Roof batten

Patent RE39825 Issued on September 11, 2007.

Abstract Claims Description Full Text

Patent References

1163034

2042586

3185070

3236170

3647606

3878574

3889892

Ventilated cap for the ridge of a roof
Patent #: 3949657
Issued on: 04/13/1976
Inventor: Sells

Header for a solar energy collection system
Patent #: 4178914
Issued on: 12/18/1979
Inventor: Erb

D257282

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Inventors

Assignee

Diversi-Plast Products, Inc.

Application

No. 10805686 filed on 03/19/2004

US Classes:

52/553, With spacing or space-forming feature52/198, ENCLOSURE OR COVER, WITH SUPPLEMENTAL FLUID-GUIDING PORT BETWEEN AMBIENT AND ENCLOSED USABLE SPACE (E.G., ROOF RIDGE VENT)52/199Attic vent

Examiners

Primary: Slack, Naoko

Attorney, Agent or Firm

Patterson, Thuente, Skaar & Christensen, P.A.

Foreign Patent References

2 939 730 DE 04/01/1981
44 21 941 DE 01/01/1996
2 062 056 GB 05/01/1981
2062056 GB 05/01/1981
2127060 GB 04/01/1984
2243169 GB 10/01/1991
H09-177198 JP 07/01/1997
WO 98/15701 WO 04/01/1998

International Classes

E04B 7/00
E04D 1/00

Description

FIELD OF THEINVENTION

This invention relates to roof coverings and, in particular, this invention relates to building materials or devices which extend the lives of tile roofs by preventing water infiltration.

BACKGROUND OF THE INVENTION

Most tile roofs include an exterior decking or sheathing, which overlays a structural framework of either trusses or rafters. Typically, decking includes plywood sheets or other planking members. One or more layers of overlayment, such as felt(tar) paper, is usually attached to the decking. Battens are normally placed over the felt paper before tiles are installed. The battens are usually fixed to the roof by fasteners, such as nails or staples, driven through the battens and felt paper andinto the roof decking. Battens are typically wood strips and serve to separate the tiles from the overlayment. Separation between tiles and overlayment is necessary to ensure that water infiltrating the tiles onto the felt paper evaporates quickly. Ifwater is otherwise allowed to stand or pool, the water may infiltrate through the felt paper and penetrate the roof decking, thereby potentially causing deterioration of the roof decking and the underlying framework. When horizontal batting isinstalled, water which has infiltrated the roof tiles tends to pool on the upper-slope sides of the battens, thereby potentially causing roof deterioration.

Means previously used to avert or diminish the likelihood of deterioration to tile roofs due to water pooling and infiltration include leaving gaps between adjacent battens and cutting drainage channels on the undersides of the battens. Thesemeans have been largely ineffective and have often added to the expense and time necessary for tile roof installation as well.

As depicted in FIG. 1, roof 20 has installed thereon counter batten system 22 of the prior art. Counter batten system 22 includes vertical battens 24 overlaid with horizontal riser strips 26. Typically, vertical battens 24 are 3/8 by 11/2 inchwooden boards, often four feet in length. Vertical battens 24 are typically installed every 16 inches, on center. Horizontal riser strips 26 are typically wooden lathes and are installed atop vertical battens 24 at spacings determined by the dimensionsof the tiles to be installed. While counter batten system 22 is somewhat effective in eliminating pooled water, the expense and time required to install counter batten system 22 is often prohibitive.

There is then a need for a device or roofing material which spaces tile from underlaying roofing and structural members, which greatly reduces or eliminates water pooling when water infiltrates the roof tile system, and which may be installedquickly and efficiently.

SUMMARY OF THE INVENTION

This invention substantially meets the aforementioned needs. There is provided a spacer operatively disposable between a roof decking and an exterior roofing material. The spacer may include at least one layer of a material, the materialdefining a multiplicity of passages therethrough. The passages defined may extend generally transversely to a longitudinal axis of the spacer and may allow infiltrated liquids to drain therethrough, thereby preventing accumulation of the infiltratedliquids. The spacer may further include a generally planar first ply and a convoluted second ply cooperating to define the multiplicity of passages. A plurality of first plies and a generally convoluted second ply may be present. The second ply mayinclude a multiplicity of cross-plies extending between the first plies. The spacer may include a plurality of layers. Each adjacent layer of the spacer may be hingably connected. The layers, when assembled in a stacked relationship, may be fastenedtogether by stitching, staples, glue, hot air welding, ultrasonic welding, infrared bonding, other methods known to the art, or any combination thereof.

There is also provided a tile roof system, the tile roof system including an overlayment, a tile, and a batten. The batten may be disposable between the tile and the overlayment and may include at least one layer of a material defining amultiplicity of passages therethrough, the passages extending generally transversely to a longitudinal axis of the batten and allowing infiltrated liquids to drain therethrough.

There is further provided a method of installing a tile on a roof with a slope. The method may include the step of providing first and second battens, each batten comprising at least one layer of a material defining a multiplicity of airpassages therethrough. The defined passages may extend generally transversely to a longitudinal axes of the batten and may allow infiltrated liquids to drain therethrough. The method may further include the step of fixing the first and second battenson the roof such that longitudinal axis of the first and second battens are generally parallel and extend generally horizontally to the roof's slope. The method may further include the step of fixing the tile atop the first and second battens.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a roof of the prior art with a counter-batten system installed thereon;

FIG. 2 is a perspective view of one embodiment of the batten of this invention;

FIG. 3 is an end view of the batten of FIG. 2;

FIG. 4 is a fragmentary, cross-sectional view of a first embodiment of two layers of the batten of FIG. 2;

FIG. 5 is a fragmentary, cross-sectional view of a second embodiment of one layer of the batten of FIG. 2;

FIG. 6 is a fragmentary, cross-sectional view of a third embodiment of four layers of the batten of FIG. 2;

FIG. 7 is a plan view of a sheet of convoluted material suitable for forming the batten of FIG. 2;

FIG. 8 is a side plan view of the sheet of FIG. 7 being foldably assembled into the batten of FIG. 2 after layers have been defined therein;

FIG. 9 is a perspective view of an exemplary roof upon which battens of FIG. 2 have been installed; and

FIG. 10 is a plan view of tiles installed atop the batten of FIG. 2 on the roof of FIG. 9.

DETAILED DESCRIPTION OF THE DRAWINGS

Referring to FIGS. 2 and 3, exemplary batten (spacer) 30 is depicted. Batten 30 generally includes one or more layers 34 and may be characterized by longitudinal axis 36. Layers 34 are described below and generally serve two functions. Thefirst function is to allow water to drain therethrough. The second is to enable air exchange. These complimentary functions prevent water pooling and promote drying on roofs on which batten 30 is installed. While one or more layers 34 are contemplatedto be within the scope of this invention, if a plurality of layers 34 are present, these layers may be stacked and fixed to each other by such means as stitching 38. However, other fastening means which may be used include hot air welding (or otherfastening means using thermal energy), ultrasonic welding, infrared bonding, staples, glue, or other methods known to the art.

One embodiment of two layers of layer 34 is depicted in FIG. 4 generally as layers 50. Each layer 50 includes planar plies 52 and 54 and convoluted ply 56. Convoluted ply 56 is disposed between and bonded to (or otherwise cooperates with)planar plies 52 and 54 to define a multiplicity of air channels 58 therebetween.

Another embodiment of layer 34 is depicted in FIG. 5 generally as layer 60. Layer 60 includes planar plies 52 and 54 and second ply 62. Second ply 62 includes a multiplicity of cross-plies 64. Cross-plies 64 extend generally perpendicular (orotherwise transversely) between planar plies 52 and 54. Thus, planar plies 52 and 54 and second ply 62 cooperate to define a multiplicity of channels 58 therebetween.

Referring to FIG. 6, yet another embodiment of layers 34 is depicted generally as four layers 70. Each layer 70 includes planar ply 52 and convoluted ply 56. Planar and convoluted plies 52 and 56 are bonded to (or otherwise cooperate with) eachother to define a multiplicity of channels 58 therebetween. Layers 70 may be stacked such that convoluted plies 56 abut, thereby defining another multiplicity of channels 58 therebetween.

These embodiments of layers 34 include a corrugated plastic (resin) material with a nominal weight appropriate for the structure, and often between a range of about 140 and 160 pounds per thousand square feet. One nominal weight may be about 150pounds per thousand square feet. The plastic resin may have a 4.0 to 4.5-millimeter profile. The plastic resin may further include an about 4.0 (. -.0.2) millimeter profile. The plastic material may still further be black and include ultraviolet (UV)inhibitors to enable the plastic resin to withstand extended exposure to direct UV light. The plastic resin may include a high-density, polyethylene, corrugated, plastic resin with a brittleness temperature of about -103.0 degrees F., a deflectiontemperature of about a 162.0 degrees F. at 66 pounds per square inch, a burn rate of about 2.5 inches per minute, a self-ignition temperature of about 734.0 degrees F., and may also merit a label of "excellence" for smoke density of a 9.3 percentaverage.

Referring to FIGS. 7 and 8, exemplary sheet 80 may be formed of the materials discussed with respect to FIG. 4 and further described above. Thus, sheet 80 includes a multiplicity of channels 58 defined by a cooperation of members such as planarplies 52 and 54 and convoluted ply 56. Sheet 80 displays first and second surfaces 82 and 84. Exemplary layers 34 may be formed from sheet 80 by the slit-scoring technique or by the nick-scoring technique, each technique being more fully describedbelow. Alternatively, layers 34 may be formed by completely severing sheet 80 generally along lines 86. Separate layers 34 are then stacked and fixed as described above.

The slit-scoring technique is described in U.S. Pat. No. 4,803,813, issued to Fitterman on Feb. 14, 1989, the entire contents of which are hereby incorporated by reference. In the slit-scoring technique, hingelines 88 alternate withhingelines 90. Hingelines 88 are defined by extending a slit generally along a line 86 and parallel (or generally transversely) to channels 58. The slit extends through planar ply 54 and convoluted ply 56, thereby leaving planar ply 52 intact. Hingelines 90 are defined by extending a slit generally along a line 86 and generally parallel to hingelines 88. The slit extends through planar ply 52 and convoluted ply 56, thereby leaving planar ply 54 intact. Intact planar plies 52 and 54 are thusused as hinges and batten 30 is assembled by Z-folding layers 34 along hingelines 88 and 90 in the manner depicted in FIG. 8.

The nick-scoring technique is an alternative hinge-forming technique described in U.S. Pat. No. 5,094,041, issued to Kasner et al., on Mar. 10, 1992, the entire contents of which are hereby incorporated by reference. In the nick-scoringtechnique, lines 86 include a series of generally linear perforations. Each perforation substantially extends through planar plies 52 and 54 and convoluted ply 56. Substantially intact portions of planar plies 52 and 54 and convoluted ply 56 remainbetween perforations. Lines 86 are thusly formed into hinges and thereby define layers 34. Layers 34 may be Z-folded along lines 86 in a manner substantially resembling FIG. 8 to assemble batten 30.

Still another hinge-forming technique includes forming completely separated layers 34 and hingably connecting adjacent layers 34 with a pliable adhesive member such as tape.

Channels 58 extend generally perpendicularly, or otherwise transversely, to longitudinal axis 36 of batten 30. As more fully described below, batten 30 is installed in generally horizontal rows on a roof. Channels 58 therefore allow water todrain therethrough, preventing water pooling and enabling air exchange once tiles, or other similar materials, are installed.

As depicted in FIG. 9, roof 100 includes overlayment 102 installed over a decking member as described above. Battens 30 are fixed to roof 100 in generally parallel rows 104. Rows 104 extend substantially horizontally with respect to the slopeof roof 100. The distance between rows 104 is determined by the dimensions of the tiles or other materials to be installed. As depicted in FIG. 10, exterior roofing members such as tiles 110, are installed atop battens 30. Thusly installed on a roof,battens 30 function to space tile 110 from the remainder of roof 100 and to drain water which has infiltrated between installed tiles 110, thereby preventing the infiltrated water from pooling atop overlayment 102 and preventing the water frompenetrating into the decking and structural members of roof 100. Also as installed on roof 100, channels 58 of battens 30 serve as conduits for air exchange beneath tiles 110, thereby further promoting evaporation of infiltrating water.

Exemplary roof batten 30 may be about 3/8 inches in thickness, 11/2 inches in width, and include two hinged segments 48 inches in length. However, many other dimensions are contemplated to be within the scope of this invention. Exemplary roofbatten 30 may be utilized with clay or cement tiles, including flat tiles, S-tiles, and barrel tiles. Moreover, while exemplary roof batten 30 is depicted as being used in conjunction with roof tiles, other exterior roof materials including slate, clay,metal, and cedar may also be installed using exemplary roof batten 30.

Batten 30 of this invention thereby promotes ventilation and prevents water accumulation beneath tiles or similar exterior roofing members. The result of installing the batten of this invention is thusly a roof, which remains drier and is moreprotected from decomposition and damage than if battens of the prior art were used. The roof batten of this invention will not rot, warp, or absorb water as do many of the wooden roof battens of the prior art. Exemplary batten 30 further eliminatesexcessive nail protrusion through roof coverings, which can also promote water penetration and roof damage. Roof batten 30 of this invention may also enable a substantial decrease in time and expense necessary to install a tile roof as compared tolathe-batten systems of the prior art. Because one embodiment of roof batten 30 includes a pliable, yet resilient resin, tile breakage during installation is reduced when workers step on installed tiles. Other benefits of utilizing batten 30 includeselimination of waste and wood splinters during installation. Exemplary battens 30 also weigh less than wooden battens. In contrast to wood battens, battens 30 are easily cut to desired lengths with utility knives.

Because numerous modifications may be made of this invention without departing from the spirit thereof, the scope of the invention is not to be limited to the embodiments illustrated and described. Rather, the scope of the invention is to bedetermined by appended claims and their equivalence.

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Other References

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Opposition to Plaintiff's Motion to Strike Battels Plus' Defense of Inequitable Conduct, 2:04 CV 01005 PGC, U.S. District Court, District of Utah, Feb. 22, 2005.
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