FIELD OF THE INVENTION
This disclosure relates to repeating elements forming a surface covering and/or structure, and more specifically relates to stones, bricks, pavers and tiles for forming surface coverings, walls or other structures.
BACKGROUND OF THE INVENTION
It is well known to cover surfaces, such as walkways, driveways, patios, floors, work surfaces, walls and other interior or exterior surfaces with stones, bricks, pavers, tiles and other architectural surface covering units. It is further known to construct walls and other structures with stone and bricks. Natural stone surface coverings and structures are constructed by cutting and fitting irregularly sized and shaped stones. The work requires a skilled stonemason to select, cut and fit the stone. It is labor intensive, and accordingly expensive. Custom built natural stone surfaces and structures, however, are very attractive and desirable.
Conventional surface coverings and structures are also constructed of manufactured pavers, bricks, tiles or other units. Manufactured units are typically provided in geometric shapes, such as squares, rectangles and hexagons, or combinations thereof. Surfaces covered with manufactured units typically are laid in repeating patterns. Alternatively, it is known to lay conventional units in random, non-repeating patterns. Random patterns are regarded as esthetically pleasing and are becoming more popular. However, random patterns of manufactured units do not have the degree of natural irregularity that is desirable in custom stone walkways, driveways, patios, walls and the like.
Tessellated designs are generally known. For example, M. C. Escher is widely know to have created tessellated designs comprised of repeating patterns of recognizable animals, plants and things, such as geckos, birds, fish and boats. It is an object of tessellated design to feature repeating patterns.
SUMMARY OF THE INVENTION
According to the present invention there is provided irregular, tessellated building units. As used herein, the term “building units” or “units” refers to a bricks, blocks, stones, tiles or other two or three dimensional objects that can be used in the construction of floors, walls, retaining walls, columns or other structures, including interior and exterior structures, and including load bearing and non-load bearing structures. Each building unit has a planar configuration comprised of one or more primary rotational tessellation elements. By “planar configuration” we refer to the outer contours of the unit defined by a plane through the middle of the unit substantially parallel to the front and back faces, such outer contours being the mating sides of adjacent units.
As used herein the term “tessellation” means a shape such as a tile that repeats to cover a surface without substantial gaps or overlaps. The term “substantial gaps” means comparatively large gaps, holes or spaces that would detract from the appearance of the covered surface. The term, “without substantial gaps” means no gaps and/or comparatively small gaps that may be filled with sand or mortar, which do not adversely detract from the appearance of the surface covering or structure. A “rotational tessellation” is a type of tessellation wherein a primary element is repeated by rotating the primary element a number of times about a point or vertex. A “translation tessellation” is another type of tessellation wherein a primary element is repeated horizontally, vertically or diagonally side-by-side, normally without rotation. “Tessellation” as used herein can also mean, depending on the context, the combination of multiple units to cover a surface without substantial gaps or overlap. A “primary element” is the smallest cell of the pattern that repeats so as to cover a surface without substantial gaps or overlap. A building unit or tile can comprise one or more primary elements.
The primary element has at least two, preferably three vertices. First and second sides extend in a generally radial direction relative to the first vertex. The first and second sides are rotational images of one another. By the term “rotational image” it is meant that the sides have substantially the same length and configuration, such that a first side of one unit will mate with a second side of another unit. Third and fourth sides extend in a generally radial direction relative to the second vertex and are rotational images of each other. The first and second sides are rotationally spaced apart from one another by an angle θ, where θ is 360 degrees divided by n, where n is an integer (e.g., 60, 90, 120 or 180 degrees). The third and fourth sides are rotationally spaced by an angle φ, where φ is also evenly divided into 360 degrees. The sum of angles θ and φ is preferably 180, 240, 270 or 300 degrees. Preferred embodiments of the invention have primary elements with a third vertex, with fifth and sixth sides extending radially from the third vertex, the fifth and sixth sides being rotational images of each other, rotationally spaced by an angle γ. In these preferred embodiments, the sum of angles, θ, φ and γ is 360 degrees. The primary element may optionally include a substantially straight side.
In accordance with the invention, preferably all the sides of the primary element are irregularly shaped. By the terms “irregularly shaped” and “irregular configuration” it is meant that the side appears jagged or rough hewn and is not a straight line or a smooth curve, such that when multiple units are assembled to form a surface a regular geometric pattern is not readily apparent. However, it should be understood that an irregularly shaped side might comprise a multiplicity of straight-line segments, such that the general appearance of the side is irregular. Optionally, one or more sides could consist of or include a straight segment or a regular geometric curve.
Each building unit of the invention has a planar configuration that is comprised of x primary elements, where x is an integer equal to or greater than 1. The primary element is an irregular rotational tessellation as described above. Units of different sizes and shapes can be constructed with different numbers and arrangements of primary elements. Because all the units are combinations of primary elements, they readily mate with each other. As a result of the irregular side configurations, and different sizes and shapes of individual units, one can construct a continuous surface or structure that has a natural and non-repeating pattern appearance. As indicated there is a tessellation pattern, but the pattern is difficult to visualize. The surface has the appearance of being custom built.
One application of the invention is a surface covering. The term “surface coverings” is used in its broadest meaning, and includes architectural and product surfaces, interior and exterior surfaces, and floors, walls and ceilings. The surface covering comprises a multiplicity of units assembled to form a continuous surface without overlap between units and without substantial gaps between units. Other applications include use as a landscape edger, decorative border or tree ring.
Further applications of the invention are vertical and three dimensional structures such as walls, columns, containers and other structures. Each unit has a tessellated front face comprising one or more primary elements as described above, sides extending substantially perpendicularly from the front face, and a rear face. Preferably, connectors such as lugs or notches are provided to improve the structural connection between units. A structure, such as retaining wall, constructed of such units having different sizes and shapes will have a natural and custom appearance.
A preferred, optional feature of the invention is a building unit having spacers on the sides of the units. The spacers are preferably indented or recessed relative to the front face of the unit so that the spacers typically are not visible in the completed structure. The spacers of each unit define a gap between units, and maintain the integrity of the tessellation pattern. The visible side edges of the unit are drawn in from the construction line by approximately one-half the desired width of the gap. The contour of the visible side edge can be varied somewhat relative to the tessellation pattern to cause a variable gap width between mating units. Variable gap width further enhances a natural, custom appearance.
Another optional feature of the invention is providing indicia on or adjacent one or more sides of each unit to assist in construction of surface coverings or structures. Spacers can function as mating indicia. Alternatively, mating indicia can be separately provided.
Yet another, optional aspect of the invention is to vary the appearance of each unit to further enhance the natural, custom appearance of the surface covering. Variations include edge, surface and color variations.
The foregoing and other aspects and features of the invention will become apparent to those of reasonable skill in the art from the following detailed description, as considered in conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIGS. 1-10 are illustrations of a first embodiment of irregular, tessellated building units of the invention.
FIG. 1 is a plan view of a first surface covering of the first embodiment.
FIG. 2 is an enlarged plan view of a primary element for a first building unit of the first embodiment.
FIG. 3 is a plan view of a second surface covering of the first embodiment.
FIG. 4 is an enlarged plan view of a second unit of the first embodiment.
FIG. 5 is a plan view of a third surface covering of the first embodiment.
FIG. 6 is an enlarged plan view of a third unit of the first embodiment.
FIG. 7 is a plan view of a fourth surface covering of the first embodiment.
FIG. 8 is an enlarged plan view of a fourth unit of the first embodiment.
FIG. 9 is an enlarged plan view of a fifth unit of the first embodiment.
FIG. 10 is an enlarged plan view of a sixth unit of the first embodiment.
FIGS. 11-16 are illustrations of a second embodiment of irregular, tessellated building units of the invention.
FIG. 11 is an enlarged plan view of a primary element for a first building unit of the second embodiment.
FIG. 12 is a plan view of a second unit of the second embodiment.
FIG. 13 is a plan view of a third unit of the second embodiment.
FIG. 14 is a plan view of a fourth unit of the second embodiment.
FIG. 15 is a plan view of a fifth unit of the second embodiment.
FIG. 16 is a plan view of an exemplary surface covering of the second embodiment.
FIGS. 17-22 are illustrations of a third embodiment of irregular, rotational tessellation building units of the invention.
FIG. 17 is an enlarged plan view of a primary element of a first building unit of the third embodiment.
FIG. 18 is a plan view of a second unit of the third embodiment.
FIG. 19 is a plan view of a third unit of the third embodiment.
FIG. 20 is a plan view of a fourth unit of the third embodiment.
FIG. 21 is a plan view of a fifth unit of the third embodiment.
FIG. 22 is a plan view of an exemplary surface covering of the third embodiment.
FIGS. 23-27 are illustrations of a fourth embodiment of irregular, tessellated building units of the invention.
FIG. 23 is an enlarged plan view of a primary element for a first building unit of the fourth embodiment.
FIG. 24 is a plan view of a second unit of the fourth embodiment.
FIG. 25 is a plan view of a third unit of the fourth embodiment.
FIG. 26 is a plan view of a fourth unit of the fourth embodiment.
FIG. 27 is a plan view of an exemplary surface covering of the fourth embodiment.
FIG. 28 is an enlarged plan view of a portion of an example surface covering of the invention.
FIG. 29 is an enlarged plan view of a portion of FIG. 28.
FIG. 30 is an enlarged plan view of a second portion of FIG. 28.
FIG. 31 is a cross-section taken along line 31-31 of FIG. 29.
FIG. 32 is a cross-section taken along line 32-32 of FIG. 30.
FIG. 33 is an enlarged plan view of a portion of another example surface covering of the invention.
FIG. 34 is a cross-section taken along line 34-34 of FIG. 33.
FIG. 35 is a cross-section taken along line 35-35 of FIG. 33.
FIG. 36 is an enlarged plan view of a portion of a further example surface covering of the invention.
FIG. 37 is an edge detail of a building unit of the invention.
FIG. 38 is an elevational view of a fifth, wall embodiment of the invention.
FIG. 39 is cross-section along line 39-39 of FIG. 1.
FIG. 40 is a perspective view of a two building units of the fifth embodiment.
FIG. 41 is a perspective view of a unit of the fifth embodiment.
FIG. 42 is a perspective view of another unit of the fifth embodiment.
FIG. 43 is an enlarged cross-section of an optional spacer between two units of the fifth embodiment.
FIG. 44 is an enlarged cross-section of an optional alternative connector of the fifth embodiment.
FIGS. 45-58 are illustrations of a sixth embodiment of irregular, tessellated building units of the invention.
FIG. 45 is an enlarged plan view of a primary element for a building unit of a sixth embodiment.
FIG. 46 is a line drawing of one side of the sixth embodiment.
FIG. 47 is a plan view of a building unit of the sixth embodiment.
FIG. 48 is a plan view of a multiplicity of building units of the sixth embodiment showing various mating relationships between units.
FIG. 49 is a plan view of the building unit of the sixth embodiment having an optional first molded front face.
FIG. 50 is a perspective view of the building unit of FIG. 49.
FIG. 51 is a plan view of the building unit of the sixth embodiment having an optional second molded front face.
FIG. 52 is a perspective view of the building unit of FIG. 51.
FIG. 53 is a plan view of a surface covering constructed with the building units of FIGS. 49-52.
FIG. 54 is a perspective view of a garden edger or decorative border constructed with the units of the sixth embodiment.
FIG. 55 is a perspective view of a second garden edger or decorative border constructed with the units of the sixth embodiment.
FIG. 56 is a plan view of a ring constructed with the units of the sixth embodiment.
FIG. 57 is a perspective view of a planter or container constructed with the units of the sixth embodiment.
FIG. 58 is an elevational view of a portion of a wall constructed of units of the sixth embodiment.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Preferred embodiments of the present invention are described below by way of example only, with reference to the accompany drawings.
FIG. 1 shows a surface covering 10 constructed in accordance with a first embodiment of the present invention. Surface covering 10 comprises an arrangement of building units without substantial gaps or overlapping. Building units may be molded or otherwise made of concrete, stone, ceramics, plastic, natural or synthetic rubber, glass or other suitable material, or combinations thereof. In FIG. 1, surface covering 10 is comprised of three different sized units 20, 40 and 60. The units have what appear to be irregular configurations. Further, the surface covering 10 has the appearance of a natural, custom surface, i.e., there is no readily apparent repeating pattern.
An enlarged view of unit 20 is shown in FIG. 2. The unit comprises a single primary element 20 of a rotational tessellation as will be described in greater detail below. Primary element 20 has a first side 22 extending between points A and B. Second side 24 extends between points A and E. A transverse side 26 extends between points B and E. Transverse side 26 preferably comprises a series of segments, namely, a third side 28 extending between points B and C, a fourth side 30 extending between points C and D, and an optional fifth side 32 extending between points D and E. First 22 and second 24 sides are irregular, rotational images of one another. First and second sides extend in a generally radial direction relative to a common first vertex 34, and are rotationally spaced by an angle θ. Angle θ is derived from the formula 360°/n where the variable n is an integer, preferably selected from the group of 2, 3, 4 or 6. Thus, angle θ is preferably 60, 90, 120 or 180 degrees. Although n is preferably 6 or less, n could be larger than 6 in some applications. In the example shown in FIG. 2, the variable n is equal to 6 and θ is 60 degrees. The third 28 and fourth 30 sides are rotational images, have a common second vertex 36, and are rotationally spaced by an angle φ. Angle φ is derived from the formula 360°/m where the variable m is an integer. Preferably, the sum of angles θ and φ is 180, 240, 270 or 300 degrees. In the example shown in FIG. 2, variable m is 3 and φ is 120°. The fifth side 32 is optional, that is, the third and fourth sides could extend between points B and E, and thereby complete the circumference of the unit. The fifth side is a substantially straight line in this embodiment. Because the angle θ is defined as 360°/n, n units may be arranged in a rotational tessellation about first vertex 34. Similarly, because the angle φ is defined as 360°/m, m units maybe arranged in a rotational tessellation about second vertex 36.
FIG. 3 illustrates a surface covering 38 formed of a multiplicity of units 20. The first sides 22 mate with second sides 24 of adjacent units. In an analogous fashion, third sides 28 mate with fourth sides 30 of adjacent units. Fifth sides mate with each other. In the embodiment shown in FIG. 3, six units form a complete rotational tessellation about first vertex points 34. Further, three units form a complete rotational tessellation about second vertex points 36.
FIG. 4 illustrates a second, medium size unit 40. Unit 40 comprises two primary elements 20a and 20b as indicated by broken line 41. Unit 40 has sides that match unit 20, namely, a first side 42, second side 44, and transverse side 46 having third sides 48, fourth sides 50 and fifth sides 52. Unit 40 further includes a first vertex 54 and two second vertices 56. In unit 40, the angle between first side 42 and second side 44 is 120°.
FIG. 5 illustrates a surface covering 58 comprised entirely of second units 40. Three units 40 complete a rotational tessellation about vertex 54. Three units 40 also comprise a complete rotational tessellation about second vertex 56.
FIG. 6 illustrates a third or large unit 60, comprising three primary elements 20c, 20d and 20e as shown by broken lines 61. Unit 60 has sides that match units 20 and 40, namely first side 62, second side 64, third sides 68, fourth sides 70, and fifth sides 72. Unit 60 further includes a first vertex 74 and second vertices 76. In unit 60, the angle between the first side 62 and second side 64 is 180 degrees.
FIG. 7 illustrates the surface covering 78 comprised entirely of third units 60. Two units 60 complete a rotational tessellation about first vertex 74. Three units 60 complete a rotational tessellation about second vertices 76.
FIGS. 8-10 illustrate how building units may be made of different sizes and shapes by combining primary elements 20. In FIG. 8, unit 80 comprises two elements 20f and 20g, as reflected by dashed line 81. Unit 80 has two first sides 82, two second sides 84, a third side 88, a fourth side 90, and two fifth sides 92. Unit 80 has two first vertices 94 and a single second vertex 96.
FIG. 9 illustrates another example unit 100 comprising three primary elements 20h, 20i and 20j, as shown by broken lines 101, that are rotationally tessellated about second vertex 104. Unit 100 has three first vertices 102.
FIG. 10 illustrates yet another example unit 110 comprising three primary elements 20k, 20l and 20m as shown by broken lines 111. Unit 110 has two first vertices 112 and two second vertices 114. As will be appreciated by persons skilled in the art, additional units may be formed in other combinations of primary elements 20. The examples shown in FIGS. 8-10 are not ideal for construction of concrete pavers due to sharp edges or narrow mid-sections, but could be feasible if built from other materials. The examples are presented to illustrate the concept of forming units having different sizes and/or shapes by combining primary elements in different ways.
Returning to FIG. 1, one can visualize a plurality of units rotationally tessellated about each first vertex 14 and each second vertex 16. Each rotational tessellation may contain one or more small 20, medium 40 or large 60 units, or a combination thereof. Because of the irregularly shaped sides of each unit and the size variations among the units, the surface appears to be natural and custom fitted, that is, a regular geometric pattern is not readily apparent. Although the embodiment of FIG. 1 has three different size units, namely, single, double and triple element units, it is contemplated that numerous variations are possible, including, for example, a combination of only units 20 and 40, or a combination of only units 40 and 60. Further, it is contemplated that a surface covering could include units 80, 100 or 110, or any other units comprised of a combination of primary elements.
FIGS. 11-16 illustrate building units and an exemplary surface covering of a second embodiment of a rotational tessellation element of the invention. FIG. 11 shows a primary element 120 comprised of six sides, namely, first side 122 extending between points A and B, second side 124 extending between points A and F, third side 128 extending between points B and C, fourth side 130 extending between points C and D, fifth side 131 extending between sides D and E and sixth side 133 extending between points E and F. Together, sides 3 to 6 form transverse side 126. Element 120 has three vertices, namely, first vertex 134, second vertex 136, and third vertex 137. First 122 and second 124 sides are irregular, rotational images of one another, radiate from first vertex 134, and are rotationally spaced by an angle θ of 60 degrees. The third 128 and fourth 130 sides are rotational images of one another, radiate from second vertex 136 and are rotationally spaced by an angle φ of 180 degrees. Fifth 131 and sixth 133 sides are irregular, rotational images of one another, radiate from third vertex 137 and are rotationally spaced by an angle γ of 120 degrees. All six sides are preferably irregular in shape.
FIG. 12 illustrates a unit 140 comprised of two basic elements 120a and 120b as indicated by broken lines 141. Elements 120a and 120b are adjacent elements in a rotation about first vertex 134. The basic elements are joined at an interface 141 of first and second sides.
FIG. 13 illustrates a unit 160 comprised of two basic elements 120c and 120d as indicated by broken line 161. The basic elements are joined at an interface of sides three and four. Elements 120c and 120d share a second vertex 136.
FIG. 14 illustrates a unit 180 comprised of three basic elements 120e, 120f and 120g as indicated by broken lines 181. Elements 120f and 120g are joined along first-second side interfaces and share a common first vertex 134. Elements 120e and 120f are joined at third-fourth side interfaces and share a common second vertex 136.
FIG. 15 illustrates a unit 200 comprised of six basic elements 120h-m as indicated by broken lines 201. First 134, second 136 and third vertices 137 are identified in FIG. 15. As one may observe, unit 200 comprises a pair of primary elements from three different rotations about first vertices 134.
FIGS. 12-15 thus illustrate four ways that basic elements may be combined to form different size and shape units. Additional units may be formed by other combinations of primary element 120.
FIG. 16 illustrates an exemplary surface covering formed of the units illustrated in FIGS. 11-15. A great variety of surface coverings may be formed utilizing combinations of units 120, 140, 160, 180 and 200, as well as other units formed from different combinations of primary elements of the second embodiment.
FIGS. 17-22 illustrate building units and an exemplary surface covering of a third embodiment of the rotational tessellation element of the invention.
FIG. 17 illustrates a primary element 220 of the third embodiment. Primary element 220 has a first side 222 extending between points A and B, a second side 224 extending between points A and F. The second side 224 is a rotated image of first side 222 about first vertex 234. The angle θ of rotation is 90 degrees in the third embodiment. Basic element 220 further includes third side 228 extending between points B and C and fourth side 230 extending between points C and D. Fourth side 230 is a rotated image of third side 228 about second vertex 236. The angle of rotation between sides three and four is angle φ which in case of the third embodiment is 90°. Basic element 220 further comprises a fifth side 231 extending between points D and E, and a sixth side 233 extending between points E and F. Sixth side 233 is a rotated image of fifth side 231 about third vertex 237. The angle of rotation γ there between is 180 degrees.
FIG. 18 illustrates a unit 240 comprised of two primary elements 220a and 220b as indicated by broken lines 241. Primary elements 220a and 220b are joined at the interface between sides one and two of the respective units, and share a common first vertex 234.
FIG. 19 is a third unit 260 comprised of three primary elements 220c, 220d and 220e as indicated by broken lines 261, 263, 265. Elements 220c and 220d are joined at the interface 261 of sides one and two of adjacent elements, and have a common first vertex 234. Element 220e is joined to element 220d at the interface 263 between sides five and six, respectively, and share common third vertex 237. Element 220e is joined to element 220c at the interface 265 between sides three and four, respectively and share common second vertex 236.
FIG. 20 illustrates a unit 280 comprised of four primary elements from the third embodiment, namely elements 220f, 220g, 220h and 220i as indicated by broken lines 281. All four elements revolve around first vertex 234.
FIG. 21 illustrates a fifth unit 300 comprised of four primary elements 220j-m, as indicated by broken lines 301. In unit 300 two elements 220j and 220k are taken from a rotation about first vertex 234a. Elements 220l and 220m comprise adjacent elements about first vertex 234b.
FIGS. 18-21 thus illustrate four ways that basic elements may be combined to form different size and shape units. Additional units may be formed by other combinations of primary element 220.
FIG. 22 illustrates a surface covering formed from a mixture of units 220, 240, 260, 280, 300. As with the other embodiments, the surface covering appears to be an irregular custom made surface, with no apparent repeating pattern.
FIGS. 23-27 illustrate building units and a surface covering of a fourth embodiment of the rotational tessellation element of the invention.
FIG. 23 illustrates a primary element 320 of the fourth embodiment. Primary element 320 has a first side 322 extending between points A and B, a second side 324 extending between points A and F. The second side 324 is a rotated image of first side 322 about first vertex 334. The angle θ of rotation is 120 degrees in the fourth embodiment. Basic element 320 further includes a third side 328 extending between points B and C and a fourth side 330 extending between points C and D. Fourth side 330 is a rotated image of third side 328 about second vertex 336. The angle of rotation between sides 3 and 4 is an angle φ, which in the case of the fourth embodiment is 120 degrees. Basic element 320 further comprises a fifth side 331 extending between points D and E, and a sixth side 333 extending between points E and F. Sixth side 333 is a rotated image of fifth side 331, about third vertex 337. The angle of rotation γ there between is 120 degrees.
FIG. 24 illustrates a unit 340 comprised of two primary elements 320a and 320b as indicated by broken line 341. Basic elements 320a and 320b are joined at the interface between sides one and two of adjacent elements, and share a common first vertex 334.
FIG. 25 is a third unit 360 comprised of two primary elements 320c and 320d, as indicated by broken line 361. Elements 320c and 320d are joined at the interface of sides three and four of respective elements, and have a common second vertex 336.
FIG. 26 illustrates a unit 380 comprised of three primary elements from the fourth embodiment, namely, elements 320e, 320f and 320g, as indicated by broken line 381. All three elements revolve around first vertex 334.
FIG. 27 illustrates a surface covering 400 formed of a mixture of units 320, 340, 360 and 380. As with the other embodiments the surface covering appears to be a natural, irregular and custom made surface, with a non-repeating pattern.
The sum of the vertex angles in embodiments 2-4 are all 360 degrees.
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EMBODIMENT
ANGLE θ
ANGLE φ
ANGLE γ
TOTAL
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|
|
2
60
180
120
360
|
3
90
90
180
360
|
4
120
120
120
360
|
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Other three vertex tessellations may be provided where each angle θ, φ and γ is evenly divisible into 360 degrees and the sum of the angles is 360 degrees.
In accordance with the present invention, a wide variety of primary elements can be designed by those skilled in art. The present invention, defined in the appended claims, is not limited to the particular embodiments disclosed. These embodiments are illustrative, not limiting. Further it should be understood that the irregular lines that radiate from each vertex that are shown in the drawings are merely illustrative of the concept. The actual contour of each generally radially extending line is a matter of design choice and all configurations are within the scope of the appended claims. Provided, however, that sides 1-2, 3-4 and 5-6, respectively, are substantially rotational images of one another, as described above.
To further enhance the natural appearance of the surface covering it is desirable that the mating edges of adjacent units match less than perfectly, i.e., that the line or gap between units vary in thickness. This is preferably accomplished by introducing minor variations in the sides of the units so that the first and second sides are not identical. Likewise, there may be minor variations between the respective shapes of the third and fourth sides, and so on. Variations, however, cannot be so great as to cause problems in mating adjacent units. FIG. 28 illustrates minor variations in the thickness of the gaps 411 and 413 between adjacent units.
A further aspect of the invention is the provision of indicia on the sides or bottom surfaces of units to assist in the construction of surface coverings. FIGS. 28-32 illustrate one example of such indicia. FIG. 28 shows units 410, 412 and 414, with gaps 411 and 413 therebetween. FIG. 29 shows an enlarged view of area 416. FIG. 30 shows an enlarged view of area 418. FIGS. 28, 29 and 31 show a V-shaped projection 420 from a lower portion of the second side of unit 410 and a corresponding V-shaped recess 422 in the first side of unit 412. Similarly, FIGS. 28, 30 and 32 show a semi-circular projection 424 from a lower portion of the third side of unit 414 and a corresponding semi-circular shaped recess 426 in unit 410. The size and location of each mating projection-recess are uniformly located a consistent radial distance from the applicable vertex. The projections and recesses are preferably indented from the outer face so that they will not be visible in the completed surface covering. Construction is facilitated by easily matching V-shaped projections and recesses, and semi-circular projections and recesses, respectively. It should be understood that the particular shape of the projections and recesses depicted in the drawings are merely illustrative and not limiting. The projections also function to maintain uniform spacing between adjacent units even when the thickness of the gaps 411, 413 vary. Proper spacing assists in maintaining the integrity of the surface over large areas.
FIGS. 33-35 illustrate another indicia example to facilitate construction of surface coverings. FIG. 33 is a plan view of two adjacent units 450 and 452 with gap 451 therebetween. Each unit includes a spacer 454 and 456, respectively. Mating sides of respective units can be provided with spacers of the same size and location. Different mating sides are provided with spacers of a different width “W” or shape. Thereby, mating sides can be easily matched. As with the indicia example of FIGS. 28-32, the spacers function to maintain uniform spacing between units despite variations in the width of the gap 451. Optionally, the spacers may be provided with other indicia such as, letters, numbers or symbols to facilitate matching as shown for example at reference numeral 456 in FIG. 35.
FIGS. 36 and 37 show another example spacer. FIG. 36 shows three units 460, 462, 464, with gaps 461, 463 there between. All of the units have at least one, preferably a plurality of spacers on each side. FIG. 36 shows unit 460 having a spacer 466, unit 462 having spacers 468, 470, and unit 464 having spacer 472. The spacers in this example are adjacent each other to assist in connecting units. The spacers are preferably located on an inner portion of the unit, recessed from the front face, and typically are not visible in the completed surface. See, FIG. 37. The edges of the primary elements of the units are the construction lines 471 that are approximately halfway between outer edges 473 of the units. To maintain dimensional integrity of the surface covering, it is preferable to have at least two spacers on each side, and to locate the spacers close to the vertices. Although the spacers could be located at the vertices, i.e., corners 482 of the units, it is preferred to locate the spacers a short distance from the corner to reduce the potential for chipping or damage in shipment. Because the visible side edges, shown generally at 473, are independent of the primary element construction line, the visible edge of each side can be varied with respect to the visible edge of mating sides, which will result in variable gap width between units. Variable gap width further enhances a natural, custom appearance.
Mating of units 460, 462 is facilitated by spacers 466, 468, which help the installer match mating sides. Similarly spacers 470, 472 facilitate mating of units 462, 464. In addition, the spacers interlock and improve the structural integrity of the surface covering or structure.
As can be seen in FIG. 36, the irregular sides of units comprise a series of straight line segments 474, 475, 476, 477, 478, 479. Straight line segments are preferred for mold making. However, the general appearance of the side remains irregular.
An optional bevel 480 is provided on edge 473.
FIGS. 38-42 show a fifth embodiment of the invention, namely a wall structure. Wall 510 comprises a plurality of single primary element building units 512, and a plurality of two element building units 514. Each unit of the fifth embodiment has a tessellated planar configuration in a substantially vertical orientation, whereby assembly of multiple units forms the wall. The sides of each unit extend substantially perpendicularly from the front face, and function as the top, bottom, right and left sides of each unit. It should be understood, however, that although the sides are referred to as top, bottom, right and left for the purposes of function, the sides are actually irregularly shaped and do not lie in horizontal or vertical planes. Further it will be understood that the building units are rotational tessellations such that what might be the top of the unit in one instance could be the bottom in another depending on its orientation.
The fifth embodiment is formed from a multiplicity of building units assembled to form a continuous structure without substantial gaps between units. Each unit is comprised of x primary elements, as discussed above. Unit 512 is comprised of a single primary element. Unit 514 comprise two primary elements. The primary element is an irregular rotational tessellation as described above. A wide variety of units may be constructed having different numbers and arrangements of primary elements. Because all the units are combinations of primary elements, they readily mate with each other. As a result of the irregular side configurations, and different sizes and shapes of individual units, one can construct a wall or other structure that has a natural, random and apparent custom appearance.
The wall further comprises a base or starter course of units 516 and 518, side edge units 520, 522 and 524 and top units 526 and 528. Each of these units comprises a portion of primary element with a cut, straight side to facilitate construction. Alternatively, units may be cut as may be desired on site.
For structural applications of the invention, it is desirable to provide connectors between units to improve structural integrity. The term “connectors” means a feature that aligns adjacent units and assists in maintaining structural integrity, but does not require adjacent units be hooked or coupled together. FIG. 39 shows “S” shaped connectors 530 at two locations. An alternative connector is shown in FIG. 41, comprising projection-recess type connectors. Connector 532 is a recess, and connector 534 is a projecting lug having a configuration to mate with a recess 532 of another unit. FIG. 42 shows yet another connector having on one side, both a lug 536 and a recess 538 to mate with corresponding recess and lug of another unit. Alternatively the spacers shown in FIGS. 28-37 can be used as spacers and/or connectors in structural applications.
FIG. 43 is an enlarged cross-section between two building units showing an example spacer 540. As part of the connectors, or as separate features, each building unit is optionally provided with spacers. The spacers function to create a predetermined gap between units. The gap can provide drainage between units in some applications, e.g., retaining walls, and can be esthetically desirable. Further, the spacers assist in properly spacing units, which is important to maintaining integrity of the “pattern” over large areas. Without spacers small pebbles or debris can be trapped between units, throwing off the “pattern.” A further function of the spacers is to improve the structural integrity of the wall. Because the spacers have a relatively small surface area as compared to the side walls, a higher surface pressure (or stress) is applied between the spacer and the adjacent brick, causing the spacer to “dig into” the adjacent unit. The gaps between units formed by the spacers can remain open if desired. Alternatively the gaps may be filled in whole or in part with grout, mortar, sand or other fillers. Grout or mortar further simulates hand laid stone, and adds to the stability of the structure.
FIG. 44 shows flattened saw-tooth connectors 544 between two building units 546 and 548. The upper unit 546 is recess rearwardly from the lower unit 548. This feature is desirable for retaining walls. Another preferred feature is chamfered or beveled edges 542 between the front and side faces of each unit. Chamfered edges are both functional and add to the appearance of the units.
FIGS. 45-58 illustrate building units and exemplary surface coverings and other structures of a sixth embodiment of the invention. FIG. 45 shows a primary element 620 comprised of six sides, namely, first side 622 extending between points A and B, second side 624 extending between points A and F, third side 628 extending between points B and C, fourth side 630 extending between points C and D, fifth side 631 extending between sides D and E, and sixth side 633 extending between points E and F. Element 620 has three vertices, namely, first vertex 634, second vertex 636, and third vertex 637. As in other embodiments, first 622 and second 624 sides are irregular, rotational images of one another, and are rotationally spaced by an angle θ. The third 628 and fourth 630 sides are rotational images of one another, radiate from second vertex 636, and are rotationally spaced by an angle φ. Fifth 631 and sixth 633 sides are irregular, rotational images of one another, radiate from third vertex 637, and are rotationally spaced by an angle γ. In the sixth embodiment, angles θ, φ and γ are all substantially 120 degrees.
In the sixth embodiment at least two of the sides comprise midpoint rotations. FIG. 46 illustrates an expanded view of the line formed by first side 622 (which is also a rotational image of second side 624). First side 622 has a midpoint 639 and a plurality of line segments 641, 643, 645 and 647 on each side of the midpoint. As indicated in the drawings, the line segments 641-645 and 643-647 are set at angles relative to one another such that the overall shape of the line 622 is irregular within the meaning of the subject disclosure. Although two line segments are shown on each side of the midpoint, there could be more than two segments on each side. Further, although straight line segments are preferred for molding purposes, the portions of line 622 on each side of midpoint 639 could include curved segments or other irregular shapes. The configuration of the portion of line 622 on one side of the midpoint is a rotational image of the portion of the line on the other side of the midpoint, and the two portions are rotationally spaced about the midpoint by an angle of substantially 180 degrees. Thus, segments 641-645 are rotational images of segments 643-647. As a result, the first side 622 of one element 620 will mate not only with a second side 624 of another element 620, but it will also mate with a first side of another element 620. More preferably, each pair of sides in the sixth embodiment comprise midpoint rotations, and most preferably all six sides of the sixth embodiment comprise substantially the same configuration, that is, they are all midpoint rotations of substantially the same shape and length. As a result, any side of one element 620 will mate with any side of another element 620.
A surface can be covered by either rotating primary elements 620 relative to one another (“rotational tessellation”), by arranging primary elements 620 side-by-side relative to one another (“translation tessellation”), or by a combination thereof. For example, a rotational tessellation can be formed by rotating three primary elements 620 around any one of the vertices 634, 636, 637. A vertical translation is formed by mating first side 622 of one element with fifth side 631 of another element. A diagonal translation is formed by mating third side 628 of one element 620 with a sixth side 633 of another element. The flexibility of being able to tessellate irregular primary elements by rotation, translation or a combination thereof provides enormous opportunities for creativity.
FIG. 47 illustrates a building unit 650 that comprises a multiplicity (in this example seven) primary elements arranged together by translation. Unit 650 comprises an upper row of three primary elements 620 and a lower row of four primary elements 620. Dashed lines are provided to show the relationship between primary elements. Unit 650 has a long side 651, a short side 652, a first end 653, and a second end 654. The ends, 653 and 654 are mirror images of one another. Although the primary element has an overall hexagonal shape, the hexagonal shape is less apparent in the unit 650, which has a more irregular, rugged, natural appearance. Alternative combinations of plural or a multiplicity of primary elements to form building units having a natural stone or other irregular appearance will be apparent to those skilled in the art.
FIG. 48 is a top plan view of building units 650 assembled in different ways for purposes of illustrating some of the possible combinations of units. Because ends 653 and 654 are mirror images, units 650 can be joined end to end as shown at 655 to form for example, a landscape edger or decorative border. Ends can also be joined at a 120 degree angle, as shown at 656. Rings of various sizes and shapes can be formed in this way. Units 650 can be joined to other units rotationally at multiple points, as shown at vertices 657a and 657b. Ends can mate with sides, as shown at 658, to form branches in decorative borders. All sides can mate with all other sides, as shown for example at 659. Units can be arranged in single rows, double rows, and enlarged areas to create, for example, a decorative border connected to a platform for pots. Units 650 can thus be joined in multiple ways by rotation, translation or combinations thereof because any primary element side will mate with any other primary element side. This feature enables the end user unlimited possibilities in designing patterns of multiple units 650 to form various structures, including but not limited to, landscape edgers, decorative borders and barriers, walkways, driveways, patios, and other surface coverings. Units 650 can also be arranged in vertical configurations for constructing decorative borders, planters, containers and walls, as described below in reference to FIGS. 54 to 58.
FIGS. 49 and 50 illustrate a building unit 660. Unit 660 has the same planar configuration as unit 650, i.e., it is comprised of seven primary elements 620 arranged as shown schematically in FIG. 47. Unit 660 comprises a molded front face 662 having several discrete raised areas 664 separated by grooves 667. The raised areas 664 lend the appearance of separate stones. The grooves 667 do not follow the same pattern as the primary element, thereby further disguising the underlying tessellation pattern.
FIGS. 51 and 52 illustrate another building unit 670. Unit 670 has the same planar configuration as units 650 and 660, but has a differently molded front face design 672 comprising raised areas 674 separated by grooves 677. Because the planar configuration of both units 660 and 670 are the same, they can be combined in essentially any manner. However, the combination of multiple units having two or more differently molded front surfaces will add character to any surface covering or other structure.
The grooves 667 and 677 are shown in FIGS. 49-52 as having substantially uniform width and depth. To further enhance a natural stone appearance, the grooves can be varied in depth, width and shape. More elaborate carved and faceted faces can also be provided. For vertical applications such as walls, one or both faces can be molded to form irregular projecting rock shapes. Tumbling building units can provide unique surface and edge variations. It is only necessary for the central portion of the unit sides to conform to the tessellation pattern to provide mating surfaces between units.
FIG. 53 illustrates one example surface covering 680 that is comprised of multiple units 660 and units 670. For large surface covering applications, e.g., patios, units 660 and 670 are preferably provided with spacers as discussed above relative to FIGS. 33-37 and 43. The spacers assist in maintaining the integrity of the tessellation pattern because the spaces between units can absorb sand and other debris that otherwise would interfere slightly with mating adjacent units. Further, the spacers have a tendency to grip adjacent units to enhance the structural integrity of the surface. The relatively small spaces between units can be filled with sand or grout if desired. Those skilled in the art will appreciate that numerous different outdoor and indoor surface coverings, including but not limited to walkways, driveways, streets, patios and plazas, can be constructed with building units of this sixth embodiment. Further, by reducing the thickness of units 650, ceramic and glass tiles can be formed for covering all types of horizontal and vertical surfaces.
When spacers are used, the outer edge of the building unit should be drawn in slightly from the construction line, i.e., the edges of the tessellation pattern defined by the primary elements. The spacer defines a gap between units. The construction line is approximately midway between adjacent units. As discussed above, when spacers are used the outer edge of the unit can varied slightly from the tessellation pattern to provide a natural appearing, variable gap width between units. The same effect can be achieved without spacers molded to the units. The outer margins of the units may be drawn in from the construction line by a distance approximately equal to one-half a desired gap between units. For example, in a patio application a ½ inch gap between units could be selected, and accordingly the outer margins of the unit would be drawn in about ¼ inch from the construction line. The distance drawn in may be varied between approximately 0 to a ½ inch or more. The installer, e.g., mason, will then lay units with a typical average ½ inch gap between units. The gap can be set with the use of removable spacers or visually. After the building units have been laid out, the gaps can be filled with sand or grout.
FIGS. 54 to 58 show additional examples of structures formed with building units of the sixth embodiment. FIG. 54 shows a vertical arrangement of units 650 to form a landscape edger or decorative border. Sides 651, 652 alternate to form the top surface of the border. In this “stretch” configuration the border is somewhat similar to a conventional scallop edger, but having a rugged, natural appearance. FIG. 55 shows another border configuration where units 650 are orientated in a diagonal/vertical position, known as a “soldier” configuration. The soldier configuration is exceptionally durable because the sides 651, 652 interlock with one another. The soldier configuration can be laid in a serpentine row if desired. One can also combine the stretch and soldier configurations, e.g., by placing a unit in soldier orientation after every second stretch unit. FIG. 56 shows a tree ring. FIG. 57 illustrates a decorative planter or container formed by laying out a “tree ring” of units 650 and stacking multiple courses thereon. Successive courses can be staggered relative to lower courses if desired.
FIG. 58 shows a portion of a wall formed by orientating units 650 in a vertical configuration. For wall applications it is preferred to make the units deeper, i.e., thicker in dimension between the back and front face. Further, it is desirable to provide optional spacers on the sides of the units as discussed above in reference to FIGS. 33-37. The spacers enhance the structural integrity of the wall because the spacers dig into the sides of adjacent units. Also, the spacers provide drainage between units, which is often desirable in retaining wall applications. All or a portion of the spaces can be cemented or grouted if desired. When units 650 are adapted for use as walls or other vertical structures, it is not necessary to have a substantially flat front or rear face. In such applications, the front face or both the front and rear faces can be molded or otherwise formed in any configuration, e.g., as one or more rounded or jagged stones. It is only necessary that the planar configuration of the sides be maintained as discussed above in reference to FIG. 47 so that adjacent units will mate with each other.
To further improve the natural appearance of surface coverings it is desirable to provide variations in individual units. Dyes and colorants may be added to the units, and the color and quantity of dye may be regulated to produce color variations from unit to unit. Surface variations from unit to unit are also desirable. One method of introducing surface variation is to tumble the units after manufacture to roughen or otherwise to provide an aged appearance. These and other aging methods are well known in the art. An alternative method is to hammer the surface and/or edges of the unit to create small nicks or marks. Surface variations also may be made in the molds. For example, in a six form assembly, each mold can include a different surface irregularity or variation. Thereby, only every sixth unit would be the same.
The building units of the invention may be made in any conventional manner, for example by molding concrete or other composite materials. Two molding methods, for example, are dry cast and wet cast. Dry cast material can be used to mass manufacture low cost units. Wet cast is more expensive, but produces very high quality units. A preferred dry cast method is slip-form molding from dry mix concrete to form units suited for use in walkways, driveways and patios.
In the wet cast process, a form is constructed with side walls conforming to the planar configuration of the unit (as discussed above) with a bottom of the form designed to mold what will be the outer or top surface of the unit. The unit is molded upside down by pouring a concrete mixture into the form and allowing it to cure. An advantage of the wet cast process is that shaper details (e.g., undercuts and fissures that appear in natural stone) can be replicated, which is difficult to accomplish with other manufacturing methods.
Another form of building units of the invention comprises molding stamps, each stamp being comprised of one or more primary elements. Molding stamps are known to persons skilled in the art. Generally, a surface is formed by pouring, spreading and leveling concrete or other composite material. While the surface is wet (uncured) molding stamps are pressed into the surface, the surface being molded to conform to the stamp. In forming a stamp molded surface at least one stamp is required, but preferably several stamps are used, including stamps of different sizes and/or shapes resulting from different combinations of primary elements. The stamp molds are aligned and mated one to another in the same manner as described above in reference to pavers. The finished surface has a natural stone appearance, without an apparent repeating pattern, but is actually a concrete slab.
While preferred embodiments of the invention have been herein illustrated and described, it is to be appreciated that certain changes, rearrangements and modifications may be made therein without departing from the scope of the invention as defined by the appended claims.