Abstract:
Disclosed is a foldable transportable structure with a three dimensional rectangular shed roof shape having improved component and structural properties, and improved shipping and deployment capabilities. The integrated unique geometric folding pattern means provides enhanced folding accuracy and correct placement of interactive panels during collapse or assembly of the structure, and also greatly increases the flexibility for multiple unit combinations and component materials selection. The folding transportable structure provides a strong, safe, insulated weatherproof structure with a quick setup time, and requires NO tools or separate loose components for assembly.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application is a National Phase filing from International Application serial number PCT/US12/37185 filed Jun. 28, 2012, for a Foldable Transportable Structure of Inventor/Applicant, Vincent J. DiGregory, and a Continuation in Part of U.S. application Ser. No. 13/068,430 filed on May 11, 2011 for a Foldable Transportable Structure of Inventor/Applicant Vincent J. DiGregory. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a Foldable Transportable Structure that when deployed provides a truly collapsible, transportable, insulated and lightweight structure that is safe reliable and internationally compliant. Its designed flexibility provides maximum convenience for the following: quick deployment to nearly any geographic location; use of varying component materials and sizes; and interconnectability of single units for multiple unit combinations. The ability of the structure to be air-dropped also allows service to the most remote locations where shelter or facility use is needed. 
     2. Description of the Prior Art 
     Typically, supplied conventional structures offer only one or a few of a complete set of required properties that include: an easily erectable configuration for fast field installation; a requirement of NO tools or separate parts and pieces for assembly; a capability for remote deployment; a specific insulation value if needed; structural integrity; long-term durability; a design that allows for flexible use of materials choice and the potential to combine together multiple units. 
     U.S. Pat. No. 5,493,818 describes a “collapsible” structure having improved storage and shipping properties which are achieved by specific designing of the size, shape and hingable connection positions whereas said structure is erectable and collapsible within minutes utilizing a minimal amount of tools and effort. 
     Geometric and dimensional limitations will not allow this structure to physically collapse into a stackable configuration as claimed. The roof panels will not be able to completely stretch out to lay flat when the roof panels are of a long enough dimension to form a gabled configuration, as their combined length when laying flat is much longer than the available length that the wall panels provide when they are in their folded flat configuration. An attempt to collapse the roof panels into a fully folded flat position will cause the wall panels below to hinge-bind dramatically resulting in neither of the roof or wall panels being able to lay completely flat. Alternately, when the wall panels are in a completely folded flat position the gable roof panels will not be allowed to fully stretch out and lay flat. In summary, the designed geometry will not allow full complete collapse of the stacked panels. All Sections and Claims within U.S. Pat. No. 5,493,818 refer to the invention as being a fully collapsible structure, which it will not be able to accomplish. This may be why it has not been adopted for large scale use. 
     U.S. Pat. No. 4,779,514 describes a “modular portable building unit” susceptible to air transport, and includes a roof, foldable side walls and foldable end walls having the same width as the height of the side walls. Three of the modular building units can be interfitted (sic) to form a building having four times as much floor space as the single modular building unit. The inclusion of a floor in the modular building is optional, and the inclusion of a separate pitched roof assembly for positive roof drainage is optional. Additional object of the invention is to provide a modular building unit that when folded down will allow transport by air or truck, and to allow combinations of multiple units together. 
     This method is limited by the gable end panels being separate components, and the separate fastening components and systems required to erect and/or collapse the unit. Redeployment and transport of this structure can be accomplished only after a very time consuming and tedious removal of many parts and pieces has been done. The lack of provisions for a passage opening, door, or other means shown for ingress or egress between the connected units is detrimental to the function and internal occupant flow of the connected units. Therefore no added value to the user from connecting the units together is recognized, and this may be why this system has not been adopted for large scale use. 
     U.S. Pat. No. 4,166,343 describes a hollow, generally rectilinear structure having a top, a bottom, sides and ends that can be constructed so as to be capable of being manipulated between a “normal” or unfolded type configuration and a collapsed or folded configuration in which the ends extend generally parallel to and beneath the top and in which the sides are folded so as to be located next to the ends generally between the bottom and the top. Such a structure includes hinges connecting the ends to the top so that they can be pivoted so as to lie generally parallel to the top. Such a structure is disclosed as having utility as a playhouse or storage shed but can be utilized for other purposes such as a container. 
     This structure is limited in that the gable end panels are separate panels that are hinged to the roof panel. The erection of the unit will not be manageable by the roof having to carry the added weight of the gable panels during erection of the side walls and roof panels at the same time. This will be completely unmanageable in the field. The structure also does not have means for combination of multiple units, or optional door placement locations, or a window to provide ventilation. This may be why this structure has not been adopted for field use, and is not a presently being manufactured. 
     U.S. Pat. No. 3,906,671 describes an adjustable door frame having frame portions formed by first and second frame sections cooperatively arrangeable (sic) on a wall of an opening. 
     This method provides adjustability only to the door frame for installation to variable wall thicknesses, and can only provide one of four possible door swing functions or configurations when installed. The mitered head jamb and casing pieces directly attach to the mitered hinge and strike jambs. This static configuration does not allow for the potential inversion of the hinge and strike jambs that would be required so that the entire door and frame assembly could be installed in either a right or left hand, or inside or outside, door swing configuration. In order for a door frame assembly to be completely and fully adjustable both of the hinge and strike jamb components must have the ability to be inverted and attachable to either the head or sill components so that the entire frame and door assembly can be installed in any of the 4 each possible swing configurations. This may be why this invention has not been adapted for field structures use. 
     U.S. Pat. No. 4,395,855 describes a pre-fabricated door frame assembly, the components which are adjustable and such that the assembly can be used for either right or left handed doors and can fit a wide variety of widths and heights of door openings through walls of varying thicknesses. 
     This method is designed to attach to standard constructed building walls that are normally much wider than the thinner wall panels typically used for flat-pack shelter units, and requires separate fasteners and tools for attachment to the wall system. This invention also does not include an integrated threshold or weather strip component for exterior wall use, which would be necessary for shelter units that would be deployed in hot or cold climates. This invention has limited use in that is does not offer diversity and the flexibility to be used in both interior and/or exterior applications, and it is not easily reversible or re-installable in the field without the use of tools or separate fasteners that may or may not be available. 
     U.S. Pat. No. 3,420,003 describes an adjustable door frame that adjusts to varying wall thicknesses, and can be installed quickly and easily with screws that go directly into the wall system. It consists of several longitudinal trim and jamb components that overlap and stay in place by ratchet teeth and backing plates that when the installation screw component is installed the separate pieces become locked into place. 
     This method is designed to attach to standard constructed building walls, and requires separate fasteners and tools for attachment to the wall system. This invention also does not include an integrated threshold or weather strip component for exterior wall use, which would be necessary for shelter units that would be deployed in hot or cold climates. This invention has limited use in that is does not offer diversity and the flexibility to be used in both interior and/or exterior applications, and it is not easily reversible or re-installable in the field without the use of tools or separate fasteners that may or may not be available. 
     U.S. Pat. No. 5,448,799 describes a hinge assembly for pivotally adjoining two panels together such as a shower door and its enclosure. A pair of continuous channel members are provided which are provided with an axial aligned rod and tubular channel for rotatably (sic) receiving the rod. 
     This method includes a weather strip component that protrudes beyond the profile of the wall panel extrusions. This component could not be utilized in a foldable structure as the protrusion will not allow adjacent and connected together wall panels to lay flat against each other when the structure, is in a collapsed position. 
     SUMMARY OF THE INVENTION 
     The present invention is a Folding Transportable Shelter with improved properties of: accurate folding hinge geometry, advanced interactive and integrated components that are designed to allow for either transportable or assembled structure configuration; advanced component materials for increased insulation; structural integrity; long-term dependability; built-in flexibility for optional placements of doors, windows or clear openings; and built-in flexibility for choice and use of varying materials and sizes for integrated components. 
     It is therefore a primary objective of the present invention to provide a foldable transportable structure that will significantly enhance the quality, functionality, stackable transportability, flexibility and affordability of moveable shelter structures. 
     It is another object of the present invention to include in the design a sophisticated geometric folding pattern means that significantly improves the allowance for integration and use of varying component materials, and also significantly improves the interactive complimentary relationships of folding accuracy, necessary clearances, and continual structural contact between adjacent components during the collapse and assembly functions of the unit. 
     It is another object of the present invention to include in the design same said sophisticated geometric folding pattern means that remains static, while allowing complete flexibility for: choice of overall structure size; use of any chosen dimension for panel thicknesses and relative connector widths; ability to combine together floor, wall and roof panels that are comprised of different individual thicknesses to obtain varying insulation values; without any of the above impacting the folding and assembly accuracy, or overall capabilities of the structure. 
     It is a further object of the present invention to provide specific designed continuous pivot hinge-to-panel connectors, an adjustable door assembly, a leveling foot assembly, a strap conveyance and tie-down assembly, and a flexible fillable bladder bag component to further improve the function, flexibility and use of the structure. 
     It is a further object of the present invention to provide a foldable transportable structure that has flexible integral components that are interchangeable during the manufacturing process for making structures that provide specific solutions for use in variable field conditions that include climatic, structural, deployment and usage considerations. 
     It is still another object of the present invention to provide a foldable transportable structure that contains the flexibility to be interconnected with additional like units of varying wall thicknesses to make larger structures, and includes removable wall panel sections for in-the-field-flexibility to interchange doors, windows or clear openings to create various configurations for maximum internal occupant flow and use. 
     These, and other objects of the present invention, will become apparent to those skilled in the art upon reading the accompanying description, drawings, and claims set forth herein. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a perspective view of the erected Foldable Transportable Structure according to the present invention. 
         FIG. 2  is a sectional view of the collapsed Foldable Transportable Structure according to the present invention. 
         FIG. 3  is a sectional view of the Geometric Folding Pattern included in the Foldable Transportable Structure according to the present invention. 
         FIG. 4  is a sectional view of the Roof Eave connector component according to the present invention. 
         FIG. 5  is a sectional view of the roof to wall connected components according to the present invention. 
         FIG. 6  is a sectional view of the Roof-to-Wall connector component according to the present invention. 
         FIG. 7  is a sectional view of the mid wall to wall connected components according to the present invention. 
         FIG. 8  is a sectional view of the Wall-to-Wall connector component according to the present invention. 
         FIG. 9  is a sectional view of the Floor Curb connector component according to the present invention. 
         FIG. 10  is a sectional view of the wall to floor connected components according to the present invention. 
         FIG. 11  is a perspective view showing the Horizontal Grid and Dimension Pattern according to the present invention. 
         FIG. 12  is a sectional view of the Removable Wall Panel trim components according to the present invention. 
         FIG. 13  is a perspective view showing the Removable Wall Panel assembly according to the present invention. 
         FIG. 14  is a perspective view of the FlexFrame Door assembly according to the present invention. 
         FIG. 15  is a sectional view of the FlexFrame Door jamb components according to the present invention. 
         FIG. 16  is an exploded perspective elevation view of the FlexFrame Door components according to the present invention. 
         FIG. 17  is a perspective cut-away view of the collapsed Foldable Transportable Structure according to the present invention. 
         FIG. 18  is an elevation and section view of the Draw Latch component according to the present invention. 
         FIG. 19  is a perspective view of the erected Foldable Transportable Structure containing alternate embodiments according to the present invention. 
         FIG. 20  is a sectional view of the collapsed Foldable Transportable Structure containing alternate embodiments according to the present invention. 
         FIG. 21  is a sectional view of the Geometric Folding Pattern containing alternate embodiments included in the Foldable Transportable Structure according to the present invention. 
         FIG. 22  is a sectional view of the alternate embodiment Roof Eave connect component according to the present invention. 
         FIG. 23  is a sectional view of the roof to wall connected components containing alternate embodiments according to the present invention. 
         FIG. 24  is a sectional view of the alternate embodiment continuous flexible Dumbbell Hinge connector component according to the present invention. 
         FIG. 25  is a sectional view of the wall to wall connected components containing alternate embodiments according to the present invention. 
         FIG. 26  is a sectional view of the alternate embodiment Wall Hinge connector component according to the present invention. 
         FIG. 27  is a sectional view of the alternate embodiment Floor Curb connector component according to the present invention. 
         FIG. 28  is a sectional view of the wall to floor connected components containing alternate embodiments according to the present invention. 
         FIG. 29  is a perspective view showing the Horizontal Grid and Dimension Pattern containing alternate embodiments according to the present invention. 
         FIG. 30  is a sectional view of the alternate embodiment Removable Wall Panel components according to the present invention. 
         FIG. 31  is a perspective view showing the Removable Wall Panel assembly containing alternate embodiments according to the present invention. 
         FIG. 32  is a perspective view of the FlexFrame Door assembly containing alternate embodiments according to the present invention. 
         FIG. 33  is a sectional view of the alternate embodiment FlexFrame Door jamb components according to the present invention. 
         FIG. 34  is an exploded perspective elevation view of the alternate embodiment FlexFrame Door components according to the present invention. 
         FIG. 35  is a perspective cut-away view of the collapsed Foldable Transportable Structure containing alternate embodiments according to the present invention. 
         FIG. 36  is an elevation and section view of the alternate embodiment Reclosable Latch component according to the present invention. 
         FIG. 37  is a sectional view of the alternate embodiment Weatherstrip, Corner Trim, Panel Hook and Door Seal components according to the present invention. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       FIG. 1 , and  FIG. 19  containing alternate embodiments, shows a perspective view of the best mode contemplated by the inventor of the erected Foldable Transportable Structure  10  according to the concepts of the present invention. As seen by the drawings the foldable transportable structure  10  consist of a series of structural panels and continuous pivot hinge components connected together in a way that allows for either a folding up of the structure into a fully erected configuration as seen in  FIG. 1  and  FIG. 19 , or a folding down of the structure into a flat fully collapsed configuration for transportable methods as seen in  FIG. 2 ,  FIG. 20 ,  FIG. 17  and  FIG. 35 . 
     In general the foldable transportable structure  10  connector and hinging components can be attached together with load compliant structural adhesives, tapes or fasteners of any type. As seen in  FIG. 1  and  FIG. 19  the foldable transportable structure  10  consists of a single floor panel  11  of which each of its long axis exposed edges are connected to a Floor Curb component  19  as seen in  FIG. 9 ,  FIG. 10  and  FIG. 17 , or alternate embodiment Floor Curb component  19  as seen in  FIG. 27 ,  FIG. 28  and  FIG. 35 . One half of a Wall-to-Wall hinge component  20  as seer in  FIG. 8 , or alternate embodiment Wall Hinge component  20  as seen in  FIG. 26  is connected to the remaining short axis exposed edges of the floor panel  11  as seen in  FIG. 1  and  FIG. 19  to complete the floor panel assembly. A continuous Wall Hinge component  20  as seen in  FIG. 8  and  FIG. 26  is connected to each of the four exposed edges located on both of the short side wall panels  13  and  14 , and also to each of the four exposed edges located on both of the tall side wall panels  16  and  17 , as seen in  FIG. 1  and  FIG. 19 ,  FIG. 5  and  FIG. 23 ,  FIG. 7  and  FIG. 25 , and  FIG. 10  and  FIG. 28  to complete the short and tall side wall panel assemblies. One half of a Wall-to-Wall hinge component  20  as seen in  FIG. 8 , or alternate embodiment Wall Hinge  20  seen in  FIG. 26  is connected to each of the eight exposed edges of both of the gable wall panels  12  and  18  as seen in  FIG. 1  and  FIG. 19  to complete the gable wall panel assemblies. A Roof Eave component  22  as seen in  FIG. 4 , or alternate embodiment Roof Eave component  22  as seen in  FIG. 22 , is connected to one each long axis exposed edge of the roof panel  15  as seen in  FIG. 1  and  FIG. 19 . The remaining long axis exposed edge of the roof panel  15  is connected to Roof Ridge component  23  as seen in  FIG. 1 ,  FIG. 5  and  FIG. 17 , or alternate embodiment Roof Ridge component  23  as seen in  FIG. 19 ,  FIG. 23  and  FIG. 35 . One half of Wall-to-Wall hinge component  20  as seen in  FIG. 8 , or alternate embodiment Wall Hinge component  20  as seen in  FIG. 26  is connected to both of the remaining short axis exposed edges of the roof panel  15  as seen in  FIG. 1  and  FIG. 19  to complete the roof panel assembly. An interlocking removable panel trim component  25  as seen in  FIG. 12  is connected to each of the eight exposed edges of the removable wall panels  24  as seen in  FIG. 1 ,  FIG. 11  and  FIG. 13 , or alternate embodiment Wall Hinge component  20  as seen in  FIG. 30  is connected to each of the eight exposed edges of the removable wall panels  24  as seen in  FIG. 19 ,  FIG. 29  and  FIG. 31  to complete the removable wall panel assemblies. 
     Each long axis of the floor  11 , short walls  13  and  14 , tall walls  16  and  17  and roof panel  15  assemblies as seen in  FIG. 1  and  FIG. 19  are connected together by the integral flexible hinge portion on components  20  or  21  as seen in  FIG. 5 ,  FIG. 6 ,  FIG. 7 ,  FIG. 8 ,  FIG. 10  and  FIG. 17 , or with the alternate embodiment Dumbbell Hinge component  21  as seen in  FIG. 24  that slides into the respective hinge slots located on each of the Floor Curbs  19 , Wall Hinges  20 , Roof Eave  22  and Roof Ridge  23  components as seen in  FIG. 23 ,  FIG. 25 ,  FIG. 28  and  FIG. 35 . The Wall Hinge components  20  located at the bottom of the Gable wall panels  12  and  18  as seen in  FIG. 1  and  FIG. 19  are attached to the adjacent Wall Hinge component  20  located on the short axis of the floor panel  11  by a continuous Dumbbell Hinge component  21  as seen in  FIG. 24 , thus completing the entire structure&#39;s connected panel assembly. 
     When the structure  10  is in its fully erected configuration as seen in  FIG. 1  and  FIG. 19  each individual wall panel is secured to its adjacent panel by a series of either structural draw latches  26  as seen in  FIG. 18 , or alternate embodiment reclosable locking (Velcro™ type) straps  26   a  as seen in  FIG. 36 . These structural latches are also located around the perimeter of a removable panel  24  as seen in  FIG. 30  and must be disengaged in order to allow each individual wall panel to be folded down, or an individual removable panel to be removed or relocated within the structure. 
       FIG. 2 , and  FIG. 20  containing alternate embodiments, shows a cross section of the collapsed structure in its folded flat transportable configuration. For further reference  FIG. 17 , and  FIG. 35  containing alternate embodiments, show a more detailed view of the individual panels when they are arranged in the folded flat configuration. To collapse the structure the following procedure is followed: gable end wall panels  12  and  18  are folded inward to lay flat on top of the single floor panel  11 ; the short side walls  13  and  14  are folded inward to lay flat on top of the gable wall panels  12  and  18 ; the tall side walls  16  and  17  are folded inward to lay flat on top of the gable wall panels  12  and  18 ; the single roof panel  15  follows the folding path of each side wall  14  and  16 , as each are folded down into their relative position, to then lay flat on top of walls  14  and  16 . To secure the panels together in the folded flat configuration for transportation a series of adjustable strap tie-down assemblies made up of components  45 ,  46 ,  47  and  48  are hooked onto the Roof Eave component  22  and Roof Ridge component  23  as seen in  FIG. 17  and  FIG. 35 . To erect the structure simply reverse the process as described above. 
       FIG. 3 , and  FIG. 21  containing alternate embodiments, shows the vertical layout for the Geometric Folding Pattern that formulates the static hinge-to-hinge pivot point centering relationship between the structure&#39;s adjacent individual panels, and establishes a guide to determine the finished panel widths or height dimensions for the floor panel  11 , the wall panels  13 ,  14 ,  16  and  17 , the roof panel  15 , the gable wall panels  12  and  18 , and the vertical short and long points for the gable wall panels  12  and  18 . The relative dimensions are defined using the following static pattern formulation: a floor panel expressed as ‘A’ with an arbitrarily chosen width dimension being designated as ‘X’; a bottom short wall panel expressed as ‘B’ being of a height that is relative to 41.27617% of ‘X’; an upper short wall panel expressed as ‘C’ being of a height that is relative to 43.27018% of ‘X’; a bottom tall wall panel expressed as ‘D’ being of a height that is relative to 55.63310% of ‘X’; an upper tall wall panel expressed as ‘E’ being of a height that is relative to 57.76271% of ‘X’; a roof panel expressed as ‘F’ that is of a width that is relative to 103.98803% of ‘X’; a pair of gable panels expressed as ‘G’ that are of a width that is relative to 99.70089% of ‘X’; a pair of gable panels expressed as ‘G’ with a short point height that is of a length that is relative to 84.24725% of ‘X’ plus the chosen thickness width of the wall panels; a pair of gable panels expressed as ‘G’ with a long point height that is of a length that is relative to 112.96111% of ‘X’ plus the chosen thickness width of the wall panels. 
       FIG. 4  shows a detail cross sectional view of the Roof Eave connector component  22 . Roof Eave  22  is permanently attached to one long axis edge of the roof panel  15  as seen in  FIG. 1  and  FIG. 2 , and similar to  FIG. 5 . Roof Eave  22  is always attached to the short wall upper panel assembly  14  with Wall-to-Roof connector component  21  as seen in  FIG. 6  to create the low side of the roof slope for the fully erected structure  10  as can be seen in  FIG. 1 . See alternate embodiment for Roof Eave connector component  22  in  FIG. 22 . 
       FIG. 5  shows a detail cross sectional view of the Roof Ridge to upper wall assembly, and the related hinging motion according to the present invention. The Roof Ridge connector component  23  is permanently attached to the roof panel  15  and connected to the adjacent wall  16  by Wall-to-Roof connector component  21  as seen in  FIG. 6 . This hinged connection allows the adjacent attached panels to fold up into a fully erected structure configuration or fold down into a flat collapsed configuration. Roof Ridge  23  is always hinged to the tali wall upper panel assembly  16  to create the high side of the roof slope for the fully erected structure  10  as can be seen in  FIG. 1 . See alternate embodiment for roof ridge to wall assembly in  FIG. 23 . 
       FIG. 6  shows the Wall-to-Roof flexible hinge component  21  that is used to connect the short wall upper panel  14  as seen in  FIG. 1  to the bottom of the Roof Eave connector component  22  as seen in  FIG. 1  and  FIG. 4 , or the tall wall upper panel  16  to the Roof Ridge connector component  23  as seen in  FIG. 1  and  FIG. 5 , and provides the hinging ability to fold the structure up or down. See alternate embodiment for hinge component  21  in  FIG. 24 . 
       FIG. 7  shows a detail cross sectional view of the wall to wall middle hinged connection of an upper tall wall panel assembly  16  to a lower tall wall panel assembly  17 , and the related hinging motion according to the present invention. The Wall-to-Wall connector component  20  as seen in  FIG. 8  is permanently attached to tall wall panels  16  and  17 , or to short wall panels  13  and  14  located on the opposite side of the structure as seen in  FIG. 1 . The hinged connection allows the adjacent attached panels to fold up into a fully erected structure configuration or fold down into a flat collapsed configuration. See alternate embodiment for wall to wall assembly in  FIG. 25 . 
       FIG. 8  shows a detail cross sectional view of the Wall-to-Wall connector component  20 . Wall-to-Wall connector component  20  as seen in  FIG. 1 ,  FIG. 2  and  FIG. 17  is a permanently attached to a panel edge or Floor Curb  19  components where hinges locations are required as seen in  FIG. 2 ,  FIG. 7 ,  FIG. 10 ,  FIG. 13  and  FIG. 17 . Wall-to-Wall connector component  20  is split in half at the hinge point to then be used as a trim component for attachment to the remaining panel edges that are exposed and do not require a hinge function. See alternate embodiment for Wall Hinge connector component  20  in  FIG. 26 . 
       FIG. 9  shows a detail cross sectional view of the Floor Curb connector component  19 . Floor Curb  19  is permanently attached to each long axis edge of the floor panel  11  as seen in  FIG. 1 ,  FIG. 2  and  FIG. 10 . The top half of Floor Curb connector component  19  is removed where removable panels  24  are located to create an opening flush to the floor panel  11 . See alternate component for Floor Curb connector component  19  in  FIG. 27 . 
       FIG. 10  shows a detail cross sectional view of the Floor Curb to the lower wall assembly, and the related hinging motion according to the present invention. The Floor Curb connector component  19  is permanently attached to the floor panel  11  and connected to the adjacent wall  17  by the Wall-to-Wall connector component  20  as seen in  FIG. 8 . This hinged connection allows the adjacent attached panels to fold up into a fully erected structure configuration or fold down into a flat collapsed configuration. See alternate embodiment for floor to wall assembly in  FIG. 28 . 
       FIG. 11  shows a perspective view showing the architectural Horizontal Grid Pattern that establishes the structure&#39;s basic dimension design, and also facilitates specific aligned layout locations for removable wall panels, door and window assemblies for interchangeability between complexed units according to the present invention. Removable wall panel  24  locations allow the creation of clear openings or window  27  and door  28  installations as seen in  FIG. 1  in any one of variable locations within the tall or gable walls of the structure. The finished dimension width of the removable wall panel  24  and its respective rough opening is a result of two (2) times an Arbitrary Dimension expressed as ‘A’. See alternate embodiment for horizontal grid pattern in  FIG. 29 . 
       FIG. 12  shows a detail cross sectional view of the Removable Wall Panel  24  assembly and components. A Wall-to-Wall connector component  20  is permanently attached between the upper and lower panel sections to provide the required hinging action. An interlocking panel edge trim  25  as seen in  FIG. 12  and  FIG. 13  is permanently attached to each of the remaining removable wall panel edges. A series of draw latches  26  as seen in  FIG. 18  are attached to the panels to secure the removable wall panel  24  assembly to the adjacent panel assemblies. See alternate embodiment for removable panel assembly  24  in  FIG. 30 . 
       FIG. 13  shows a perspective elevation of the assembled removable wall panel  24 , and the locations of relative components. See alternate embodiment for removable panel assembly  24  in  FIG. 31 . 
       FIG. 14  shows a perspective elevation view of the overall configured door frame assembly  28  as seen in  FIG. 1  which includes a series of separate adjustable interlocking jamb components  29  and  30 , and a series of hinge components  31  as seen in  FIG. 15  and  FIG. 16 . See alternate embodiment for door frame assembly  28  in  FIG. 32 . 
       FIG. 15  shows a detail cross section of the jamb components to include the following: a jamb component  29 , with a series of ‘V’ shaped protrusions  38  running the length of the component, that is used for the side jambs, header and sill components; an interlocking jamb component  30 , with a series of ‘V’ shaped grooves  39  running the length of the component that mate with the ‘V’ shaped protrusions  38  of jamb component  29 , to allow overall jamb width adjustability to varying wall thickness widths; a series of thumb-turn threaded rod with compression nut locking assemblies  36  for securing jamb components  29  and  30  together; and a hinge component  31  for attachment of the door  42  and door panel trim  43  to the side jamb component  29 . See alternate embodiments for door components in  FIG. 33 . 
       FIG. 16  shows a perspective cut-away elevation of the various door frame components to illustrate more specifically individual component relationships, details, and the reversible and invertible function of the door assembly. Jamb component  29  and separate hinge components  31  each include a round hollow profile  32 , as can be more aptly seen in  FIG. 15 , on their respective outside edges that allow insertion of a continuous hinge securing rod  33  to attach the two components together. The single hinge-side jamb component  29  includes a series of cut-out sections to allow insertion of hinge components  31  and corresponding vertical alignment of their respective round hollow profiles  32 . Side jamb, header and sill components  29  each include an extruded open slot to receive a continuous weatherstrip component  34 , as can be more aptly seen in  FIG. 15 . Jamb components  29  include a series of holes  35  where a thumb-turn threaded rod with compression nut locking assembly  36  is installed. Corresponding jamb components  30  include a series of open-ended slots  37  that align with the series of thru-bolts  36  installed on jamb components  29 . Together components  36  and  37  allow for a sliding back and forth motion between jamb components  29  and  30  for adjustability to variable adjacent wall panel thicknesses. Jamb components  29  include a series of protruding ‘V’ shapes  38  that rest into a corresponding series of reverse retention ‘V’ shapes  39  that are integral to jamb components  30 . Jamb components  29  and  30  are then prevented from sliding apart when tightened together with the thumb turn threaded rod with compression nut assembly  36 . The two each side jamb components  29  each include on their ends a pair of male tabs  40  that fit into a corresponding pair of female slots  41  that are punched into the top surfaces of the header and sill components  29 . The series of tabs  40  and slots  41  prevent potential horizontal movement between the two each side jamb components  29  and the header and sill components  29 . The series of tabs  40  and slots  41  also allow the hinge-side jamb component  29  and attached door components  42  and  43  to be inverted between the header and sill components  29  in order to change the door to either a right or left handed swing function. The entire door assembly  28  is also installable on either the exterior or interior of the wall to additionally provide for any of the four each possible swing functions required. A structural insulated door panel  42  as seen in  FIG. 15  and  FIG. 33  is wrapped on all four side edges with a ‘U’ shaped trim cap component  43 , and is attached with a series of fasteners  44  to a series of symmetrically centered surface mounted hinge components  31 . A commercially available flush mounted latching and locking mechanism is installed in the door panel component  42  to complete the door assembly. Each of the door assembly components can be made from any variety or combination of metals, plastics, composites, fiber reinforced polymers, fiberglass or other types of material. See alternate embodiments for door components in  FIG. 33  and  FIG. 34 . 
       FIG. 17  shows a perspective cut-away view of the collapsed structure showing the adjustable strap conveyance and tie-down assembly, the adjustable leveling foot assembly, the spiral ground stake component, the fillable bladder bag component, and the relationship between components according to the present invention. A series of load compliant looped strap carrying handles  45  are attached to the floor curb component  19  for conveyance of the transportable structure  10 . Two separate continuing sections of the tie-down strap  46  are interconnected with a commercially available load compliant ratchet-tight buckle  48 . The remaining end of the tie-down strap  46  is attached to a commercially available load compliant flat hook  47 . Hook  47  connects to the Roof Eave component  22 , or Roof Ridge component  23  for securing the structure  10  while it is in a flat collapsed transportable configuration, or alternately hooks onto either the eyelet  54  that is integral to bladder bag  53 , or onto a spiral ground stake  55 , for securing the fully erected structure  10  to the ground. The bladder bag  53  is filled with water, or is covered with earth, sand, gravel, or other material to add hold-down ballast weight to the fully erected structure  10 . A series of adjustable leveling pad assemblies are installed inside of the Floor Curb connector component  19 . A load compliant square tube  49  is securely installed in component  19 . A load compliant leveling tube adapter  50  is inserted into component  49 . A load compliant fast-turn threaded rod  51  of sufficient length is welded to a load compliant leveling foot  52 , and is then inserted into the receiving threads of the leveling tube adapter  50 . When the structure  10  is in its collapsed transportable configuration the leveling foot pad  52  is in a completely retracted position and alternately provides stacking guidance and transportation containment by sliding into and resting on the top track and curb of a lower structure&#39;s roof components  22  and  23 . See alternate embodiments for the structure in  FIG. 35 . 
       FIG. 18  shows a section and elevation view of the structural load compliant valance draw latch  26  as can be seen in  FIG. 1  that is connected to the various adjacent panel assemblies to secure the panels from unhinging or being removed while the structure is in a fully erected configuration. See alternate embodiment latch in  FIG. 36 . 
       FIG. 19 , containing alternate embodiments to  FIG. 1 , shows a perspective elevation of the best mode contemplated by the Inventor of the erected foldable transportable structure  10  according to the concepts of the present invention, and is further fully described at page 12, line 4 through page 14, line 14 above. 
       FIG. 20 , containing alternate embodiments to  FIG. 2 , shows a cross section of the collapsed structure in its folded flat transportable configuration, and is further fully described at page 14 line 15 through page 15 line 5 above. 
       FIG. 21 , an alternate embodiment to  FIG. 3 , shows the vertical layout for the Geometric Folding Pattern that formulates the static hinge-to-hinge pivot point centering relationship between the structure&#39;s adjacent individual panels, and establishes a guide to determine the finished panel widths or height dimensions for the floor panel  11 , the wall panels  13 ,  14 ,  16  and  17 , the roof panel  15 , the gable wall panels  12  and  18 , and the vertical short and long points for the gable wall panels  12  and  18 , and is further fully described at page 15, line 6 through page 16, line 2 above. 
       FIG. 22 , an alternate embodiment to  FIG. 4 , shows a detail cross sectional view of the Roof Eave connector component  22 . Roof Eave  22  as seen in  FIG. 19  and  FIG. 20 , and similar to  FIG. 23 , is permanently attached to one long axis edge of the roof panel  15 . Roof Eave  22  is always attached to the short wall upper panel assembly  14  with Dumbbell Hinge  21  as seen in  FIG. 24 , to create the low side of the roof slope for the fully erected structure  10  as can be seen in  FIG. 19  and  FIG. 20 . The open hinge slots in Roof Eave  22  can receive a Dumbbell Hinge  21  as seen in  FIG. 24  and  FIG. 23  where hinging action is required, or can receive Weatherstrip  56 , Corner Trim  57  or Panel Hook  58  as seen in  FIG. 37  where required. 
       FIG. 23 , an alternate embodiment to  FIG. 5 , shows a detail cross sectional view of the Roof Ridge to upper wall assembly, and the related hinging motion according to the present invention. The Roof Ridge connector component  23  is permanently attached to the roof panel  15  and connected to the adjacent wall  16  by Wall Hinge connector component  20  as seen in  FIG. 26  and the separate continuous flexible Dumbbell Hinge connector component  21  as shown in  FIG. 24 . The open hinge slots in Roof Ridge  23  and Wall Hinge  20  can receive a Dumbbell Hinge  21  as seen in  FIG. 24  where hinging action is required, or can receive Weatherstrip  56 , Corner Trim  57  or Panel Hook  58  as seen in  FIG. 37  where required. 
       FIG. 24 , an alternate embodiment to  FIG. 6 , shows a detail cross sectional view of the structural and flexible continuous Dumbbell Hinge component  21  that is inserted with a sliding motion into the respective open hinge slots of the connector components  19 ,  20 ,  22  and  23  as seen in  FIG. 22 ,  FIG. 23 ,  FIG. 25 ,  FIG. 28  and  FIG. 35 . The Dumbbell Hinge component  21  provides the flexible hinging motion between connected adjacent panel assemblies for folding ability of the structure, and performs as a positive continuous weatherstrip between adjacent panels when the structure is in its fully erected configuration as seen in  FIG. 19 . 
       FIG. 25 , containing alternate embodiments to  FIG. 7 , is a detail cross sectional view of the wall to wall middle hinged connection of the upper tall wall panel assembly  16  to the lower tall wall panel assembly  17 , and the related hinging motion according to the present invention. The mid wall connection is also used between the lower and upper short wall panel assemblies  13  and  14  on the opposite side of the structure as seen in  FIG. 19 . The middle hinge assembly consists of two (2) each opposing separate continuous Wall Hinge connector components  20  as seen in FIG.  26  and permanently attached adjacent wall panel assemblies, connected together by the separate continuous flexible Dumbbell Hinge connector component  21  as seen in  FIG. 24 . The open hinge slots in Wall Hinges  20  can receive a Dumbbell Hinge  21  where hinging action is required, or can receive Weatherstrip  56 , Corner Trim  57  or Panel Hook  58  as seen in  FIG. 37  where required. 
       FIG. 26 , an alternate embodiment to  FIG. 8 , shows a detail cross sectional view of Wall Hinge  20  that is permanently attached to the short axis ends of floor panel  11  and roof panel  15 , and to all of the exposed edges of gable panels  12  and  18 , wall panels  13 ,  14 ,  16  and  17  as seen in  FIG. 1 ,  FIG. 2 ,  FIG. 17 ,  FIG. 19 ,  FIG. 20 ,  FIG. 23 ,  FIG. 25 ,  FIG. 28  and  FIG. 35 , and to removable panel assemblies  24  as seen in  FIG. 30  and  FIG. 31 . The open hinge slots in Wall Hinge  20  can receive a Dumbbell Hinge  21  as seen in  FIG. 24  where hinging action is required, or can receive Weatherstrip  56 , Corner Trim  57  or Panel Hook  58  as seen in  FIG. 37  where required. 
       FIG. 27 , an alternate embodiment to  FIG. 9  shows a detail cross sectional view of the Floor Curb connector component  19 , Floor Curb  22  as seen in  FIG. 19  and  FIG. 20  is permanently attached to each long axis edge of the floor panel  11  as seen in  FIG. 28 . The top half of Floor Curb connector component  19  is removed where removable panels  24  are located to create an opening flush to the floor panel  11 . The open hinge slots in Floor Curb  19  can receive a Dumbbell Hinge  21  as seen in  FIG. 24  where hinging action is required, or can receive Weatherstrip  56 , Corner Trim  57  or Panel Hook  58  as seen in  FIG. 37  where required. 
       FIG. 28 , an alternate embodiment to  FIG. 10 , shows a detail cross sectional view of the Floor Curb to the lower wall assembly, and the related hinging motion according to the present invention. The Floor curb connector component  19  is permanently attached to the floor panel  11  and connected to the adjacent wall  17  by Wall Hinge connector component  20  as seen in  FIG. 26  and the separate continuous flexible Dumbbell Hinge connector component  21  as shown in  FIG. 24 . The open hinge slots in Floor Curb  19  and Wall Hinge  20  can receive a Dumbbell Hinge  21  as seen in  FIG. 24  where hinging action is required, or can receive Weatherstrip  56 , Corner Trim  57  or Panel Hook  58  as seen in  FIG. 37  where required. 
       FIG. 29 , an alternate embodiment to  FIG. 11 , shows a perspective view showing the architectural horizontal grid pattern that establishes the structure&#39;s basic dimension design, and also facilitates specific aligned layout locations for removable wall panels, door and window assemblies for interchangeability between complexed units according to the present invention, and is further fully described at page 18, lines 15 to 20 above. 
       FIG. 30 , an alternate embodiment to  FIG. 12 , shows a detail cross sectional view of the removable wall panel  24  components. A Wall Hinge  20  as seen in  FIG. 26  is permanently attached to all edges of the removable panels as seen in  FIG. 31 . A semi-rigid Panel Hook  25  as seen in  FIG. 37  is inserted into the relative Wall Hinge  20  slots to provide an interlocking weather seal around the perimeter of the removable panel  24  as seen in  FIG. 31 . A series of reclosable dual lock straps  26  as seen in  FIG. 36  are engaged between the removable panel  24  and adjacent wall panels to secure the removable panel  24  assembly in place. 
       FIG. 31 , containing alternate embodiments to  FIG. 13 , shows a perspective elevation of the assembled removable wall panel  24 , and the locations of relative components. 
       FIG. 32 , containing alternate embodiments to  FIG. 14 , shows a perspective elevation view of the overall configured door frame assembly  28  as seen in  FIG. 19  which includes a series of separate adjustable interlocking jamb components  29  and  30 , and a series of hinge components  31  as seen in  FIG. 33  and  FIG. 34 . 
       FIG. 33 , an alternate embodiment to  FIG. 15 , shows a detail cross section of the jamb components to include the following: a jamb component  29 , with a series of ‘V’ shaped protrusions  38  running the length of the component, that is used for the side jambs, header and sill components; an interlocking jamb component  30 , with a series of ‘V’ shaped grooves  39  running the length of the component that mate with the ‘V’ shaped protrusions  38  of jamb component  29 , to allow overall jamb width adjustability to varying wall thickness widths; a series of latch spring-bolt and compression hook assemblies  36  for securing jamb components  29  and  30  together; and a hinge component  31  for attachment of the door  42  and door panel trim  43  to the side jamb component  29 . 
       FIG. 34 , an alternate embodiment to  FIG. 16 , shows a perspective cut-away elevation of the various door frame components to illustrate more specifically individual component relationships, details, and the reversible and invertible function of the door assembly. Jamb component  29  and separate hinge components  31  each include a round hollow profile  32 , as can be more aptly seen in  FIG. 33  on their respective outside edges that allow insertion of a continuous hinge securing rod  33  to attach the two components together. The single hinge-side jamb component  29  includes a series of cut-out sections to allow insertion of hinge components  31  and corresponding vertical alignment of their respective round hollow profiles  32 . Side jamb, header and sill components  29  each include an extruded open slot to receive a continuous weatherstrip component  34 , as can be more aptly seen in  FIG. 33 . Jamb components  29  include a series of holes  35  where either a thumb-turn threaded rod with compression nut or a latch spring-bolt compression hook locking assembly  36  is installed. Corresponding jamb components  30  include a series of open-ended slots  37  that align with the series of thru-bolts  36  installed on jamb components  29 . Together components  36  and  37  allow for a sliding back and forth motion between jamb components  29  and  30  for adjustability to variable adjacent wall panel thicknesses. Jamb components  29  include a series of protruding ‘V’ shapes  38  that rest into a corresponding series of reverse retention ‘V’ shapes  39  that are integral to jamb components  30 . Jamb components  29  and  30  are then prevented from sliding apart when tightened together with the latch spring-bolt and compression hook assembly  36 . The two each side jamb components  29  each include on their ends a pair of male tabs  40  that fit into a corresponding pair of female slots  41  that are punched into the top surfaces of the header and sill components  29 . The series of tabs  40  and slots  41  prevent potential horizontal movement between the two each side jamb components  29  and the header and sill components  29 . The series of tabs  40  and slots  41  also allow the hinge-side jamb component  29  and attached door components  42  and  43  to be inverted between the header and sill components  29  in order to change the door to either a right or left handed swing function. The entire door assembly  28  is also installable on either the exterior or interior of the wall to additionally provide for any of the four each possible swing functions required. A structural insulated door panel  42  as seen in  FIG. 33  is wrapped on all four side edges with a ‘U’ shaped trim cap component  43 , and is attached with a series of fasteners  44  to a series of symmetrically centered surface mounted hinge components  31 . A commercially available flush mounted latching and locking mechanism is installed in the door panel component  42  to complete the door assembly. Each of the door assembly components can be made from any variety or combination of metals, plastics, composites, fiber reinforced polymers, fiberglass or other types of material. 
       FIG. 35 , an alternate embodiment to  FIG. 17 , shows a perspective cut-away view of the collapsed structure showing the adjustable strap conveyance and tie-down assembly, the adjustable leveling foot assembly, the spiral ground stake component, the fillable bladder bag component, and the relationship between components according to the present invention, and is further fully described in page 21, line 19 through page 22, line 16 above. 
       FIG. 36 , an alternate embodiment to  FIG. 18 , shows a section and elevation view of the structural load compliant Reclosable Latch  26   a  as can be seen in  FIG. 19  and  FIG. 30  that is connected to the various adjacent panel assemblies to secure the panels from unhinging or being removed while the structure is in a fully erected configuration. 
       FIG. 37  shows sectional views of the Weatherstrip  56 , Corner Trim  57 , Panel Hook  58  and Door Seal  59  components according to the present invention. 
     The problems addressed by the Foldable Transportable Structure  10  are many as can be easily seen by those skilled in this art. The Foldable Transportable Structure  10  greatly enhances the ability and proficiency to deploy moveable structures and reduce transportation costs, by including a well-arranged series of structural panels, hinges and other components, which are connected together in a certain way that allows the structure to be folded down into a collapsed configuration to provide a very compact transportable structure. The Foldable Transportable Structure  10  supports easy and complete assembly in the field, especially in more remote locations, by not requiring the use of power, separate hand tools, or separate loose connectors and fasteners that can be misplaced or lost. The Foldable Transportable Structure  10  saves field time and labor costs by requiring only three to four unskilled persons less than five minutes to fully erect it, and it can also be as easily collapsed and re-deployed to a different location in as little time. The Foldable Transportable Structure  10  is environmentally responsible as all individual components are designed to provide more than just one integrated function, thus substantially reducing raw material quantities, environmental impact and production costs. The flexible design of the Foldable Transportable Structure  10  allows for choice of varying raw materials to meet fluctuating market conditions or any user required specifications. The design of the Foldable Transportable Structure  10  includes a Geometric Folding Pattern, as seen in  FIG. 3  and  FIG. 21  that provides folding ability of the structure, and also establishes or allows for: combination of varying panel thicknesses for the floor, wall and roof panels; the guided folding motion and cohesive interaction of each individual structure component; maintaining minimal clearances and continual structural support between all adjacent components during the folding process or transportable configuration. The Foldable Transportable Structure includes panel connector components that are multi-functional in that they can accept various flexible Dumbbell Hinge components or Weatherstrip, Corner Trim and Panel Hook components that are interchangeable and can be easily replaced in the assembled structure if they become damaged in the field. The Foldable Transportable Structure  10  provides additional value to the end user as units can be optionally equipped witty an integrated Removable Wall Panel system, as amply seen in  FIGS. 11 through 13  and  29  through  31  to allow for the in-the-field switching of the door or window locations, or to create other clear opening locations for flexible flow-through configurations within multiple combined units. The Reversible FlexFrame Door assembly, as amply seen in  FIGS. 14 through 16  and  32  through  34  saves raw materials and costs by providing a one-size-fits-all assembly. The Foldable Transportable Structure  10  will find wide use anywhere disaster relief, military, and other civil types of operations are required. Private industry would be employed to manufacture the many units required. 
     Thus it will be appreciated by those skilled in the art that the present invention is not restricted to the particular preferred embodiments described with reference to the drawings, and that variations may be made therein without departing from the scope of the present invention as defined in the appended claims and equivalents thereof.