OUTDOOR STRUCTURE AND METHODS

Abstract

An outdoor structure includes a plurality of vertically extending walls joined together to form a standing structure surrounding an interior volume. Each of the walls includes a structural polymer panel and a veneer directly adhered to the structural polymer panel. The standing structure can be frameless and supportless. The standing structure can bear at least 90% of a load of the standing structure.

Claims

1. A frameless structure comprising: at least three vertically extending walls joined together to form a standing structure surrounding an interior volume and adapted to bear a compressive load comprising the weight of other components supported by the standing structure; the standing structure being free of a supporting frame; each of the walls comprising a panel of polymeric foam, each having a thickness of at least 1 inch; each of the walls further including a plurality of veneer members substantially covering a major surface of the foam panel and adhered to the foam panel with structural adhesive; the structural adhesive being (i) between the foam panel and each of the veneer members; and (ii) between adjacent veneer members.

2. The structure of claim 1 wherein: (a) the standing structure defines an opening in communication with the interior volume; and (b) the structure further includes a frame and door assembly held in the opening.

3. The structure of claim 1 wherein the thickness of the foam panel and veneer together is not greater than 6 inches.

4. The structure of claim 1 further including a base horizontally supporting the standing structure, the base comprising at least one foam panel with a thickness of 1-6 inches.

5. The structure of claim 1 wherein each foam panel comprises graphite polystyrene.

6. A kit for an outdoor structure, the kit comprising: (a) at least three panels of polymeric foam; each panel having a thickness of at least 1 inch, opposite top and bottom edges, and opposite side edges and adapted to assemble into a frameless standing structure; (b) a plurality of veneer members; (c) structural adhesive adapted to adhere the veneer members onto the foam panels (i) between each foam panel and each of the veneer members; and (ii) between adjacent veneer members; and (d) wherein the kit is free of a supporting frame.

7. The kit of claim 6 wherein the edges of each of the foam panels can be fitted together to form the frameless standing structure.

8. The kit of claim 7 wherein the edges of the foam panels include a plurality of projections alternating with recesses, such that the panels can be fitted together by projections from a first panel being received in recesses of a second panel.

9. The kit of claim 6 wherein each panel comprises graphite polystyrene.

10. The kit of claim 6 wherein the veneer members simulate an appearance of stone or brick.

11. The kit of claim 6 wherein each panel has a uniform thickness not greater than 6 inches.

12. The kit of claim 6 wherein each panel has a uniform thickness not greater than 2 inches.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] The accompanying drawings, which are incorporated herein, constitute a part of the description and illustrate several aspects of the present disclosure. In the drawings:

[0018] FIG. 1 is a perspective view of outdoor structures, utilizing structural polymer panels and veneer, constructed in accordance with the principles of this disclosure;

[0019] FIG. 2 is a perspective of the structural polymer panels of FIG. 1 being assembled, and before the veneer has been attached;

[0020] FIG. 3 is a perspective view of a portion of FIG. 1 depicting the step of attaching veneer to the structural polymer panels; and

[0021] FIG. 4 illustrates a kit of structural polymer panels that can be used to assemble the outdoor structure of FIG. 1.

DETAILED DESCRIPTION

[0022] FIG. 1 illustrates a structure 10, which can be constructed using the materials and methods described herein. The structure 10, in this example, is an outdoor structure, specifically, an outdoor kitchen 12. The structure 10 can be an indoor structure, as well.

[0023] The outdoor kitchen 12, in this example, includes a plurality of vertically extending walls 14 joined together to form a plurality of standing structures 16 surrounding an interior volume 18 (FIG. 2). In this example, the outdoor kitchen 12 includes a grill assembly 20 mounted on top of a standing structure 16 and at least partially inside of the interior volume 18. A sink 22 is mounted on top of a standing structure 16 and at least partially inside of the interior volume 18. A countertop is 24 mounted on top of a standing structure 16. The counter top 24 can be granite, quartz, marble, or any type of commercially available countertop.

[0024] Still in reference to FIG. 1, the outdoor kitchen 12 can also include a smoker 26 supported by a standing structure 16, and it may include a frame and door assembly 28 held within an opening 30 (FIG. 2) in the standing structure 16 in communication with the interior volume 18. Many embodiments of the outdoor structure 10 are possible, and the example shown in FIG. 1 is just one of many possible embodiments. The standing structure 16 can support internal frames 56 (FIG. 3), which can be used for the door assembly 28 and/or windows.

[0025] Referring now to FIG. 2, each of the walls 14 includes a structural polymer panel 32. The panel 32 can include any structure that is stable, durable, breathable, adaptable to all climate zones, and resource efficient. For example, usable material for the structural polymer panel 32 can include cast or extruded polyisocyanurate (rigid urethane) or extruded polystyrene, polyethylene or polypropylene foam; particle foams including expanded polystyrene EPS, expanded polypropylene EPP, and expanded polyethylene EPE; or any extrudable, moldable or castable polymer or polymer foam.

[0026] One preferred example material for the polymer panel 32 is structural foam including, for example, graphite polystyrene. Graphite polystyrene is adaptable in size, thickness, shape, and density. It comes in a variety of thicknesses. It is versatile, in that it can be shaped or formed to the design needed. For example, the structural polymer panel 32 can be designed on a computerized design package and then cut to an exact form using CNC tooling. Graphite polystyrene is breathable and semipermeable, which is helpful in moisture management. It is adaptable to all climate zones, meaning that it can be used outdoors through both hot summers and cold winters. One preferred graphite polystyrene is available under the tradename NEOPOR from BASF Corporation.

[0027] The structural polymer panel 32 utilized for outdoor structures 10 can be made with a thickness that is appropriate for the outdoor structure 10. The greater the thickness is, the greater the compressive strength and the less likelihood of structural failure through crushing or buckling. The thinner the foam panel 32 is, the easier it is to handle and the less expensive it is. It has been found that for use in an outdoor kitchen to support things such as grill assemblies 20, sinks 22, granite countertops 24, smokers 26, etc., the structural polymer panel 32 should have a thickness of at least 1 inch. It has been found that the structural polymer panel 32, to work well in the outdoor kitchen 12, need not have a thickness any greater than 6 inches.

[0028] Each of the walls 14 includes veneer members 34 directly adhered to the structural polymer panel 32. The veneer members 34 can have an aesthetically pleasing appearance, to simulate the look of stone or brick. The veneer members 34 may be selected to complement the appearance of an adjacent house. By the term directly adhered it is meant that there is nothing in between the veneer members 34 and the structural polymer panel 32 other than structural adhesive that is used to attach the veneer members 34 to the structural polymer panel 32. One preferred embodiment of the veneer members 34 is a lightweight concrete veneer, but any type of veneer is usable.

[0029] Each of the veneer members 34 has a decorative front 80, an opposite back surface, and an outer periphery 82 (surrounding edges). Typical, usable veneer members 34 will have a thickness between the front 80 and back surface of not more than 4 inches, often 0.5-2 inches.

[0030] The structural adhesive is applied between the structural polymer panel 32 and each of the veneer members 34, along a vertical plane on the back surface, where the veneer members 34 are placed against the panel 32. The structural adhesive is also applied between all of the peripheral edges 82 of adjacent veneer members. This results in a composite panel 36, comprising the structural polymer panel 32, structural adhesive, and veneer members 34. In some embodiments, the composite panel 36 consists of or consists essentially of the structural polymer panel 32, structural adhesive, and veneer members 34.

[0031] Many different types of structural adhesives, or their equivalent, may be used. One type is polyurethane, for example, an aerosol dispensed, single part, moisture cured polyurethane adhesive. One structural adhesive useable herein is commercially available from Tremco under the name ILLBRUCK masonry adhesive for brick and stone. The ILLBRUCK adhesive is PU700 rapid curing gun grade polyurethane foam adhesive and includes the following properties: polyurethane foam; fire class B3 using a test method DIN 4102; limits canister temperature of +10 C. to +30 C.; limits of ambient temperature of +5 C. to +35 C.; density of 20-30 kg/m3; open time of 8 minutes using a test method of 3 cm in width at 23 C. and 50% RH; tack free time of 8 minutes using a test method of 3 cm in width at 23 C. and 50% RH; cutting time of 24 hours using a test method of 3 cm in width at 23 C. and 50% RH; loading time of 24 hours; tensile strength of 10,000 kPa using a test method of DIN 53455; thermal conductivity of 40 mW/m.Math.K; temperature resistance short term of 40 C. to +130 C.; temperature resistance long term of 40 C. to +90 C.; storage in shaded dry conditions between +10 C. and +25 C. with canisters upright; and a shelf life of 12 months when stored in original unopened containers. The structural adhesive, or its equivalent, has rapid curing (joint can be handled within 10 minutes and cure fully within 24 hours); is easy to use with no mixing, no water, no dust, and no specialized tools or equipment necessary; and has long term resistance to seawater, limewater, dilute acids and caustic solutions.

[0032] The thickness of the composite panel 36, being the structural polymer panel 32 plus the veneer member 34 and adhesive, will not be greater than about 6 inches, in order to have both sufficient strength, but without excessive weight or cost. Often, the thickness of the composite panel 36 will be 3-6 inches thick.

[0033] The composite panel 36, formed of the structural polymer panel 32, veneer members 34 and adhesive for each of the walls 14 of the standing structure 16 is load bearing. By load bearing, this means that other structure, typically used to bear the load in like structures, is not needed. For example, standing structure 16 is free of internal frames (is frameless) and free of any other supports (is supportless). In particular, the composite panel 36 would bear at least 90%, for example, at least 95%, and preferably 98%-100% of a load of the standing structure 16. This leads to advantage, in the simplicity of the construction of the standing structure 16, the overall weight, and the inexpensiveness. In many examples, the standing structure 16 has walls 14 with load bearing capability that consist of or consist essentially of the composite panel 36.

[0034] In reference now to FIG. 4, a kit is shown at 40. The kit 40 includes at least one of the structural polymer panels 32, which can be used to make the standing structure 16. The at least one foam panel 32 can be cut into a plurality of the panels 32, such as four panels 32. Alternatively, the kit 40 can include a pre-cut plurality of the foam panels 32. The kit 40 will often also include a plurality of the veneer members 34 and the structural adhesive. In FIG. 4, it can be seen how the foam panels 32 can be cut to specific unique shapes for whatever is the final structure 10 to be made.

[0035] The structural polymer panels 32, as shown in FIG. 4, are often precut for building the desired structure, such as outdoor kitchen 12. The structural polymer panels 32 can include a plurality of projections 42 alternating with recesses 44, such that the panels 32 can be easily mated together with the projections 42 from one panel 32 being received into recesses 44 of another panel 32 to form the standing structure 16. The panels 32 have opposite top and bottom edges 46, 48 and opposite side edges 50, 51. The projections 42 and recesses 44, in this embodiment, are formed along the side edges 50, 51.

[0036] The structural polymer panels 32 can be fitted together along the side edges 50, 51 and stood along the bottom edges 48 to form a frameless standing structure 16 surrounding the interior volume 18. Adhesive can be used between the side edges 50, 51 to secure the panels 32 together to form the standing structure 16.

[0037] The outdoor structure 10 may include a base 60 (FIGS. 2 and 4) horizontally supporting the standing structure 16. The base 60 can include at least one structural polymer panel 32 with a thickness of 1-6 inches.

[0038] After the structural polymer panels 32 are fitted together to form the vertically extending walls 14 and the standing structure 16, the face 54 (FIGS. 2 and 3) of the panel 32 can receive the structural adhesive. In some instances, the structural adhesive can substantially cover the panel face 54. The veneer members 34 can then be applied to the panel face 54 against the structural adhesive. The structural adhesive is also applied between the edges of adjacent veneer members. The structural adhesive will adhere or bond the veneer members 34 to the panel face 54, as well as bond adjacent veneer members 34 to each other. FIG. 3 illustrates the step of applying the veneer members 34 to the panel face 54 of the structural polymer panels 32.

[0039] In one example, the resulting outdoor structure 10, which includes the standing structure 16, plus the grill assembly 20, plus the granite countertop 24, plus the steel frame and door assembly 28 weighed about 1,100 lbs. A prior art structure including the same grill assembly, countertop, and door, using concrete blocks adhered together instead of the composite panels 36, weighed about 3,500 lbs.

[0040] The panels 32 can be provided in the kit form 40, or they can be pre-assembled. The panels 32 can be made on the fly with a CNC tool, and they do not need to be molded.

[0041] When making outdoor structures 10, the panels 32 can have a thickness of 1-6 inches. Many types of structures can be constructed using composite panels 36 including, for example, columns, fountains, retaining walls, seawalls, tool sheds, animal shelters, etc. When the panels 32 are used for retaining walls or seawalls, the panels 32 will have a thickness of 6-12 inches.

EXPERIMENTAL

[0042] A test column was assembled using Neopor graphite Expanded Polystyrene EPD panels with a foam thickness of 2 inches; foam density of 2.0 lbs./CF; and outside dimensions of: 26.37536 (without veneering) with a 222.37522.375 matching Neopor square panel glued in place to the inside walls and at the bottom of the test box. The weight testing includes an OSB panel with attached 24 cross members that was placed on top of the assembled test boxes to accommodate the test load pallet placement. Testing weight increments: (10) 4812 units.

[0043] Test 1: Structural Polymer Panel Alone

[0044] The test column had a 3681 lbs. load (which included 61 lbs. platform and 50 lbs. pallet weight) placed on it, and it remained fully intact with no signs of cracking, breaking or damage. Under the 3681 lbs. load, the box compressed . At 3381 lbs., the compression was not measurable. The test column was calculated to have failed at 17.4 psi (compressive strength).

[0045] Test 2: Structural Polymer Panel and Veneer with Adhesive Only Along the Back Surface of the Veneer

[0046] The text column as described above was used. Adhesive used with the veneer was Oldcastle Structure Bond adhesive (aerosol Urethane). This adhesive is available commercially under the brand name Illbruck PU700, as described above. The test column had concrete veneer (1.5 inches thick) glued to it with the structural adhesive. The structural adhesive was not applied between edges of adjacent veneer members.

[0047] With a 6502 lbs. load (which includes 61 lbs. platform, a 51 lbs. pallet and 50 lbs. pallet weight), the column remained fully intact, but revealed some vertically cracked units on all 4 sides, which was deemed to have failed. At the 6212 lbs. loading vertical cracks were not visible. The test column was calculated to have failed at 21.2 psi (compressive strength).

[0048] Test 3: Structural Polymer Panel and Veneer with Adhesive Along the Back Surface of the Veneer and Between Edges of Adjacent Veneer Members

[0049] The test column as described above was used. Adhesive used with the veneer was Oldcastle Structure Bond adhesive (aerosol Urethane). The test column had concrete veneer (1.5 inches thick) glued to it with the structural adhesive. The structural adhesive was also applied along between the edges of adjacent veneer members.

[0050] With 10,666 lbs. load (which includes a 61 lbs. platform, a 51 lbs. pallet and two 51 lbs. pallets weight) the column remained fully intact with no cracking, breaking or damage of any kind. For safety reasons, the testing was terminated due to height concerns. The test column was calculated to have at least a 34.8 psi (compressive strength).

CONCLUSION

[0051] Using structural panels of polymer with veneer attached to the structural panels of polymer and attached along adjacent veneer edges with structural adhesive results in a structure that is at least 3 times as strong when using only structural panels of polymer, and more than 1.5 times as strong when only applying the adhesive between the foam and the veneer. Using structural polymer panels with veneer attached to the foam and attached along adjacent veneer edges with structural adhesive results in a structure that has a compressive strength of greater than 21.2 psi; indeed, greater than 25 psi, 30 psi, and 34 psi. The upper limit was not determined, as testing had to be stopped for safety reasons.