preferably placed as near as possible to the stool post 315 in order to minimize the moment created by cantilevering the caster tube 320 off the stool post 315. The farther the caster stem 326 is located from the stool post 315, the greater the bending moment introduced to the caster tube 320. High bending moments can cause the tubular structure 310 of the end leg 300 to flex or sag under the combined weight of the mobile folding table 100 which disadvantageously decreases the distance the stool post 315 is lifted off the ground during folding of the mobile table 100. The requirement of lifting the end leg 300 off the floor preferably determines the minimum distance the caster 300 can be mounted away from its stool post 315.
Further, the upright end leg tubes 312 on each end leg assembly 300 are configured differently from the center leg assemblies 200 in order to facilitate the rotational characteristics required for the end leg assemblies 300 as the mobile table 100 folds and unfolds. The end leg uprights 312 are preferably skewed at an angle of five degrees (5°) from vertical, however the leg may be skewed at another angle depending on the particular configuration of the mobile foldable table. The skewed configuration of the end leg uprights 312 allows for a shorter distance between pivot points 23A, 23B, 29A and 29B of the end leg assembly 300 and the adjacent center leg assembly 200 on the table frame structure 20A or 20B while at the same time allowing leg assembly stool seats 202 and 302 to be spaced at regular intervals.
In one embodiment, a torsion bar 550, shown in
The torsion bar assembly 600 with its center torsion bar 550 is preferably located at the central hinge 17 and is mounted directly to the table frame structure 20A and 20B at one end 520 and is rigidly connected to the frame via a clutch mechanism 560 at the other end 530. The clutch mechanism 560 is preferable use to prevent the center torsion bar 550 from rotating through one-hundred eighty degrees (180°) as the mobile table 100 or 400 travels from a completely unfolded open position to a completely folded closed position which would be the case if the center torsion bar 550 were to be fastened by existing conventional methods. The clutch mechanism 560 prevents the center torsion bar 550, which is typically spring steel or some other medium to high carbon alloy steel, from experiencing excessive plastic deformation when the center torsion bar 550 is twisted past ninety degrees (90°).
The clutch mechanism 560 preferably allows only ninety degrees (90°) of rotation in the center torsion bar 550. This aspect will maintain the stresses experienced by the center torsion bar 550 material as low as possible and thereby increase the life span of the center torsion bar 550 and the center torsion bar assembly 600.
The clutch mechanism 560 permits the center torsion bar 550 to rotate freely and not build up stored energy as the mobile table travels from a fully folded closed position, shown in
At the ninety degree (90°) angle between the table frame structures 20A and 20B, the clutch mechanism 560 will engage the center torsion bar 550. Any further movement of the mobile folding table 100 and 400 in the unfolding direction will twist the engaged center torsion bar 550 thereby storing energy as the mobile table continues to the unfolded position 100 shown in
In the fully unfolded position, the table sections 5A and 5B are substantially parallel to the floor and are said to be in a zero degree (0°) position. In this position, the folding table frame structure 20A an 20B and table frame rails 25A, 25B, 27A and 27B are also parallel to the floor and are in the zero degree (0°) position. When the mobile table 100 is in the unfolded position, the center torsion bar 550 has its maximum amount of stored energy.
Additionally, the wheeled casters 30 of the end leg assemblies 300, which were facilitating the movement of the unfolding table 100, have lifted off the floor and allowed the unfolded table 100 to rest on the seat stool base 315 thereby allowing the unfolded table to maintain a good grip on the floor and prevent the unfolded table from wandering from its position. Conversely, when the unfolded table is lifted from the unfolded position by the operator, the hinge section 17 of the table will move vertically. The vertical movement of the center hinge section 17 will be translated to the leg assemblies 200 and 300 via the short, center leg and end leg drive links 8A, 8B, 40A, 40B, 45A and 45B to the center leg and end leg assemblies 200 and 300. The translated movement will force the leg assemblies 200 and 300 to pivot and swing inward as the mobile table 100 rises. The wheeled casters 30 of the end leg assemblies 300 will swing down and land on the floor and thereby transfer the weight of the folding table 100 onto the wheeled caster 30. The caster wheels will make it easier for the mobile table 100 to move and travel towards its folded table position 400.
In moving the unfolded table 100 to a folded position 400, the stored energy in the center torsion bar 550 preferably provides the operator with an additional or supplemental lifting force when lifting the unfolded table 100 to a folded position 400. This is advantageous, since the greatest amount of lifting force is required at the beginning of the folding process. The operator will benefit by needing to exert substantially less force than required by existing folding table designs. The center torsion bar 550 will continue to deliver its lifting assist force as the mobile folding table continues to fold towards the closed position 400 until the table again reaches the half way folded position shown in
A pin holder 604A or 604B, shown in
The dowel pin 910 is preferably metallic, such as steel, and may have chamfered ends or a spiral cut along its surface to make inserting or removing the dowel pin 910 into and out of the pin holder 604A and 604B easier. The other free end 914 of the dowel pin 910 preferably extends beyond the outside surface 902 of the pin holder 604A or 604B such that the dowel pin 910 can come into operative contact with one of two pin guides 1050 and 1150, shown in
The pin guides 1050 and 1150, shown in
The unslotted pin guide 1150 serves as a rigid attachment point for one end 654B of the center torsion bar 550. The opposite end 654A of the center torsion bar 550 is aligned with the slotted pin guide 1050. The slotted pin guide 1050 is also preferably welded or otherwise securely attached to the outermost hinge plate 19A of the mobile foldable table 100 and 400 concentric with the folding axis 10 of the mobile table 100 and 400 in a position that allows the dowel pin 910 to travel freely inside the slot 1055 as the mobile table 100 and 400 is unfolded from its completely folded position at zero degrees (0°), shown in
In the partially folded or unfolded position of
Additionally, since the center torsion bar 550 is coincident with the hinge axis 10 of the folding mobile table 100 and 400, the center torsion bar assembly further comprises a surface 719, shown in
The female socket 850 is preferably welded or securely attached by other means to a center torsion bar cover tube 650 with an identical female socket 850 attached to the opposite end of the cover tube 650. The cover tube 650 should span the distance between the table frame rails 25A, 25B, 27A and 27B and can function as a protective barrier around the center torsion bar 550. The cover tube 650 can protect the center torsion bar 550 from wear and tear and may additionally protect a table operator from injury due to the failure and rupture of the center torsion bar 550 during the loading or unloading phase of the mobile folding table 100 and 400.
The clutch mechanism 560 also comprises pin guide end caps 1200, shown in
The upper hinge or saddle section 1605 preferably has a semi-circular or U-shaped configuration to complimentarily or concentrically accept the end leg hinge 305, as shown in
The bracket mounting surface 1610 is preferably flat so as to mount flush with the underside surface of the table sections 5A and 5B, as shown in
The end leg support bracket 1505 is preferably made of a plastic based material, such as molded polyvinyl chloride (PVC) material to provide flexibility and minimize scratching of the end leg hinge tube 305. The plastic based material also prevents gouging of the end leg hinge tube 305 which can lead to rust and added friction in the operation of the end leg hinge tube 305. Though less preferred, other materials, such as metallic based end leg support brackets 1505, may be used even if such materials may sometimes lead to gouging of the end leg hinge tube 305 after repeated use.
As shown in
As shown in
As shown in
As shown in
The lock backstop 1535, the end leg hinge tube 305, the lock tab 1530 and the lock arm base 1513 cooperate to maintain the lock mechanism arm 1510 in a substantially horizontal orientation and parallel to the floor below as the table 100 is moved between a semi-closed and open position. The stability lock mechanism 1501 is thus a safety feature of the table 100 since a user or operator is not required to manually line up the lock mechanism arm 1510 as the table 100 is being moved to a semi-closed position.
The lock tab 1530 normally contacts the end leg hinge tube 305 throughout much of its motion and prevents the lock arm from swinging below a horizontal orientation relative to the floor below. This aspect is a result of the orientation and position of the lock mechanism arm 1510 on the end leg hinge tube 305, via the lock yoke 1515. The lock tab 1530 loses contact with the end leg hinge tube 305 when the table is nearly opened. For example, the table position where the angle between the two table sections 5A and 5B is about one hundred sixty degrees (160°). At this point, as the table continues to travel to a fully opened position of about one hundred eighty degrees (180°), the backstop mounting base 1833 provides a mechanism to pivot the lock mechanism arm 1510 so as to maintain its horizontal orientation under the table 100. The backstop mounting base 1833 contacts an end of the lock arm base 1513 to properly pivot and position the lock mechanism arm 1510. In returning the table to a semi-closed position, the lock mechanism arm 1510 can thus be maintain in a horizontal orientation throughout the table's movement.
In the moving the table from a fully opened position, as shown in
As the table 100 is moved from the open position to closed position, gravity causes a downward motion of the lock mechanism arm 1510 about the lock arm pivot point 1517. As the lock mechanism arm 1510 pivots, the lock tab 1530 will enter a backstop hold space or area 1840 in the lock backstop 1535 between the backstop arm 1835 and mounting backstop base 1833. The lock tab 1530 will enter the backstop hold area 1840 when the angle between the two table sections 5A and 5B is about one hundred sixty degrees (160°). The lock tab 1530 will remain in the backstop hold area 1840 as the table 100 continues toward its semi-closed position 1500. If a user or operator attempts to swing the lock mechanism arm 1510 up and out of the way towards the table, to thereby reach a fully closed shipping position, the lock tab 1530 will come into contact with the backstop arm 1835. This creates a physical obstruction such that the backstop arm prevents the lock mechanism arm 1510 from being swung out of the way during folding. Otherwise, a user might inadvertently swing the lock mechanism arm 1510 out of the way and set the table in the unstable shipping position 400, potentially causing injury if the table where to fall.
The stability lock mechanism 1501 also provides a way for a user or operator to intentionally bypass the stability lock mechanism 1501 so that the table 100 can be folded from an open position, past the semi-closed position 1500, shown in
The invention has been described and illustrated with respect to certain preferred embodiments by way of example only. Those skilled in that art will readily recognize that the preferred embodiments may be altered or amended without departing from the true spirit and scope of the invention. Therefore, the invention is not limited to the specific details, representative devices, and illustrated examples in this description. The present invention is limited only by the following claims and equivalents.
The present application claims the benefit of U.S. provisional patent application No. 60/450,498, filed on Feb. 26, 2003 and titled “Mobile Folding Table Having a Lifting Assist Center Torsion Bar and Lift Off Casters”.
Number | Date | Country | |
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60450498 | Feb 2003 | US |
Number | Date | Country | |
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Parent | 10788217 | Feb 2004 | US |
Child | 11698365 | Jan 2007 | US |