The present invention relates to concrete masonry for veneering the face of a building and particularly to a large concrete masonry unit that can be produced on conventional block making equipment.
Concrete masonry units (CMU) are typically produced in commercial block machines. The standard sized CMU or concrete block produced is 8 inches tall by 8 inches wide by 16 inches long and includes two large cores. This block is referred to as the 8-inch block and is the standard of the industry.
A block machine typically makes three 8″ blocks at a time, and those blocks are typically compressed and formed in about 10 seconds on the machine. The blocks are free standing after the forming step, and are then transported to a kiln in which low-pressure steam heat is applied to cure the concrete.
Another product that is commonly produced by the masonry industry is the concrete masonry veneer unit. As the veneer units are used to provide a facade on a building, they do not require the structural strength of an 8″ block and are typically produced with a 4-inch width. Although the standard veneer unit is typically 8″ tall by 16″ long, larger sizes are also desirable, including 12″ tall by 16″ long or even 16″ tall by 24″ long. To reduce the cost of the veneer units, block makers have added interior cores to the veneer block. The conventional veneer block produced on a commercial block machine is a nominal size of 8″ tall by 16″ long by 4″ wide.
During a ten second block making cycle, the mold goes into place in the machine, a feed drawer moves overhead with the concrete mix, the mix goes into the mold and slightly overfills it while at the same time the mold is vibrated mechanically to cause the mix to flow rapidly to the bottom of the mold, and an overhead compressive ram moves down and compresses the mix in the mold into its final shape. A standard 8″ block has a face shell thickness of about 1 inch. For the pour cycle of the block machine, the 1″ opening for the face shell becomes a limitation on production, as it is difficult to get the mix to drop down and fill the mold in the allotted cycle time. This becomes even more difficult when producing a standard veneer block, which has a face shell thickness of about ¾″. It is difficult to get the mix to flow into the narrow face shell area in the short time frame of the block making cycle. It is therefore very difficult to produce conventional hollow core veneer blocks on a commercial block machine, as a result of the difficulty in getting the mix to flow into the narrow mold in the short duration of the block making cycle.
There is now an increased demand for veneer blocks taller than the standard 8″ size. The added height of the taller hollow core veneer blocks makes it even more difficult to produce them in a commercial block machine. Tall veneer blocks, such as those 12″ tall by 16″ long or 16″ tall by 24″ long, are therefore produced as solid rectangular shaped blocks, which, since they lack cores and therefore lack the narrow face shell cavities in the mold, are easily filled by a commercial block machine. Although solid rectangular shaped veneer blocks are adequate for veneering the face of a building, they are not optimal as the solid block adds to both its weight and production cost.
What is needed therefore is a block that can be produced on a commercial block machine within a standard production cycle but with the weight and cost advantages of a conventional hollow core block.
The object of the present invention is to provide a veneer block having the weight and production cost advantages of a hollow core block but without a narrow face shell that limits production in a standard block machine.
These, and other objects and advantages will be apparent to a person skilled in the art by reading the attached description along with reference to the attached drawings.
According to the present invention, there is provided a lightweight concrete masonry unit for veneering the face of a building. The veneer block includes a body with planar front, top, bottom, and side surfaces with the top, bottom, and sides perpendicular to the front surface. One or more channels are formed in the rear surface. The depth of the channels are restricted to maintain no less than one inch of remaining wall thickness between the channel bottoms and the opposite front surface. The novel shape and larger minimum wall thickness of the lightweight veneer block enables production on a commercial block machine within the standard cycle time, realizes weight and raw material cost savings up to 50%, and allows block heights heretofore not attainable with conventional hollow core veneer blocks.
The following is a listing of part numbers used in the drawings along with a brief description:
Referring to
As a result of the channels 34 formed in the rear surface 26, the narrowest part of the block body 22 is the web section 40 between the channel bottom 38 and the front surface 24. The veneer block 20 of the present invention is typically formed in a commercial block machine and it is therefore desirable to maintain the web section 40 at a thickness, between the channel bottom 38 and the front surface 24, of at least one inch. Maintaining the web section 40 at one inch or more ensures that the entire veneer block 20, including the web section 40, will be formed correctly within the short cycle time of the block machine. The present invention therefore provides a lightweight veneer block 20 that achieves its weight advantage without the inclusion of internal hollow cores. Conventional concrete masonry units for veneering typically include hollow cores to achieve a weight and cost advantage. However, for a veneer block having a 4-inch depth, the addition of hollow cores creates a narrow shell face that limits the height to which the veneer block can be produced in a commercial block machine.
The size of veneer blocks are commonly specified by their thickness or depth, height, and length. The preferred embodiment of the veneer block 20 depicted in
Veneer blocks are typically installed on a building structure by one of two methods. One method, anchored veneer, involves mechanical fasteners such as wall ties for securing the blocks to the structure. A second method, adhered veneer, involves a bonding material such as mortar for securing the blocks to the structure.
Referring to
With reference to
The present invention therefore enables the production of lower weight veneer blocks in a commercial block machine without limiting the height of the blocks. The veneer block of the present invention achieves this by its novel shape, which achieves the weight savings without adding interior cores to the block. The novel shape also enables easy production of tall veneer blocks, such as blocks greater than 7 inches in height, which are difficult to achieve in a hollow core veneer block as a result of the narrow shell thickness.
Although the veneer block of the present invention has preferably two channels, it could also be produced with one, three, or other channels, as long as the design provides adequate bottom and rear surface area for bonding to the building structure. Also the invention is not restricted to channels shaped as shown herein. The channel sidewalls could be at other angles or could be curved instead of straight, if preferred, as long as the veneer block were designed to be stable when standing on its bottom surface. For the preferred embodiment shown in
As shown in
To enhance the attractiveness of the veneer block 20, the front surface 24 or face of the block can include a glossy finish. This is achieved by controlling the raw ingredients, the particle size distribution of the ingredients, and by a multiple step finishing process including grinding and sanding the face of the block.
The rear surface 26 of the veneer block 20, including the channel sidewalls 36 and channel bottom 38, has unglazed surfaces. The rear surface 26 is unglazed to facilitate better adhesion to workable mortars.
The veneer concrete masonry block is typically designed to support the anticipated weight of successive tiers of overhead blocks. Preferably the block has a compressive strength of 1900 psi or greater.
As the invention has been described, it will be apparent to those skilled in the art that the embodiments shown herein may be varied in many ways without departing from the spirit and scope of the invention. Any and all such modifications are intended to be included within the scope of the appended claims.
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