1. Field of the Invention
This disclosure relates to structures for buildings and in particular to methods for and apparatuses of layered structural components that connect to the exterior framing of a structure, the layered structural components provide insulation, drainage and support load bearing external façades.
2. Description of the Related Art
The connection of external facades to the external framing of a structure has been done by various methods to include the use of adhesives, nails and screws. The advent of polystyrene sheets necessitated new methods of connecting the relatively thick and light foam insulation to external framing because traditional nails, screws and adhesive fasteners do not provide a long term reliable connection of the foam insulation layer to the exterior framing. In particular, the effectiveness of insulation requires the continuity of the insulation and a firm continuous connection of the insulation to the exterior framing to properly insulate the structure. Innovations to address this problem included U-shaped channels that embed into the polystyrene insulation. The structure of the channels can vary, but they typically include a central plate with a pair of opposing flanges that extend from the central plate at an approximately ninety (90) degree angle. The junction between the flanges and central plate can further include structural enhancements such as corner beads. The depth in which the flanges of the channels embed into the insulation can vary greatly. Some channels are constructed to provide a stand-off or are alternatively employed with additional structural elements to define a stand-off from the insulation that defines a gap or dead space between layers of construction or a continuous series of layers. The U-shaped channels are typically nailed or screwed into the studs of the exterior framing.
Current construction specifications and building codes can require multiple layers to be connected together for insulation, fireproofing, moisture drainage and moisture resistance. These layers have varying thicknesses and structural attributes. Many external facades are relatively light weight such as vinyl siding and can be readily attached the exterior framing, but many external façades such as thin brick and tile require enhanced structural systems for the loads associated with their external façade. As a result, many systems for the connection of multiple layers of construction do not provide the required support for thin brick and tile external facades. Other systems for connecting the multiple layers have undesirable characteristics such as extending the multiple layers further away from the exterior framing and thereby distancing the load of the thin brick and tile an excessive distance from the exterior framing. Finally, there is often a credibility gap between the actual structure and the specified structure because of construction method short cuts and care made in the connectivity of the multiple layers. This results in nails and screws not being correctly connected to the external framing, but simply to the external sheathing. Nails and screws connecting to the external sheathing not provide long term reliable nail or screw connections that are demanded in modern highly insulative structures.
A structure connection system is needed that can support specification and building code requirements and provide support for a wide array of external facades. Heretofore, there has never been a compact system and method for rapidly connecting external layers to an external framing. The present disclosure provides a high quality connection system and method to readily assemble multiple layers, place the multiple layers under compression to provide structural support and retain the desired functions of the insulation, barrier, drainage mat and external façade components.
The structure connection system has flexibility in its application, but provides structural support for any type of external façade to include thin brick and tile under severe weather conditions. The structure connection system includes an array of separate backing plates that are connected to the exterior framing and extend in approximately horizontal rows perpendicular to the vertical studs. The backing plates overcome the need for an exact alignment of the nails and/or screws with the studs of the exterior framing and thereby aid in the rapid construction of a quality structure. Multiple layers are connected between a batten plate and the backing plate and placed in compression to provide a high integrity structure. The external façade of thin brick and tile is then connected to the batten plate.
A structure connection system for connecting an exterior façade to an exterior framing is described that comprises a first section and a second section. The first section preferably includes an exterior sheathing, a moisture resistant barrier, an insulation sheathing and a plurality of batten plates. The second section includes an external façade.
The exterior sheathing of the first section is a rigid flat panel that is adapted to be positioned against the exterior framing. The insulation sheathing is a thermal rigid insulation board sheathing that has a front approximately planar surface and a back approximately planar surface. Each batten plate of the plurality of batten plates is a right angle elongate plate. The right angle has a first elongate leg and a second elongate leg. The batten plate defines an elongate axis. The first leg of the batten plate has a first width normal to the elongate axis defined by the batten plate and the second leg has a second width normal to the elongate axis defined by the batten plate. The width of the first leg is equal to or greater than the width of the second leg. The second leg is inserted into the insulation sheathing and the first leg is positioned against the front planar surface of the insulation sheathing. Each batten plate of the plurality of batten plates is located in fixed spaced separation from the adjacent batten plate. A plurality of first fasteners connect the first section into an integrated assembly. The first fasteners connect to the batten plates and are adapted to connect the first section to the exterior framing. The first fasteners place the first section under compression.
The second section includes an external façade and a plurality of second fasteners. The plurality of second fasteners connect the external façade to the plurality of batten plates. The assembled first section and second section are connected to the external framing as a cantilever structure.
Referring initially to
The first section includes an arrangement of backing plates 12, exterior sheathing 14, a moisture resistant barrier 16 and insulation sheathing 18 and batten plates 20. A second section includes a drainage mat 22, a metal grid panel 24 and an outer surface covering 26. The first section connects to exterior framing 3 of exterior framing 3. The second section connects to the first section.
Backing plates 12 are preferably sheet metal strips or plates. Backing plates 12 are flat elongate plates. Backing plates 12 have a first side, a second side opposed to the first side, a third side and a fourth side opposed to the second side. The first side and second side of backing plates 12 preferably have a width that is approximately three (3) to six (6) inches. The third side and fourth side preferably have a thickness between approximately one sixteenth ( 1/16) and approximately three thirty-second ( 3/32) of an inch. The second sides of backing plates 12 interface with and connect to exterior framing 3. Backing plates 12 preferably extend approximately horizontal along external framing 3. The spacing and dimensions of backing plates 12 on external framing 3 can vary depending upon a desired application of structure connection system 10, but are preferably spaced at standard on-center vertical distance spacing such as for example approximately twelve (12), approximately sixteen (16) or approximately twenty-four (24) inches.
Backing plate 12 is preferably a thin flat galvanized sheet metal plate, but backing plate 12 can be fabricated of any suitable structural material to include structural composite materials. Backing plate 12 is preferably an elongate sheet metal strip that minimizes the horizontal depth of structure connection system 10 while providing adequate structural connectivity to exterior framing 3. The application of backing plates 12 to exterior framing 3 can also depend upon factors such as the dimensions of backing plates 12 and local building codes.
Backing plates 12 provide a structural connection across exterior framing 3 that advantageously expedites the assembly of the remaining layers of the first section of structure connection system 10. Backing plates 12 overcome the need for an exact alignment of the connection between the first section of structure connection system 10 and the relatively narrow width of standard sized studs 4 such as the approximate one and a half (1.5) inch actual side edge width of the standard two by four (2×4) or two by six (2×6) inch wood or metal stud 4 of exterior framing 3.
Exterior wall sheathing 14 connects directly to the front of backing plate 12 and/or exterior framing 3. Exterior wall sheathing or exterior sheathing 14 preferably provides both a structural and an insulative barrier. Exterior sheathing 14 can be any type of material for wall structural sheathing applications to include wood sheathing products such as plywood and oriented strand board, fiberboard (which as defined herein can include wood and/or non-cellulose fibers that can include other plant materials or recycled fibers) and masonry board.
In the preferred embodiment, exterior sheathing 14 is exterior grade wallboard sheathing. Depending upon the individual application of structure connection system 10, the material of exterior wall sheathing 14 has to be in compliance with local building codes to include, for example, water resistivity, water absorption, strength, structural stability, fire proof ratings and mold resistance for residential, industrial or commercial buildings. Exterior wall sheathing 14 is available in standard sizes such as, but not limited to four by eight (4×8) foot sheets. Standard thicknesses for exterior sheathing 14 include one-half (½) and five-eighths (⅝) inches, but it is understood that the thickness and overall height and width dimensions can vary depending upon factors such as building codes and a given application of structure connection system 10.
Moisture resistant barrier 16 is connected directly to exterior wall sheathing 14 and is preferably a combined air and moisture barrier. Moisture resistant barrier 16 provides enhanced drainage when subjected to extreme levels of wind and driving rains. Moisture resistant barrier 16 is preferably vapor permeable, but can be a low permeance barrier or vapor barrier depending upon the climatic conditions and internal environmental requirements. Types of moisture resistant, barrier 16 include building paper such as asphalt coated traditional paper or felt and polymeric-based barriers such as housewrap plastic sheet wrappings, moisture resistant barrier insulative sheathing and liquid applied building wrap. Moisture resistant barrier 16 can come in various forms as previously noted to include sheets of various sizes, rolls and as a liquid that can be applied by brush or spray. Depending upon the type and quality of exterior sheathing 14 as well as other factors, moisture resistant barrier can be optional in structure connection system 10.
Insulation 18 is a rigid insulation board sheathing that can vary in thickness depending upon the desired application. Insulation 18 has standard industry thicknesses that can vary from less than one (1) inch to four (4) or more inches. In the preferred embodiment, insulation 18 is closed cell, moisture-resistant rigid extruded polystyrene foam, board that is suitable for residential or commercial applications. Insulation 18 as a rigid board is also suitable for compressive load applications such as those applied by structure connection system 10. Insulation 18 can come in sheets of various sizes such as, but not limited to 4×8 foot sheets.
Each batten plate 20 is an elongate right angle plate. Batten plate 20 includes a first leg 20a and a second leg 20b that are connected along one of their respective elongate edges to define an elongate approximately ninety-degree (90°) angle. A longitudinal axis is defined by elongate batten plate 10. First leg 20a is preferably plate or flat shaped with a first width perpendicular to the elongate axis between second leg 20b and a free edge and the second leg 20b is preferably plate or flat shaped and has a second width perpendicular to the elongate axis between first leg 20a and a free edge. The first leg 20a defines a plurality of apertures that extend approximately through and approximately normal to the plane defined by first leg 20a. In the preferred embodiment, batten plate 20 first leg 20a has a width approximately between one and three-quarters (1¾) inch and approximately two (2) inches and second leg 20b has a width between approximately one-quarter (¼) and five-sixteenth ( 5/16) inch.
Batten plates 20 typically come in standard lengths such as four (4) or eight (8) foot lengths that can correspond to the dimensions of insulation 18. It is understood, that batten plates 20 can be fabricated in any dimensions, but are preferably flat elongate plates with a minimal second leg 20b width.
Batten plate 20 can be fabricated by any means to include, but not limited to formed, welded or cast. In the preferred embodiment, batten plate 20 is a fabricated of galvanized steel, but it is understood that batten plate 20 could be made of wide variety of materials to include other metals/metal alloys as well as low conductivity materials such as cellulose and composite materials to include ceramics and/or polymers. Batten plate 20 can also include one or more layers or coatings of low conductivity materials.
The second section includes a drainage mat 22 and external façade 21. In this preferred embodiment, external façade 21 includes a metal grid panel 24 and thin brick, stone or tile 26, but it is understood that other alternative external facades 21 such as, but not limited to siding, stucco and panels can be employed with structure connection system 10.
Drainage mat 22 connects directly to insulation 18 and/or batten plate 20. Drainage mat 22 can be positioned over and/or connect to batten plate 20. Drainage mat 22 can have a range of porous structures that accommodate the drainage liquids and the flow of air or a solid insulation barrier with surface channels for the downward flow of fluids. The drainage of liquids in drainage mat 22 is assisted by capillary action. Drainage mat 22 can vary from drainage paper that has a minimal thickness to thicker mat type structures with an exterior face that defines channels or pathways for water drainage. Drainage mat 22 has a structural integrity that preserves the pathways for fluid flow under compression. In addition, drainage mat 22 can be one or more layers and preferably does not absorb moisture, is not a food source for mold and has thermal resistance qualities.
Grid panel 24 is positioned directly against drainage mat 22. Grid panel 24 is a sheet with a front 18a that faces in an exterior direction and a back 20a (See
Grid panels 24 can vary in their dimensions and thickness of their construction. Grid panels 24 preferably have a rectangular conformation that is suitable for being connected together to form an array of grid panels 24, but can be fabricated to any dimensions for a particular construction. For example, standard grid panel 24 dimensions include between approximately forty-eight (48) and approximately ninety-six (96) inches by between approximately eight (8) inches and approximately twenty-four (24) inches by approximately eight (8) inches and approximately twenty-four (24). Grid panels 24 are preferably fabricated of rust resistant sheet metal, but grid panels 24 can be made of a variety of materials to include polymers, polymer composites and ceramics as well as metals. The dimensions of grid panel 24 can vary to accommodate the dimensions of the different sizes and shapes of materials of bricks 26.
Bricks 26 are commonly known as thin brick and tile, but can be natural materials such as stone or man-made materials that include man-made simulated stone as well as tile. Further, the height length dimensions of bricks 26 can vary. Bricks 26 are typically initially connected to grid panel 24 using an adhesive and the mortar is applied between bricks 26 to secure bricks 26 in position and provide a weatherproof, long-lasting external façade with an enduring visual appeal.
Structure connection system 10 is connected together as individual components and/or layers. Horizontal backing plates 12 are fastened to exterior framing 3 in fixed spaced separation in preferably horizontal rows. The distance between rows is preferably sixteen (16) or twenty-four (24) inches on center, but this can vary depending upon the intended application. The layers of exterior sheathing 14, moisture resistant barrier 16 and insulation 18 are temporarily connected in sequence to backing plates 12 using standard methods in the industry that can include bolts, nails and glue. It is understood that individual layers such as exterior sheathing, moisture resistant barrier 16 and insulation 18 can be prefabricated or replaced by materials that combine two or more of their functions in structure connection system 10.
A plurality of batten plates 20 are preferably connected to insulation sheathing 18 in an approximately parallel alignment at fixed spaced intervals. Batten plates 20 connect to insulation sheathing 18 and secure the first section to backing plates 12 as a cantilevered structure. Insulation sheathing 18 can define cuts or slots with a predefined depth and vertical separation that are configured to receive second leg 20b of batten plate 20. In the preferred embodiment, the free edge of second leg 20b is embedded in and has a friction connection with insulation 18.
Insulation 18 can further include a shallow cut configured to receive and/or align first leg 20a of batten plate 20 such that the outwardly facing side of first leg 20a is approximately aligned or flush with the outwardly facing planar surface of insulation 18. The cut for batten plate 20 can be made during the fabrication process or at the construction site. Similarly, the nature of insulation 18 as a rigid board material is such that the second leg 20b and first leg 20a can be manually pressed into insulation 18 and be approximately aligned with the outwardly facing planar surface of insulation 18. For example, the free edge of second leg 20b can be shaped with as an edge that facilitates the penetration of second leg 20b into insulation 18.
The first section is connected to backing plate 12 by first fasteners 30 that are positioned through batten plates 20, insulation 18, moisture resistant barrier 16, exterior sheathing 14 and backing plates 12. The first legs 20a of batten plates 20 preferably define a plurality of apertures 32 at predetermined locations along the elongate length of leg 20a. The location of each aperture 32 of the plurality of apertures 32 correlates with the spacing intervals for backing plates 12 for a particular structural application. First fasteners 30 are preferably screws that are received by apertures 32 of batten plates 20 and have sufficient length and hardness to penetrate through insulation 18, moisture resistant barrier 16, exterior sheathing 14, backing plate 12 and exterior sheathing 3. First fasteners 30 connect to batten plate 20 and place the first section in compression between batten plates 20 and backing plates 12. First fasteners 30 are preferably continuously threaded along their shank and suitable for power tool installation, cutting through and connection to backing plates 12. While batten plates 20 preferably include a plurality of apertures 32, the tip of first fastener or fastener 30 can also be used to cut through batten plates 20, backing plate 12 and exterior framing 3.
The resistance to thermal conductivity of the first section is enhanced by the arrangement of the different layers of the first section and the relative thermal isolation of fasteners 30 that connect the first section to exterior framing 3 through apertures 32 in backing plate 12. The plurality of apertures 32 in batten plates 20 preferably include thermal isolation inserts 33 that are positioned in apertures 32 and can extend along first leg 20a. Inserts 33 to provide a physical insulative barrier between batten plate 20 and fastener 30. The physical insulative barrier between batten plate 20 and fastener 30 is thermal break that resists the undesirable transfer of heat or cold within structure connection system 10. Inserts 33 as defined herein extended sleeves to provide additional thermal isolation.
Batten plates 20 are approximately vertically aligned and located at horizontal intervals along backing plates 12. Batten plates 20 preferably connect to backing plates 12 at approximately twelve (12) inch, sixteen (16) inch or approximately twenty-four (24) inch intervals depending upon factors such as the on-center distance between the studs 4 of exterior framing 3. Batten plates 20 can be connected to backing plates 12 and/or exterior framing 3 at any location relative to studs 4 to include in approximate alignment with studs 4 or at any other location on backing plates 12 relative to studs 4. The intervals or spacing between batten plates 20 can vary depending upon the desired application of structure connection system 10.
Backing plates 12 provide a structural element across exterior framing 3 that advantageously provides for an expedited the rapid assembly of structure connection system 10. Backing plates 12 overcome the need for an exact alignment of the connection between the first section of structure connection system 10 and the relatively narrow one and a half (1.5) inch width of the side edge of the standard metal or wood two (2) by four (4) inch stud 4 or other structural elements of exterior framing 3. Further, while studs 4 of exterior framing 3 are typically spaced in standard twelve (12) sixteen (16) or twenty-four (24) inches on center, in many instances the actual fixed spaced separation of studs 4 of exterior framing 3 varies during the normal course of construction. This variation in the on-center distance can be significant relative to the narrow width of studs 4 and the need to make solid connections between structure connection system 10 and exterior framing 3. In contrast, the present disclosure employs fasteners 30 to connect batten plates 20 to the approximately three (3) to six (6) inch width of backing plates 12. Further, backing plates 12 are positioned in an approximately horizontal alignment and vertically spaced at a standardized distance such as approximately sixteen (16) or approximately twenty-four (24) inches on center accommodate a much more rapid construction with greater structural integrity.
Continuing with the preferred embodiment, drainage mat 22 and grid panels 24 of the second section are preferably initially connected to the first section by adhesive. A plurality of second fasteners 34 connects grid panels 24 and drainage mat 22 to the first leg 20a of batten plates 20. Second fasteners 34 are preferably screwed through existing apertures in grid panels 24 and have a metal cutting tip that is suitable to cut through drainage mat 22 and batten plates 20. This structural arrangement aids in the speed of assembly of the second section to the first section of structure connection system 10 by creating larger target areas for first section fasteners 30 to backing plate 12 and second section second fasteners 34 to batten plate 20. In addition, the separate layers add flexibility and efficiency when they are required to be cut and/or bent to accommodate building structural variations such as window and door openings as well as corners. The head and shaft of second fasteners 34 can further include an insulative coating, sleeves, inserts and/or washers to lessen the thermal conductivity of second fasteners 34.
Batten plate 20 second leg 20b is preferably inserted into insulation 18. Second leg 20b is preferably fully inserted into insulation 18 such that the inwardly directed side of first leg 20a directly abuts insulation 18. In addition, insulation 18 can include a channel slot that receives and positions first leg 20a approximately flush with the external surface of insulation 18. The depth of the channel slot can further include the head of fasteners 30 that are inserted into insulation 18 to define an approximately flush outwardly facing surface with insulation 18 for the application of drainage mat 22 and grid panels 24 as a plane. It is understood that most drainage mats 22 configurations have sufficient thickness and structure to flexibly accommodate first leg 20a positioned on the outer surface of insulation 18 without being indented therein and still retain a planar configuration for grid panels 24. It is critical for the long term reliability and weather protection that the external façade be constructed to define as true of a flat plane as practical without waves or any form of undulations.
Referring now to
The front faces 18a of grid panels 24 define partitions 36, 38, 40 and 42 that are cantilever beams that extend between lateral edges 22a and 22b and outwardly from front 18a. Partitions 36, 38, 40 and 42 define three (3) approximately U-shaped channels 30a, 32a and 34a, respectively there between that receive thin bricks 26. The opening for each channel 30a, 32a and 34a is directed outward from and is approximately perpendicular to front face 18a.
Grid panel 24 upper edge 26a and lower edge 28a as well as partitions 36, 38, 40 and 42 are aligned with a longitudinal axis-X. Grid panel 24 lateral edges 22a and 24a are aligned with axis-Y that is perpendicular to longitudinal axis-X. It is understood that as described herein the axis-Y is a vertical axis and axis-X is a horizontal axis. Axes X and Y define a plane that is aligned with grid panel 24. It is also understood that the terms up, upward or the upward direction is defined as approximately vertical movement in the direction from lower edge 28a towards upper edge 26a. The terms down, downward or the downward direction is defined as approximately vertical movement in the direction from upper edge 26a towards lower edge 28a. The terms inward, inward direction or inwardly are defined as approximately in the direction perpendicular to grid panel back 20a and towards exterior framing 3. Similarly, the terms outward, outward direction and outwardly are defined as approximately in the direction perpendicular to grid panel front 18a and out or away from exterior framing 3. It is understood that grid panels are typically installed along a level horizontal line, but that grid panels 24 can be installed at an acute angle from the horizontal.
Channel 30a is defined by partition 40, partition 36 and wall 37. Channel 32a is defined by partition 36, partition 38 and wall 39. Channel 34a is defined by partition 38, partition 42 and wall 41. Walls 37, 39 and 41 are approximately aligned with front 18a and plane X-Y. In this one preferred embodiment, partitions 36a and 38a are positioned equidistantly between partition 40a and partition 42a. Partition 40a includes lower edge 28a and partition 42a includes upper edge 28a.
Partition 38 is preferably a V-shaped fold in sheet 24 that protrudes outwardly from front 18a. Partition 38 includes an upward facing first portion 38a and a downward facing second portion 38b joined at a fold or an edge 38c. Portion 38a defines a ledge that preferably inclines downward from wall 41 to edge 38c. The angle of inclination of portion 38a from the perpendicular to wall 41 can vary and/or be arcuate, but preferably defines a slope from the horizontal for the downward flow of water. Portion 38b is inclined downward from edge 38c to wall 39. The angle of inclination of portion 38b from the perpendicular to wall 39 can vary and/or be arcuate, but defines a slope from the horizontal for the downward flow of water to back 20a. The gap between portions 38a and 38b preferably increases from edge 38c to front 18a to define the approximate V-shape of partition 38.
Upwardly facing portion 38a is a support structure for the thin bricks and includes at least one drainage aperture 44 that is a through hole in grid panel 24. At least one aperture 44 is preferably a plurality of apertures 44 that is arranged in a fixed spaced separation along portion 38a. In this one preferred embodiment, the arrangement of the plurality of apertures 44 is approximately aligned with partition 38 and the longitudinal axis-X. As shown by exemplary axes A and C, the location of each aperture 44 defines a vertical axis aligned with axis-Y. In this preferred embodiment, at least a portion of each aperture 44 extends from portion 38a onto wall 41 of channel 34. Each aperture 44 has a downwardly directed angle of orientation that is an acute offset from the vertical axis and directed inwardly.
Individual apertures 44 are preferably defined by rectangular shaped rims with an approximately three-quarter (¾) inch longitudinal length and approximately one-quarter (¼) inch lateral length. Apertures 44 are preferably spaced at approximately one and one-quarter (1¼) inch intervals between lateral edges. As described above, the rims of apertures 44 on portion 38a preferably extend across and onto the adjoining wall 41. The lower second portion 38b of the V-shaped partition 38 is a solid wall that is impermeable to fluids. Apertures 44 defined in upward facing portion 38a are vertically aligned with solid wall downwardly facing portion 38b.
Partition 36 preferably has the same V-shaped folded structure as partition 38 with an upward facing first portion 36a and a downward facing second portion 36b joined at a fold or an edge 36c. Portion 36a defines a ledge that inclines from wall 39 to edge 36c. The angle of inclination of portion 36a from the perpendicular to wall 39 can vary and/or be arcuate, but preferably defines a slope from the horizontal for the downward flow of water. Portion 36b is inclined downward from edge 36c to wall 37. The angle of inclination of portion 36b from the perpendicular to wall 37 can vary and/or be arcuate, but defines a slope from the horizontal for the downward flow of water. The gap between portions 36a and 36b preferably increases from edge 36c to front 18 to define the approximate V-shape of partition 36.
Upwardly facing portion 36a is a support structure for thin brick and includes at least one drainage aperture 46 that is a through hole in grid panel 24. At least one aperture 46 is preferably a plurality of apertures 46 that is arranged in a preset fixed spaced separation along portion 36a. In this one preferred embodiment, the arrangement of the plurality of apertures 46 is approximately aligned with partition 36 and the longitudinal axis-X. As shown by exemplary axes B and D, the location of each aperture 46 defines a vertical axis aligned with axis-Y. In this preferred embodiment, at least a portion of each aperture 46 extends from portion 36a onto wall 39 of channel 32. Each aperture 46 has a downwardly directed angle of orientation that is an acute offset from the vertical axis and directed inwardly.
Individual apertures 46 are preferably defined by rectangular shaped rims with an approximately three-quarter (¾) inch longitudinal length and approximately one-quarter (¼) inch lateral length. Apertures 46 are preferably spaced at approximately one and one-quarter (1¼) inch intervals between lateral edges. As described above, the rims of apertures 46 on portion 36a preferably extend across and onto the adjoining wall 39. The lower second portion 36b of the V-shaped partition 36 is a solid wall that is impermeable to fluids. Apertures 46 defined in upward facing portion 36a are vertically aligned with solid wall downwardly facing portion 36b.
Partition 40 preferably has the same V-shaped folded structure as that of partitions 36 and 38. Partition 40 includes an upward facing first portion 40a and a downward facing second portion 40b joined at a fold or an edge 40c. Portion 40a defines a ledge that inclines from wall 37 to edge 40c. The angle of inclination of portion 40a from the perpendicular to wall 37 can vary and/or be arcuate, but preferably defines a slope from the horizontal for the downward flow of water. Portion 40b is inclined downward from edge 40c to a terminal free end or lower edge 28 of grid panel 24. The angle of inclination of portion 40b from the perpendicular can vary and/or be arcuate, but claims a slope from the horizontal for the downward flow of water. The gap between portions 40a and 40b preferably increases from edge 40c to front 18 to define the approximate V-shape of partition 40.
Upwardly facing portion 40a is a support structure for the thin bricks and includes at least one drainage aperture 48 that is a through hole in grid panel 24. At least one aperture 48 is preferably a plurality of apertures 48 that is arranged in a fixed spaced separation along portion 40a. In this one preferred embodiment, the arrangement of the plurality of apertures 48 is approximately aligned with partition 40 and the longitudinal axis-X. As shown by exemplary axes A through D, the location of each aperture 48 defines a vertical axis aligned with axis-Y. In this preferred embodiment, at least a portion of each aperture 48 extends from portion 40a onto wall 37 of channel 30a. Each aperture 48 has a downwardly directed angle of orientation that is an acute offset from the vertical axis and directed inwardly.
Individual apertures 48 are preferably defined by rectangular shaped rims with an approximately one-half (½) inch longitudinal length and approximately one-quarter (¼) inch lateral side length. Apertures 48 are preferably spaced at approximately one-half (½) inch intervals between lateral edges. As described above, the rims of apertures 48 on portion 40a preferably extend across and onto the adjoining wall 37. The lower second portion 40b of the V-shaped partition 40 is a solid wall that is impermeable to fluids. Apertures 48 defined in upward facing portion 40a are vertically aligned with solid wall downwardly facing portion 40b.
Partition 42 is located along upper side edge 26a and is preferably includes a single fold with a free end that extends at an acute angle upwardly. Partition 42 is configured to interface with the partition 40 located along lower longitudinal side edge 28a such that an array of grid panels 24 can be connected. Partition 42 can also have the same or alternative variation of the V-shaped folded structure as partitions 36, 38 and 40 and retain the same interface with partition 40.
As shown in
Apertures 44, 46 and 48 are described herein as having rectangular rims and being linearly aligned at fixed intervals along partitions 36, 38 and 40. It is understood, however, that the rims of apertures 44, 46 and 48 can take any shape, such as for example circular, polygons or slots that extend onto at least part of portions 36a, 38a and 40a and remain within the scope of the present disclosure. Similarly, the arrangement of apertures 44, 46 and 48 can vary in their intervals and alignments and remain within the scope of this disclosure. Apertures 44, 46 and 48 are configured and located to enhance the transfer of moisture from front face 18a through apertures 44, 46 and 48 onto their respective partitions 38b, 36b and 40b and down rear face 22a of grid panels 24. In the preferred embodiment, apertures 44, 46 and 48 are punched through grid panel 24 from front face 18a towards rear face 20a. This important manufacturing difference leaves an inwardly directed taper around the perimeter of each aperture that facilitates the flow of moisture into apertures 44, 46 and 48 and onto the back of grid panel 24 and/or into drainage mat 22. This construction in combination with the straight sided rectangular shape of apertures 44, 46 and 48 further facilitates the passages of moisture or water through apertures 44, 46 and 48 and downward onto the back of grid panel 24.
Partition 42 can have the same approximate structure as that of partitions 36, 38 and 40 or alternatively have a structure that is a simple cantilevered beam that bounds the upper side of channel 34. The cantilevered beam of partition 42 has an upward facing side 42a and a downward facing side 42b and preferably inclines upward from wall 41 to upper edge 26 of grid panel 24. Partition 42 is preferably a liquid impermeable partition, but partition 42 can also include one or more apertures. The angle of inclination of partition 42 from the perpendicular to wall 41 can vary and/or be arcuate, but preferably defines a slope from the horizontal for the downward flow of water. Partition 42 or first connector 42 also preferably functions to connect with other sheets 12.
The distance between partitions 36, 38, 40 and 42 can vary depending upon the intended application of grid panel 24. For example, standard distances between partitions can include 2¾, 2½, 2¾, 3⅝ and 7⅝ inches. It is understood, however that the distance between partitions can be varied for any desired application to include variations from the above-identified standard distances and can further include variations in the distance between partitions to facilitate dimensional design variations in thin brick styles such as stone or simulated stone applications.
Sheets 12 are connected together in an arrangement by positioning partition 42 in the gap between portions 40a and 40b of partition 40 of another grid panel 24. Similarly, partition 40 receives a partition 42 from another grid panel 24 such that sheets 12 can connect across a drainage panel 14 and/or support structure 16 of a wall.
Grid panel 24 also includes a plurality of apertures or through holes 60 in channel 34a, 62 in channel 32a and 64 in channel 30a. Apertures 60, 62 and 64 are preferably defined by rectangular rims with the elongate axis aligned with axis-X. In one preferred embodiment apertures 60, 62 and 64 are covered with double-faced tape or used in conjunction with adhesive to temporarily connect the thin bricks 26 positioned on each ledge or partition 36a, 38a and 40a during the laying of thin bricks 26. The tape and/or adhesive temporarily lock thin bricks 26 in place on grid panel 24. Joint mortar is applied around the thin bricks 26 to permanently attach the thin bricks 26 the grid panel 24. Mortar tie apertures 110, 112 and 114 are preferably formed as partial punches in walls 41, 39 and 37 respectively and assist in the strength of the connection between the mortar, thin bricks 26 and grid panel 24. Mortar tie apertures 110, 112 and 114 are preferably positioned at approximately two and one-half (2½) to three (3) inch intervals to facilitate the anchoring of the joint mortar and thin brick or tile in position in channels 34a, 32a and 30a.
The height and length dimensions of grid panels 24 can vary depending upon the intended application of structure connection system 10. Factors include the dimensions of drainage mat 22, size of thin bricks 26 and the exterior framing. In one preferred embodiment grid panels or sheets 24 range in dimensions from approximately eight (8) to twelves (12) inches in height and from forty-eight (48) to ninety-six (96) inches in length. It is understood that sheets of grid panels 24 can be fabricated in any dimensions to meet any particular construction need to include larger dimensions of 10 feet by 12 feet, for example. Sheets 12 are preferably made of corrosion resistant sheet metal, but sheets 12 can also be fabricated of other materials such as polymers or composites.
Referring now to
As shown in
Referring now to
As shown in
Referring now to
Batten plates 20 are connected to exterior framing 3 as described previously (See
The external façade, such as horizontal siding, is connected to batten plates 20 using fasteners 34 as described previously. The spacing between batten plates 20 can be driven by many different factors to include the type of external façade 21.
As shown in
Fasteners 30 connect the first section into an integrated assembly against backing plates 12 and/or the exterior framing 3 of the external structure. The threads of fasteners 30 assist in the placing of the layers of the first section in compression between the plurality of batten plates 20 and backing plate 12 and/or exterior framing 3. The rigidity of the first section is such that the connection provided by fasteners 30 supports the first section as a cantilevered assembly connected to exterior framing 3. The connection between fasteners 30 into and through the apertures 32 of batten plates 20 include inserts 33 that provide a thermal break.
The second section connects to the plurality of batten plates 20 and is supported by the connection of the first section to the exterior framing 3. Second fasteners 34 connect the external façade and drainage mat 22, when present, to batten plates 20. In the preferred embodiment, the second section includes grid panels 24 and fasteners 34 extend through grid panels 24 and drainage mat 22 to securely connect the grid panels 24 to the exterior framing 3 as an extension to the existing cantilevered first section.
Grid panels 24 provide a unique fluid flow system that provides enhanced fluid flow behind grid panels 24 for the dissipation of fluids from on or behind grid panels 24. When grid panel 24 comes in contact with a fluid such as water for example that can be in the form of vapor, moisture penetration, water intrusion or condensation, the water is provided defined avenues of direction downward from grid panel 24 as shown by exemplary axes A, B, C and D as shown in
The water that drains down front 18a of grid panel 24 that is not collected by aperture 44, for example, passes down to wall 39 and/or partition 36 and through apertures 46 and is redirected by portion 36b to the back side of grid panel 24. Alternatively, draining water that is missed by apertures 44 and 46 is received into and redirected by the increased number of apertures 48 on partition 40. When grid panel 24 is connected with other grid panels 24 and partition 42 is positioned between portions 40a and 40b, partition 42 can be positioned and inclined to provide a redirection of drainage or liquid to back 20. It is the intended function of apertures 44, 46 and 48 to redirect the water or other liquid from front 18a of grid panel 24 to back 20a and/or drainage mat 22 when present.
Grid panels 24 are specifically constructed to remove potential barriers for the downward travel of water and eliminate areas that can accumulate water due to the angle of partitions 36, 38, 40 and 42 and walls 37, 39 and 41. For example, grid panel 24 apertures 44, 46 and 48 are preferably punched in the manufacturing process from the front 18a to the back of grid panel 24. The punching process creates a lip on the opposing back side from the punch. The front to back punch direction provides for smooth uninterrupted fluid flow from the front 18a of the grid panel 24 to the back side. In contrast, the standard industry process punches from the rear to the front and creates an undesirable lip that redirects fluid flow around the apertures. The arrangement of apertures 44, 46 and 48 advantageously redirects water from diverse paths of fluid flow on front 18a through apertures 44, 46 and 48 to the back side of grid panel 24. In addition, the preferably angular shaped rims of apertures 44, 46 and 48 of grid panels 24 aid in the drainage of water through grid panels 24 over arcuate shaped apertures. The water from grid panels 24 is collected and drained at the base of the structure. Further, grid panel 24 has a structure that reduces the likelihood of the undesirable growth of mold and mildew through the use of sloped surfaces that preclude the pooling of liquids and apertures that advantageously provide a plurality of paths for air to circulate through grid panel 24.
In the preceding specification, the present disclosure has been described with reference to specific exemplary embodiments thereof. It will be evident, however, that various modifications, combinations and changes may be made thereto without departing from the broader spirit and scope of the invention as set forth in the claims that follow. In addition, though the present invention is described in terms of a series of embodiments, each embodiment of the present invention can combine one or more novel features of the other embodiments. The specification and drawings are accordingly to be regarded in an illustrative manner rather than a restrictive sense.
Number | Name | Date | Kind |
---|---|---|---|
800655 | Kitsee | Oct 1905 | A |
830313 | Penn | Sep 1906 | A |
874909 | Fischer et al. | Dec 1907 | A |
1850961 | Mortenson | Mar 1932 | A |
1861359 | Pyron | May 1932 | A |
1946690 | Haines | Feb 1934 | A |
1994644 | Harshberger | Mar 1935 | A |
2005380 | Marsh | Jun 1935 | A |
2043706 | Myers | Jun 1936 | A |
2054573 | Mendenhall | Sep 1936 | A |
2078069 | Eliel | Apr 1937 | A |
2114451 | Mattes | Apr 1938 | A |
2202568 | Worden | May 1940 | A |
2243339 | Henzel | May 1941 | A |
2870624 | Sampson | Jan 1959 | A |
3270473 | Smith | Sep 1966 | A |
3353315 | Barker | Nov 1967 | A |
3387422 | Wanzer | Jun 1968 | A |
3533206 | Passeno, Jr. | Oct 1970 | A |
3740911 | O'Leary | Jun 1973 | A |
3868801 | Weiner | Mar 1975 | A |
3962504 | Sherwin | Jun 1976 | A |
4333290 | Koberstein | Jun 1982 | A |
4589241 | Volpenhein | May 1986 | A |
4619090 | McManus | Oct 1986 | A |
4662140 | Porter | May 1987 | A |
4741137 | Barratt | May 1988 | A |
4956949 | Francis | Sep 1990 | A |
5113631 | diGirolamo | May 1992 | A |
5226273 | Burke | Jul 1993 | A |
5313753 | Sanger | May 1994 | A |
5367847 | Hepler | Nov 1994 | A |
5381635 | Sanger | Jan 1995 | A |
5566517 | Ishii et al. | Oct 1996 | A |
5660907 | Skalka | Aug 1997 | A |
5667190 | Scott | Sep 1997 | A |
5715637 | Hesterman | Feb 1998 | A |
5799462 | McKinney | Sep 1998 | A |
5865001 | Martin | Feb 1999 | A |
5953883 | Ojala | Sep 1999 | A |
6003278 | Weaver | Dec 1999 | A |
6058672 | McClellan | May 2000 | A |
6138423 | Poutanen | Oct 2000 | A |
6186469 | Scott | Feb 2001 | B1 |
6240691 | Holzkaemper et al. | Jun 2001 | B1 |
6421972 | Dalphond et al. | Jul 2002 | B1 |
6725616 | Pease | Apr 2004 | B1 |
6786015 | Wilt | Sep 2004 | B2 |
6857237 | Dalphond et al. | Feb 2005 | B1 |
6892507 | Pease | May 2005 | B1 |
6951086 | Passeno | Oct 2005 | B2 |
7424789 | Zhou | Sep 2008 | B2 |
7493732 | Brailsford | Feb 2009 | B2 |
7617646 | Losse | Nov 2009 | B2 |
7743569 | Schwalenberg | Jun 2010 | B1 |
8141310 | Trezza | Mar 2012 | B2 |
8429866 | Knight et al. | Apr 2013 | B2 |
8555583 | Ciuperca | Oct 2013 | B2 |
8572918 | Zhou | Nov 2013 | B1 |
8820016 | Zhou | Sep 2014 | B2 |
8833023 | Masure et al. | Sep 2014 | B2 |
8925269 | Beaudin | Jan 2015 | B1 |
8962088 | Shaw | Feb 2015 | B2 |
8966845 | Ciuperca | Mar 2015 | B1 |
20100058700 | LeBlang | Mar 2010 | A1 |
20110197537 | Oberg | Aug 2011 | A1 |
Entry |
---|
Code Compliant Continuously Insulated Exterior Wall Assembly by Knight Wall Systems dated Jun. 19, 2013. |