1) Field of the Invention
The invention relates to materials used in the field of construction and renovation. More particularly, the invention presents a waterproofing membrane and its uses.
2) Description of the Prior Art
Waterproofing membranes are common in the art of roof waterproofing. Known waterproofing membranes are typically provided with a layer of bitumen which may be modified by styrene-butadiene-styrene (SBS), and which is covered on one or both sides with peel-off sheets. The peel-off sheets prevent the successive layers of the membrane from adhering to one another when it is rolled-up for distribution purposes. At the time of installation of the membrane however, the peel-off sheet or sheets must be removed and this operation is found quite cumbersome by installation workers. Prior art waterproofing membranes are typically provided with an embedded reinforcement sheet layer that gives additional tearing resistance to the membrane. The reinforcement sheet is incorporated into the body of the membrane by dipping it into a molten bath of bituminous composition during the manufacture, and it is thus sandwiched within bitumen on both sides.
Bitumen has somewhat inherent adhesive characteristics which can be stimulated by heating. Therefore, known waterproofing membranes are generally applied either by heating with torches, which softens the bituminous layer and allows it to adhere to the rooftop, or by application of hot air-blown asphalt which acts as an adhesive between the membrane and the rooftop. While bituminous membranes modified with styrene-butadiene-styrene (SBS) can be applied with both methods, application with the air-blown bitumen method yields better results because they tend to become excessively softened when submitted to heat, especially in summer. However, the air-blown asphalt method generates strong odors which are found repulsive by workers and the nearby public. There thus remains a need for a waterproofing membrane which would be easier to install while retaining the advantage of being package able for shipment.
In another aspect, in building construction, air leakage can account for an important percentage of the total heat loss in homes because warm air leaks out while cold air leaks in. Along with the air, moisture (vapor) escapes and can condense inside the walls or attic and could cause serious structural damage when mold, mildew and rot occurs. For example, showers in bathrooms are often especially susceptible since the humidity content of the air inside regularly reaches high levels. A good seal in the walls of a shower is desired.
To avoid air and vapor transfers, builders use products to create an air/vapor barrier envelope. The most important property of an air-vapor barrier is the ability to resist airflow and air pressure. A continuous air/vapor barrier completely encloses air within a building, keeping water vapor from entering insulated cavities where it can condense. Vapor retardants inhibit vapor diffusion, but remain partially permeable to air and humidity. Bitumen-based layers are often applied to masonry or sheathing material to create air and vapor barriers. The users of membranes currently face problems when applying such membranes to vertical surfaces, because relatively complex steps are required to achieve robust adherence. Of course, if an effective seal is not attained, the membrane system will leak and not achieve its very purpose. A need is thus felt to improve the means to install such barriers on vertical surfaces.
Now turning to still another aspect, it is know in the field of tile application that many good adhesives need to used at controlled atmospheres, often at 20° C. This is also the case for application of masonry products. This is a problem in applications where a controlled atmosphere is difficult to attain. Refrigerators must sometimes be stopped for several days to change tiles, which causes the loss of profits. A need is strongly felt for an adhesive which may be applied at a wider range of temperatures.
Now turning to yet another aspect, it is know in the field of construction to provide synthetic bricks that are adhered to the walls of buildings to provide an appealing facing. The known systems to adhere synthetic bricks to the vertical surfaces of walls of buildings require many layers in order to provide a durable construction that will last with time and changing weather. A need is thus felt for a system that will make brick surfaces easier to install.
An object of the invention is to provide a membrane which addresses at least some of the inconveniences of the prior art.
An object of the invention is to provide a membrane that can be applied with an adhesive coating without the need of a peel-off sheet.
An object of the invention is to provide a waterproofing membrane which can be applied to a vertical surface more easily than the prior art membranes.
Another object of the invention is to provide a waterproofing membrane that can serve as an adhesive for the purpose of mounting a brick, stone or tile facade.
In accordance with one aspect, the invention provides a waterproofing membrane to be applied on a surface. The waterproofing membrane comprises a bituminous layer of bitumen based waterproofing material having opposite first and second sides and having a thickness of from 0.5 mm to 4 mm; a protective layer of impervious surfacing material directly adhered to said first side of the bituminous layer; a support sheet layer made of a porous material and having a first and second surface with the first surface directly adhered to the second side of the bituminous layer by means of the waterproofing material transuding partially into the pores of the support sheet; and an adhesive coating to be partially transuded into the pores of the support sheet and to be adhered to the surface.
In accordance with another aspect, the invention provides a method of waterproofing comprising the steps of: providing a support sheet layer, the support sheet layer made of a porous material and having a first and second surface; heating and applying a bituminous layer of bitumen based waterproofing material to the first surface of the support sheet so that the resulting bituminous layer has a thickness of from 0.5 mm to 4 mm, and an exposed side; adhering a protective layer of impervious surfacing material directly to said exposed side of the bituminous layer, the protective layer, bituminous layer and support sheet layer forming a waterproofing membrane; applying an adhesive coating to at least one of a support surface and the second surface of the support sheet; and adhering the second surface of the support sheet layer to the support surface by the adhesive coating.
In accordance with still another aspect, the invention provides a method of adhering appliqués to a membrane having a bituminous layer of bitumen based waterproofing material, the method comprising the steps of: softening a selected portion of the bituminous layer by heating; and applying the appliqué against the selected softened portion of the bituminous layer.
Further features and advantages of the present invention will become apparent from the following detailed description, taken in combination with the appended drawings, in which:
It will be noted that throughout the appended drawings, like features are identified by like reference numerals.
Referring to
Turning now to
The bituminous layer 12 is made of between 50 and 100% by weight of bitumen which can be mixed with polymers, among others. Bitumen has the property of being waterproof and exposes an certain amount of inherent adhesiveness. Different types of bitumen exist, bitumen which have a penetration number comprised between 60 to 220 dmm and a softening point comprised between 70° C. and 140° C. are preferably used for modification with polymers. It is furthermore possible to use mixture of various types of bitumen, and the properties of the bitumen can be modified by adding mineral oils, fatty substances, chemical agents which make it impenetrable to roots, and others. The preferred bitumen is Type III oxidized bitumen, available from Shell.
The ratios of polymers used in preparing a bitumen mixture may vary depending of the physical and chemical properties needed. In a waterproofing membrane, for example, the bituminous layer 12 may comprise between 5 to 15% by weight of copolymers, which can be, for example, a mixture of between 25 to 70% propylene, 20 to 70% butene and 0 to 15% ethylene.
Instead, or in combination with a polymer, a filler can be blended into the bituminous mixture. The types of fillers commonly used are various, among them are included slate powder, calcium carbonate, talc, kaolin and other compounds which are well-known in the art. The usual purpose of the filler is to increase the stability of the mixture. Preferably, the filler used may have such a fineness as to pass through a 75-micron screen, although fillers which pass to an extent through a 60-micron (200-mesh) screen may also be used.
The membrane 10 can be used as an adhesive instead of being used only for its waterproofing characteristics, in which case the use of fillers is preferably avoided. The bituminous layer can be softened by heating which increases its adhesiveness, and it then returns gradually to its firmer state as the heat dissipates. The adhesiveness characteristics of the bituminous layer 12 can be increased substantially by adding a “tackifier” blended in with bitumen. The adhesiveness of the bituminous layer 12 can be evaluated by the quantity of pounds per square foot that can be applied to an adhered decorative brick 32 before the brick 32 is pulled apart from the surface. The best results were achieved using styrene-isoprene-styrene (known as SIS) in a concentration of 5% to 30%, preferably 12 to 18%, and most preferably 15% by weight, homogeneously blended into a bituminous layer of 1 mm thickness, as the tackifier, which resulted in adhesion characteristics of over 12 pounds per square foot. SBS (Styrene-Butadiene-Styrene) may also be used, especially in applications where the adhesiveness of the membrane is not a priority. Alternative tackifiers selected to enhance the adhesive characteristics of the membrane should both generate desired adhesion characteristics in the membrane 10, and be compatible with bitumen.
The thickness of the bituminous layer is between 0.5 and 4 mm, but preferably 1.0 to 1.5 mm. If it is too thin however, it does not provide desirable adhesiveness and adaptability to the slightly rugged surfaces of decorative bricks 32. If it is too thick, it becomes overly cumbersome and loses some resistance to shearing forces.
The kraft paper 14 acts as a support sheet to the bituminous layer 12, and is preferably chosen between 0.2 and 0.3 mm thickness and of a density of between 36 and 44 pounds per cubic foot. Its function is to provide tearing resistance to the membrane 10 and to facilitate the adherence of the membrane to a surface using the adhesive coating 20. The preferred process to combine the bituminous layer 12 and the kraft paper 14 includes applying molten bitumen mixture onto the kraft paper 14. The kraft paper 14 is sufficiently porous to allow partial penetration or transuding of the molten bitumen into its pores, and yet sufficiently resistant to provide the desired tearing resistance to the membrane 10. Alternative support sheets can be used but should preferably have similar porosity and tearing resistance to maintain the desired characteristics. Suitable alternatives could be other types of paper, fabrics, fiber matrix, or mixtures of these.
The polyethylene film 16 can be referred to as the protective layer. Although this layer is optional, its use is advantageous because it impedes adhesion of the waterproofing layer that would otherwise be exposed and therefore provides for shipping the membrane as a roll or as stacked panels. In applications where the membrane is used as an adhesive, the use of a thin film (less than 20 μm) of low-density polyethylene as the protective layer is useful because it will go up in smoke when the membrane is heated, thus exposing the softened bituminous layer, and will not affect the adhesive characteristics of the membrane. Other types of protective layers having similar characteristics can be substituted to the polyethylene film 16, and should be thin and of low density. The polyethylene film can be applied onto the softened bitumen layer, or after it has hardened, and will typically adhere to it either way.
In applications where the membrane 10 is used solely for its waterproofing characteristics, it is not necessary for the protective layer 16 to be burnable by the heat since the membrane 10 is typically not heated. The array of permissible substitutes is thus substantially increased. For example, a sheet of metal can be used and further protect the bituminous layer 12 from UV light once the membrane is installed on a roof, for example.
The surface 18 on which the membrane 10 is applied can be a wall, a roof, a board, or any other suitable surface. The adhesive coating 20 that is used to secure the support sheet 14 to the surface 18 can be adapted to the specific use of the membrane 10. Wall-paper glue has been found quite useful to install the membrane 10 directly on a wall, but alternative adhesive coatings such as that formed by a two-sided adhesive film or a contact adhesive can be used. However, to apply the membrane 10 to a vertical surface, it is preferred to provide it on a board 24 (see
The board 24 on which the membrane 10 is preferably provided can be of any suitable material, like a wood fiber board, a gypsum board, a perlite™ board, an insulating board or a board of plywood. When using the panel 26 in or against an external wall, it is advantageous to use an insulating board, made of an insulating material such as polystyrene, because the waterproofing panel then provides all three of waterproofing, insulating and adhesive characteristics at once and can be applied by a worker in a single step of fastening.
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Advantageously, when waterproofing panels 26 are disposed side by side, a bond in the bituminous layers 12 of the successive panels 26 can be achieved simply by heating the junction between the panels 26 with a metal plate to form a continuous seal 31. This is important when creating air-vapor barriers. The softened bituminous layer 12 of one panel 26 then fuses with the softened bituminous layer 12 of the adjacent panel. When fasteners 30 are applied, they typically generate heat during penetration, this heat will contribute to softening the bituminous layer 12 and maintaining an impervious seal around the fasteners 30. In applications where the waterproofing membranes 10 are used without boards, they can be overlapped and heated to adhere to one another at the juncture portion, or a tape made of the waterproofing membrane 10 can be applied in an overlapping manner between two membranes 10 or panels 26 onto a portion of heat-softened bitumen.
With reference to
The best adhesion characteristics of the membrane were obtained when the surface of the appliqué, which is adhered to the membrane, is smooth and porous to create a strong bond with the bitumen. Decorative bricks 32 are preferably made by cutting bricks in two along their length, which is illustrated in
The decorative bricks 32 are preferably, sequentially installed one by one by successively heating a portion of the membrane to soften the bituminous layer 12, and applying the decorative bricks 32 against the softened portion with slight pressure. Mortar can be added between the bricks 32, on the bituminous layer 12, to achieve a natural finish. Once a brick 32 is installed, a seal can be created above it by heating: the area above the brick 32 for the bituminous layer 12 to slowly liquefy, and an accumulation of the bituminous composition dams up on the top edge of the brick nearest to the membrane 10. Water is thus kept from seeping in behind the brick 32 through sealing imperfections. Turning now to
The embodiment(s) of the invention described above is (are) intended to be exemplary only. The scope of the invention is therefore intended to be limited solely by the scope of the appended claims.
This application is a continuation-in-part of U.S. patent application Ser. No. 09/933,798 filed Aug. 22, 2001, Ser. No. 10/338,857 filed Jan. 9, 2003, and Ser. No. 10/486,838 filed Nov. 16, 2004, the specifications of which are hereby incorporated by reference, all of which are now pending.
Number | Date | Country | |
---|---|---|---|
Parent | 09933798 | Aug 2001 | US |
Child | 11159236 | Jun 2005 | US |
Parent | 10486838 | Nov 2004 | US |
Child | 11159236 | Jun 2005 | US |
Parent | 10338857 | Jan 2003 | US |
Child | 11159236 | Jun 2005 | US |