This relates to the field of modular structures and, more particularly, to modular flooring platforms.
When people need to stay in remote locations for an extended period of time, they often need more than a lightweight camping tent for shelter, so they construct more robust shelters made of soft-sided tents that are often associated with remote bases for the military or humanitarian operations. Such soft-sided tents that have been in use for decades because they are durable and can be reused many times.
It is common to construct a wooden platform on which to erect the tent to elevate the tent from the ground and to provide a level floor. Unfortunately, when the base needs to move, these wooden platforms are difficult if not impossible to move and reuse at the next location. The wooden platforms also rot and often need repair, especially in hot and wet locations. Likewise, the wooden platform does not provide sufficient thermal insulation to the floor, making heating and cooling the tents energy inefficient.
What is needed is a modular platform that does not suffer from the drawbacks associated with wooden platforms and that can be constructed, deconstructed, transported, and reused repeatedly. Such a platform may be used as a base for tents or for hard-sided building structures, for example.
An example of such a modular floor platform comprises a floor made of a plurality of individual composite floor panels interconnected by tongue and groove joints. The individual composite floor panels have a foam core and a rigid cover over the foam core. A frame attaches the floor panels together along a perimeter of the floor. Legs are positioned beneath the frame and upwardly support the floor.
Another example of a modular floor platform comprises a plurality of individual composite floor panels. Each floor panel has (a) a foam core positioned between a planar upper surface and a planar lower surface of a rigid cover over the foam core and (b) a peripheral edge defining a tongue and groove joint member. The tongue and groove joint members of adjacent floor panels are mated together forming a flat floor. A frame attaches the floor panels together along a perimeter of the flat floor in such a way that the frame suspends the floor panels from an upper section of the frame. Legs beneath the frame upwardly support the floor.
A method of constructing a floor platform comprises arranging a plurality of legs on terrain in a pre-determined grid pattern; forming a floor upwardly supported on the legs by interconnecting tongue and groove joints of a plurality of individual composite floor panels and positioning respective tongue and groove joints against respective legs; and attaching the floor panels together along a perimeter of the floor with a frame.
The following optional features may be included in either of the floor platform examples and/or the method.
The individual composite floor panels may have a foam core and a rigid cover over the foam core and the rigid cover may include a planar upper surface and a planar lower surface opposite the planar upper surface. On at least some of the floor panels, the planar upper surface and planar lower surface extend beyond a peripheral edge of the foam core forming a groove of the tongue and groove joints between the planar upper surface and planar lower surface.
The individual composite floor panels may have a foam core and a rigid cover over the foam core and the rigid cover may include a planar upper surface and a planar lower surface opposite the planar upper surface. On at least some of the floor panels, the foam core extends beyond a peripheral edge of the planar upper surface and a peripheral edge of the planar lower surface forming a tongue of the tongue and groove joints.
The legs may upwardly support the floor by directly contacting the tongue and groove joints.
The floor may include at least one tongue and groove joint not directly contacting the frame and at least one of the legs may upwardly support the floor by directly contacting the at least one tongue and groove joint not directly contacting the frame.
The frame may include an upper section and the floor panels may be attached to the frame in such a way that the floor panels are suspended from the upper section.
Referring to
The floor platform 100 may be used as a flooring structure for a tent 10 as illustrated in
The floor platform 100 may also be used as a flooring structure for a hard-sided building 20 as illustrated in
Referring back to
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The composite structure may be lightweight and resistant to heat, water, rot, pests, and other common environmental problems, associated with degrading wood structures. The foam core may be made of a polymeric foam material such as expanded polystyrene, expanded polyurethane, phenolic foam, and/or extruded polystyrene for example. The rigid cover may be made of a rigid polymer sheet material such as, for example, fiberglass-reinforced phenolic resin, fiberglass-reinforced polyester, extruded polystyrene, extruded polyurethane, or the like. The rigid cover is bonded to the core with an adhesive. The selection of core materials and cover materials will depend on the intended use of the platform 100 and its desired properties.
The exterior edges of the floor panels 200 may be capped to cover the foam core 210 for substantially preventing water and/or pest intrusion and to enhance the strength of the edges. Suitable capping materials include, but are not limited to, metals such as steel, aluminum, stainless steel, and galvanized metals; and fiber-reinforced polymer materials.
The planar upper surface 206 and planar lower surface form a tongue joint member 212 and a groove joint member 214 on opposed sides of the panel 200a. To form the tongue joint member 212, a first peripheral edge 216 of the upper planar surface 206 and a first peripheral edge 218 of the lower planar surface 208 terminate over the foam core 210 such that the foam core 210 extends beyond these peripheral edges 216,218.
To form the groove joint member 214, a second peripheral edge 220 of the upper planar surface 206 and a second peripheral edge 222 of the lower planar surface 208 terminate beyond the foam core 210 such that these peripheral edges 220,222 extend beyond the foam core 210 forming a groove between the upper planar surface 206 and lower planar surface 208.
Referring to
Alternate examples of possible floor panel 200 configurations are in
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The floor panels 200 may be configured in many other ways than the three examples shown and described here, thus the scope of possible configurations is not limited to only the examples in the drawings.
Referring to
The anchors 302 may be attached and extend directly from the frame 300 or, as in the case shown, may form part of the threaded fastener 306, making the threaded fastener and eye bolt or the like.
The threaded fastener 306 extends through a hole 224 in the floor panel 200 such that the anchor 302 extends from the underside of the floor panel 200 and the mating threaded fastener 310 is positioned on the upper section 308 of the frame 300.
The attachment mechanism 304, regardless of its form, may in certain examples, be attached the frame 300 in such a way that the floor panels 200 are suspended from the upper section 308 of the frame 300.
Referring to
A threaded rod 408 extends from within the tubular member 404 as indicated by dashed line and upwardly above the threaded section 406, which is mated with the threaded rod 408. A height adjustment mechanism 410 attached to the threaded rod 408 functions as a handle-like feature for allowing a user to raise and lower the threaded rod 408 by screwing it up or down. Atop the threaded rod 408 is a horizontal platform 412 having a mounting block 414 attached thereto. A portion of the horizontal platform 412 extends beyond the peripheral edge of the floor panel 200 positioned on the mounting block 414. That portion includes a hook mechanism 416 thereon.
The leg 400a may be secured in place by burying at least a portion of the leg in the terrain T where the platform 100 is to be constructed.
Alternate examples of possible leg 400 configurations are shown in
In
The legs 400 may be made of any material suitable to support the weight of the platform and anything on the platform 100. Metals are suitable, especially corrosion resistant metals such as stainless steel, galvanized steel, or other galvanized metals, for example.
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The floor platform 100 is advantageously designed to be modular and portable so that it can be erected, taken apart, and shipped to different locations repeatedly. Accordingly, it is also designed to be relatively lightweight compared to conventional wooden platforms.
A method of constructing a floor platform is now described by referring to
Because it is known where the tongue and groove joints are located, it is possible to know where to position each leg 400 on the terrain T based on a pre-determined grid pattern associated with where the frame 300 and joints 204 will be. The grid pattern including measurement may be provided as written instructions for the user to follow.
Once the legs 400 are positioned in the proper locations on the terrain T, the height of each leg 400 may be adjusted so that the mounting blocks 414 are on the same level plane prior to installing the floor panels 200. Because the legs are independently height adjustable, the fact that the terrain might be uneven does not matter with respect to providing a level floor.
The floor panels 200 may be interconnected with the tongue and groove joints 204 and placed on the legs 400. The frame may be placed around the perimeter of the floor 202 formed by the floor panels 200 and attached to the periphery of the floor panels 200 bounding the perimeter of the floor 202.
The floor platform 100 has many uses, but it is particularly advantageous for use in connection with temporary shelters such as those used by military forces or by humanitarian operations. The platform is designed to replace conventional wooden platforms that rot and cannot be easily constructed, taken apart, transported, and re-constructed repeatedly.
This disclosure describes example aspects and embodiments, but not all possible aspects embodiments of the modular floor platform and associated methods. Where a particular feature is disclosed in the context of a particular aspect or embodiment, that feature can also be used, to the extent possible, in combination with and/or in the context of other aspects and embodiments. The platform and its associated methods may be embodied in many different forms and should not be construed as limited to only the embodiments described here.
This claims priority from U.S. provisional Application No. 62/330,924, filed May 3, 2016, which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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62330924 | May 2016 | US |