FIELD OF THE INVENTION
The present invention relates to the assembly of temporary or permanent structures (borders, enclosures, decking, walkways, platforms, sheds, cabins, etc.), indoors or outdoors, and more particularly, to assembling temporary or permanent indoor or outdoor structures (borders, enclosures, decking, walkways, platforms, sheds, cabins, etc.) without requiring the use of any tools other than human hands for assembly.
BACKGROUND OF THE INVENTION
The building of structures for recreational or utility purposes (decks, walkways, platforms, etc.) traditionally requires the person building the structure to have at least moderate carpentry and construction skills. In addition, tools and materials such as hammers, nails, screws and screwdrivers, saws, etc., are required. Depending on the size and scale of the project, it also can be necessary to dig holes or trenches for a foundation, mix and pour cement for that foundation (or buy cement pre-mixed, and pay delivery charges), then, upon completion of the task, remove the resultant spoils and unused (wasted) construction materials. All of these require significant physical effort, are time-consuming, and of significant expense. Adding railing/fencing to the structure, or wall-height partitions for privacy and/or security, adds to the effort, complexity, and expense.
A need exists for a product that allows a person with no building or construction experience to complete such types of projects with minimal effort and no special skills, while reducing or eliminating unnecessary expense, effort and waste.
At least one previous attempt to achieve some of the benefits of a modular approach is disclosed in U.S. Pat. No. 6,209,267 to Dantzer, described as a modular decking system for use in constructing a square or rectangular deck of the type normally attached to a house or other dwelling. It makes use of mostly precut or possibly preassembled components such as rectangular base frames and floor panels, in conjunction with certain commercial off-the-shelf building/construction components, such as nails, metal connecting brackets, screws, bolts, etc., to connect the deck components into a square or rectangular shape, and connect the overall deck to a house or other building. Railings are installed via shaped wooden posts attached by bolts, screws, or nails, at outside edge frame junctions and corners. These posts have vertical slots for the installation of railing panels, and holes bored vertically into the top, to accept finishing caps bolted into these vertical bored holes. The railing panels slide vertically down into the vertical slots in the posts. The outside periphery of the floor surface is finished by attaching finished lumber boards. The Dantzer patent also describes a foundation system that utilizes posts resting on concrete foundation blocks, or, alternatively, foundation components that are mounted either in a commercially available bracket-and-spike combination driven into the ground, or in a bracket and anchor combination which is set in concrete.
Unfortunately, the Decking System of Dantzer still makes use of nails, screws, bolts, etc., for connecting the components. In addition, not all components are precut or preassembled, which means that some cutting of components and/or materials would be necessary. All this would require the use of tools and materials such as hammers, nails, screws, screwdrivers, saws, nuts and bolts, etc.
In addition, the components of the Decking System of Dantzer are oriented to square or rectangular decks, rather than irregular or custom shapes, including open areas inside the outer periphery of the overall floored area.
Also, the Dantzer design allows only for the installation of fence-height railings, while the present invention enables a second, higher level of panels to be installed, allowing for the creation of true privacy walls. The Dantzer design does not allow the installation of railings or partitions anywhere except at the edge of the deck, therefore there is no provision for partitioning the surface space or spaces inside the periphery of the deck. The present invention allows the installation of posts at any junction of Floor Panels or corner of a single Floor Panel, and these posts, in conjunction with Post Brackets, make it possible to install fence or wall-height panels at variable locations, thereby allowing interior space or spaces to be partitioned into separate areas.
The Dantzer system also makes no provision for roofing an assembled structure, either partially or completely.
Another disadvantage of the Dantzer system is that removal or disassembly of the Dantzer design would be difficult, if not impossible, without damaging or destroying at least some of the components or materials. An additional removal disadvantage is that if the foundation had been installed into concrete, heavy tools and effort would be required to break up the concrete to completely remove the structure. The present invention does not make any use of concrete footings or foundations, and can be removed using the same means, and virtually the same effort, as that used to assemble it, with minimal cosmetic repair work to the site necessary after removal.
It is therefore an object of the invention to eliminate any necessity for tools of any kind, other than human hands, to assemble the structural components comprising this invention.
It is another object of the invention to reduce, if not eliminate, any necessity for foundation excavation or construction.
It is another object of the invention to allow either indoor or outdoor assembly of structures using the same set of components.
It is another object of the invention to eliminate wastage of building materials, by allowing precise pre-planning of component requirements.
It is another object of the invention to allow the partitioning of the interior space of a structure into separated areas.
It is another object of the invention to allow the disassembly and removal of any structure previously assembled from the components of this invention, by the same means used to accomplish the original assembly.
It is another object of the invention to allow an assembled structure to be fully or partially enclosed, partitioned, and/or roofed, regardless of structure configuration or floor plan.
It is another object of this invention to allow flexibility in the final configuration of any structure produced by using the components comprising this invention, including the ability to partially or completely surround physical objects, areas, or features in, or planned for, the installation area.
SUMMARY OF THE INVENTION
In accordance with the present invention, there is provided a system of prefabricated modular components, designed to fit and connect together using no tools other than human hands.
Primary components are Floor Panel Frames, shaped and configured to accept Floor Panels that provide a flat walking and/or supporting surface. The Floor Panel Frames are assembled in an interlocking manner by Floor Panel Frame Connectors. These Floor Panel Frame Connectors, in a variety of configurations, provide a supporting/connecting base for the Floor Panel Frames, and have radially-distributed vertically-extending columns that fit into identically-shaped receiving holes at each bottom corner of the Floor Panel Frames, thus connecting each Floor Panel Frame to any adjacent Floor Panel Frame or Frames.
Floor Panels may have solid surfaces, or slotted/ventilated surfaces, depending on the desired use for which the structure, or portion of a structure, is assembled. Floor Panels are assembled to Floor Panel Frames, and secured to the Floor Panel Frame with Floor Panel Latch components.
The Post configuration of the Floor Panel Frame Connector allows for the installation of Posts at any junction of Floor Panel Frames, or at any corner of an individual Floor Panel Frame. These Posts, in conjunction with Post Brackets, allow for the installation of Partition Panels in single or double-height levels, for the creation of either railings or partition walls. Posts are half-height or full-height, depending on the intended height to which Partition Panels will be installed.
When installed in an indoor location, or a temporary outdoor location on a paved or otherwise flat, solid surface, no foundation anchoring is required. When permanently installed in an outdoor location, an Anchor component is used to secure each Floor Panel Frame assembly to the installation surface. The Anchor component consists of a metal shaft of variable length (depending on local building/construction codes), with angled or helical tines at the end of the Anchor that will be drilled into the installation surface, and a retaining disc and square drive shaft at the top end of the Anchor.
A Ramp component allows wheeled vehicle or implement access to the finished flooring surface. The Ramp component is a specially configured Floor Panel Frame, and accepts the same Floor Panel, and in the same manner, as that used to provide a walking or supporting surface on Floor Panel Frames. The Ramp also can be anchored to the ground in the same manner, and using the same Anchor component, as that used with Floor Panel Frames.
Partition Panels provide decorative and/or utilitarian vertical barriers at any edge of a Floor Panel Frame. They are installed into Post Brackets by sliding them down into slots, or channels, on the appropriate sides of Post Brackets. Post Brackets are installed onto Posts by sliding them down over and onto Posts. Other than that portion of a Partition Panel that fits into the Post Bracket slots, or channels, the configuration, materials, finish, etc., of the Partition Panel are variable.
Optionally, all or a portion of an assembled structure can be roofed using a subset of components designed for that purpose. A Roof Bracket is installed at the top of either a half-height or full-height Post to provide connectivity and support for Roof Beams and Integrated Gutter sections, as well as Downspouts. Each junction of Beams and Integrated Gutter Sections is sealed by a Junction Seal, and held in place by variable combinations of Roof Panels and Roofing Clamps secured by hand-installed Roof Bolts. Precipitation falling on the roofed portion of an assembled structure is either dispersed or captured via Downspout Pipes and through dispersal or harvesting Water Fittings.
Inherent in the modular nature of the component design is the ability to create finished structures of custom or variable horizontal surface configurations, thereby allowing structures to be installed around, or to entirely enclose, either pre-existing or planned physical obstructions or features, such as trees, pillars/posts, plants or planted areas, etc. This capability is available for either indoor or outdoor installations.
BRIEF DESCRIPTION OF THE DRAWINGS
A complete understanding of the present invention may be obtained by reference to the accompanying drawings, when considered in conjunction with the subsequent, detailed description, in which:
FIG. 1 is a front perspective view of an example un-roofed structure being assembled;
FIG. 2 is a front perspective view of a non-roofing subset of components;
FIG. 3 is a front perspective view of a full set of floor panel frame connector components;
FIG. 4 is a front perspective view of an anchor component, shown in two possible lengths to indicate the variability of the shaft length, and the floor panel frame component;
FIG. 5 is a combined above and below perspective view of a single floor panel frame assembly, with optional anchor;
FIG. 6 is a combined front perspective view of a floor panel being secured to a floor panel frame by a floor panel latch, also illustrating a floor panel latch cap;
FIG. 7 is a top perspective series view of a floor panel latch being installed into one “latch chamber” inside the “body” of the floor panel frame at each of the four corners;
FIG. 8 is an elevated front perspective view of a ramp component, shown both inverted (top) and upright (bottom);
FIG. 9 is an exploded perspective series view of an example assembly of floor panel frame components in a square configuration (top), and the resultant assembly after the installation (bottom);
FIG. 10 is a front perspective view of a set of half-height and full-height post components, shown both horizontally (left) and upright (right);
FIG. 11 is a top perspective view of a floor panel frame connector configured to accept the externally-threaded end of a post component;
FIG. 12 is a top perspective view of a complete set of edge frame section components, shown both upright and inverted;
FIG. 13 is a top perspective series view of an example corner assembly being finished by edge frame section components;
FIG. 14 is a combined bottom and side perspective view of a post bracket, with dowels extending from the bottom surface of the post bracket, being installed over a post, into a post configuration floor panel frame connector;
FIG. 15 is an exploded front perspective view of an example post/partition panel assembly;
FIG. 16 is a top perspective view of a post/post bracket assembly top junction, and the components that can be installed to that junction;
FIG. 17 is a top perspective view of a roofing subset of components;
FIG. 18 is a combined top and bottom exploded perspective view of an integrated gutter component and a “single” roof beam, in their relative installation positions;
FIG. 19 is a top and bottom perspective view of a “double” roof beam;
FIG. 20 is a top and bottom perspective view of a “single” and a “quad” roof panel;
FIG. 21 is a combined top and bottom perspective detail view of a corner connection point of both “single” and “quad” roof panel components (24a), and a side connection point of a “quad” roof panel (24b);
FIG. 22 is a top perspective view of a roofing connection and sealing components assembly at one side connection location for a “quad” roof panel;
FIG. 23 is a combined bottom perspective series view of a “quad” roof panel being installed to the midpoint of a “double” roof beam (top), and in its installed location (bottom);
FIG. 24 is a top and bottom perspective view of a set of roofing component connecting and sealing components;
FIG. 25 is a front exploded perspective view of an example corner assembly of supporting and connecting components for a roof panel installation;
FIG. 26 is an elevated front perspective view of the same example corner assembly in FIG. 25, showing the relative installation positions of precipitation-conveying and sealing components;
FIG. 27 is an elevated front perspective series view of the installation of a junction seal component onto the junction of precipitation-conveying components installed at this example junction assembly;
FIG. 28 is an exploded front perspective view of the relative installation positions of the final connecting and sealing components at this example junction;
FIG. 29 is an elevated front perspective view of the completed example corner installation of roofing components shown in FIGS. 25 through 28;
FIG. 30 is a front exploded perspective view of an example series of possible downspout/downspout pipe/water fitting component combinations;
FIG. 31 is a front perspective view of a full set of water fitting components;
FIG. 32 is a top and bottom perspective series view of an installation of downspout pipe stabilizer components; and
FIG. 33 is an elevated front perspective view of an example fully-enclosed and roofed structure.
For purposes of clarity and brevity, like elements and components will bear the same designations and numbering throughout the Figures.
DESCRIPTION OF THE PREFERRED EMBODIMENT
FIG. 1 is a front perspective view of an example un-roofed structure being assembled. It illustrates one possible configuration of a structure that can be assembled using a subset of components, with some of those components indicated in their relative positions for installation, and some in their installed positions.
FIG. 2 is a front perspective view of a non-roofing subset of components. Combinations of these components, in varying numbers depending on the size and configuration of the desired structure, allow the assembly of unroofed structures of any desired or required size or configuration.
FIG. 3 is a front perspective view of a full set of Floor Panel Frame Connector 105 components. The four configurations at the top of the figure are identified as “Basic” connectors. Each is configured as one or more “quadrants” of a full circle; the “outside” corner configuration is one quadrant, the “side” is two (2) adjacent “quadrants”, the “inside” corner is three (3) adjacent “quadrants,” and the “full junction” all four “quadrants” of a circle. These configurations are used when no Post 125 components are to be installed at the junction of two or more Floor Panel Frame 100 components connected by Floor Panel Frame Connector 105 components, or at one or more corners of a single Floor Panel Frame 100 assembly. The Post 125 configuration Floor Panel Frame Connector 105 is used when a Post 125 will be installed at a junction of two or more Floor Panel Frame 100 components, or at one or more corners of a single Floor Panel Frame 100. Both the Post 125 configuration connector and the full-junction “Basic” connectors can accept a Junction Cap 160. The Junction Cap 160 is installed into the central column of a Post 125 configuration Floor Panel Frame Connector 105 when no Post 125 is installed into the Post 125 configuration connector. A Junction Cap 160 is installed into the central column of a full-junction “Basic” connector when both “Basic” and Post 125 configuration connectors are used in a structure, to allow visual consistency in their finished appearance. The shorter columns extending upwardly from the “floor” of all configurations of Floor Panel Frame Connector 105 components are intended to be inserted into the holes in the “legs” of Floor Panel Frame 100 components or Edge Frame Section 170 components, when those components are installed onto the connectors. They are equidistantly spaced in a radial pattern, two per “quadrant” of all configurations of Floor Panel Frame Connector 105 components.
FIG. 4 is a front perspective view of an Anchor 120 component, shown in two possible lengths to indicate the variability of the shaft length, and the Floor Panel Frame 100 component. (The Anchor 120 and Floor Panel Frame 100 are not shown in relative scale.) The variability in shaft length of the Anchor 120 component is to allow conformity with local or regional building code requirements for foundation depth. Regardless of shaft length, the configuration and dimensions of the top and bottom portions are identical. The top portion consists of a square “drive” shaft, to be used in drilling or screwing the Anchor 120 into the installation surface. (NOTE: This attachment of the Anchor 120 component into the installation surface would almost certainly require the use of some tool to accomplish. While this might seem to invalidate the claim that no tools are required, the claim of “no tools” is made only for assembly of a structure, not attaching a structure to an installation surface.) Immediately below the “drive” portion of the shaft is the retaining disc. This flat disc will, if and when the Anchor 120 component is fully installed, seat against the retaining shoulder at the inner bottom of the anchoring hole in the center of a Floor Panel Frame 100. This retaining shoulder is identical to the retaining shoulder visible in the anchoring hole of the Ramp 145 component illustrated in FIG. 8. Near the bottom of the Anchor 120 shaft are tines, shown here as inclined three-quarter discs. These tines could also be helical in shape, similar in configuration to the tines used for heavy-duty tent stakes, as in those available from Hogan Company, Inc. tent stakes, specifically their Auger Stakes. The Anchor 120 component is an optional component for attaching outdoor structure assemblies to the installation surface, and would not be used for indoor assemblies, or temporary assemblies on outdoor surfaces.
The Floor Panel Frame 100 component is the basic assembly and supporting unit of any floored structure. It is shown in an inverted view (top right), and its upright, installation orientation (bottom right). It is square, with four supporting “legs”, one at each corner. These legs are shaped to fit onto one “quadrant” of a “Basic” Floor Panel Frame Connector 105, or in the case of the Post 125 configuration of the Floor Panel Frame Connector 105, into one “quadrant” of that component. In the bottom surface of each “leg” are two holes. The depth of these holes is equal to the length, or height, of the two round columns projecting upward from each “quadrant” of all Floor Panel Frame Connector 105 components. The top center surface portion of the Floor Panel Frame 100 is recessed, or “sunken”, below the top-most surface of the component. This recessed space will receive a Floor Panel 110. Diagonal cross-members extend from each inner corner of the recessed space in the top center of the Floor Panel Frame 100, and meet at the anchoring hole in the center of the Floor Panel Frame 100. At the bottom inner edge of the anchoring hole is a retaining shoulder. It is this shoulder that will receive the outer edge of the retaining disc of the Anchor 120 component when it is fully installed, and it is this connection point between the two components that will secure the assembly to the installation surface. The slot visible in the top surface of each inner corner of the Floor Panel Frame 100 is the entrance to a specially shaped “latch chamber” located inside the body of each inner corner of the Floor Panel Frame 100. It is this “latch chamber” that will allow the Floor Panel 110, when it is installed, to be secured to the Floor Panel Frame 100.
FIG. 5 is a combined above and below perspective view of a single Floor Panel Frame 100 assembly, with optional Anchor 120. In this illustration, where a single Floor Panel Frame 100, unconnected to any other Floor Panel Frame 100, is assembled, an “outside corner” configuration of the Floor Panel Frame Connector 105 is used. One Floor Panel Frame Connector 105, of a configuration appropriate to the desired structure, is required at each corner of a Floor Panel Frame 100, whether or not it is, or will be, connected to one or more additional Floor Panel Frame 100 components. The base surface of the anchoring hole at the center of the Floor Panel Frame 100 extends vertically below the level of the “legs” at the corners of the Floor Panel Frame 100, and the installation of a Floor Panel Frame Connector 105 at each corner is required to make the Floor Panel Frame 100 assembly sit levelly and stably on the installation surface, as well as to provide a “finished” appearance to each corner of the Floor Panel Frame 100. The two receiving holes in the bottom of each “leg” of the Floor Panel Frame 100 slide smoothly down onto and over the connector columns on the inner top surface of the base of a Floor Panel Frame Connector 105, until firmly seated. If the assembly is to be anchored into the installation surface, the Anchor 120 component is inserted through the anchoring hole in the center of the Floor Panel Frame 100, and drilled or screwed into the installation surface until the Anchor 120 retaining disc is firmly seated against the retaining shoulder at the inner base of the anchoring hole, thereby solidly securing the Floor Panel Frame 100 and Floor Panel Frame Connector 105 components to the installation surface. A Floor Panel 110 is inserted vertically down into the recessed space in the top center of the Floor Panel Frame 100. The diagonal channels and round center recess in the bottom surface of the Floor Panel 110 fit down over and onto the cross-members and top surface of the anchoring hole until they are firmly seated. These shaped and recessed spaces prevent lateral movement of the Floor Panel 110 when installed. The top surface of the installed Floor Panel 110 is flush with the top surface of the Floor Panel Frame 100 and the top surface of the Floor Panel Frame Connector 105. The Floor Panel 110 will be secured to the Floor Panel Frame 100 by installing a Floor Panel Latch 115 at each corner.
FIG. 6 is a combined front perspective view of a Floor Panel 110 being secured to a Floor Panel Frame 100 by a Floor Panel Latch 115, also illustrating a Floor Panel Latch Cap 165. The Floor Panel 110 has one (1) recessed hole in each corner. The top half of this hole is round, large enough and deep enough to allow the round top portion of the Floor Panel Latch 115 to fit snugly but smoothly inside, with the surface of the installed Floor Panel Latch 115 flush with the top surface of the Floor Panel 110. The bottom half of the hole is a rectangular slot or channel cutting through the remaining thickness of the Floor Panel 110, to allow the T-shaped lower portion of the Floor Panel Latch 115 to pass through the Floor Panel 110 into a corresponding rectangular entry into the Floor Panel Frame 100. The top recessed surface of the Floor Panel Latch 115 is shaped to allow the installer's fingers to be used to rotate the Floor Panel Latch 115 when it is installed. Also illustrated is the Floor Panel Latch Cap 165, shown in an inverted view, as well as its installation orientation. This component, of some flexible and water-resistant natural or synthetic material, is shaped to fit down over and into the top surface of the Floor Panel Latch 115, protecting it from the weather, and also providing a visually “finished” appearance.
FIG. 7 is a top perspective series view of a Floor Panel Latch 115 being installed into one “latch chamber” inside the “body” of the Floor Panel Frame 100 at each of the four corners. In this series of views, the Floor Panel 110 that would be secured by the installation of the Floor Panel Latch 115 components is not shown. View 7A illustrates the Floor Panel Latch 115 in position to be inserted into the channel, or slot, at the top of the “latch chamber”. View 7B provides the same view, but with the top recessed corner surface of the Floor Panel Frame 100 shown as if partially transparent, illustrating the location and configuration of the “latch chamber”. View 7C shows the Floor Panel Latch 115 fully inserted into the “latch chamber”. The arrow indicates that, when fully inserted, the Floor Panel Latch 115 should be rotated clock-wise 90 degrees. View 7D shows the Floor Panel Latch 115 after having been rotated inside the “latch chamber”. The T-shaped portion of the Floor Panel Latch 115 is now opposed to the channel through which it was inserted, thereby locking, or “latching”, this corner of the Floor Panel 110 in place. With a Floor Panel Latch 115 installed at each corner, the Floor Panel 110 is secured in place. This view also indicates the installation of the Floor Panel Latch Cap 165, with the shaped extrusion on the bottom side inserted into the recessed top space of the Floor Panel Latch 115.
FIG. 8 is an elevated front perspective view of a Ramp 145 component, shown both inverted (top) and upright (bottom). The Ramp 145 provides an inclined surface between the installation surface and the horizontal load-bearing surface of an assembled floored structure, allowing wheeled implements, objects, or vehicles to be rolled from the installation surface onto the floored surface. It has two “legs” identical in size and configuration to those supporting one side of a Floor Panel Frame 100. These “legs” install onto a Floor Panel Frame Connector 105 in exactly the same manner as one side of a Floor Panel Frame 100 does, thereby connecting the Ramp 145 to a larger or more extensive structure. It has a square recessed top surface space, identical in dimension and configuration to the square space in the top surface of a Floor Panel Frame 100. This space is filled by a Floor Panel 110 identical in configuration and dimensions to the Floor Panel 110 component that is installed into a Floor Panel Frame 100. The only difference lies in the inclination of that space from the horizontal plane of the Floor Panel Frame 100. The top edge of the cylindrical anchoring hole at the center of this recessed space of the Ramp 145 slopes downward, but is nevertheless of sufficient depth that the square “drive” portion of an Anchor 120 will lie below this sloped surface when and if an Anchor 120 component is used to attach this component to the installation surface. The end of the Ramp 145 opposite to the end that is installed to a Floor Panel Frame Connector 105 has a solid surface with a textured, slip-resistant surface finish.
FIG. 9 is an exploded perspective series view of an example assembly of Floor Panel Frame 100 components in a square configuration (top), and the resultant assembly after the installation (bottom). It illustrates multiple Floor Panel Frame 100 components being installed to multiple “Basic” Floor Panel Frame Connector 105 components to form a square assembly, with a Ramp 145 being installed along one side of one Floor Panel Frame 100. Note that the configuration of Floor Panel Frame Connector 105 components at each junction or corner is determined by the configuration of each junction. The center junction, where four (4) Floor Panel Frame 100 components are joined requires a “full junction” connector. The side junctions, where two (2) Floor Panel Frame 100 components, or a Floor Panel Frame 100 and a Ramp 145, meet, require a “side” configuration. The point where two (2) Floor Panel Frame 100 components are joined to the Ramp 145 component requires an “inside corner” connector. It should be apparent from this example that floored structures of an almost infinite size and configuration can be assembled, simply by varying the number and arrangement of components.
FIG. 10 is a front perspective view of a set of half-height and full-height Post 125 components, shown both horizontally and upright. Posts are necessary to provide a vertical supporting framework for the installation of Partition Panels and roofing components to a structure, as desired or required. Posts require the use of the Post 125 configuration of the Floor Panel Frame Connector 105. The half-height Post 125 allows the installation of a single level or course of Partition Panels, thereby creating “fence”-height railings or walls, while the full-height Post 125 allows the installation of two vertically adjacent levels or courses of Partition Panel 135 components, thereby creating full-height walls. The only difference between the half-height and full-height Post 125 components is their overall length or height. Each Post 125 has a round central hole throughout the entire length of the component. The top or upper portion of this hole is internally threaded to a depth sufficient to accept either a Finial 155 component, or a Roof Bracket 180 component. The shaft of the Post 125 is round, with the bottom portion externally threaded to a length equal to the depth of the threaded hole in the central column of a Post 125 configuration Floor Panel Frame Connector 105.
FIG. 11 is a detail perspective view of a Floor Panel Frame Connector 105 configured to accept the externally-threaded end of a Post 125 component, as well as the “legs” of Floor Panel Frame 100 components and/or Edge Frame Section 170 components. It is structurally equivalent to the “full junction” Basic Floor Panel Frame Connector 105, but with the addition of an enclosing side wall around the periphery of its base, and with the hole in the central shaft threaded to accept the outside threaded end of either a half-height or full-height Post 125 component.
FIG. 12 is a top perspective view of a complete set of Edge Frame Section 170 components. Edge Frame Section 170 components are only necessary for a structure, or portion of a structure, that has Post 125 configuration Floor Panel Frame Connector 105 components installed. There are five (5) configurations of the Edge Frame component. Each configuration is shown both inverted and in its upright installation orientation. Straight-sided square or rectangular structure assemblies without enclosed unfloored interior spaces require only the “side” and “outside” corner configurations of the Edge Frame Section 170 component. The “inside”, “U”, and “square” configurations are necessary for structures with irregular edges or enclosed unfloored interior spaces. Edge Frame Section 170 components may be used in various combinations to finish the periphery of a floored structure, or interior unfloored spaces in any assembled configuration. The “legs”, or corner supports, of an Edge Frame Section 170 are identical to the “legs” of a Floor Panel Frame 100, and install into the Post 125 connector configuration of a Floor Panel Frame Connector 105 identically with the installation of a Floor Panel Frame 100.
FIG. 13 is a top perspective series view of an example corner assembly of a Floor Panel Frame 100 and a Post 125 configuration of a Floor Panel Frame Connector 105, being finished by Edge Frame Section 170 components. One “leg” of the Floor Panel Frame 100 occupies one quadrant of the interior space of the Post 125 configuration connector, while the two “side” configurations and single “outside” corner configuration of the Edge Frame Section 170 components are installed into the remaining quadrants to produce a finished appearance, and to fill the remaining three quadrants of the connector. Filling all four quadrants of the Post 125 configuration connector provides an effectively solid support base for this junction of components, and keeps detritus and precipitation from accumulating in the space.
FIG. 14 is a combined bottom and side perspective view of a Post Bracket 130, with dowels extending from the bottom surface of the Post Bracket 130, being installed over a Post 125, into a Post 125 configuration Floor Panel Frame Connector 105. The Post Bracket 130 has a channel, or “slot”, on the outside of each of its four sides. These channels allow the installation of either Partition Panel 135 components, one into each channel, or the installation of a Finishing Strip 150 into any channel into which a Partition Panel 135 is not installed. The dowels would be installed to the bottom of the Post Bracket 130 during the manufacturing process, not by the person or persons assembling a structure. The exposed, unthreaded ends of the dowels would fit down into the corresponding holes in the top surface of the Post 125 configuration Floor Panel Frame Connector 105 when the Post Bracket 130 is fully installed to the Post 125. With the Post 125 fully screwed into the Post 125 configuration Floor Panel Frame Connector 105, and the Post Bracket 130 fully inserted down over the Post 125, with the dowels fully inserted into their receiving holes in the top surface of the Post 125 configuration Floor Panel Frame Connector 105, the Post 125 cannot be rotated without either lifting the Post Bracket 130 high enough to remove the dowels from their receiving holes, or applying horizontally-rotating force sufficient to shear off the dowels. Thus, installing the Post Bracket 130 effectively “locks” the Post 125 component in place, rotationally. The Post 125/Post Bracket 130 assembly is now effectively “locked” in place, both vertically and rotationally.
FIG. 15 is an exploded front perspective view of an example Post 125/Partition Panel 135 assembly. A half-height Post 125 component (left) and a full-height Post 125 component (right) are shown in their installation positions relative to the Post 125 configuration Floor Panel Frame Connector 105 components, although not shown inserted into the connectors. A single Post Bracket 130 has been slid down over the half-height Post 125, with a Post Bracket Cap 140 in its relative installation position above it. Two Post Bracket 130 components have been slid onto a full-height Post 125, with one Post bracket Cap 140 slid onto the full-height Post 125 between them, and another Post Bracket Cap 140 at the top of the second Post Bracket 130 in its relative installation position. Above each of the top-most Post Bracket Cap 140 components are the two components that can be installed through the Post Bracket Cap 140 component into the top of either a half-height or full-height Post 125; these are the Finial 155, and a Roof Bracket 180. (Only one or the other of these two components can be installed to the top of a single Post 125.) The Finial 155 component is used to secure a Post 125 assembly when no roofing components will be installed to this Post 125 assembly. The Roof Bracket 180 is used to secure the Post 125 assembly below it, while simultaneously allowing the installation of roofing components. The installation of either the Finial 155 or Roof Bracket 180 effectively secures the full Post 125 assembly, from the Post 125 configuration Floor Panel Frame Connector 105 to the Finial 155 or Roof Bracket 180, into a single, connected unit.
The Partition Panel 135 components are installed by sliding them down into the channels on the sides of adjacent installed Post Bracket 130 components. When a second, higher course of Partition Panel 135 components is installed to a full-height Post 125 assembly, the bottom edge surface of the second, or higher, Partition Panel 135 will rest on the top surfaces of the Post Bracket Cap 140 components installed at the tops of the adjacent lower installed Post Bracket 130 components. This would leave a space, or gap, between the top edge surface of the lower installed Partition Panel 135 and the bottom edge surface of the upper installed Partition Panel 135. If desired, this gap can be closed by the installation of a Partition Panel Connector 175 component. This H-shaped component fits down over the top edge of the lower Partition Panel 135, and the bottom edge of the upper Partition Panel 135 fits down into the upper portion of the H-shaped Partition Panel Connector 175, thereby closing the gap between the two Partition Panel 135 components. The horizontal length of an installed Partition Panel Connector 175 is equal to the horizontal distance between adjacent installed Post Bracket Cap 140 components, and leaves no unfilled horizontal gap between those adjacent Post Bracket Cap 140 components. The Partition Panel Connector 175 is not structurally necessary, and its installation is optional.
FIG. 16 is a top perspective view of a Post 125/Post Bracket 130 assembly top junction, and the components that can be installed to that junction. A Post Bracket Cap 140, shown both inverted (left) and in its upright installation orientation relative to the top of a Post Bracket 130 (right), is installed at the top of every Post Bracket 130, regardless of whether the Post Bracket 130 is installed onto a half-height Post 125 or a full-height Post 125. The inverted view of the Post Bracket Cap 140 (left) shows the recessed channels that will fit down over and around the top of the Post Bracket 130. The beveled hole in the center of the Post Bracket Cap 140 top surface allows the Post Bracket Cap 140 to be installed over a full-height Post 125 when necessary, and also allows the installation of the Finial 155 component, shown here in a simple but functional configuration, or the Roof Bracket 180 component. With the Post Bracket Cap 140 installed, the threaded “bolt” extending from the base of both the Finial 155 and Roof Bracket 180 is screwed by hand into the threaded top portion of the longitudinal hole running the length of the Post 125, until the beveled base either of the Finial 155 or Roof Bracket 180 is firmly seated in the beveled hole in the center of the Post Bracket Cap 140, as well as against the top surface of the Post 125. It can now be seen that, once either the Finial 155 or Roof Bracket 180 has been secured in place, the entire assembly of the Post 125 configuration Floor Panel Frame Connector 105, Post 125, Post Bracket 130, and Post Bracket Cap 140 then would be effectively one “solid” piece.
Any channel of a Post Bracket 130 that does not have a Partition Panel 135 installed would be filled by the installation of a Finishing Strip 150. The Finishing Strip 150 component is shaped and sized to fill one channel of a Post Bracket 130, and is installed into a channel of the Post Bracket 130 by sliding it fully down into an unoccupied channel of the Post Bracket 130, thereby providing additional support and solidity to the Post Bracket 130, preventing the accumulation of detritus in the unoccupied channel, and presenting a visually “finished” appearance to the Post 125 assembly's outer surface. When installed, its top surface would be level with the top surface of an installed Partition Panel 135.
FIG. 17 is a top perspective view of a roofing subset of components. (The Post Bracket Cap 140 component is the only component shown in this drawing that is not exclusively for roofing.) Because structures will vary in configuration from installation to installation, depending on intended use, not all components shown in this drawing are necessary to roof every structure. However, these are all the components necessary to roof any structure that can be assembled from the Handmade Structure System components. The Roof Bracket 180 component provides the connection point for Roof Beam 185, Gutter Block 200, and Integrated Gutter 190 components installed at the top of an installed Post 125 component. The Roof Beam 185, in either single-length or double-length configuration, provides horizontal support for the Integrated Gutter 190 components. The Integrated Gutter 190 component is so-called because it performs two functions: (1) it collects and conveys liquid precipitation from the roofed area of a structure to the periphery of a structure, and (2) it provides the installation point and structural support for the Roof Panel 245 components. The Downspout 195 component collects, redirects, and conveys the precipitation conveyed by the Integrated Gutter 190 components downward through one or more assemblies of Downspout Pipe 220 components toward the installation surface. Gutter Block 200 components prevent the outflow of collected precipitation at one quadrant of a roof junction where a Downspout 195 is not installed. The Junction Seal 205 component provides a water-tight seal at the junction of Roof Beam 185, Integrated Gutter 190, Roof Bracket 180, Downspout 195, and Gutter Block 200 components. Roof Bolt 215 components provide a secure connection of all roofing components installed at the top of an installed Post 125 assembly, either half-height or full-height. The Downspout Pipe Stabilizer 230 component is used when all or a portion of a full-height structural assembly is roofed. It provides a secure midpoint connection for an assembly of Downspout Pipe 220/Downspout Pipe Extension 225 components on a full-height structure. Water Fitting 235 components, installed at the bottom terminus of a Downspout Pipe 220 assembly, allow this collected and directed precipitation flow to be either dispersed away from an assembled structure over the installation surface, connected to an external water storage system, or conveyed to a more distant dispersal/collection point, such as a drainage ditch, sewer, etc.. Various configurations of Downspout Pipe 220 assemblies and Water Fitting 235 components allow connection to a water storage system that is either above or below ground, Any water collection/storage/conveyance system is external to the Handmade Structure System components, and is neither described in, nor claimed as a part of, this invention.
FIG. 18 is a combined top and bottom exploded perspective view of an Integrated Gutter 190 and a “single” Roof Beam 185, in their relative installation positions. The Roof Beam 185 is basically an “I” beam with specially configured end connections and top and bottom surfaces, and provides full horizontal support for the Integrated Gutter 190. The top surface of the Roof Beam 185 is shaped to accept the installation of an Integrated Gutter 190. The bottom surface of the Roof Beam 185 is shaped to be installed over the top edge of a Partition Panel 135, if one is installed beneath the Roof Beam 185, although it is not required that a Partition Panel 135 be installed beneath a Roof Beam 185. The Integrated Gutter 190 fits down over and onto the Roof Beam 185. The “channel” in the top longitudinal surface of the Roof Beam 185 accepts the “tab” extrusion along the bottom longitudinal surface of the Integrated Gutter 190. This prevents lateral shifting between the two surfaces when the Integrated Gutter 190 is installed onto the Roof Beam 185. Each end of the Roof Beam 185 is shaped as one quadrant (a 90-degree segment of the 360 degrees) of a full circle, with a downward extension of the outer edge of this curved shape equal in depth to the depth of the inner “channel” of a Roof Bracket 180, into which it will be inserted. Each end of the Integrated Gutter 190 has a shape identical to the one-quadrant shape of the Roof Beam 185 ends, and a downward extension of that “quadrant” shape edge, of a vertical length that brings the bottom of that curved extension flush with the bottom of the vertically downward extension of the Roof Beam 185 end when the Roof Beam 185 and Integrated gutter 190 are in their installed positions. The curved, downward extensions at the ends of both the Roof Beam 185 and Integrated Gutter 190 are of equal horizontal thickness, and the combined thickness of these extensions is equal to the horizontal radius of the Roof Bracket 180 inner “channel”. When both a Roof Beam 185 and Integrated Gutter 190 are installed into one quadrant of a Roof Bracket 180, that quadrant of the inner “channel” of the Roof Bracket 180 will be completely filled.
FIG. 19 is a top and bottom perspective view of a “double” Roof Beam 185. A “double” Roof Beam 185 is structurally equivalent to a combination of two “single” Roof Beam 185 components, a Roof Bracket 180, and a Post Bracket Cap 140, but in one solid piece. This component allows for a greater span between installed Post 125 components without a Post 125 being installed beneath the midpoint, thereby allowing more unobstructed floor space within an assembled structure. The bottom surface of that portion of the “double” Roof Beam 185 that is structurally equivalent to a Post Bracket Cap 140 varies from an actual Post Bracket Cap 140 in that it has no channels in its bottom surface shaped to fit over a Post Bracket 130. Instead, it has a single square cavity, intended to accept an identically-shaped extrusion at the top center of a double-width variation of a Partition Panel 135 configured as a double door or window, if one is installed beneath the “double” Roof Beam 185. (The configuration of a Partition Panel 135 that would make use of the square cavity just described is a possible and optional component configuration, and is not included in this specification.) As with the “single” Roof Beam 185, the installation of a Partition Panel 135 beneath a “double” Roof Beam 185 is not required.
FIG. 20 is a top and bottom perspective view of a “single” and a “quad” Roof Panel 245. A “single” Roof Panel 245 is used to roof over a single Floor Panel Frame 100. A “quad” Roof Panel 245 is used to roof over four Floor Panel Frame 100 components assembled into a square. Both configurations of the Roof Panel 245 have a continuous channel around their bottom periphery. The configuration of elements at the four corners of both “single” and “quad” Roof Panel 245 components is identical in dimension and structure. Both configurations of the Roof Panel 245 component has four corner posts, with a hole in the bottom surface of each of the posts threaded to accept a Roof Bolt 215. Each of the corner posts is positioned to align with the hole in each corner of a Post Bracket Cap 140. Both configurations have diagonally-intersecting vertical members to provide rigidity and support. These diagonals merge into the posts at each corner. Each of the posts at the corners of both Roof Panel 245 configurations has a threaded hole in its bottom center.
A “single” Roof Panel 245 is installed onto four Integrated Gutter 190 components contiguously installed at right angles to each other around the edges of a single Floor Panel Frame 100, with their four inner side walls effectively forming an open “box” framework. A “single” Roof Panel 245 will be installed down onto the top of this “box”. The continuous channel around the bottom periphery of the “single” Roof Panel 245 fits snugly down over and onto the top side/edge surface of each of the four Integrated Gutter 190 components, thereby sealing the “top” of the aforementioned “box”, and conveying precipitation from each of the four sloped surface planes of the Roof Panel 245 into the four Integrated Gutter 190 components onto which it is installed.
A “quad” Roof Panel 245 is installed onto a square “box” frame formed by two Integrated Gutter 190 components installed end-to-end on each of the four sides. The end-to-end Integrated Gutter 190 components forming each side of this “box” may be installed onto a “double” Roof Beam 185, or two “single” Roof Beam 185 components. Because each side of the “quad” Roof Panel 245 spans the gap between two Integrated Gutter 190 components installed end-to-end, the midpoint of each side of the “quad” Roof Panel 245 is configured with two (2) equivalents of the posts in each corner, for a total of twelve (12) posts. The “quad” Roof Panel 245 has vertically thickened portions at the underside center of each sloped plane, to provide additional strength and support for the larger surface area of each plane. These thickened portions taper in width from each of the side connecting points of the “quad” Roof Panel 245 to the underside apex of the “quad” Roof Panel 245.
FIG. 21 is a top and bottom perspective detail view of a corner connection point of both “single” and “quad” Roof Panel 245 components (21A), and one of the four side connection points of a “quad” Roof Panel 245 (21B). When either configuration of the Roof Panel 245 is in its installed position, the threaded hole in each of these posts will align with the unthreaded holes in each corner of the Post Bracket Cap 140 upon which the bottom surface of the Roof Panel 245 posts rests, or the structural equivalent of a Post Bracket Cap 140 at the center of a “double” Roof Beam 185. This alignment allows the upward insertion of a Roof Bolt 215 through the unthreaded hole in the corner of the Roof Bracket 180 Cap, or the structural equivalent of the Post Bracket Cap 140 at the center of a “double” Roof Beam 185. The Roof Bolt 215 components are then screwed by hand into the threaded holes in the bottom of the Roof Panel 245 corner posts. Four (4) hand-tightened Roof Bolt 215 components are required to secure a “single” Roof Panel 245 in place, while twelve (12) Roof Bolt 215 components are required to secure a “quad” Roof Panel 245; one at each corner, and two at each side connection point.
FIG. 22 is a top perspective view of a roofing-connection-and-sealing-components assembly at one side connection location for a “quad” Roof Panel 245. In this particular example, the two (2) Integrated Gutter 190 components have been installed onto a “double” Roof Beam 185, but could have been installed onto two “single” Roof beam 185 components installed end-to-end. Both sides of this particular Roof Bracket 180 assembly have been filled with Gutter Block 200 components. Note the shape formed by the top edge surfaces of the Integrated Gutter 190 components and the Gutter Block 200 components, and how that shape matches the shape of the peripheral channel at the midpoint of the “quad” Roof Panel 245 shown in FIG. 21. Each midpoint connection point of the “quad” Roof Panel 245 will fit down over and onto an identical configuration of Integrated Gutter 190 and Gutter Block 200 components at each side of the square being roofed by the “quad” Roof Panel 245.
FIG. 23 is a top perspective view of a “quad” Roof Panel 245 being installed to the midpoint of a “double” Roof Beam 185 (top), and in its installed location (bottom). It illustrates how the positioning of the “quad” Roof Panel 245 brings the two posts at each midpoint of that “quad” Roof Panel 245 into alignment with the corner holes of the Post Bracket Cap 140, or its structurally equivalent portion of a “double” Roof Beam 185, at that midpoint. FIG. 23A shows the “quad” Roof Panel 245 in position to be lowered onto the installed Integrated Gutter 190 and Gutter Block 200 components at this side of the “quad” Roof Panel 245. FIG. 23B shows the “quad” Roof Panel 245 in its installed position, relative to the other components at this location. Each of the “quad” Roof Panel 245 component's four (4) side midpoints will fit onto and over the components at their respective locations. With all components at this location installed, one (1) Roof Bolt 215 will be upwardly inserted through each of the four (4) holes in the corners of either the Post Bracket Cap 140, or, as in this example, the structurally-equivalent portion of a “double” Roof Beam 185, and screwed into the threaded holes of the “posts” of the Roof Panel 245, if one is installed, or into the threaded holes of Roofing Clamp 210 components otherwise.
FIG. 24 is a top and bottom perspective view of a set of roofing component connecting and sealing components. The components are shown inverted on the left-hand side of the figure, and in their upright or installation orientation on the right-hand side of the figure.
At the top of the figure is the Roofing Clamp 210. This component is used to secure each corner joint of a roofing component juncture that is not occupied by a Roof Panel 245 to an installed Post 125 assembly, either half-height or full-height. The Roofing Clamp 210 has a vertical element, analogous to the corner posts of a Roof Panel 245. The vertical element of the Roofing Clamp 210, like the corner posts element of a Roof Panel 245, has a threaded hole in its center. The top portion of the Roofing Clamp 210 is shaped to fit snugly down over the corner joint formed by the juncture of two Downspout 195 components, or two Gutter Block 200 components, or a Downspout 195 and a Gutter Block 200, installed adjacently and at right angles to each other, into a single Roof Bracket 180, and after the installation of a Junction Seal 205 component. The bottom surface of the vertical element of a Roofing Clamp 210 will rest on the top corner surface of either a Post Bracket Cap 140, or the structurally-equivalent portion of a “double” Roof Beam 185.
Immediately below the Roofing Clamp 210 is the Roof Bolt 215 component. The Roof Bolt 215 has a shaft threaded to screw into either the threaded hole in a Roofing Clamp 210, or the threaded hole in the posts of a Roof Panel 245. The head of the Roof Bolt 215 has a large “tang” to enable the hand-installation of the bolt.
On either side of the Roof Bolt 215 components is the Junction Seal 205 component. This component is formed to fit down into the “four-cornered” junctions of Downspout 195/Gutter Block 200/Integrated Gutter 190 assemblies, the configuration of said assemblies determined by the desired or required roofing configuration of an assembled structure. It seals all the vertical junctures of these components, and also seals the top of the Roof Bracket 180 that supports the entire grouping of roofing components installed to the Roof Bracket 180. The round extrusion on the bottom surface of the Junction Seal 205 fits into the hole in the top of the central column of a Roof Bracket 180, to prevent lateral shifting of its bottom surface relative to the top surface of the Roof Bracket 180 onto which it is installed.
Below the Junction Seal 205 component is the Downspout 195 component. This component captures liquid precipitation flowing to it from the Integrated Gutter 190 components, and redirects that precipitation downwardly through its “pipe” element downwardly into a Downspout Pipe 220 toward the installation surface. The top “floor” of the Downspout 195 has a hole with a beveled or chamfered “lip” to facilitate water flow into the downwardly-oriented “pipe” element of the Downspout 195. The ends of the side wall are vertically angled at 45 degrees to allow them to fit flush with adjacently-installed Downspout 195 components, or Gutter Block 200 components, or Integrated Gutter 190 components, whichever might be installed adjacent to the Downspout 195. The top surface of the Downspout 195 “floor” that is installed over and into a Roof Bracket 180 is “stepped down” from the remaining “floor” surface, to allow the Junction Seal 205 component, when installed, to bring the entire top surface of this junction of components to a horizontally flush and even level with the top “floor” of the Integrated Gutter 190. The bottom end of the “pipe” element of the Downspout 195 is threaded on its outside surface to allow Downspout Pipe 220 components to be screwed by hand onto the “pipe” element of the Downspout 195. That curved and downwardly projecting portion of the Downspout 195 that will be inserted into the Roof Bracket 180 is shaped identically with those portions of the Roof Beam 185 and Integrated Gutter 190 components that insert into the top inner channel of a Roof Bracket 180. The thickness of the curved downwardly-extending portion of the Downspout 195 is equal to the combined thickness of the portions of the Roof Beam 185 and Integrated Gutter 190 components that are inserted into the circular channel on top of the Roof Bracket 180, thereby entirely filling one quadrant of the circular channel of the Roof Bracket 180, when installed. The remaining portion of the “base” element of the Downspout 195 will rest on the top surface of the Post Bracket Cap 140 installed below it, or the structurally-equivalent portion of a double Roof Beam 185, with the curved inner surface of the “base” element of the Downspout 195 resting flush against the round outer side wall of the Roof Bracket 180.
At the bottom of the figure, the Gutter Block 200 component is shown. This component is physically equivalent to the supporting “base” portion of a Downspout 195, and the curved connecting portion that is inserted into the Roof Bracket 180, but with a straight and solid “back” wall at a right angle to its side walls, instead of the curved vertical side wall of the Downspout 195. It installs in exactly the same manner as a Downspout 195, and is used to close one quadrant of a Roof Bracket 180 assembly at which no Downspout 195 is installed. Like the Downspout 195, the curved inner surface of its supporting “base” will rest flush against the round outer side wall of the Roof Bracket 180. It will prevent water from flowing out of one quadrant of one junction of roofing components at the top of a Post 125 assembly.
FIG. 25 is a front exploded perspective view of an example corner assembly of supporting and connecting components for a Roof Panel 245 installation. In this example, a Post Bracket Cap 140 will be installed atop an installed Post 125, with a Post Bracket 130 having been slid down over the Post 125, and Finishing Strip 150 components installed into the side channels of the Post Bracket 130. This Post 125 assembly may be either half-height or full-height, as both half-height and full-height structures may be roofed. The threaded “bolt” portion of a Roof Bracket 180 will be inserted through the Post Bracket Cap 140 and screwed into the threaded hole in the top of the Post 125. In this example, a “single” Roof Beam 185 will be installed into one quadrant of the Roof Bracket 180, and a “double” Roof Beam 185 will be installed into an adjacent quadrant of the Roof Bracket 180. Two (2) Integrated Gutter 190 components are shown being installed, one onto the “single” Roof Beam 185 and one onto the “double” Roof Beam 185.
FIG. 26 is an elevated front perspective view of the same example corner assembly shown in FIG. 25, showing the relative installation positions of precipitation-directing and sealing components. With the Roof Beam 185 and Integrated Gutter 190 components installed, this example corner assembly will be completed by installing a Downspout 195 and a Gutter Block 200 into the quadrants of the Roof Bracket 180 not filled by Integrated Gutter 190 components, with a Junction Seal 205 then installed to seal this junction of components at the Roof Bracket 180. Then a “single” Roof Panel 245 will be installed downwardly into the corner formed by the Integrated Gutter 190 components. Three (3) Roofing Clamp 210 components will be installed down over the three “outside” corners of the junction. Three (3) Roof Bolt 215 components will be inserted upwardly through the respective corners of the Roof Bracket 180 Cap and screwed into the threaded holes in the Roofing Clamp 210 components, while a fourth Roof Bolt 215 (not visible here) will be inserted through the fourth (inside) corner hole of the Post Bracket Cap 140 and screwed into the threaded hole in the immediate corner post 125 of the “single” Roof Panel 245.
FIG. 27 is an elevated front perspective series view of the installation of a Junction Seal 205 component onto the junction of precipitation-conveying components installed at this example junction assembly. The Downspout 195 and Gutter Block 200 components are shown in their installed positions relative to the Roof Bracket 180, Roof Beam 185 and Integrated Gutter 190 components. This view further illustrates the manner in which this variety of components can be arranged at the Roof Bracket 180 to accommodate any desired or required configuration of roofing assembly. The Junction Seal 205 completes any combination of installed components at a Roof Bracket 180, making it ready for the installation of Roof Panel 245 and/or Roofing Clamp 210 components.
FIG. 28 is an exploded front perspective view of the relative installation positions of the final connecting and sealing components at this example junction. With the completed assembly of all other components at this example junction assembly, the Roofing Clamp 210 and Roof Panel 245 components are installed. With the Roofing Clamp 210 and Roof Panel 245 components in their installed positions, four (4) Roof Bolt 215 components will be inserted upwardly through the holes in the corners of the Roof Bracket 180 Cap, and screwed into the threaded holes in the Roofing Clamp 210 and Roof Panel 245 components.
FIG. 29 is an elevated front perspective view of the completed example corner installation of roofing components shown in FIGS. 25 through 28. With four (4) Roof Bolt 215 components at each junction (one at each corner) regardless of the combination of components joined at the junction, each junction is securely fastened to the Post 125 assembly beneath it. The installation of a variety of roofing components is possible at any junction, depending on the desired configuration of the assembled structure, and the desired configuration of the roofing. It is not necessary to roof an entire structure. It is possible to roof only a portion of an assembled structure, and the area covered by the roofed portion need not correspond to the floored portion of the assembled structure.
FIG. 30 is a front exploded perspective view of an example series of possible Downspout 195/Downspout Pipe 220/Water Fitting 235 component combinations. Pipe components are configured in two (2) lengths. The longer of the two is the Downspout Pipe 220, while the shorter is the Downspout Pipe Extension 225. The tops of the Downspout Pipe 220 and Downspout Pipe Extension 225 are threaded along their inner surfaces at a length equal to the length of the threading on the outside surface of the “pipe” portion of the Downspout 195. The Downspout Pipe 220 and Downspout Pipe Extension 225 components may be screwed together by hand in any desired or required configuration, and either may be screwed by hand onto the threaded “pipe” portion of the Downspout 195, thereby extending the water-conducting length of that component downward toward the installation surface.
The Downspout Pipe Extension 225, like the Downspout Pipe 220, is threaded on both its top inner surface and bottom outer surface. The Downspout Pipe Extension 225 typically would be used to connect two (2) Downspout Pipe 220 components assembled to a full-height roofed structure, allowing the water flow to reach near the installation surface.
Depending on the height of the structure to which the Downspout 195 and its related components are to be installed, and also depending on the purpose desired by the installer, the combinations of these components for any particular assembly is completely variable.
Possible Assembly 1 could be used at a Downspout 195 assembly on a full-height structure to convey precipitation to a point near the installation surface, there to be either dispersed or harvested. At this near-installation-surface level, the harvesting configuration of the Water Fitting 235 would allow connection to an underground water storage system, or conveyance of the water to a drainage system at some distance from the assembled structure, while the dispersal configuration Water Fitting 235 would allow the dispersal of the water horizontally across and onto the installation surface.
Possible Assembly 2 would allow connection from just below the vertical midpoint of a full-height structure to an above-ground water storage system, such as a rain barrel or trough, for example.
Possible Assembly 3 allows precipitation directed from a half-height roofed structure to be either dispersed over the installation surface, or connected to an underground storage system, or conveyed to a more distant drainage system.
Possible Assembly 4 would allow precipitation directed from a half-height roofed structure to be connected to an above-ground storage system, such as a rain barrel or trough, for example.
As stated, these are only some of the possible configurations. Other configurations could be assembled, as desired or required. In each assembly where the harvesting configuration Water Fitting 235 is used, the Water Fitting Cap 240 would be used to seal a threaded connection where a connection to a water storage system is not made.
FIG. 31 is a front perspective view of configurations of Water Fitting 235 components. If precipitation conveyed from the roofed portion of a structure is to be dispersed over the installation surface, then the dispersal configuration of the Water Fitting 235 would be used. If this conveyed precipitation is to be collected (harvested) into a water storage system, the harvesting configuration would be used. It is possible to use both fittings on the same assembled structure, although only one Water Fitting 235 component can be installed at the bottom terminus of any individual Downspout Pipe 220 assembly at a time. Except for the fan-shaped “exit” portion, both configurations are identical. The dispersal configuration simply redirects the flow of water at a horizontal 90 degree angle, presumably away from the assembled structure. The harvesting configuration has two threaded connectors set into a “plate” or “wall” obstructing the fan-shaped “exit” portion. These threaded connectors are of a size and threading to allow the connection of standard garden hoses or their equivalents to the two threaded outlets. The Water Fitting Cap 240 is used to seal a connector when no connection is made between one of the threaded outlets of the harvesting configuration and a water storage system. Like the threaded connector at each end of a standard garden hose and the body of the hose itself, the top and bottom portions of both Water Fitting 235 components rotate independently of each other about their connecting juncture, allowing the Water Fitting 235 to be oriented to any desired or required direction.
FIG. 32 is a top and bottom perspective series view of an installation of Downspout Pipe Stabilizer 230 components. Downspout Pipe Stabilizer 230 components are used only with full-height assembled structures at those locations that have Downspout Pipe 220 assemblies installed. The Downspout Pipe Stabilizer 230 component has two configurations: 1) Corner, shown on the left, and 2) Side, shown on the right. The corner configuration is used at an “outside” corner of an assembled structure, when two Downspout Pipe 220 assemblies are installed adjacent at a right angle to each other at a single Post 125 assembly. The “side” configuration is used at any other location where a Post Bracket Cap 140 has two adjacent corner holes available and a Downspout Pipe 220 assembly is installed. (Note: Downspout 195 and Downspout Pipe 220 assemblies, including Downspout Pipe Stabilizer 230 components, cannot be installed at an “inside”, or L-shaped, corner of an assembled structure.)
The Downspout Pipe Stabilizer 230, in either configuration, consists of a ring element with an inside diameter large enough to allow a Downspout Pipe 220 or Downspout Pipe Extension 225 to fit snugly but smoothly through it. It is used at the approximate vertical midpoint of a full-height Downspout Pipe 220 assembly (refer to “Possible Assembly 1” in FIG. 33), or near the bottom of a Downspout Pipe 220 assembly extending downward from a Downspout 195 installed to approximately the vertical midpoint of a full-height structure (refer to “Possible Assembly 2” in FIG. 30), typically for connection to an above-ground water storage system.
The “side” configuration has two (2) downward-projecting cylindrical extrusions at each end of a horizontal connecting bar. The two extrusions insert into two adjacent corner holes of a Post Bracket Cap 140. The ring element is thus aligned with an installed Downspout Pipe 220/Downspout Pipe Extension 225 assembly, with the Downspout Pipe Extension 225 fitting inside the ring. This component provides stability to the Downspout Pipe 220 assembly by limiting vibration or other lateral movement of the Downspout Pipe 220 assembly caused by wind or the flow of water downward through the Downspout Pipe 220 assembly. The “corner” configuration has an L-shaped horizontal connecting bar, with three (3) cylindrical downward-projecting extrusions, and is installed into three (3) Post Bracket Cap 140 corner holes. It provides the same stability for two Downspout Pipe 220 assemblies installed adjacent at a right angle to each other at an outside corner of an assembled full-height structure, that the “side” configuration provides for a single Downspout Pipe 220 assembly.
FIG. 33 is an elevated front perspective view of an example fully-enclosed and roofed structure. This example structure illustrates some possible combinations of the Handmade Structure System components, and is intended to give a general idea of the possibilities for assembling structures using this invention. Although this example structure is basically rectangular, the inclusion of the roofed “porch” illustrates that this system of components is not limited to rectangular structures, nor is there any inherent limitation to the size or configuration of an assembled structure. The roofed “porch” also illustrates that the two Roof Panel 245 configurations/sizes can be used in a single structure. The Partition Panel 135 components shown in this example illustrate the variability of materials used for the interior “panel” portion of the Partition Panel 135, as they are shown here as being of a mesh screen material, rather than a solid “panel” as illustrated in previous figures. The Floor Panel 110 components used to provide the floored surface of the “porch” illustrate that the Floor Panel 110 surface need not be solid, but could also be “slotted” or “ventilated”, to allow precipitation to flow or melt through. The surface finish, materials, and decoration of the “panel” portions of Partition Panel 135 components, as well as the top surface of Floor Panel 110 components, is completely variable, allowing great flexibility in both the appearance and utility of these surfaces. With the appropriate fittings installed to either a Partition Panel 135 or Floor Panel 110, it would be possible to conduct water, electricity, or heating/cooking gas into a structure. Other possible configurations of Partition Panel 135 components include fully functional windows in a variety of forms, bifold doors, wire-mesh panels, etc. While this example illustrates a full-height structure, it is possible to create fully-enclosed and roofed half-height structures, or partially-enclosed and-or partially-roofed structures, and structures with separate sections or portions of variable height, enclosure, roofing, etc.
Since other modifications and changes varied to fit particular operating requirements and environments will be apparent to those skilled in the art, the invention is not considered limited to the example chosen for purposes of disclosure, and covers all changes and modifications which do not constitute departures from the true spirit and scope of this invention.
Having thus described the invention, what is desired to be protected by Letters Patent is presented in the subsequently appended claims.