The invention relates generally to methods of securing an installed metal roof. More specifically, the invention relates to methods for fastening installed metal panels to structural roof support beams, without detrimentally effecting the existing insulation and roof system.
Rectangular metal panels are widely used to form roofs on industrial buildings. In typical installations, walls or columns are constructed that support horizontal metal beams. These are positioned parallel to one another and at regular intervals. The rectangular metal panels are then placed on top of the metal beams. They are typically arranged on a grid so that the sides and ends of adjacent panels overlap. After covering the roof with metal panels, additional layers of material are added to seal and/or insulate the roof. These can include one or more layers of sand, gravel, insulation, foam, concrete, silicon paint, tar, perlite, gypsums and/or other materials.
In typical installations, the metal panels have been insufficiently fastened or attached to the metal beams. This leaves the roof vulnerable to high winds and hurricanes, which can tear the metal panels away and expose the interior of the structure.
Accordingly, methods have been applied to further attach existing metal panels to the metal beams. Metal clips are fastened to the deck from underneath, that lap onto the edge of the beam adding additional fastening. Where the beams are flanged a fastener with an oversized washer is installed from underneath grabbing the flange and the deck. Also, the metal panels may be fastened to the metal beams by drilling a hole through the metal beam and into the metal panel. The metal roof is corrugated so that it has parallel peaks and valleys at regular intervals. Fastening is installed on a grid pattern at each place where a valley of the metal roof touches a beam. A screw (or a nut and bolt) are then used to better attach the metal panel. While this method is effective, it suffers from a couple significant disadvantages. First, it requires scaffolding, ladders or other apparatus to permit a construction worker to install the fasteners. Where the building is used to shelter an industrial operation, such as a factory, that runs around the clock, it may be difficult to install these fasteners without interfering with the normal operations within the building. Second, drilling into the metal panels generates debris. Also the pull out values are low for this use of the fasteners, so an increased number of units must be installed. Again, depending upon the particular application, if the building is used to shelter a clean environment, such as a pharmaceutical plant, this may interfere with normal operations within the building. Another method is to cut a 6 or 8 inch strip of the existing roof system from above directly over the beam, exposing the deck, and installing additional fastening. The dilemma of this installation is that it interrupts the integrity of the roof system weakening the complete unit, causing leaks and additional fastening requirements of the roof system.
It is an object of the present invention to provide a method of attaching a corrugated metal roof to metal supporting beams.
According to one aspect of the invention, an installed metal roof deck is formed by a plurality of rectangular, overlapping, corrugated panels covered with at least one layer of insulation or sealer and supported from below by a plurality of parallel beams. The installed metal roof deck is secured by identifying a first location for a first fastener. The first location occurs where a first beam meets a first valley in the corrugated panels. A first access hole is drilled through the at least one layer of insulation or sealer at the first location. The first access hole does not extend through the corrugated panels. A first self-tapping screw is positioned through the first access hole. The first self-tapping screw is driven through the corrugated panels and into the first beam. A second location for a second fastener is identified. The second location occurs where the first beam meets a second valley in the corrugated panels. A second access hole is drilled through the at least one layer of insulation or sealer at the second location. The second access hole does not extend through the corrugated panels. A second self-tapping screw is positioned through the second access hole and driven through the corrugated panels and into the first beam. A template that extends from the first self-tapping screw to the second self-tapping screw is positioned. The template includes regular marks to identify intersections between valleys in the corrugated panels and the first beam. Additional access holes are drilled through the at least one layer of insulation or sealer at locations aligned with the regular marks on the template. The additional pilot holes do not extend through the corrugated panels. Additional self-tapping screws are positioned through each of the additional access holes and driven through the corrugated panels and into the first beam.
According to further aspects of the invention, the first location for the first fastener is identified by viewing the metal roof deck from a perspective below the plurality of metal beams. The regular marks on the template are spaced at an interval equal to a distance between valleys in the corrugated panels. The additional self-tapping screws are positioned through each of the additional access holes comprises by placing a head of the self-tapping screws in an extended socket having a length sufficient to reach through the at least one layer of insulation or sealer, and secure fastener head at deck below. The additional self-tapping screws are driven through the corrugated panels and into the first beam using a power drill, which automatically stops before the self-tapping screws strip by releasing a clutch.
A corrugated metal roof is secured using a plurality of self-tapping screws. The corrugated metal roof consists of a plurality of rectangular panels. These are arranged on a grid and supported below by metal beams. The metal panels are positioned so that they overlap with adjacent panels along both sides and both ends of each panel. The metal panels are covered with top layers of insulation and/or sealer. A first metal beam is found, preferably by measuring its location from below then drilling an access hole through the top layers of insulation and/or sealer. Through that hole we install the pilot fastener where the beam is expected. Either striking the beam, or by inspection making the necessary adjustments to contact the beam. The fastener is driven by an elongated socket, engages a self-tapping screw. The elongated socket is driven by a clutched-drill. The self-tapping screw is driven through the metal panel and the metal beam below until the clutch of the drill releases, which indicates that the screw is tight and secure. In the event that the clutch does not release, one of two possible problems exist. The clutch is set too tight and the screw has stripped out the hole. In this case, the clutch must be loosened so that it will release before the screw strips out the hole. Preferably this adjustment is made before beginning the project. Alternatively, the screw did not hit a beam. In this case, an inspection is made from below to determine the distance and direction of the miss. If the first screw was near the beam, the same access hole may be used. If the miss was substantial, another access hole can be drilled. In either case, a second screw is put into the valley of the metal panel and is positioned to hit the beam based upon the determined distance and direction of the miss. The first screw is positioned in one of the valley's nearest to the end of the beam. Next, a second access hole is drilled. It is positioned over the same beam, but at the opposite end. The same procedure used with the first screw is applied to the second screw. With these two in place, a straight-line guide is positioned between the first and second screw. The distance between valleys is known. Accordingly, additional screws are drilled through each valley and into the same beam. After securing each screw, the access hole through the top layers of insulation and/or sealer is filled. This may be accomplished by spraying polyurethane foam (or “poly” foam) sealer into the hole. A wide variety of such sealers are commercially available in a spray can, with a small tube for dispensing the foam. This tube is placed at an angle into the pilot hole so that the end of the tube abuts the side of the pilot hole. The foam accumulates in the hole until it is filled. An additional layer of sealer may be used to cover and further protect the access hole.
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The panels are supported from below by beams 120. These are regularly spaced and run parallel to each other. The beams may be “I” beams, flanged joists, C channel, Z bar or any other commercially used beam. The fasteners are selected depending upon the type and thickness of the beams.
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Next, a second screw 204 is positioned based upon the position of the first screw 202 as well as from a measurement taken from below. An access hole is drilled through the top layers of insulation and/or sealer. The self-tapping screw is then drawn through the metal panel and through the metal beam until its head is tight against the metal panel. Because the clutch was adjusted with the first screw, it will release when tightened and before the self-tapping screw 204 strips the hole it drilled in the metal beam.
Next, a template 206 is positioned between the first screw 202 and the second screw 204. The template is preferably an aluminum metal strip but can be made of any material and could alternatively be a simple straight line drawn between the first screw 202 and second screw 204. The template is marked at regular intervals having the same spacing as the valleys in the corrugated metal panels below. These markings are used to estimate the location for the intermediate screws. An access hole is drilled at each mark. In some installations the metal panels can be stretched and in others compressed. Accordingly, after drilling an access hole the operator must feel whether it is aligned with the center of a valley. If it is close, but not perfectly aligned, the operator may be able to adjust by positioning the screw at a slight angle. If it is further off the center of a valley, however, another access hole is drilled directly over the valley. Subsequent holes are similarly adjusted. When a row is completed, the access holes are filled by injecting poly foam. This hardens. At the end of the day, a strip of roofing material is used to further seal and protect the holes.
Next, the template 204 is moved over the adjacent beam. Because the spacing of the beams can be determined from below, it is easily positioned based upon the location of the screws 202 and 204 in the first row. The process of drilling pilot holes and fastening self-tapping screws is repeated so that a screw is drawn into the intersection between each valley and a beam.
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Another self-tapping screw 308 is shown as its head is drawn tight against the adjacent valley of metal panel 302. Again, an access hole 318 was drilled through the layer of insulation 310 and the layers of sealer 312. The pilot hole 318 is sufficient to accommodate an extended socket 320. The extended socket 320 holds the head of the self-tapping screw 308. It is used to position the screw 308 and then to drive it through the metal panel 302 and into the beam 304. The socket 320 is driven by a clutched drill or other powered driver.
In the foregoing specification, embodiments of the invention have been described with reference to numerous specific details that may vary from implementation to implementation. Thus, the sole and exclusive indicator of what is the invention, and is intended by the applicants to be the invention, is the set of claims that issue from this application, in the specific form in which such claims issue, including any subsequent correction. Any definitions expressly set forth herein for terms contained in such claims shall govern the meaning of such terms as used in the claims. Hence, no limitation, element, property, feature, advantage or attribute that is not expressly recited in a claim should limit the scope of such claim in any way. The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense.
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