The present invention relates to modular platform systems, such as are used to provide crossover platforms and access platforms in workplace environments.
Platform systems are utilized in a variety of industrial and commercial facilities to provide access from one location to another. Generally speaking, such platform systems often fall into one of two categories: crossover platforms and access platforms. Crossover platforms function as bridges, providing a path over some obstruction, such as pipes or industrial machinery. Access platforms, on the other hand, typically allow a user to reach or access a desired area or object from another location.
Usually, platform systems are specially designed and constructed for a particular location and application. While this provides an acceptable platform for one situation, it is not adaptable or reconfigurable as the situation changes (or for another situation). To address this limitation, the art has provided modular platform systems which are configurable for use in a variety of different situations. These systems utilize a number of components, which can be selected and assembled according to the needs of a particular situation. In this way, a wide variety of different crossover and access platforms can be provided using different combinations and configurations of the available components. One such modular platform system is shown and described in U.S. Pub. No. 2013/0015016 (“the '016 publication”), filed on Jul. 16, 2011 and accorded U.S. application Ser. No. 13/184,499, which is incorporated herein by reference in its entirety for all purposes.
The present invention recognizes the foregoing considerations, and others, of the prior art.
In accordance with one aspect, the present invention provides a platform system comprising a platform structure having at least one modular platform unit with platform connection features on side surfaces thereof to which other components can be connected, the other components including at least two of another modular platform unit, a stair unit having a plurality of steps, a tower unit, a handrail unit, and a ladder unit. The platform system according to this aspect further includes a stair assembly connected to the platform structure via the platform connection features. The stair assembly comprises a plurality of stair units connected together to provide a number of steps equal to the sum of steps of the stair units. For example, the plurality of stair units may comprises at least three stair units each having no more than six steps.
According to some exemplary embodiments, the left and right stringers of each stair unit may comprise a side plate having upper and lower stair connection features for attachment of upper termination elements and base elements, respectively. Stair units of the stair assembly may be interconnected together at an interconnection location via web plates that are attached to the side plates using the stair connection features in lieu of upper termination elements and base elements at the interconnection location.
Handrail sections of the stair units may preferably be connected to form a continuous handrail along a length of the stair assembly. For example, the handrail sections of the stair units may be connected together using transition handrail sections. Internal couplings (e.g., comprising expansible coupling elements engaging an inner surface of the handrails for connecting the handrails together) may be used to connect the handrail sections together.
The platform system may further comprise a tower assembly connected to the platform structure via the platform connection features, the tower assembly comprising a plurality of tower units connected together to provide a total height corresponding to a height of the stair assembly. In such embodiments, the tower units may be interconnected using generally U-shaped brackets. Moreover, the handrail units and handrails of the stair assembly may be attached using a nut plate locking assembly inserted into a tubular end of a handrail support post.
According to another aspect, the present invention provides a stair assembly for use in a platform system. The stair assembly comprises a plurality of stair units each comprising a pair of left and right side plates having a plurality of spaced apart steps extending therebetween. The plurality of stair units are arranged such that left side plates of the plurality of stair units are axially aligned with each other and right side plates of the plurality of stair units are axially aligned with each other. Left side plates of adjacent stair units of the plurality of stair units are rigidly interconnected and right side plates of adjacent stair units of the plurality of stair units are rigidly interconnected.
For example, the adjacent left side plates and the adjacent right side plates may be in end-to-end abutment and interconnected via web plates. According to some preferred embodiments, the left side plates, the right side plates, and the web plates may be L-shaped. Furthermore, the left and right side plates of a lowermost stair unit may have respective removable base elements attached thereto. Likewise, the left and right side plates of an uppermost stair unit may have respective removable upper termination elements attached thereto.
A further aspect of the present invention provides a tower assembly for use in a platform system. The tower assembly comprises a plurality of tower units (e.g., two, three, or more) stacked one on top of the other, each of the tower units having an inverted generally U-shaped configuration with a top portion and pair of depending leg portions. Adjacent tower units are interconnected via a pair of removable side brackets.
According to some embodiments, each of the tower units comprises at least one cross-support extending between the depending leg portions. First and second removable base fittings may be attached to respective of the depending leg portions of a lowermost tower unit of the plurality of tower units. A separate top piece may be located above the top portion of an uppermost tower unit of the plurality of tower units. The top portion and the depending leg portions of the tower units may be formed of rectangular tubing.
A still further aspect of the present invention provides a method of assembling a stair assembly for use in a platform system. One step of the method involves obtaining a plurality of stair units each comprising a pair of left and right side plates having a plurality of spaced apart steps extending therebetween. The plurality of stair units are arranged such that left side plates of the plurality of stair units are axially aligned with each other and right side plates of the plurality of stair units are axially aligned with each other. Another step involves rigidly interconnecting the left side plates of adjacent stair units of the plurality of stair units and right side plates of adjacent stair units of the plurality of stair units using a plurality of web plates.
According to another aspect, the present invention provides a combination comprising a plate structure defining at least one fastener through-hole. A tubular member defining a fastener receipt hole is also included. A nut plate locking device having a nut plate and an associated spring plate is received in the tubular member, the spring plate carrying at least one spring urging it away from the nut plate. The nut plate has a threaded hole aligned with the fastener through-hole of the plate structure and the fastener receipt hole of the tubular member. A threaded fastener extends through the fastener through-hole of the plate structure and the fastener receipt hole of the tubular member into threaded engagement with the threaded hole of the nut plate such that the tubular member is connected to the plate structure.
A washer piece having a flat side and a curved side may be situated between the plate structure and the tubular member. Moreover, the nut plate locking device may have a flange located at one end thereof to limit insertion into the tubular member. According to some embodiments, the threaded hole may be defined by a nut attached to the nut plate.
Other objects, features and aspects of the present invention are provided by various combinations and subcombinations of the disclosed elements, as well as methods of practicing same, which are discussed in greater detail below.
A full and enabling disclosure of the present invention, including the best mode thereof, to one of ordinary skill in the art, is set forth more particularly in the remainder of the specification, including reference to the accompanying drawings, in which:
Repeat use of reference characters in the present specification and drawings is intended to represent same or analogous features or elements of the invention.
It is to be understood by one of ordinary skill in the art that the present discussion is a description of exemplary embodiments only, and is not intended as limiting the broader aspects of the present invention, which broader aspects are embodied in the exemplary constructions.
In this example, each of stairway 12, platform 14, and tower 16 is formed of a plurality of smaller units that are preferably assembled on-site. For example, stairway 12 has fifteen stairs (“steps”) along its rise, and may be formed of three 5-step units (or a 6-step unit, a 5-step unit, and a 4-step unit, etc.). Similarly, the tower 16 may be formed of multiple tower units assembled on site to achieve the desired height. Different heights of tower units may be sold so that the tower heights correspond to the different heights of stairways (or ladders) that can be formed using components of the system. As can be seen, platform 14 is formed in this example of three platform units 100 connected to form a longer rectangular platform. One skilled in the art will recognize, however, that more or fewer platform units 100 can be provided, and they can be connected to form various shapes of platforms, such as rectangular platforms, L-shaped platforms, T-shaped platforms, etc. In a preferred embodiment, platform units 100 may be identical to the modular platforms in the '016 publication, having standard connection features (e.g., a pattern of holes for fasteners) on all four sides thereof.
Because the stairs, towers, and ladders can be made to a desired height by combining a relatively small number of different units, a wide variety of platform heights can be achieved. In fact, a greater number of different platform heights can be achieved using a smaller number of dedicated component sizes than would otherwise be the case. For example, assuming the largest stair size available in a prior art platform system is an 11-step unit, it would not be possible to have a rise higher than eleven steps without an intervening landing. According to the present invention, a stair assembly of, for example, fifteen steps may be made by combining multiple units, such as three 5-step units. Thus, for example, the longest individual stair unit may be a 6-step unit, but longer stairways (i.e., greater heights) can still be achieved in comparison with the prior art by various combinations of the stair units (the same is true for the tower units and ladder units.) As a result, the manufacturer (or distributor) may stock a fewer number of different unit sizes while offering more platform system heights and combinations. This allows a reduction in inventory for the manufacturer and greater flexibility to the user. In addition, it is often cheaper to ship several smaller units than one larger unit, resulting in a reduction in shipping costs as well.
Referring now to
For example, the bottom of stair unit 200 in this case has a pair of base elements 208a and 208b attached to the respective side plate. As shown, base elements 208a and 208b define a flat bottom for resting against a support surface such as a floor. The top of stair unit 200 in this case has a pair of upper termination elements 210a and 210b also attached to the respective side plates. Base elements 208a-b and upper termination elements 210a-b may be formed in any suitable manner, such as casting. A pair of gussets 212a and 212b may be attached to the respective upper termination elements 210a-b for connection to the underside of a modular platform 100 (similar to the gussets described in the '016 publication). Cross supports (such as cross support 213) may extend between the stringers under the steps to provide additional structural integrity.
Stair unit 200 further has a pair of sloped handrails 214a and 214b also attached to the stringers 204a and 204b. Each of the handrails is preferably formed of three separable sections, namely lower section 216, middle section 218, and upper section 220. For example, lower section 216 can be removed (along with base elements 208a and 208b), leaving at least middle section 218 in place, if another stair unit is to be located below this stair unit. Similarly, upper section 220 can be removed (along with upper termination elements 210a and 210b), leaving at least middle section 218 in place, if another stair unit is to be located above this stair unit. The sections of handrails 214a and 214b may be connected together using suitable internal couplings, such as those described below. Otherwise, the overall configuration and external appearance of handrails 214a and 214b is intended to resemble the handrails shown in the '016 publication.
In this regard,
Turning now to
Referring now to
In order to connect handrails of different stair units together, internal coupling 228 is first positioned in the open end of one tubular handrail with set screw 238 in place. The tubular handrail of the other stair unit is abutted with the tubular handrail having coupling 228. Set screw 238 is then tightened so that coupling elements 230a-b expand into firm engagement with the inner surfaces of both tubular handrails. Preferably, hole 234 will be located on the underside of the tubular handrail so it will not normally be seen. One skilled in the art will appreciate that a similar coupling arrangement will preferably be used in every set of tubular handrails that will abut in the overall stair assembly.
Referring now to
As can be seen most clearly in
As shown, a spring plate 250, typically formed of a suitable polymeric material such as nylon, is loosely coupled to the back of nut plate 246. In this regard, spring plate 250 includes a pair of projections 252a-b removably received in corresponding upper and lower slots defined in nut plate 246. Flexible arms 254a-b slightly urge nut plate 246 away from spring plate 250. This allows relative movement between nut plate 246 and spring plate 250 to facilitate insertion of nut plate assembly 244. Also, the spring action of arms 254a-b tends to hold nut plate assembly 244 in the correct position until tightening can occur. Spring plate 250 preferably includes a flange 256 at its bottom end that limits insertion of nut plate assembly 244 such that the nuts 248a-b will aligned with corresponding holes in the support post.
Support post 242 is then attached to stringer 204 using bolts 258a-b that extend through holes in the stringer into threaded engagement with respective nuts 248a-b. As bolts 258a-b are tightened, nut plate 246 is drawn into secure engagement with the inner surface of post 242 to eliminate looseness in the handrail. In this embodiment, post 242 has a circular cross-section all the way to its bottom end. Thus, a handrail washer 260 with a flat side and a curved side is preferably positioned between stringer 204 and post 242, as shown. In other embodiments, the bottom of support post 242 can be formed into a “D” shape, thus eliminating the need for handrail washer 260. One skilled in the art will appreciate, however, that forming such a D-shaped portion of support post 242 involves additional processing steps that are avoided if washer 260 is used. Also, while nut plate assembly 244 has been described in relation to attachment of a support post of a stair handrail, one skilled in the art will appreciate that it can also be used to attach handrail units 400 to modular platform units 100.
Referring now to
Similar to stair unit 200, tower unit 300 includes removable components that may or may not be used, or are used differently, depending on the situation. In this regard, a pair of removable base fittings 306a-b are provided at the bottom of the respective legs of tower component 302. For example, base fittings 306a-b may be attached using a pair of vertically aligned attachment holes extending through the legs of tower component 302. If this particular tower unit 300 is not the lowest tower unit in a taller tower assembly, these same holes are used to connect it to another tower unit below.
Removable side brackets 308a-b and top piece 310 are also provided. Side brackets 308a-b, which are generally U-shaped as shown, are shiftable to allow interconnection to another tower unit above. Top piece 310 is used at the top tower unit of the overall tower assembly (or at the top of tower unit 300 if it is used alone). In this example, top piece 310 is formed of rectangular tubing, and sits atop the upper beam of main tower component 302. Top piece 310 is held in place by fasteners (e.g., bolts) extending through aligned holes defined in it and brackets 308.
Referring now to
In
A ladder unit 500 is illustrated in
It can thus be seen that the present invention provides a modular platform system that is easily adaptable into a wide variety of configurations. One skilled in the art would be able to determine the most appropriate materials from which to form the various components described above in order to meet anticipated strength and rigidity requirements. In many cases, however, the various structural components may be formed of steel or another suitable metal.
While preferred embodiments of the invention have been shown and described, modifications and variations may be made thereto by those of ordinary skill in the art without departing from the spirit and scope of the present invention. In addition, it should be understood that aspects of the various embodiments may be interchanged both in whole or in part to yield still further embodiments. Furthermore, those of ordinary skill in the art will appreciate that the foregoing description is by way of example only, and is not intended to be limitative of the invention as further described in the appended claims.
This application is a divisional of copending U.S. application Ser. No. 15/466,465, filed Mar. 22, 2017, which is based upon and claims the benefit of U.S. provisional application Ser. No. 62/312,260, filed Mar. 23, 2016. Each of the foregoing applications are incorporated fully herein by reference in their entirety for all purposes.
Number | Date | Country | |
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62312260 | Mar 2016 | US |
Number | Date | Country | |
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Parent | 15466465 | Mar 2017 | US |
Child | 16830579 | US |