A. Field of the Invention
The invention relates to roofing and specifically to roofing ventilation. The ventilated roof system and method of the Invention provides full ventilation of the underside of the roof deck, prevents blinding of ventilation intakes by attic insulation, provides a secondary barrier to water intrusion into the living space of the building, allows elimination of soffits in roof construction, and allows escape of water vapor from the interior of the building.
B. Statement of the Related Art
The portion of a building roof that is exposed to the elements is protected by a durable, weather-resistant surface, such as shingles. As used in this document, the term ‘shingle’ means tab shingles, architectural shingles, cementatious shingles, metal shingles, slate, sheet metal, tar paper, underlayment, roll roofing, ceramic tile roofing, wood shakes, synthetic versions of any of the above and any other weather proofing product that may be applied to a pitched roof.
The shingles are supported by a roof deck. As used in this document, a ‘roof deck’ means the generally planar structural covering the upper side of a building and providing support for shingles. The ‘roof deck’ usually is composed of wood in the form of plywood sheets or dimensioned lumber. The term ‘roof deck’ also may include other roofing materials previously applied to the plywood or dimensioned lumber, such as tar paper or other underlayment, ice and water shields, and shingles.
The roof deck has a pitch from the eave (lower edge) of the roof to the ridge of the roof so that water and snow will fall from the roof. As used in this document, the term ‘ridge’ means a high location on a roof, such as where the roof deck intersects another roof deck for a gable or hip roof or intersects a vertical wall for a shed roof.
To apply shingles to a roof deck, the roof deck is first covered by underlayment. The course of shingles proximal to the lower edge of the roof is then nailed to the deck over the underlayment. Each subsequent course of shingles proceeding from the lower edge to the ridge of the roof overlaps the preceding course and is nailed to the roof deck so that water running from each shingle flows onto the top of the adjacent downhill shingle. The underlayment and shingles cooperate to form a composite surface that is tight to rain water, snow melt and water vapor.
The roof deck is supported by rafters that extend from the eave to the ridge of the roof. The ends of the rafters at the eave are covered by a fascia board. As used in this document, the term ‘attic’ refers to an attic and also refers to any other air space under a roof assembly, such as the space between a ceiling or insulation and a roof deck of a structure equipped with a cathedral ceiling.
Moisture in the form of water vapor is released into the air inside a structure by the occupants of the structure, by the building plumbing systems and by the soil underneath the structure. If that water vapor is trapped under the impermeable shingle roof, the resulting condensation can damage the roof, can damage the remainder of the structure and can promote growth of mold within the attic. To avoid these effects, the space underneath the roof must be ventilated. Ventilation also serves to allow air heated by solar gain to escape from the space under the roof, reducing the cooling load on the building. During daylight hours, the sun shining on the roof warms the roof deck, causing the roof deck to be warmer than the ambient air. The warm roof deck warms the air immediately below the roof deck. During cold weather, heat within the inhabited space of the structure will leak into the attic space, which also warms the air in the attic space. The air within the attic that is warmed by the sun or by escaped building heat expands, becomes buoyant, and tends to rise. Because the roof is pitched, the warm air rises along the roof deck toward the ridge of the roof. The warm air can be released from the ridge by a ridge vent or at the gable from a gable end vent.
Warmed air escaping from the ridge vent will place the attic space at a lower air pressure than the ambient pressure outside the attic. For effective ventilation, eave vents are provided to allow make-up ambient air to enter the area under the roof. A roof equipped with eave and ridge vents acts as a large, low-pressure air pump, pumping air out through the ridge vent and in through the eave vents. The power input to the roof air pump system is heat energy generated either by sunlight shining on the roof deck or by heat leaking into the attic from the heated living space of the structure. If any portion of the roof is starved for ventilation air, then the lack of air flow through the air-starved attic space may cause the problems associated with excess moisture.
Any roof ventilation system must deal with building insulation. Insulation may be applied between joists of an attic space or may be applied between rafters supporting a roof deck. If the insulation blocks the flow of air along the underside of the roof deck, the evils of inadequate ventilation will occur. A problem location in prior art roof ventilation systems is the area of the eaves of the roof. Insulation installed proximal to the eave may block the air intakes, preventing the flow of ventilation air through the attic. Insulation applied between the rafters also may block ventilation air and may be separated from the underside of a roof deck by a baffle, frequently composed of styrofoam. Any improper installation of the baffle or of the insulation can block the flow of air, resulting in excess moisture and condensation. Ventilation air also may be blocked by anything that gets in the way of the air, including the building structure or building debris.
The present invention is not taught by the prior art.
The Invention is a system for construction of a roof that provides complete ventilation of the underside of the roof deck while allowing water vapor to escape from the structure and avoiding any interference with the ventilation of the roof deck due to blockage of air flow by insulation or by other building materials such as wood, dry wall, metal beams, masonry, or any other structural components or construction debris that may block the flow of air under the roof deck.
The roof ventilation system includes a pitched sub-deck installed on the rafters of a structure. The sub-deck is composed of plywood sheet, dimensioned lumber or oriented strand board and covers the rafters. The sub-deck must be strong enough to support a worker during installation of the roofing system and strong enough not to sag excessively after construction is completed. Once the roof is completed, the structural duties of the sub-deck are minimal and so the sub-roof deck may be light in weight. Plywood having a thickness of ⅜″ has proven suitable in practice for the sub-deck. Where the ventilated roofing system of the invention is retrofitted to an existing roof, the deck of the existing roof becomes the sub-deck of the ventilated roofing system of the Invention. The ends of the rafters below the sub-deck are covered by a sub-fascia. Where the ventilated roofing system of the Invention is retrofitted to an existing roof, the prior art fascia board of the existing roof becomes the sub-fascia of the ventilated roofing system.
A barrier fabric composed of a liquid water-impermeable and water vapor-permeable flexible non-woven fabric is installed over the top of the sub-deck. An example of such a fabric is Tyvek® Home Wrap® by DuPont. A second example is Tyvek® Attic Wrap, which features a reflective layer. A third example is Typar® House Wrap by Polymer Group, Inc. The barrier fabric is permeable to water vapor, so water vapor penetrating through the structure is not stopped by the barrier fabric and can pass through the barrier fabric. Liquid water, however, cannot pass through the barrier fabric under the pressures that the fabric will experience on a roof. The fabric barrier drapes over the edge of the sub-deck and the sub-fascia at the eave of the roof and may be attached to the sub-fascia.
Furring strips are installed on top of the barrier fabric and are attached to the sub-deck and the rafters. A ‘furring strip’ is one or more elongated members, such as dimensioned lumber, that are disposed on top of the barrier fabric and that run from proximal to the eave to the ridge of the roof. Each furring strip is located above a rafter and is nailed through the barrier fabric to the rafter. The top of the furring strip is in a spaced-apart relation to the top of the barrier fabric. A separation between the top of the barrier fabric and the top of the furring strip of about 1.5 inches has proven suitable in practice.
The roof deck is composed of plywood, dimensioned lumber or oriented strand board and spans the adjacent furring strips. The roof deck provides the structural support for the weather-resistant surface of the roof. Underlayment and shingles cover the roof deck in the conventional manner, providing a water-impermeable composite surface to the roof deck. The roof deck is in the spaced-apart relation to the barrier fabric and the sub-deck. The separation between the roof deck and the barrier fabric also serves to protect the barrier fabric from nail penetrations by nails used to install the shingles to the roof deck.
The space between the barrier fabric and the underside of the roof deck and between each pair of adjacent furring strips defines a ventilation channel to provide a flow of air to the underside of the roof deck. The exit to the ventilation channels is any suitable exhaust vent located so as to exhaust air from a ventilation channel. The exhaust vent may be a ridge vent or may be a vent installed at the intersecting planes of a hip roof. The exhaust vent may be installed proximal to the top of a shed roof or may be installed at any intermediate location on a roof deck requiring ventilation; for example, below an architectural feature such as a skylight that otherwise would block the flow of air through the ventilation channel.
The intake to the ventilation channels is any suitable soffit or eave intake vent. An intake vent that has proven suitable in practice is a corrugated plastic intake vent attached to the sub-fascia. The barrier fabric overlaps the sub-deck and sub-fascia at the eave and is disposed between the intake vent and the sub-fascia, securing the barrier fabric to the sub-fascia. The corrugated plastic intake vent has an inlet side and an exhaust side. The inlet side of the plastic intake vent is exposed to the ambient air outside the structure. The exhaust side of the corrugated plastic intake vent is disposed within the ventilation channel, so that the corrugated plastic vent communicates between the ambient air outside the structure and the ventilation channel. The corrugated plastic vent is covered by a fascia that blocks access to the ventilation channels other than through the corrugated plastic intake vent. A gutter to control water flowing from the roof may be attached to the fascia.
The corrugated plastic vent prevents entry of insects, animals, debris and water into the ventilation channels. The disposition of the plastic corrugated vents assures that blowing rain or snow cannot enter the intake vents. An overflowing gutter at a roof edge is a common location for entry of water into a structure. Any water overflowing on the building side of a gutter mounted to the fascia is prevented from entering the structure by the barrier fabric.
The ventilation channels provide protected ventilation for the roof that cannot be blocked by insulation, allowing insulation to be packed into the attic in a quantity and manner that would otherwise block conventional ventilation. The barrier fabric serves as secondary containment for any water that may penetrate the weather-resistant surface of the roof deck or enter through the ridge vent. Rather than entering the occupied portion of the structure, the water is conveyed to the roof edge and discharged through the corrugated plastic intake vent to the outside of the structure. The barrier fabric is not exposed to sunlight or to weather, and so should last indefinitely. The water vapor-permeable barrier fabric also allows the water vapor that otherwise would condense on the sub-deck to pass through the sub-deck and to be exhausted from the building.
If a barrier fabric with a reflective surface is used, the reflective surface reduces radiant heat gain or loss through the barrier fabric and hence through the roof.
The installation of any roofing product presents obvious hazards to the installers because of the potential for falls. The use of the sub-deck in the roofing system of the Invention allows installation of the barrier fabric and the remainder of the roof system by an installer who can physically stand upon the sub-deck, which promotes safety—a major consideration in any roofing installation.
The ventilated roof system of the invention may be retrofitted to an existing roof with little or no work conducted within the building. The ventilated roof system also provides a thermal break from the conditioned air inside the building, aiding energy efficiency of the building. To fully realize the energy savings of the ventilated roofing system in a retrofit of an existing roof, existing openings into the attic are closed, such as existing gable end vents, existing ridge vents and existing intake vents.
Roofing product makers, such as shingle makers, frequently limit warranties of the installed roofing products to roofs that have adequate ventilation. The superior ventilation of the roof system of the Invention will preserve rights under those warranties. Because the superior ventilation, the ventilated roof system of the invention will last longer than a conventional roof, saving the building owner the expense of replacement and saving roofing contractors the costs of warranty claims. The sub-deck protects the barrier fabric during the life of the roof from damage from below, as by a homeowner moving things about in the attic.
The ventilated roof apparatus 2 includes a sub-deck 18 that is attached to and supported by the rafters 6, generally by nails penetrating through the sub-deck 18 and extending into the rafters 6. The sub-deck 18 is composed of plywood, oriented strand board or dimensioned lumber that sheathes the top surface of the rafters 6.
The sub-deck supports a sheet of barrier fabric 20 that covers the sub-deck 18. The barrier fabric 20 is composed of a non-woven polymer that is permeable to water vapor 22 (
Furring strips 24 are attached to the barrier fabric 20, sub-deck 18 and the rafter 6, generally by nails penetrating the furring strips 24, barrier fabric 20, sub-deck 18 and extending into the rafters 6. The furring strips 24 extend from the eave 14 to the ridge 16. The furring strips 24 may be composed of any suitable material, but 2×3 or 2×4 dimensioned lumber has proven suitable.
The deck 26 is attached to the furring strips 24. The deck 26 is composed of plywood, oriented strand board or dimensioned lumber. Shingles 28, as defined above, are attached to the top surface of the deck 26 and provide a barrier to weather. The furring strips 24 separate the sub-deck 18 and the deck 26 so that the deck 26 and sub-deck 18 are in a spaced-apart relation 30. Where the furring strips 24 are 2×3 or 2×4 dimensioned lumber, the deck 26 and sub-deck 18 are separated by 1.5 inches, which has proven suitable in practice. Any other suitable thickness for the furring strips 24 and hence the spaced-apart relation 30 of the deck 26 and sub-deck 18 may be used, provided that the separation is large enough to allow adequate ventilation of the deck 26 and is small enough to avoid an unpleasant appearance of the ventilated roof system 2.
The spaced-apart relation 30 of the deck 26 and sub-deck 18 defines ventilation channels 32 extending from the eve 14 to the ridge 16. A suitable intake vent 34 allows ambient air 12 to enter the ventilation channels 32 proximal to the eave 14. A suitable exhaust vent 34 allows air to exit the ventilation channels 32 proximal to the ridge 16. While any intake 30 may be used, the RafterVent by DCI Products, 415 South Penn Street, Clifton Heights, Pa. 19018 has proven suitable in practice for the intake vent 34. While any exhaust vent 36 may be used, the SmartRidge I and SmartRidge II exhaust vents by DCI Products are suitable for the exhaust vent 36.
As shown by
The construction of the ventilated roof system at the eave 14 is illustrated by
The intake vent 34 is attached to the sub-fascia 40, with the overhang 44 disposed between the intake vent 34 and the sub-fascia 40. The intake vent 34, in this instance a RafterVent by DCI Products, allows air 12 to pass through many small channels defined by the intake vent 34. The air 12 moves as indicated by arrows 38. The air 12 moves through the intake vent 34 due to solar heating of air 12 within the ventilation channels 32 or due to warming of the air within the ventilation channels 32 due to escaped building heat. The warmed air 12 is less dense than cooler air 12 outside of the building 4 and tends to rise toward the ridge 16, where the air discharges from the exhaust vent 36.
Also from
From
This application is entitled to priority from U.S. Provisional Patent Application 61/788,427 by John C. Henderson filed Mar. 15, 2013. Provisional application 61/788,427 is incorporated by reference as if set forth in full herein.
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Number | Date | Country | |
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61788427 | Mar 2013 | US |