This invention relates to the field of building materials. More particularly, this invention relates to crushed stone building systems.
Historically, construction of walls, interior and exterior, has implemented numerous building methods and materials. Ancient societies such as the Ancient Egyptians and the Sumarians are believed to have initiated large-scale manufacture of bricks with a systematic approach using engineered dimensions for wall construction and other types of building.
Conventional bricks, also called compressed earth blocks (CEBs), in use today are typically ceramic blocks made of kiln-fired materials, such as clay. On a small scale, clay bricks are formed in a mold, which is called the soft mud method, and on a large, commercial scale, clay bricks are made by extruding clay through a die and wire-cutting the bricks, which is called the stiff mud process. Sometimes the clay is mixed with water and these dampened clay bricks are subjected to high pressures. Such bricks are highly resistant to weathering and therefore well-suited for construction of exterior walls. The shaped clay is dried and fired to achieve the final brick shape with the desired strength. The firing process is usually done by a continuously fired kiln, in which the bricks move slowly through the firing on a conveyor belt or the like. This enables production of an essentially indefinite number of bricks which exhibit consistent physical characteristics.
Other types of building materials are sometimes used for wall construction, including wood, vinyl, stucco, and/or stones. For many years stones or natural rocks were thought by many in the building trade to be superior to bricks both functionally and aesthetically. However, stones for use in wall construction are typically heavier than bricks and must normally be sculpted into the proper shape. Some prefer stone walls because the stones are shaped and colored more naturally and randomly, and provide less of an “assembly-line” look, and more aesthetically pleasing look. However, using such irregular shapes in construction of a wall introduces difficulties in addition to regular building considerations. For example, irregular shapes may require individual stones to be broken/sculpted in order to finish the corner or side of a wall or to fit with other stones in the construction of a wall. However, this is very difficult, time-consuming, and wasteful because stones and rocks tend to break and crack irregularly. For this and other reasons, the commercial success of “natural” stone walls remains limited, despite their aesthetic, functional, and other advantages.
Attempts have been made to produce manufactured stone walls which do not require the use of sculpted or reshaped stones. Such attempts have comprised cast stone “tiles” which are cast from aggregate and/or ground stone and are plastered to the sides of a building to provide the illusion of natural stone walls. However, such stone tiles are not easily used in conjunction with conventional bricks.
A recent trend in home building involves the use of varying external materials to build a single wall, such as areas of brick and areas of wood paneling and/or areas of brick and areas of stone all in one wall surface. However, there is no known method of effectively combining bricks and stones in the production of a wall. The regularity of bricks and the irregularity of stones makes it very difficult to integrate the two into a single wall structure, even with the use of the aforementioned manufactured stone tiles.
Further, unlike the stone tiles, conventional bricks are laid on top of each other a certain distance from the side of a building to create a brick wall. The space between the bricks and the side of the building has the advantage of acting as an insulating space. Such a space is not possible with stone tiles, which are plastered to the side of a building. Accordingly, it is desirable to provide a wall with a stone appearance which enjoys such insulating properties.
In relation to the above and other needs, the present invention include a manufactured stone for use in building a wall, the manufactured stone having a plurality of surfaces, wherein at least one of the surfaces includes a simulated-stone appearance and having a length, a height, and a depth, and wherein at least one of the length, height, and depth are determined based at least on a compatibility factor. The compatibility factor is used to derive a dimension equation for the length, height, and depth and the dimension equations are used to fabricate the manufactured stone blocks.
Further advantages of the invention will become known by reference to the detailed description when considered in conjunction with the figures, which are not to scale so as to more clearly show certain details, wherein like reference numbers indicate like elements throughout the several views, and wherein:
Referring now to
Crushed stone or an aggregate mixture, or other material suitable for creating simulated-stone blocks, may be used for the manufactured stone blocks 22. Referring now to
Referring now to
As shown, the manufactured stone blocks 22 making up the front face 38 of the wall 24 may vary in shape and dimensions. However, in a preferred embodiment of the invention, both the length 26 and the height 28 are based on compatibility factors. The compatibility factors allows the maker of the manufactured stone blocks 22 to fabricate numerous shapes and sizes of manufactured stone blocks 22 that may be used in conjunction with one another to build a stable, well organized wall 24. The dimensions of the manufactured stone blocks 22 are proportional so that various sizes of manufactured stone blocks 22 may be used in conjunction to build a wall 24. This provides improved structural integrity and support, but also a desired seemingly disorderly and more natural appearing organization of the manufactured stone blocks 22 on the wall 24.
The compatibility factors are preferably determined based on the dimensions of the classic clay brick, sometimes referred to as a compressed earth block (“CEB”). The dimensions of a compressed earth block in the United States typically include a length 26 of about eight (8) inches, a height 28 of about two and one quarter (2.25) inches, and a depth 30 of about four (4) inches. Thus, the compatibility factor for the length 26 is eight (8) inches in a preferred embodiment. Also, the compatibility factor for the height 28 is two and a quarter (2.25) inches and the compatibility factor for the depth 30 is four (4) inches and remains constant, that is, the manufactured stones 22 are preferably manufactured with dimensions at multiples of the compatibility factors for length 26 and height 28, but are manufactured at substantially the compatibility factor for depth 30, which is substantially equal to the depth 30 of a compressed earth block.
One motivation and advantage behind sizing manufactured stone blocks 22 based on their CEB counterparts is that the manufactured stone blocks 22 and the CEBs may be easily used in conjunction if their shapes are proportional. With reference to
Mathematical relationships discussed below relate the dimensions of the CEBs 50 to the dimensions of the manufactured stone blocks (MB) 22 and may be used in the manufacture of manufactured stone blocks 22. The manufactured stone block 22 dimensions are represented by the functions L(N), H(N) and D for length as a function of N, height as a function of N, and depth, respectively. The relationships between the dimensions of the manufactured stone blocks 22 and the CEBs 50 may be understood with reference to
The lengths 58 of the MBs 22 are not simply half of the length 52 of the CEB. One must account for the mortar or similar substance used for setting the CEBs 50 and MBs 22 in place. The width of the mortar (MW) is represented by 54 and is preferably about half an inch. Thus, the length 58 of an MB 22 in order to fit two MBs for every one CEB (also referred to as the first size of MBs) is represented by the equation as follows:
L=(½)(CEBL)−(½)(MW).
Referring now to
L=CEBL.
Referring now to
L=( 3/2)(CEBL)−(½)(MW).
Referring now to
L=(2)(CEBL)+MW.
The lengths 58 of the above sizes and the remaining sizes of MBs may be represented by the equations compiled in TABLE 1 below.
TABLE 1 compiles the various equations representing the lengths 58 of MBs 22 corresponding to a particular value of the integer variable N. These various equations, however, may be represented by a simplified equation including N as a variable and not a number as follows:
L(N)=(N/2)(CEBL)+[(N/2)−1][MW],
wherein L is a function of N and L is the length 58 of the MB 22, N is an integer variable, CEBL is the compatibility factor for length, which is preferably the length 52 of the CEB 50, and MW is the mortar width, which represents the preferred width of any mortar-like substance used to build the wall.
Similarly, the height 28 of the MBs 22 may be represented a simplified equation as follows:
H(N)=(N/2)(CEBH)+[(N/2)−1][MW],
wherein H is a function of N and H is the height 28 of the MB 22, N is an integer variable, CEBH is the compatibility factor for height, which is preferably the height 28 of a CEB 50, and MW is the mortar width, which represents the preferred width of any mortar-like substance used to build the wall.
As discussed above, the depth of the MBs is preferably constant and is represented by the equation as follows:
D=CEBD,
wherein D is a constant and represents the depth 30 of the MB 22 and CEBD,is the depth of the CEB 50.
In other embodiments, different compatibility factors may be chosen and equations representing those compatibility factors may be derived. For example, if CEBs from the United Kingdom were being used in conjunction with MBs 22, the compatibility factors may be CEBL=215 millimeters, CEBH=65 millimeters, and CEBD=102.5 millimeters, which are the standard dimensions of CEBs in the United Kingdom. Thus, MBs could be manufactured according to the derived equations and used in conjunction with United Kingdom CEBs without the need for time consuming modification of MBs 22.
Referring now to
Referring now to
Further, in other alternate embodiments of the invention, MBs may be used to construct a wall in conjunction with other building materials, such as wood paneling or vinyl siding, where certain dimensions of the building materials are used to derive the compatibility factors and related equations for determining the dimensions of MBs.
Referring now to
The foregoing description of embodiments for this invention have been presented for purposes of illustration and description. They are not intended to be exhaustive or to limit the invention to the precise form disclosed. Obvious modifications or variations are possible in light of the above teachings. The embodiments are chosen and described in an effort to provide the best illustrations of the principles of the invention and its practical application, and to thereby enable one of ordinary skill in the art to utilize the invention in various embodiments and with various modifications as is suited to the particular use contemplated. All such modifications and variations are within the scope of the invention as determined by the appended claims when interpreted in accordance with the breadth to which they are fairly, legally, and equitably entitled.