Patent Application
20080155938
1. Field of the Invention
This invention relates generally to a wall on the exterior of a habitable building, and more particularly relates to a wall made of a panel of fiber reinforced concrete stones.
2. Description of the Related Art
Most habitable buildings are made of vertical support members, such as wood or metal studs or steel beams. The support members form a substructure to which sheets of sheathing material is attached. Typical sheathing includes plywood, oriented strand board (OSB) or some type of lightweight, insulating material, such as that sold under the trademark CELOTEX.
The conventional method of applying masonry units, such as stones, bricks and artificial stone, to the exterior surface of a building, such as a house, involves many steps. Once the sheathing is in place on the building, a tar-paper or other moisture-impermeable sheet is stapled or otherwise mounted to the exterior surface of the sheathing. The next step is the attachment of a screen or wire over the paper to the sheathing to which the mortar can attach. The screen is typically stapled or nailed to the sheathing. A common problem with attaching the screen to the sheathing is securely attaching the screen using enough fasteners to keep the screen in place. Once the screen is fastened, a mortar is troweled over the screen. When the mortar will form the base for a plurality of masonry units, such as stones, the mortar is rough so that the stones have a subsurface to which to attach. The stones are then attached to the wall in a pattern that gives the building a pleasing appearance and has sufficient structural integrity. Mortar is then injected in gaps between the stones.
The process of attaching paper, screen and mortar to the sheathing of a conventional building requires substantial skill. Any problems in constructing the underlying structure may not be apparent to the owner of the building until many years have passed and water has infiltrated the building or large amounts of stucco or stone have fallen off the building. Additionally, the process of selecting, cutting and attaching stones to a building's exterior is one that requires time and skill in mechanically cutting and aesthetically arranging the stones.
Therefore, the need exists for a method of forming an exterior of a building that requires less skill than the conventional method, and which is less susceptible to damage from lower skilled artisans.
The invention is a method of forming an exterior wall of a habitable building having a substructure made of vertical support members. The method comprises mounting a first fiber-reinforced concrete panel to the substructure, such as by driving screws through the panel. The first panel has a plurality of adjacent masonry units protruding from the face thereof that are separated by a groove formed between each of the masonry units and the next adjacent masonry unit. The method includes the step of mounting a second fiber-reinforced concrete panel to the substructure, the second panel also having a plurality of adjacent masonry units protruding from the face thereof separated by a groove. At least one of the masonry units of the first panel is separated from at least one of the masonry units of the second panel by a groove. The method includes the step of injecting mortar into the grooves between the masonry units on each panel and into the groove between said at least one of the masonry units of the first panel and said at least one of the masonry units of the second panel. This provides a structural connection between the panels, and hides seams that are formed between panels.
The invention contemplates the use of a wall panel comprising a fiber-reinforced concrete rear plate and a plurality of fiber-reinforced concrete masonry units protruding from a face of the rear plate. Each of the masonry units is spaced from the next adjacent masonry unit by a groove for receiving mortar. Shoulders are formed on the periphery of the panel adjacent each of the masonry units for forming a groove that can receive mortar when the wall panel is mounted to the building. In a preferred embodiment, a flashing is formed on at least one edge of the rear plate for being received under a masonry unit of another wall panel. In a preferred embodiment, at least one rib is formed on a major surface of the rear plate and protruding in a direction substantially opposite the masonry units for positioning the wall panel against the building. The rib prevents rocking of the wall panel when it is aligned against the building.
The invention permits stone, brick, tile and other modular masonry units to be formed on individual panels before the panels are attached to a building. This may eliminate the need to attach tar paper and screen to the sheathing of the building, and removes much of the room for error in the installation process. Additionally, the finished product is mold-resistant, much stronger than walls made with conventional sheathing materials, and less costly to construct.
In describing the preferred embodiment of the invention which is illustrated in the drawings, specific terminology will be resorted to for the sake of clarity. However, it is not intended that the invention be limited to the specific term so selected and it is to be understood that each specific term includes all technical equivalents which operate in a similar manner to accomplish a similar purpose. For example, the word connected or term similar thereto are often used. They are not limited to direct connection, but include connection through other elements where such connection is recognized as being equivalent by those skilled in the art.
The panel 10 in
The stones 13-16 are preferably integral with the rear plate 17 (see
The panel 10 is preferably formed from glass fiber reinforced concrete (GFRC), but can be made of other fiber-reinforced cementitious materials, or may be made from unreinforced concrete, or a combination of a reinforced plate 17 and unreinforced stones 13-16. When the panel 10 is formed, preferably by pouring or spraying uncured concrete into a mold, the stones 13-16 are preferably formed at the same time as, and integrally with, the rear plate 17. Thus, no adhesive or mortar is needed to connect the stones 13-16 to the rear plate 17, because the entire unit is one piece. Alternatively, the process could involve a first pour for the stones and a second pour for the backer, which may be a different or the same material; or the backer could comprise a separate piece. The concrete may be colored before molding, or colored afterward.
The preferred panel 10 is preferably made of about 1-2 weight percent water reducer, about 1 percent plasticizer, about 25 percent alkali-resistant chopped glass fibers (different sizes and shapes) with the balance being half portland cement and half lightweight sand. These materials are mixed together, sprayed into a mold and cured to form a sheet. Of course, the panel 10 can be formed by pouring or injecting into a mold, and using other processes.
The panel 10 can be a standard size for construction sheathing, such as four feet wide by eight feet long, or it can be in smaller sizes to reduce weight so that two average men can lift and install the panel 10. The thickness can vary between about one inch and several inches, such as a eight inches, ten inches or even twelve inches thick. The dimensions of the panel are not limited other than by the ability of the end user to install it. Thus, if two men are going to install the panels, the dimensions will be different than if a crane is going to be used.
Of course, other materials can be used to make the panel. Additionally, panels of other sizes can be made, as will be recognized by the person having ordinary skill in the art. For example, a panel could be made that is the length and width of the entire side of the building. Panels can be manufactured that have window openings already formed in the appropriate areas. Still further, panels can be made that extend around corners of the building to avoid seams at building corners.
The panel 10 is mounted to the substructure of a building, such as a home, office, commercial building, outbuilding, condominium or any other building that is habitable, and forms the exterior sides of the building. The substructure of the typical building is made of wooden or steel stud walls, such as those referred to as “two-by-fours”, vertically oriented to support the floor above. However, the substructure in some buildings is made of large wooden, steel or other posts or beams at corners only. The present invention can be used with any such substructure to which it can be mounted.
The panel is attached to the substructure by fasteners, such as nails, screws, staples or any other fasteners driven through the panel into the studs of the substructure, or alternatively may be adhered thereto. The nails mount the panel to the substructure in a manner similar to a sheet of a material conventionally used as a sheathing, such as OSB or plywood, is mounted to a substructure in a conventional building. The panel 10 is rigidly mounted to the studs to provide the same or better sheathing as conventional sheathing materials. The panel 10 can be used in combination with conventional sheathing, or as a substitute for conventional sheathing and may provide structural reinforcement for the wall.
The fasteners are driven through the rear plate 17 on the flashing 11 and 12 and into the substructure of the building, such as the studs or sheathing that lies behind the panel 10. The fasteners can also be driven through the gaps 100 and 103 between the stones 13-16. The rear plate 17 is preferably parallel to the plane formed by the exterior walls of the building. The invention can also be mounted on a floor or roof of a building, for example, if the product has tile-shaped masonry units or other structures suitable for such an environment. In this configuration, the rear plate is parallel to the plane of the structure to which the panel is mounted. It may also be desirable to seal between the panels in such applications to make a more waterproof system.
Once the panel 10 is mounted in place, another similar panel 20 is mounted adjacent the panel 10 as shown in
When the stones 24 and 26 overlap the flashing 11, grooves are formed between the stones 24 and 13 and the stones 26 and 15. The grooves simulate the grooves formed between conventional stones mounted to a wall, as are the grooves 100, 101, 102 and 103 (see
After the panels 10 and 20 are mounted to the building, the panel 30 is mounted to the building with its stones 33-36 aligned with the stones of the panel 20 in an aesthetically pleasing manner. The panel 30 is fastened to the building using fasteners, and grooves are formed between the stones of the panel 30 and the stones of the panel 20. The stones 35 and 36 overlap the upwardly facing flashing of the panel 20, thereby providing another weather-resistant seal prior to mortar being injected in the groove. With the invention, a wall can be constructed when the weather is very cold, because the panels are cured concrete. Subsequently, when the weather is warm enough, mortar can be injected between the masonry units. Between installation of panels and the injection of mortar, the wall is still weather-resistant enough, by virtue of its water-shedding structures, to be unconcerned about substantial weather-related problems.
It is preferred that a sufficient number of panels be attached to the wall of the building to substantially cover the portion of the building that is desired to be covered by the masonry units on the panels. Once this is accomplished, a grout material is disposed, preferably by injecting, in every groove between every masonry unit. This grouting of the stones in the panels accomplishes many purposes. First, grout completely prevents rain, snow, air, insects and other outdoor matter from penetrating the panel. Second, grout may provide some mechanical support between the panels. Third, grout hides all grooves and panel seams in such a way that it is virtually impossible to determine whether the wall formed by the panels was installed as panels with multiple, integral stones, or one stone at a time in a conventional manner. This is because the same grout is injected in the grooves between masonry units on the same panel as is injected into the grooves between stones on separate panels. Thus, the grout between each stone within a panel is the same as the grout between each stone on different panels, and once the grout is in place the seams between panels are not visible. Thus, one cannot distinguish between panels, which would not be the case with pre-grouted panels.
In the preferred embodiment, the panels are installed from right to left and from bottom to top, which is determined by the positioning of the flashing on the top and left edges. The textures and surfaces of stones are of standard artificial stone. Alternatively, the panels could be installed from top to bottom and/or left to right, especially if the panels are reconfigured for such installation, but the first technique is preferred for the panels shown in the Figures.
Each panel preferably has spacers formed on edges, such as the edges with the flashing, to space each panel's stones from the adjacent panel's stones and thereby maintain a constant gap for the mortar. Referring to
An alternative to the stone-shaped masonry units as on the
By having the rib 58 and the cooperating void 59, the panel 50 can be cut along its length at any point and still rest with stability against the wall. Additionally, the panel 50 will also still overlap another panel's flange.
An alternative wall panel 60 is shown in
Cornerpieces can be made to fit over corners of buildings to reduce the infiltration at the weak area of a building. A cornerpiece 80 is shown in
The corners having flashing 82 and 83 that the masonry units at the end of an adjacent wall panel overlap. Masonry units 85 and 86 (see
The masonry units in each wall panel and the cornerpieces are arranged so that they can be cut at any point and they will match up with (by either over or under lapping) the next panel.
The panels have flashing at one end and at the top, which is preferably about one-half inches thick. The panels also have masonry units at the opposite end and at the bottom having a rear relief, so that the overlapping masonry units extend over the flashing when two panels are mounted adjacent one another. This provides a water shedding feature while the building is under construction.
While certain preferred embodiments of the present invention have been disclosed in detail, it is to be understood that various modifications may be adopted without departing from the spirit of the invention or scope of the following claims.
