Abstract:
A light weight, modular building fastening apparatus which allows rapid construction of custom modular buildings as an improvement to traditional framing systems is provided. The modular fastening system comprises a set of panels that form the roof and walls of the structure which are connected to a set of panels thorough the use of fasteners.

Description:
This application claims the benefit of U.S. Provisional Application No. 61/777,658 filed on Mar. 12, 2013 and U.S. Provisional Application No. 61/783,510 filed on Mar. 14, 2013, which are hereby incorporated by reference in their entirety as if fully set forth herein. 
    
    
     BACKGROUND OF THE INVENTION 
     The present invention relates to rapid construction methods for building construction. Traditional framing methods required construction workers to cut building materials on-site to serve as the frame of a building. A need for more efficient methods for building customized structures has been shown, including the use of standardized parts that can be easily customized for different structures. 
     SUMMARY OF THE INVENTION 
     The invention is a light weight, quick fastening building system which allows rapid construction of modular structures as an improvement to traditional framing using both steel and wood. The modular system allows builders to customize a framing system to a variety of architectural layouts. The modular nature of the system also saves weight, time, and space in construction efforts. 
     The invention comprises a number of panels that are fastened together with fasteners and connectors. The panels may be placed to form the roof and walls of a structure. A set of fasteners may be placed near the ends of each panel to fasten one or more panels to a connector. The connectors of each system may be customized to form a particular architectural shape. Although this system comprises many types of building layouts, one embodiment described is a traditional roofed house structure. In this embodiment, one or more continuously-connected modular structures are formed. Depending on the width of the connectors and panels, several matching sets of modular structures may be placed in rows to form the shape of the building, or one wide set of modular structures can be used alone to form the shape of the building. 
     The roof of the modular structure is formed by roof panels that are connected to the tops of the exterior wall panels and headers with roof panels to exterior wall panel connectors. The roof panels are connected together by a roof ridge connector. A modified double mount may be used in the system to add extra strength to the roof and supporting structures. Headers may be placed at the floor and at the tops of the exterior wall panels of the modular system. The headers may be connected at both upper and lower ends of the exterior wall panels by sets of fasteners. 
     The roof panels are connected to the exterior wall panels of the structure via two sets of roof to wall connectors. The exterior walls may be formed from a number of panels stacked together with their ends flush and their vertical surfaces aligned. Additionally, the panels of the exterior walls may be held together through the use of interior tongue and groove connections. 
     The exterior walls may connect to rigid slabs at the base of a building via two sets of wall to slab connectors. The rigid slabs may serve as a foundation for the building. In this way, the connectors support a continuous structure which lends strength and ensures water tightness and insulation integrity. 
     The invention is a modular building system that has a plurality of rigid connectors and a plurality of prefabricated exterior panels. Each of the rigid connectors is fixedly attached to one or more of the prefabricated exterior panels. Plural fasteners are included for fixedly attaching the rigid connectors to the prefabricated exterior panels by passing one or more of the fasteners through at least one of the rigid connectors and the prefabricated exterior panels. The plurality of rigid connectors include rigid wall connectors for interconnecting some of the prefabricated exterior panels as wall panels, rigid connectors for connecting the wall panels to others of the prefabricated exterior panels as roof panels, and roof ridge connectors for connecting two or more of the roof panels. 
     A plurality of the angled connectors is connected to the wall panels, the roof panels, and the roof ridge connectors connected to the roof panels form a rigid roof truss and rigid exterior walls, with the exterior walls giving support to said roof truss. The exterior wall panels are connected to the roof truss to form a continuous rigid structure that serves as the support structure of a building. 
     The rigid angled connectors include comprise a first set of rigid flanges, shelves, and risers which form an “L” shape with a rigid 90 degree angle, and a continuous second set of rigid roof support plates with angles to the risers. The roof truss has a peaked shape formed by two of the prefabricated panels which are connected together by the roof ridge connectors. The prefabricated exterior wall panels comprise stacks of prefabricated exterior panels that comprise two or more of the panels vertically connected. 
     The stacks of the panels are connected together with the wall connectors, the edges of each of the panels being flush together, and vertical surfaces of each of the panels being aligned. The stacks of panels are held together by sets of wall panels having corresponding tongue and groove connectors, wherein the rigid connectors further compose rigid footer connectors. The wall panels are fastened to footings with the rigid footing connectors. 
     The roof ridge connectors are made from two identically shaped side plates welded together at the inner edges. 
     These and further and other objects and features of the invention are apparent in the disclosure, which includes the above and ongoing written specification, with the drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  shows the total modular system with prefabricated panels, roof ridge connectors, roof connectors, wall to roof connectors, footer to wall connectors, and footing connectors. 
         FIG. 2  schematically shows roof ridge connectors, roof connectors, a wall to roof connector, and a footer to wall connector. 
         FIG. 3  shows a roof connector. 
         FIG. 4  shows a wall to roof connector. 
         FIG. 5  shows a footer connector. 
         FIG. 6  shows a connector boxing a wall to door or wall to window. 
         FIG. 7  shows a footer to wall connector. 
     
    
    
     DETAILED DESCRIPTION 
     Dimensions are shown on some figures are used as examples, and may vary to facilitate different building shapes and sizes. Prefabricated panels are used to form side walls and roofs of structures. In one embodiment, the prefabricated panels forming the roof may be longer than the prefabricated panels forming the side walls. Alternatively, the prefabricated panels forming the roof and side walls may have similar or equal lengths. Shaped connectors connect panels to each other and to footings. 
       FIG. 1  shows an overview of the total modular system  1 .  FIG. 2  shows cross-sections of various connectors  10  attached to side wall panels  12  and roof panels  14  with screws  16 . Footer connector  20  is positioned between a wall panel  12  and a footer  22  that may be composed of poured concrete. Fastener  23  secures the footer connector  20  to footer  22  before the wall panel is erected. The roof to wall connector  30  has a lower flange  32  that is attached to the inside of one or more wall panels  12  with screws  16 . One or more wall panels  12  may be connected together through the use of internal tongue and groove connections to create a desired wall height and thickness. In one embodiment, four wall panels  12  are connected together, and screws  16  pass through all four wall panels and into the tongue and groove connections at the point where the panels slide together. 
     A roof to wall connector  30  has a flange  32  connected along a top inner portion of a side wall panel  12 . Roof to wall connector  30  has a shelf  34  that overlies the top of the wall panel  12 . Shelf  34  is connected to flange  32 , and a riser  36  is connected to the shelf  34 . A roof support plate  38  extends at an angle to the riser  36  and is connected to an inside surface of the roof panel  14  with screws  16 . The roof to wall connector  30  extends continuously along one or more wall panels  12  and one or more roof panels  14 . 
     A roof ridge connector  40  is made of two identically shaped side plates  42  welded together at the inner edges  43 . The plates  42  in connector  40  have continuous roof connection plates  44  which extend between welded edges  43  and lower edges  45 . Flanges  46  extend inwards from the bottom side of roof panels  14 . A ceiling beam  48  extends between the flanges  46 . The plates  42  have roof end plates  50  which cover upper edges  15  of roof panels  14 . Extensions  52  that extend in an inward and upward direction may be joined and welded at their tops or may be covered by roof ridging material. Roof ridge beams  54  extend between edges  55  formed between the roof end plates  50  and the extension  52 . 
       FIG. 3  shows a roof ridge connector  40  that that runs along part of the length of the roof. The roof ridge connector  40  may be made of 16 gauge red iron steel or other material. The roof ridge connector  40  comprises components  56  and  57  that are similar in shape and may have identical dimensions. Components  56  and  57  are connected together by ceiling beam  48  and roof ridge beam  54 . The roof ridge connector is made of continuous 16 ga metal. Two are required for each beam. The connector is made of 16 ga red iron metal and runs the full length of the roof cove. It is made of two components. The drawing above shows both components. It takes two of these to make the beam. As you can see on the lower drawing, two of these beams are welded together to make the beam. A ¼″ by 1″ flat strap is welded to the components for support, one on the bottom and one on the top as see above. They are made to fit whatever roof pitch is needed for the structure. The top end of the panels are screwed through the beam into the 4 layers of the multiply in the panel to secure the panel to the structure. 
     The dimensions of the roof ridge connector  40  are customizable to fit whatever roof pitch desired for the structure. The roof plates  44  are connected by screws  16  which pass through the ceiling beam  48  into the four layers of the multiple roof panels to secure the roof ridge connector  40  to the roof panel  14 .  FIG. 2  shows to the connection of the roof ridge connector  40  to the roof panels  14 . Two or more screws  16  connect the wall panels  12  together. In one embodiment, these screws  16  are high tech 2,000 lb. shear strength screws measuring ¼″×1½″. 
       FIG. 4  shows a roof to wall connector  30  that may be composed of 16 gauge red iron or other material. The position of the roof to wall connector  30  can be seen in relation to the wall panels  12  and roof panels  14  in  FIG. 2 . Roof to wall connector  30  sits on the top of the wall panel  12  and connects the wall panel  12  to the roof panel  14 . The roof to wall connector  30  may run the total length of the wall panel  12  or a portion of the length of the wall panel  12 . The top linear portion of the roof to wall connector  30  is bent at an angle that facilitates the desired roof pitch of the building. The connector is made of 16 ga red iron. It sits on the top of the wall and connects the wall to the roof panel. The connector usually comes in 16 feet lengths and runs the total length of wall. The 5″ side is bent at the angle, depending on what the roof pitch is. There are ¼″×1½″ tech screws that are screwed through the multiply of the panel. The screws go through 4 layers of the tongue and groove at the point where the panels slide together. 
     The footer connector  20  in  FIG. 5  forms an “L” shape and may be made of 16 gauge red iron or other material. The position of the footer connector  20  can be seen in relation to the wall panels  12  and footer  22  in  FIG. 2 . The footer connector  20  is used to connect the wall panels  12  to the footer  22  and runs the total length or a part of the length of the wall panels  12 . The footer connector  20  is secured to the wall panels  12  on the interior surface of the structure by several screws  16 . The footer connector  20  is also connected to the footer  22  with bolts  23  which may be pre-installed in the footer, for example when the concrete of the footer is being poured. In one embodiment, the footer  22  has a 1½″×3″ step down to keep water from penetrating the foundation. Footer connectors  20  of varying dimensions may be used to prevent water ingress on buildings with varying dimensions. 
     Additionally, the footer connector  20  is used to connect the gable ends of the walls to the roof. The footer connector  20  runs the full length or a portion of the length of the walls panels  12  from the side wall to roof connector  40  to the ridge connector  50 . Footer connector  20  is secured to the wall panels  12  on the inside of the structure by screws  16 , which may have the same dimensions as the screws used to affix the wall panels  12  together. 
       FIG. 6  shows connector  60  that may be made of 16 gauge red iron. Connector  60  is made in the shape of a c-channel and is used to cap the top of the walls panels  12  and runs the total length of the wall panels  12 . Connector  60  is also used to box in window openings and door openings in the walls of the structure. Connector  60  is secured to the wall panels  12  on the interior surface of the modular structure with screws  16 . The connector is made of 16 ga red iron. It is made in the shape of a c-channel and is used to cap the top of the walls and runs the total length of the walls. It is also used to box in window openings and door openings. It is secured to the panels on the inside of the structure by ¼″×1½″ tech screws. These screws are inserted through 4 layers of the multiply, the area where the panels are slid together in the tongue and groove areas. 
       FIG. 7  shows footer to wall connector  70  that may be made of gauge red iron or other material. Footer to wall connector  70  is made in the shape of an “L” and is used to connect the wall panels  12  to other walls in the running vertical corners. Footer to wall connector  70  may run the entire length or a part of the length of each wall corner. Footer to wall connectors  70  are secured to the wall panels  12  on the inside of the structure with screws  16 . The connector is made of 16 ga red iron. It is made in the shape of a L and is used to connect the walls to the footer and runs the total length of the walls. It is secured to the panels on the inside of the structure by ¼″×1½″ tech screws. These screws are inserted through 4 layers of the multiply, the area where the panels are slid together in the tongue and groove areas. It is also connected to the footer with bolts pre-installed in the footer when the footer is being poured. The footer has a 1½″×3″ step down to keep water from penetrating the foundation. 
     This same connector is used to connect the gable ends of the walls the roof. It runs the full length of the walls from the side wall/roof connector to the ridge beam. It is secured to the panels on the inside of the structure by ¼″×1½″ tech screws. hese screws are inserted through 4 layers of the multiply, the area where the panels are slid together in the tongue and groove areas. 
     While the invention has been described with reference to specific embodiments, modifications and variations of the invention may be constructed without departing from the scope of the invention.