The present invention relates to a connecting device, system and method for constructing a structure. Specifically, the device is a connector or bracket for use in connecting the structural elements of a roof, including connecting purlins to the truss or rafters in the construction of a roof for a building, including a post frame building. The present connecting device also provides reinforcement to roof connection points, while avoiding the inherent weakness in structure created by traditional fastening devices and methods. The present connecting device improves the efficiency in construction of a roof structure, including permitting installation of the device and assembly of roof trusses at ground level prior to installation, thereby avoiding performing these tasks at heights above the ground.
It is well-known in the construction, architectural and building industries that constructing a strong roof is a must for any structure. Components of a roof structure generally include rafters extending downward from a central ridge board, purlins running horizontally above the rafters and joists, which create the roof framing surface running the width of the roof structure and perpendicular to the rafters. Alternately, trusses may be used in place of rafters. Proper connection of each of these structural components is important for the strength and longevity of the resulting roof structure.
Purlins are longitudinal structural members running horizontally above and connected to the rafters. Purlins contribute to the structural support of the roof and assist in maintain the integrity of the roof sheeting, which is attached to the purlins. Purlins further support the rafters, which are the sloping beams extending from the central ridge and joined to walls of the building. A purlin should be strong enough to withstand loads, such as snow and wind, which it will encounter during the life of the roof and should not weaken or sag in an obvious manner that would give the roof sheeting an undulating and/or uneven appearance.
During construction of a roof, the roof purlins are connected to the truss or rafters on an edge, or upright, while other purlins are installed with the boards laid flat. The current industry standard for fastening purlins on edge would be to drive a 6 inch 60d ring shank nail lengthwise through the purlin and into the truss or rafter below, while the current industry standard for fastening purlins laid flat would be to drive or air-nail multiple 3 inch 16d ring shank nails through the purlin and into the truss or rafter below.
However, this type of traditional fastener and connection method results in several problems. A first problem is that driving a long nail into and through a 3.5 inch purlin and then into a truss is difficult. Oftentimes, the nail will not drive straight, which may cause the nail to miss the target or push out the side of the truss, rafter or framing member. The result is a weak and unsightly connection. Wood grain, knots, and other imperfections in the wood members increase the risk of misalignment, which may result in the boards to split or splinter. The weak connection will decrease the overall wind load of the structure, increasing the risk of wind damage. Additionally, this connection task is often performed at varying heights, meaning the worker is up on the roof structure, which further increases the difficulty of the task.
A second problem is that the roof purlins are limited in length, so they must be joined together at certain points along the building's length. The common method is to overlap the purlins at the truss connection point. The problem with this method is that the purlins are now misaligned or staggered. This increases the difficulty of properly fastening the roof sheeting to the purlin where the stagger occurs, and also increases the risk for roof leaks increases due to the fastener missing the purlin below. This method also limits the number of fasteners which can be used to fasten the purlin to the truss, as installing multiple 60d nails in such close proximity, will often cause the truss member to split, weakening the connection even further. This type of connection is also not visually appealing and provides a “cluttered” appearance to the framing. Additionally, a builder may be required to stagger the joints of the purlins, further complicating the construction process while still maintaining a weak connection point.
A third problem is that in buildings with an overhang, which extends beyond the exterior wall of the building, will be subject to forces from high winds placed on the connection point of the overhang. Limited fasteners and lumber that has been split or splintered offer minimal pull-out resistance and are often the cause of roof failure. The risk of splitting or splintering is increased on buildings with no overhang, as the purlin is fastened at the very end of the board, which is prone to this type of damage.
A need, therefore, exists for an improved connector device or bracket for constructing and reinforcing a structure, and in particular a roof structure. Specifically, a need exists for improved devices and systems for use in roof construction.
Moreover, a need exists for an improved connector device for connecting roof purlins to the truss or rafter in the construction of a roof for a building. Specifically, a need exists for a purlin connector designed to install a purlin in a specific position based on the desired connection, for example, either on edge or upright position, or in a flat or horizontal position.
Additionally, a need exists for an improved connector device and system for providing a more secure connection of roof purlins to trusses or rafters for a building.
A need further exists for an improved connector device and system requiring fewer fasteners resulting in a more efficient and stronger connection, as fewer fasteners results in potentially fewer weakened or split places in the framing member.
A need further exists for efficiently connecting multiple purlins to each other and/or to a rafter without the need for splicing or overlapping the purlins.
A need further exists for an improved connector and system providing improved wind damage resistance to the roof structure.
Additionally, a need exists for a connector device for securing a purlin to an end rafter or truss without the connector extending beyond an end of the rafter or truss.
A need further exists for an improved connector and system that permits construction of the initial roof structure, such as a truss, at ground level thereby eliminating the need for temporary bracing.
The present disclosure relates to an improved device, system and method for constructing and reinforcing a structure, in particular a roof structure. Specifically, the present disclosure relates to a connector or bracket useful for connecting roof purlins to trusses or rafters in the construction of a roof for a building. The present disclosure provides embodiments of connectors useful for securing purlins in different positions and in relation to the rafter or truss. For example, in one embodiment, a purlin connector is provided to install a purlin on edge or upright position. In another embodiment, a purlin connector is provided for installing a purlin installed in a flat or horizontal position. Additional embodiments of various connectors are also provided.
To this end, in an embodiment of the present disclosure, a device for use in constructing a structural element of a building, specifically a roof, is provided. In one embodiment, the device is a connector for joining two structural elements, such as purlins, rafters and trusses together in a perpendicular arrangement for roof construction. The connector comprises a base having a center section with a first longitudinal edge and a second longitudinal edge, a first side panel connected to the first edge of the center section, a second side panel connected to the second edge of the center section, a first wing extending from a top of the first edge of the center section and positioned perpendicular to the first side panel, a second wing extending from a top of the second edge of the center section and positioned perpendicular to the second side panel. This particular connector device embodiment is useful for connecting and installing purlins in an upright or “on edge” position.
In another embodiment, a connector device for constructing a roof is provided. The connector comprises a base having opposing side walls connected by a center section, an opening within the center section, the opening having a first edge and a second edge, a first tab extending from the first edge of the opening and perpendicular to the center section and, a second tab extending from the second edge of the opening and perpendicular to the center section. The opposing tabs are also staggered or offset in relation to one another. This particular connector embodiment is useful for connecting and installing purlins in a flat or horizontal position.
In yet another embodiment of the present connector device, the device comprises a U-shaped body having opposing side walls connected by a center section. The center section includes a center opening having a perimeter, with two opposing upright tabs on opposing sides of the perimeter of the center opening. This connector embodiment is also useful for connecting and installing purlins in a flat or horizontal position.
In a further embodiment, a connector device is provided for installing purlins in an upright or vertical position. The connector device comprises a base having opposing side walls connected by a center section, an opening within the center section, the opening having a first edge and a second edge, a first tab extending from the first edge of the opening and perpendicular to the center section and, a second tab extending from the second edge of the opening and perpendicular to the center section.
In another embodiment of the present disclosure, a method for constructing a roof structure is provided. The system includes the steps of providing a structural element for a constructing a roof including purlins and trusses, placing the purlins and trusses into position, securing the purlins and trusses together using a connector and installing a plurality of fasteners through the connector joining the structural elements, and lifting the engaged structural elements into position to create the roof structure.
It is, therefore, an advantage and objective of the present disclosure to provide a connector device and system for use in constructing the roof of a building quickly and easily.
It is further an advantage and objective of the present disclosure to provide an improved connector device and system for constructing the roof of a building wherein the roof has improved integrity and resistance to wind damage.
It is yet another advantage and objective of the present disclosure to provide an improved connector device and system for constructing a roof of a building wherein the majority of the construction of the roof structure can be accomplished at ground level.
Additional features and advantages of the present disclosure are described in, and will be apparent from, the detailed description of the presently preferred embodiments and from the drawings.
The drawing figures depict one or more implementations in accord with the present concepts, by way of example only, not by way of limitations. In the figures, like reference numerals refer to the same or similar elements.
The present disclosure relates to a device and systems for constructing a structure. Specifically, the present disclosure relates to an improved device and system for constructing the roof of a building. The present disclosure relates to a securing or connecting device useful for connecting roof purlins to the truss or rafter in the construction of a roof for a building. In one embodiment, a purlin connector is provided to install a purlin on edge, or a vertical or upright position. In another embodiment, a purlin connector is provided for installing a purlin in a flat or horizontal position. Additionally, a method of constructing a roof using the connectors of the present disclosure is also provided.
An advantage of the various embodiments of the connector or bracket device of the present disclosure is that the connectors permit structural members, such as purlins, to be fully in contact with one another, meaning there is no material separation of the members. This feature allows for the structural members to maintain a consistent height, uniformity and stability without variation from structural member to structural member. The connectors are typically used where there is a connection or butt joint between members, which can inherently lead to instability. Use of the present connectors and the manner in which they are attached to the structural members avoids these issues.
The design of the present connector embodiments further permit fastening through the main body of the subject connector into the truss or rafter below. Specifically, the angle holes on the opposing sides of the main body of the connector means that the nails, or preferably screws, are installed at a 45 degree angle from both sides of the main body. Utilization of the tabs on the various connector embodiments further contribute to the secure installation afford by the present connectors. Furthermore, the use of the present connectors simplifies purlin installation because the connectors set the purlin into predetermined positions. Use of the present connectors permits two purlins to be installed in a straight line in end-to-end contact thereby eliminated overlap and splicing. Finally, the present connector embodiments allow for purlin joints to be offset from each other, thus offsetting load points, which provides further structural integrity to the overall roof structure.
The present disclosure further relates to a method for constructing a roof structure. The method includes the steps of providing a structural element for a constructing a roof including purlins and trusses, placing the purlins, rafters and/or trusses in position, securing the purlins, rafters and/or trusses together using an improved connector according to the present disclosure, and a plurality of fasteners installed through the connector, and finally lifting the engaged structural elements into position to create the roof structure.
Now referring to the figures, wherein like numerals refer to like parts,
As shown in
The connector 10 further includes two opposing wings, a first wing 24 and a second wing 26. Each wing extends from a top of the center section 14 and are spaced apart from one another approximately the width of the raised center section. These opposing wings 24, 26 extend outward and perpendicular to the respective side panels 20, 22, and are configured to attach the purlins 50 using fasteners with a second structural member, such as a rafter 52.
Perpendicular tabs extend from a top edge of each of the first side panel 20 and the second side panel 22. Specifically, a first tab 28 extends outward and perpendicular from a top of the first side panel 20 and in an opposite direction from the first wing 24, while a second tab 30 extends outward and perpendicular from a top of the second side panel 22 in an opposite direction from the second wing 26. The first and second perpendicular tabs 28, 30 are configured for attachment to the underside of the purlins 50 using fasteners.
As shown in
This particular connector 10, as well as all of the connectors of the present disclosure can be constructed using known methods from any suitable material, preferably steel, including galvanized steel for strength and longevity. Additionally, the connecters can be configured into various sizes suitable for the particular project, such as double ply trusses and rafters.
As shown in
The connector 200 includes a pair of tabs, a first tab 216 and a second tab 218. The first tab 216 extends from the first edge 212 of the opening 210 in an upright or perpendicular position in relation to the center section 208. The second tab 218 extends from the second edge 214 of the opening 210 also in an upright or perpendicular position to the center section 208. The opposing tabs 216, 218 are also in a staggered or offset alignment in relation to one another. The opposing tabs 216, 218 are further spaced apart from each other across the opening 210 such that they can be secured to either side of a second structural member such as a rafter or truss (
As shown in
The connector 400 includes a pair of tabs, a first tab 416 and a second tab 418. The first tab 416 extends from the first edge 412 of the opening 410 in an upright or perpendicular position to the center section 408. The second tab 418 extends from the second edge 414 of the opening 410 also in an upright or perpendicular position to the center section 408. The opposing tabs 416, 418 are also in a staggered alignment in relation to one another. The opposing tabs 416, 418 are further spaced apart from each other such that they can be secured to either side of a second structural member such as a rafter or truss using screws 34 as previously described.
The connectors 10, 100, 200, 300, 400 shown in present disclosure allows the purlins 50 to be joined together at the joint or connection point of the rafter or truss without the risk of splitting the boards by offering a larger area where the boards can be joined. This in turn, greatly reduces the risk of splitting or splintering of the wood purlins. Additionally, the connectors can be installed at multiple purlin locations, including the lap, middle of the purlin, and where an end wall overhang is utilized. The present connectors are also suitable for use on the end of the building where an overhang may be present. These connectors offer greater resistance to pull-out and reduce the risk of total roof failure.
The present disclosure further includes a method for construction of a roof structure. The method includes the steps of providing a structural element for a constructing a roof including purlins and trusses, placing the purlins and trusses in position, securing the purlins and trusses together using a connector and a plurality of fasteners installed through the connector, and lifting the connected structural elements into position to create the roof structure.
An advantage of using the present connectors and method is that it permits construction of all or a portion of a roof structure prior to lifting the roof onto the building structure. In this manner, the connectors can be installed onto the truss or rafter while still on the ground and prior to truss installation, thereby decreasing the difficulty of installation while providing a safer working environment. As the post frame industry continues to seek entry into the residential and commercial markets, there will be the need for meeting increased wind loadings. The present connectors are designed to assist with meeting these increased loadings by reinforcing the roof connection points that are typically most prone to failure.
It should be noted that various changes and modifications to the presently preferred embodiments described herein will be apparent to those skilled in the art. Such changes and modifications may be made without departing from the spirit and scope of the present invention and without diminishing its attendant advantages. Further, references throughout the specification to “the invention” are nonlimiting, and it should be noted that claim limitations presented herein are not meant to describe the invention as a whole. Moreover, the invention illustratively disclosed herein suitably may be practiced in the absence of any element which is not specifically disclosed herein.
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