The present specification generally relates to building panels for structure and, more specifically, prefabricated arcuate building panels to form a tubular building structure.
Most buildings utilize traditional construction techniques in the form of a foundation that is then built upon with frame members to construct walls that are then topped with a roof. Various additional materials are attached to these structures to form a cohesive unit fit for living. Generally, and traditionally, these materials are delivered to a worksite and assembled in place. Although this assembly technique has been useful, there exists a need to improve both the types of materials and this traditional construction technique, wherein the materials can be lessened or improved, and the construction time and process can be accelerated.
In one embodiment, a building panel is provided. The building panel includes an exterior wall portion, an interior wall portion, a pair of opposing sidewalls, a first end portion and an opposite second end portion. The pair of opposing sidewalls are connected to the exterior wall portion and the interior wall portion spacing apart the interior wall portion from the exterior wall portion to define a cavity therebetween. The exterior wall portion, the interior wall portion and the pair of opposing sidewalls are arcuate in shape to define the building panel. The first end portion has a slip lock slot extending between the pair of opposing sidewalls. The second end portion has a slip lock tab member extending between the pair of opposing sidewalls. The slip lock slot of the building panel is configured to receive the slip lock tab member of a second building panel to adjoin the first and second building panels in a continuous fashion.
In another embodiment, a building structure is provided. The building structure includes a plurality of building panels interlocked to form an annular segment. Each of the plurality of building panels includes an exterior wall portion, an interior wall portion, a pair of opposing sidewalls connected to the exterior wall portion and the interior wall portion, a first end portion, and an opposite second end portion. The pair of opposing sidewalls space apart the interior wall portion from the exterior wall portion to define a cavity therebetween. The exterior wall portion, the interior wall portion and the pair of opposing sidewalls are arcuate in shape to define each of the plurality of building panels. The first end portion has a slip lock slot extending between the pair of opposing sidewalls. The opposite second end portion has a slip lock tab member extending between the pair of opposing sidewalls. Each of the pair of opposing sidewalls has a recess portion with a plurality of receiving connectors positioned therein, and each of the pair of opposing sidewalls having a plurality of protrusions extending therefrom. The slip lock slot of one the plurality of building panels is configured to receive the slip lock tab member of another one of the plurality of building panels and such an arrangement continues with the remaining plurality of building panels to form the annular segment.
A building structure is provided. The building structure includes a first plurality of arcuate building panels interlocked to form a first annular segment and a second plurality of arcuate building panels forming a second annular segment. The first plurality of arcuate building panels include a first pair of opposing sidewalls, a first end portion having a first slip lock slot, an opposite second end portion having a first slip lock tab member, and each of the first pair of opposing sidewalls having a plurality of protrusions extending therefrom. The first slip lock slot of one the first plurality of arcuate building panels is configured to receive the first slip lock tab member of another one of the first plurality of arcuate building panels and such an arrangement continues with the remaining first plurality of arcuate building panels to form the first annular segment. The second plurality of arcuate building panels include a second pair of opposing sidewalls, a first end portion having a second slip lock slot, an opposite second end portion having a second slip lock tab member, and each of the second pair of opposing sidewalls having a recess portion with a plurality of receiving connectors positioned therein. The second plurality of arcuate building panels are interlocked by the second slip lock slot of one the second plurality of arcuate building panels receives the second slip lock tab member of another one of the second plurality of arcuate building panels and such a second arrangement continues with the remaining second plurality of arcuate building panels to form the second annular segment. An interconnection between the first annular segment and the second annular segment is formed when the plurality of protrusions are received within and between each of the plurality of receiving connectors within the recess portion to couple to the plurality of protrusions to the plurality of receiving connectors to form a tubular structure with a bore extending there through.
The embodiments set forth in the drawings are illustrative and exemplary in nature and not intended to limit the subject matter defined by the claims. The following detailed description of the illustrative embodiments can be understood when read in conjunction with the following drawings, where like structure is indicated with like reference numerals and in which:
Embodiments described herein are directed to improved building panels and method for use of assembling the building panels in constructing a cohesive tubular structure that forms a livable space. The building panels described herein are generally arcuate in shape and include a specific structure to enable the fitment and connection of a plurality of adjacent panels into the cohesive annular segment with a bore extending there through that defines the livable space. Each of the building panels incorporate structure, moisture barrier, air gap, interior finish support system, ventilation ductwork, and interconnection components into a singular form to form the livable structure. Further, the livable structure may be positioned within a portion of earth, positioned on an earth surface, or may be positioned above the earth surface.
Each of the building panels of the present disclosure are generally arcuate in shape having a predetermined continuous arc at a predetermined degree depending on a desired diameter of the livable structure. Further, each of the building panels is generally a corrugated hollow body that includes an exterior wall portion, an interior wall portion and a pair of opposing sidewalls that space apart the interior wall portion from the exterior wall portion to define a cavity therebetween. Each of the building panels have a first end portion have a slip lock slot extending between the pair of opposing sidewalls and an opposite second end that has a slip lock tab member extending between the pair of opposing sidewalls. Further, each of the building panels include a recess portion with a plurality of receiving connectors positioned on each sidewall and a plurality of protrusions extending from each sidewall.
To form the annular segment, the slip lock slot of one building panel is configured to receive the slip lock tab member of on adjacent building panel and so on. Additional building panels are used to form an infinite number of additional annular segments. The additional annular segment is affixed to couple to the annular segment together with the seams in an offset manner. In embodiments, the plurality of receiving connectors of the annular segment receive the plurality of protrusions of the adjacent additional annular segment and the plurality of receiving connectors of the adjacent additional annular segment receive the plurality of protrusions of the annular segment to affix or couple the segment to one another in both an end-to-end fashion and sidewall-to-sidewall (edge-to-edge) fashion forming the cohesive tubular shape with the bore that defines the interior space that may be finished with both traditional and non-traditional building materials to create an inviting living space.
As used herein, the term “longitudinal direction” refers to the forward-rearward direction of the building structure (i.e., in the +/−X-direction depicted in
Referring now to
The building structure 10 may be formed with a plurality of building panels 14 and include a specific structure to enable the fitment and connection of a plurality of adjacent panels into an annular segment 34a and a plurality of annular segments 34b are interconnected from edge-to-edge to form the cohesive tubular structure 16 with a bore 18 extending there through, as discussed in greater detail herein. A plurality of floor joists 20 are positioned along an inner portion 26 of the bore 18 to define a livable space 22 between the floor joists 20 and an apex 24 of the inner portion 26 of the livable space 22 of the tubular structure 16.
Further, as illustrated in
Now referring to
Referring now to
The exterior wall portion 38 of the building panel 36a is aligned with an exterior of the building structure 10 (
The interior wall portion 40 of the building panel 36a may be generally aligned with the inner portion 26 of the livable space 22 of the tubular structure 16. The interior wall portion 40 may generally be used for the attachment of finish materials to complete the structure. As such, the interior wall portion 40 is corrugated 41 to increase strength. The corrugation 41 of the interior wall portion 40 is less prominent than the corrugation 39 of the exterior wall portion 38 so as to enable the fastening of finish materials, as best illustrated in
To accommodate traditional building and framing conventions, each of the plurality of channels 56 may be spaced sixteen (16) inches on center. In some embodiments, each of the plurality of channels 56 has a shape, such as, but not limited to a keystone shape, so as to enable the coupling of the stick member 58 into the channel without the need for additional fasteners. Accordingly, the material selected for the building panel 36a has some resilience or flexion to allow for this coupling without fasteners.
The building panel 36a includes a first end portion 46 and an opposite second end portion 48. In some embodiments, the first end portion 46 may include angled portions 47 that are angled with respect to the other portions of the first end portion 46 and the second end portion 48 may include angled portions 49 that are angled with respect to the other portions of the second end portion 48. In some embodiments, the angled portions 47, 49 are positioned on the exterior wall portion 38. In other embodiments, the angled portions 47, 49 may be included on the interior wall portion 40 or a combination of the interior wall portion 40 and the exterior wall portion 38.
The cavity 44 extends a length of the building panel 36a and may be exposed at either the first end portion 46 and/or the second end portion 48 of the building panel 36a until an adjacent building panel, such as building panel 36b and/or 36f is coupled to the building panel 36a, as discussed in greater detail herein. In some embodiments, when the building structure 10 may be partially or fully covered by earth 12 (e.g., the building structure 10 of
Still referring to
For example, the slip lock slot 50 of the building panel 36a is configured to receive the slip lock tab member 54 of the building panel 36b, and so on, to create the annular segment 34a. In embodiments, the slip lock tab member 54 enters into the slip lock slot 50 from either the pair of openings 52a, 52b to slidably engage with the slip lock slot 50. As such, the annular segment 34a is formed by the building panels 36a-36f continuous connected from end-to-end. Further, the additional annular segments, such as the annular segment 34b, is formed by the building panels 36a′-36f′ continuous connected from end-to-end.
As such, embodiments disclosed herein enable the interconnection of adjacent panels within the annular segment 34a, additional annular segments, such as annular segment 34b, and so on, without the need for additional fasteners, but instead utilizes press-fit, interference fit, or friction fit connections to form the each of the annular segments 34a, 34b, and so on.
In some embodiments, the connection of the first end portion 46 and the second end portion 48 may include an additional channel or trough having a size to receive a gasket member. The gasket member may generally be a resilient material configured to prevent the infiltration of moisture to the interior space.
Each of the pair of opposing sidewalls 42a, 42b further include a recess portion 60 positioned adjacent to the second end portion 48. A plurality of receiving connectors 62 are positioned within the recess portion 60. In some embodiments, each of the plurality of receiving connectors 62 may be elliptical in shape. In other embodiments, each of the plurality of receiving connectors 62 may be other shapes such as circular, square, hexagonal, octagonal, rectangular, and/or the like. In some embodiments, each of the plurality of receiving connectors 62 may be uniformly spaced apart. In other embodiments, each of the plurality of receiving connectors 62 may be irregularly spaced apart.
Each of the pair of opposing sidewalls 42a, 42b further include a plurality of protrusions 64 extending from the respective sidewall of the pair of opposing sidewalls 42a, 42b. In some embodiments, each of the plurality of protrusions 64 may be circular in shape. In other embodiments, each of the plurality of protrusions 64 may be other shapes such as elliptical, square, hexagonal, octagonal, rectangular, and/or the like. In some embodiments, each of the plurality of protrusions 64 may be uniformly spaced apart. In other embodiments, each of the plurality of protrusions 64 may be irregularly spaced apart.
The spacing of the plurality of protrusions 64 corresponds to the spacing of the plurality of receiving connectors 62 such that plurality of protrusions 64 of the adjacent building panels of the annular segment 34b are received in the spacing between the plurality of receiving connectors 62 of the adjacent building panels of the annular segment 34a to affix or couple adjacent annular structures such as annular segment 34a to annular segments 34b and so on.
That is, the plurality of receiving connectors 62 and the plurality of protrusions 64 are generally configured to enable the joining of adjacent panels during assembly, wherein an adjacent building panel can be press-fit into place without the need for additional fasteners. As such, this configuration may allow the last building panel of an adjacent annular segment, such as angular segment 34b to be placed without bending the other adjacent building panels 36a-36f of the annular segment 34a while permitting for the structural integrity required.
Still Referring to
The junction 70 connecting or coupling the plurality of rigid members 66, 68 may be positioned within the cavity 44, as best illustrated in
The building panel 36a may utilize a variety of material thicknesses and corrugation depth (both the interior wall portion 40 and exterior wall portion 38) dependent upon the finished radius of the assembled tubular shape. Further, the building panel 36a may be formed from a variety of different materials including low density polyethylene (LDPE), Linear Low Density Polyethylene (LLDPE), Medium Density Polyethylene (MDPE), High Density Polyethylene (HDPE), cross-linked polyethylene (XLPE), polypropylene (PP), polycarbonate (PC), nylon, plastisols, combinations thereof, and/or the like.
Referring now to
At block 1005, the mold is mounted within a rotational molding machine also known as rotomolding, rotomold, and rotocasting. At block 1010, a material is added to the mold. The material may be liquid or powder. Example material may include, without limitation, LDPE, LLDPE, MDPE, HDPE, XLPE, PP, PC, and/or the like. The mold is rotated in three different dimensions, at block 1015. At block 1020, the mold is heated within an oven. At block 1025, the mold is cooled and, at block 1030, the mold is opened and the building panel is removed from the mold at block 1035. Such a process creates parts that are extremely durable. Further, it should be appreciated that to form the building panels, the molds are formed with certain angles and curved surfaces, such as the radiused corner portions 57, the angled portions 47, 49, and/or the like assist in the dimensional stability, durability and strength of the building panel as well as for removal from the mold.
Referring now to
At block 1105, a first building panel is positioned at a desired location. In some embodiments, the desired location may be positioned within or below an earth surface. In other embodiments, the desired location may be on the earth surface or above the earth surface such as on stilts. At block 1110, a second building panel is adjoined to the first building panel. The adjoining is from an end-to-end arrangement. That is, the slip lock tab member of the first building panel is received in a slip lock slot of the second building panel. It should be appreciated that the slip lock tab member of the first building panel is inserted into the slip lock slot of the second building panel through one of the openings in the lateral direction (i.e., +/−Y direction).
At block 1115, “N” building panels are adjoined in a continuous fashion to form a first annular segment. In some embodiments, “N” building panels are an additional four panels to form the first annular segment. In other embodiments, when the inner diameter of the living space is larger or smaller than that as illustrated, “N” building panels may be more or less than the six building panels as illustrated. As such, each annular segment is the plurality of building panels adjoined end-to-end.
In some embodiments, “N” building panels are an additional four panels to form the first annular segment. In other embodiments, when the inner diameter of the living space is larger or smaller than that as illustrated, “N” building panels may be more or less than the six building panels as illustrated. As such, each annular segment is the plurality of building panels adjoined end-to-end.
At block 1120, a new first building panel of a second and adjacent annular segment is positioned with the first end portion and the second end portion offset from the first end portion and the second end portion of the first building panel of the annular segment and connected to the first building panel of the annular segment by the plurality of protrusions received by the plurality of receiving connectors to affix the new first building panel of an adjacent annular segment to the first building panel of the annular segment.
At block 1125, a new second building panel of the second annular segment is adjoined to the first building panel of the second annular segment via the slip lock tab member of the first building panel is received in a slip lock slot of the second building panel and the new second building panel of the second annular segment is affixed to the a portion of the first and second building panels of the annular segment via the plurality of protrusions received by the plurality of receiving connectors. That is, the building panels of the second annular segment are offset or rotated with respect to the building panel of the annular ring so to distribute load and overlap seams.
At block 1130, “N” building panels are adjoined in a continuous fashion to form the second annular segment. At block 1135, a determination is made whether more livable space is desired. If no more livable space is desired, at block 1135, then the assembly process ends, at block 1140. If more livable space is desired, at block 1135, then art block 1145, “N” additional annular segments are required by repeating blocks 1120-1130.
As such, it should be understood that multiple building panels are adjoined edge-to-edge to form the annular segment with additional building panels utilized to form successive annular segments that are assembled end-to-end with each successive annular segment affixed or coupled to the previous annular segment via the plurality of protrusions received by the plurality of receiving connectors to form a continuous and cohesive tubular structure.
The final tubular structure has a circumference that is generally formed from the attachment of six building panels, as illustrated. However, this is non-limiting and more than or less than six panels with differing degrees of angle may be used. The tubular structure may be supported without the need for foundational elements and can easily be placed directly on the earth surface and/or covered with earth.
It should be appreciated that this arrangement may allow for an even distribution of weight and load across the building panels 36a-36f and further facilitates an assembly method that alters the position of adjacent building panels 36a′-36f′ relative to each other to strengthen the assembled structure. Accordingly, in assembly, building panels 36a′-36f′ are assembled in adjacency by overlapping the seamed connection to the building panels 36a-36f such that the seams between building panels are staggered relative to each other. Such an arrangement continues for “N” annular segments and “N” building panels.
It should now be understood that the embodiments described herein are directed to improve building panels used in constructing a cohesive tubular structure that forms a livable space. The building panels described herein are generally arcuate in shape and include a specific structure to enable the fitment and connection of a plurality of adjacent panels into the cohesive tubular structure with a bore extending there through that defines the livable space. Each of the building panels are generally a corrugated hollow body. To form the cohesive tubular structure, the slip lock slot of one building panel is configured to receive the slip lock tab member of an adjacent building panel and so on to form an annular segment. Additional building panels are used to form an infinite number of additional annular segments. Each additional annular segment is affixed or coupled to the annular segment together with the seams in an offset manner to define the tubular structure. As such, the building panels couple to one another in an end-to-end fashion and couple to adjacent panels in an edge-to-edge fashion.
It is noted that the terms “substantially” and “about” may be utilized herein to represent the inherent degree of uncertainty that may be attributed to any quantitative comparison, value, measurement, or other representation. These terms are also utilized herein to represent the degree by which a quantitative representation may vary from a stated reference without resulting in a change in the basic function of the subject matter at issue.
While particular embodiments have been illustrated and described herein, it should be understood that various other changes and modifications may be made without departing from the spirit and scope of the claimed subject matter. Moreover, although various aspects of the claimed subject matter have been described herein, such aspects need not be utilized in combination. It is therefore intended that the appended claims cover all such changes and modifications that are within the scope of the claimed subject matter.
The present application is a continuation application of co-pending U.S. patent application Ser. No. 17/842,011 filed on Jun. 16, 2022, entitled “Building Structure and Methods of Assembly”, which in turn claims priority to U.S. Provisional Patent Application Ser. No. 63/211,776 filed on Jun. 17, 2021, and entitled “Arcuate Building Panel and Method for Use,” the contents of both are incorporated herein in their entirety.
Number | Date | Country | |
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63211776 | Jun 2021 | US |
Number | Date | Country | |
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Parent | 17842011 | Jun 2022 | US |
Child | 18655702 | US |