This invention relates to construction.
More particularly, the invention relates to a method and apparatus for assembling a strong, lightweight thermal panel.
In a further respect, the invention relates to a method and apparatus for quickly assembling a thermally insulated building structure.
For many years, residential and other building structures have been constructed by erecting a frame consisting of two by fours and other wood lumber, and by mounting sheet rock and other siding and insulation on or between the two by fours. One conventional disadvantage of wood frames is that they are susceptible to termite damage. Another disadvantage is that the wood currently used to build wood frames often is relatively “young” and not fully cured, which increases the likelihood the wood will warp after it is installed and after sheet rock and other siding is mounted on the wood. A further disadvantage of wood frames is that they are, because of wood shortages, becoming increasingly expensive. Another disadvantage of wood frames is that they are labor intensive. Still a further disadvantage of wood frames is that they are hydrophilic. Still another disadvantage of wood frames is that they tend to be permeable to heat.
Another construction technique, commonly found in commercial buildings, is the use of metal studs to construct interior, non-load bearing walls. Such metal studs ordinarily are not utilized for exterior walls because they are excellent transmitters of heat and because they are not strong enough to be utilized to construct a load bearing wall. Like wood frames, frames constructed with metal studs also tend to be labor intensive.
Accordingly, it would be highly desirable to provide an improved construction system which would minimize labor, would minimize the transmission of heat into or out of a building structure, would provide load bearing walls, would simplify construction, and would resist damage by insects.
Therefore, it is a principal object of the invention to provide an improved construction method and apparatus.
Another object of the invention is to provide structural panels which can be interchangeably utilized for the roof or wall of a structure.
A further object of the invention is to provide a construction system which permit the exterior walls and roof of a home to be erected in a single day.
These and other, further and more specific objects and advantages of the invention will be apparent to those of skill in the art from the following detailed description thereof, taken in conjunction with the drawings, in which:
Briefly, in accordance with the invention, I provide an improved structural panel for a building. The panel includes at least first and second stud members each comprising an elongate member. Each stud member includes a neck having a selected thickness, a front, a back, a first elongate side, a second elongate side, and a cross-sectional area; includes a plurality of openings formed through the neck intermediate the first and second elongate sides and having a cumulative cross-sectional area and a cumulative area normal to the cumulative cross-sectional area, the cumulative cross-sectional area of the openings being at least equal to the cross-sectional area of the neck; and, includes a plurality of venturi bridges each adjacent at least one of the openings and extending from the first elongate side to the second elongate side of the stud. The venturi bridges have a cumulative cross-sectional area less that the cumulative cross-sectional area of the plurality of openings; a cumulative surface area on the front of the neck; and, a cumulative surface area on the back of the neck. Each stud member also includes at least one flange outwardly projecting from one of the sides of the neck. Each of the stud members is comprised of at least one metal having a thermal conductivity greater than 0.030 g-cal/(sec.)(sq. Cm.)(degree C./cm.) at eighteen degrees Centigrade. The panel also includes a foam panel having an outside face; an inside face; a top; a bottom; a first edge having a surface area extending between the inside face and the outside face and adjacent the front of the neck of the first stud member to form a first structural and thermal transmission interface; and, a second edge having a surface area extending between the inside face and the outside face and adjacent the back of the neck of the second stud member to form a second structural and thermal transmission interface. The ratio of the surface area of the first edge to the cumulative area of the openings in the neck of the first stud is in the range of 10:1 to 1.33:1 to limit the transmission of heat from the first stud to the first edge. The ratio of the portion of the surface area of the first edge to the cumulative surface area of the venturi bridges on the front of the neck of the first stud is in the range of 25:1 to 4:1 to limit the transmission of heat from the first stud to the first edge.
In another embodiment of the invention, I provide an improved lightweight substantially rigid shear-resistant structural panel for a building. The panel includes at least first and second stud members each comprising an elongate member. Each stud member includes a top; a bottom; a neck having a selected thickness, a front, a back, a first elongate side, a second elongate side, and a cross-sectional area; a plurality of openings formed through the neck intermediate the first and second elongate sides and having a cumulative cross-sectional area, the cross-sectional area of the openings being at least equal to the cross-sectional area of the neck; and, a plurality of venturi bridges each adjacent at least one of the openings and extending from the first elongate side to the second elongate side of the stud. The venturi bridges have a cumulative cross-sectional area less that the cross-sectional area of the plurality of openings; a cumulative surface area on the front of the neck; and, a cumulative surface area on the back of said neck. Each stud member also includes a first flange outwardly projecting from the first elongate side of the neck; and, a second flange outwardly projecting from the second elongate side of the neck and spaced apart from and opposed to the first flange. Each of the stud members is comprised of at least one metal having a thermal conductivity greater than 0.030 g-cal/(sec.)(sq. Cm.)(degree C./cm.) at eighteen degrees Centigrade. The wall panel also includes a foam panel having an outside face; an inside face; a top; a bottom; a first edge having a surface area extending between the inside face and the outside face, adjacent the front of the first stud member to form a first structural and thermal transmission interface, and between the first and second flanges of the first stud member; and, a second edge having a surface area extending between the inside face and the outside face, adjacent the back of the second stud member to form a second structural and thermal transmission interface, and between the first and second flanges of the second stud member. The wall panel also includes a first support member extending along the top of the foam panel between the first and second stud members. The support member includes a first end connected to the top of the first stud member and a second end connected to the top of the second stud member. The wall panel also includes a second support member extending along the bottom of the foam panel between the first and second stud members. The second support member includes a first end connected to the bottom of the first stud member and a second end connected to the bottom of the second stud member.
In a further embodiment of the invention, I provide an improved building construction. The building construction includes a wall; and, a thermally insulated roof having a slope greater than 2/12 and including a plurality of spaced apart metal studs with thermally insulative foam panels interposed between the studs, the studs being shaped and dimensioned to engage and support the panels between the studs.
In still another embodiment of the invention, I provide an improved method of constructing an enclosed thermally sealed building structure. The method includes the steps of constructing a wall including a top, a plurality of spaced apart metal studs, and, a plurality of thermally insulative foam panels interposed between said metal studs; constructing a roof including a plurality of elongate metal support members, and a plurality of thermally insulative foam panels interposed between said metal support members; installing the wall at a selected construction site; and, installing the roof on the wall such that a portion of the foam panels in the roof are adjacent the top of the wall and a portion of the foam panels in the wall to form a thermal seal between the roof and the top of the wall.
In still a further embodiment of the invention, I provide an improved method of reducing the thermal conductivity of a structural panel for a building. The wall includes at least first and second stud members each comprising an elongate member including a neck having a selected thickness, a front, a back, a first elongate side, a second elongate side, and a cross-sectional area; and, at least one flange outwardly projecting from one of the sides of the neck. Each of the stud members is comprised of at least one metal having a thermal conductivity greater than 0.030 g-cal/(sec.)(sq. Cm.)(degree C./cm.) at eighteen degrees Centigrade. The wall also includes a foam panel having an outside face; an inside face; a top; a bottom; a first edge having a surface area extending between the inside face and the outside face and adjacent the front of the first stud member to form a first structural and thermal transmission interface; and, a second edge having a surface area extending between the inside face and the outside face and adjacent the back of the second stud member to form a second structural and thermal transmission interface. The improved method includes the steps of forming a plurality of openings through the neck of at least the first stud member intermediate the first and second elongate sides and having a cumulative cross-sectional area and a cumulative area normal to the cumulative cross-sectional area; and, forming a plurality of venturi bridges in at least the first stud member. Each venturi bridge is adjacent at least one of the openings and extends from the first elongate side to the second elongate side of the stud. The venturi bridges have a cumulative cross-sectional area less that the cumulative cross-sectional area of the plurality of openings; a cumulative surface area on the front of the neck; and, a cumulative surface area on the back of the neck. The ratio of the portion of the surface area of the first edge adjacent the cumulative surface area of the venturi bridges on the front of the neck of the first stud is in the range of 25:1 to 4:1 to limit the transmission of heat from the first stud to the portion of the first edge extending from the openings in the first stud and venturi bridges in the first stud to the inside face of the foam panel.
In yet still a further embodiment of the invention, I provide an improved method of producing a strong, lightweight metal stud that minimizes the transmission of heat through the stud and resists forces that act to bend the stud. The method includes the steps of providing a thin elongate metal panel having a thickness and comprised of at least one metal having a thermal conductivity greater than 0.030 g-cal/(sec.)(sq. Cm.)(degree C./cm.) at eighteen degrees Centigrade; forming a plurality of openings through the panel to produce a plurality of venturi bridges each adjacent at least one of the openings; and, bending the panel. Bending the panel forms a neck having a thickness equal to said thickness of said metal panel; a front; a back; a first elongate side; and, a second elongate side. The plurality of openings are formed through the neck intermediate the said first and second elongate sides and have a cumulative cross-sectional area and a cumulative area normal to the cumulative cross-section area. The plurality of venturi bridges each extend from the first elongate side to the second elongate side of the stud. The venturi bridges each have a cumulative cross-sectional area less that the cross-sectional area of the plurality of openings; have a cumulative surface area on the front of the neck; and, have a cumulative surface area on the back of the neck. Bending the panel also forms a first flange outwardly projecting from the first elongate side of the neck and having a thickness at least twice the thickness of the metal panel; and, forms a second flange outwardly projecting from the second elongate side of the neck, spaced apart from and opposed to the first flange, and having a thickness at least twice the thickness of the metal panel.
In yet still another embodiment of the invention, I provide an improved method of producing a structural panel for a building. The method includes the step of providing at least first and second stud members each comprising an elongate member. Each stud member includes a neck having a selected thickness; a front; a back; a first elongate side; and a second elongate side. Each stud member also includes at least one flange outwardly projecting from one of the sides of the neck. Each of the stud members is comprised of at least one metal having a thermal conductivity greater than 0.030 g-cal/(sec.)(sq. Cm.)(degree C./cm.) at eighteen degrees Centigrade. The method also includes the step of providing a foam panel. The foam panel has an outside face; an inside face; a top; a bottom; a first side having a surface area and having a pair of spaced apart edges; and, a second side having a surface area and having a pair of spaced apart edges. The method also includes the step of positioning the foam panel intermediate the first and second metal stud members such that a portion of the first side extends between the inside face and the outside face and adjacent the front of the first stud member to form a first structural and thermal transmission interface; such that one of the edges of the first side is adjacent the front of the first stud member; such that a portion of the first side extends away from the first stud member; such that the other of the edges of the first side is spaced apart from the first stud member; such that a portion of the second side extends between the inside face and the outside face and adjacent the back of the second stud member to form a second structural and thermal transmission interface; such that one of the edges of the second side is adjacent the back of the second stud member; such that a portion of the second side extends away from the second stud member; and, such that the other of the edges of the second side is spaced apart from the second stud member. The method also includes the steps of placing a structural member along the other of the edges of the second side; and, interconnecting the structural member and the second stud with a plurality of spaced apart support members each having a first end connected to the structural member and a second end connected to the second stud.
Turning now to the drawings, which depict the presently preferred embodiments of the invention for the purpose of illustration thereof, and not by way of limitation of the invention, and in which like characters refer to corresponding elements throughout the several views,
A plurality of generally rectangular openings 16 to 19, 20, 21 are formed through neck 11. The shape and dimension of each of the openings can vary as desired. The area of each opening 16 to 19 is calculated by multiplying the length U times the width D. Each opening 16 to 19 has a shape and dimension equivalent to the other openings 16 to 19. The area of each generally rectangular opening 20, 21 is also calculated by multiplying the length of the opening times the width of the opening. When the areas of each opening 16 to 21 are summed, a cumulative area of the openings is obtained. This cumulative area includes the area of openings 16 to 19, 20, 21 and of any other comparable openings in neck 11. Circular openings like openings 25 and 26 are formed through neck 11 to facilitate threading electric wiring and other cables or lines through I-stud 10. The circular area of these openings 25, 26 are included when calculating the cumulative area of the openings in neck 11. Openings 16 to 19 also have a cumulative cross-sectional area. The cumulative cross-sectional area of openings 16 to 19, 20, 21 represents the area which is not available to heat for direct transmission from one elongate side 203 of neck 11 to the other elongate side 201 of neck 11. The cross-sectional area of openings 17, 21, 16 is calculated by multiplying the width of neck 11, indicated by arrows R in
The surface area on the front of neck 11 equals the overall area of neck 11 minus the cumulative area of all the openings 16 to 21, 25, 26 formed through neck 11. The overall area of neck 11 equals the width of neck 11, indicated by arrows 230 in
The surface area of the back of neck 11 is equivalent to the surface area on the front of neck 11. The surface area on the front of neck is generally equal to the surface area of side 201 plus the surface area of side 203 plus the surface area of the venturi bridges 22, 24, 23 in stud 10.
Each venturi bridge 22 to 24 is adjacent at least one of openings 16 to 21, 25, 26 and has a surface area on the front of neck 11 and a surface area on the back of neck 11. Each venturi bridge 22 to 24 extends between sides 201 and 203. In
Bridges 22 to 24 also have a cumulative cross-sectional area. The cumulative cross-sectional area of bridges 22 to 24 represents the area which is available to heat for direct transmission from one elongate side 203 of neck 11 to the other elongate side 201 of neck 11. The cross-sectional area of bridges 17, 21, 16 is calculated by multiplying the width of each bridge, indicated by arrows R in
I-stud 30 illustrated in
The cumulative area of all the openings formed in neck 30A of stud 30 is determined by adding together the area of each opening in neck 30A. The cumulative surface area on the front (or back) of neck 30A for the venturi bridges in stud 30 is determined by adding together the surface area on the front (or back) of neck 30A for each venturi bridge. On the other hand, the cross-sectional area of the openings formed through neck 30A is determined by selecting the axis 233, 234 that passes through openings having the greatest cumulative cross-sectional area. Axes 233 and 234 are parallel to the elongate centerline of stud 30. The elongate centerline is generally parallel to the flanges (for example, flanges 14 and 15 in
In
I-stud 40 illustrated in
Foam panel 110 is also indicated in ghost outline and is identical in shape and dimension to panel 66. An elongate groove 112 is formed in the second side of panel 110. Groove 112 is identical to the groove formed in the second side (not visible) of panel 60. The shape and dimension of groove 112 is identical to that of groove 111, although groove 112 opens in a direction opposite that of groove 111.
H-shaped metal stud 70 is similar to metal studs 10, 30, and 40, except that stud 70 does not include openings formed through the neck 75 of stud 70. In addition, neck 75 is not flat like necks 11, 30A, 54. Instead, neck 75 has sections or ribs 80, 76, 77, etc. that are offset from one another.
One principle function of the openings and venturi bridges formed in the necks of studs 10, 30, and 40 is to reduce the conduction of heat into the necks of the studs. This is important in the combination of the invention because C-shaped or I-shaped metals studs are used to interconnect and secure foam panels. Foam panels provide efficient thermal insulation. This thermal insulation can be breached and bypassed if heat is readily transmitted from the neck of the metal studs to foam panels and from foam panels into the interior space in a building. The structure of studs 10, 30, 40 minimizes the transfer of heat at the neck-foam panel interface. In contrast, the panel structure of
Stud 70 includes flanges 71 and 72 along one side and includes flanges 73 and 74 along the other side. Neck 75 extends between flange pair 71-72 and flange pair 73-74. Neck 75 includes parallel, interconnected, offset panels or ribs 80, 76, 77, 78, 79. As noted, the offset design of ribs 76-80 functions to split between panels 66 and 110 the quantity of heat that is transmitted from neck 75 to the sides of panels 66 and 110. If desired, however, a neck 75A which is essentially flat and lies in one plane in the manner of necks 54, 30A and 11 can be utilized in place of the neck 75 illustrated in
In
In
In roof 301, panel 66, along with other panels coplanar with panel 66, extends at least to dashed line 237. See
In
Orthogonal foam panel 90 includes outside face 91 (i.e., the face exposed to the outdoors), inside face 92 (i.e., the face exposed to the interior of a building) parallel to face 91, top 93, a bottom (not visible) parallel to top 93, a first rectangular edge 94 extending between the inside face 92 and the outside face 91, and a second rectangular edge (not shown) parallel to edge 94 and extending between inside face 92 and outside face 91. Edge 94 is adjacent and contacting the back 54B of neck 54. Edge 94 preferably fits snugly between flanges 56 and 57 such that flange 57 contacts inside surface 92 and flange 56 contacts outside surface 91.
Foam panel 100 includes outside face 101 (i.e., the face exposed to the outdoors), inside face 102 (i.e., the face exposed to the interior of a building) parallel to face 101, top 103, bottom 105 parallel to top 103, a first rectangular edge (not visible) extending between the inside face 102 and the outside face 101, and a second rectangular edge 104 parallel to the first rectangular edge and extending between inside face 92 and outside face 91. Edge 104 is adjacent and contacting the front 54A of neck 54.
Edge 104 preferably fits snugly between flanges 41 and 42 such that flange 41 contacts inside face 102 and flange 42 contacts outside face 101. This configuration of the structural combination of stud 40 and of panel 100 (or 90) strengthens stud 54 because panels 90 and 100 resist compression and therefore help prevent stud 54 from bending when a shear force is applied to stud 54 in the direction of arrow 242. Similarly, flanges 41 and 42 function to hold the edge 104 in a fixed position, which increases the ability of edge 104 and panel 100 to resist a force acting on panel 100 in the direction indicated by arrow 242. In the roof panel construction illustrated in
By way of example, and not limitation, during construction of a wall, a series of vertically oriented studs 40 is placed on eighteen inch centers. A foam panel 90, 100 about eighteen inches wide is placed between each adjacent pair of spaced apart flanges such that the first edge (for example, edge 94), i.e., the right hand edge, of a vertically oriented panel contacts the back 54B of the neck of one stud and the second edge (for example, edge 104), i.e., the left hand edge of a vertically oriented panel contacts the front of the neck of another stud. Consequently, as shown in
A pair of U-shaped members 111, 111A (
As can be seen, each wall panel of the type illustrated in
Limiting the transfer of heat from the neck 54 of a metal stud 40 to the edge 104 of a foam panel 100 at the neck 54—edge 104 interface between neck 54 and edge 104 is critical in the practice of the invention. Heat transferred from the face 54A of neck 54 to edge 104 can travel through the inside portion of panel 100 indicated by arrows S in
Similarly, as the surface area of venturi bridges on the front (or back) of the neck 54 decreases, the ability of neck 54 to transmit heat to edge 104 decreases. The cumulative surface area of venturi bridges on the front 54A of neck 54 can be calculated in the manner earlier described. The ratio of the surface area of edge 104 to the cumulative surface area of the venturi bridges in neck 54 should be in the range of 25:1 to 4:1, preferably 25:1 to 10:1, to limit the transmission of heat from neck 54 to edge 104. In
FIGS. 12 to 15 illustrate a bracket 140 utilized to secure a wall panel to a concrete foundation 203, wood frame foundation, or other foundation. Bracket 140 includes a foot 141 with oblong aperture 143 formed therethrough. Bracket 140 also includes a rectangular body 142 normal to and depending from foot 141. During installation of a wall panel a plurality of brackets is attached to foundation 203 at desired intervals. These intervals preferably correspond to the intervals between the studs 40A in a wall panel. The brackets 140 are attached to foundation 203 by driving bolts through openings 143 into the foundation. Or, screws or other fasteners can be inserted through openings 143A. After the brackets 140 are attached to foundation 203, a wall panel is positioned on the brackets 140 in the manner illustrated in
The studs 10, 30, 40, 40A, 70 utilized in the practice of the invention are preferably fabricated from metal, but can be fabricated from any desired material. When metal is utilized it has a thermal conductivity greater than 0.030 g-cal/(sec.)(sq. cm.)(degree C./cm.) at eighteen degrees Centigrade. The preferred metal is steel. The construction of the invention, including flanges 71, 72, 73, 74 that are each formed by folding the edge of a panel over on itself, enables lightweight 20 gauge steel panels to be utilized to roll and form studs 10, 20, 40, 40A, 70 from a flat panel of steel. The ability to use such a thin gauge of metal reduces the cost of constructing the panels of the invention.
In use, wall panels of the type illustrated in
If desired, once a wall panel of the type shown in
The foam used in panel 60, 90, 100, etc. can vary as desired, but expanded polystyrene foam panels are presently preferred, in part because they are lightweight and do not exude harmful chemicals.
Panels constructed in accordance with the invention can be utilized to construct flat or sloped roofs. Sloped roofs usually have a slope of at least 2/12.
Number | Date | Country | |
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Parent | 10875708 | Jun 2004 | US |
Child | 12018791 | Jan 2008 | US |
Parent | 10101549 | Mar 2002 | US |
Child | 10875708 | Jun 2004 | US |