The present invention relates to blocks that can be interlocked and that can be used in making structures such as paved surfaces, walls and other types of structures, or in various other applications.
Arrangements of interlocking blocks can be used for various purposes. For example, a paved surface can be made of a plurality of concrete blocks, such as pavers, paving tiles or other types of paving units, which are interlocked in a particular pattern.
Concrete blocks used in a paved surface typically have simple prismatic shapes, such as rectangular prisms. In cases where the concrete blocks have a natural stone appearance to give a natural and aesthetic look to the paved surface, their simple prismatic shapes, which lack randomness, tend to diminish the paved surface's natural look. While some paving blocks have been provided with slightly irregular shapes, their ability to appear randomly shaped is limited and they therefore still result in paved surfaces with a somewhat deficient natural feel. Also, these slightly irregularly shaped paving blocks typically need to be arranged in a relatively intricate pattern which complicates their installation.
Similar deficiencies may be encountered in other types of structures that can be made of interlocking blocks, such as walls, decorative surfaces, or structures used for various other purposes, as well as in various other applications that use arrangements of interlocking blocks.
Accordingly, there is a need for blocks that appear to have highly random shapes and that can be easily arranged for making structures, such as paved surfaces, walls or other types of structures, or for various other applications.
As embodied and broadly described herein, the invention provides a block suitable for use in an arrangement of blocks that are interlocked. The block comprises: a first side surface extending between a first edge and a second edge, the first side surface being irregular and having a first half and a second half that are congruent; a second side surface extending between the second edge and a third edge, the second side surface having a first half and a second half that are congruent; a third side surface extending between the first edge and a fourth edge, the third side surface being congruent with a first portion of the first side surface; a fourth side surface extending between the third edge and a fifth edge, the fourth side surface being congruent with a second portion of the first side surface such that the first portion and the second portion of the first side surface constitute the first side surface; and a fifth side surface extending between the fourth edge and the fifth edge, the fifth side surface having a first half and a second half that are congruent.
The invention also provides a block suitable for use in an arrangement of blocks that are interlocked. The block comprises a plurality of side surfaces configured such that the block has a shape formed of a plurality of contiguous instances of a basic shape. The basic shape comprises: a first side surface extending between a first edge and a second edge, the first side surface being irregular and having a first half and a second half that are congruent; a second side surface extending between the second edge and a third edge, the second side surface having a first half and a second half that are congruent; a third side surface extending between the first edge and a fourth edge, the third side surface being congruent with a first portion of the first side surface; a fourth side surface extending between the third edge and a fifth edge, the fourth side surface being congruent with a second portion of the first side surface such that the first portion and the second portion of the first side surface constitute the first side surface; and a fifth side surface extending between the fourth edge and the fifth edge, the fifth side surface having a first half and a second half that are congruent.
The invention also provides a set of blocks capable of interlocking with one another. Each block comprises a plurality of side surfaces configured such that the block has a shape formed of at least one instance of a basic shape. The basic shape comprises: a first side surface extending between a first edge and a second edge, the first side surface being irregular and having a first half and a second half that are congruent; a second side surface extending between the second edge and a third edge, the second side surface having a first half and a second half that are congruent; a third side surface extending between the first edge and a fourth edge, the third side surface being congruent with a first portion of the first side surface; a fourth side surface extending between the third edge and a fifth edge, the fourth side surface being congruent with a second portion of the first side surface such that the first portion and the second portion of the first side surface constitute the first side surface; and a fifth side surface extending between the fourth edge and the fifth edge, the fifth side surface having a first half and a second half that are congruent. The set of blocks comprises: a first block having a shape formed of a single instance of the basic shape; and a second block having a shape formed of a plurality of contiguous instances of the basic shape.
The invention also provides a block suitable for use in an arrangement of blocks that are interlocked. The block comprises: a first side surface extending between a first edge and a second edge, the first side surface being irregular and having a first half and a second half that are congruent; a second side surface extending between the second edge and a third edge, the second side surface having a first half and a second half that are congruent; a third side surface extending between the third edge and a fourth edge, the third side surface being congruent with the first side surface; a fourth side surface extending between the fourth edge and a fifth edge, the fourth side surface being congruent with the first side surface; a fifth side surface extending between the fifth edge and a sixth edge, the fifth side surface being congruent with the second side surface; and a sixth side surface extending between the first edge and the sixth edge, the sixth side surface being congruent with the first side surface.
The invention also provides a block suitable for use in an arrangement of blocks that are interlocked. The block comprises: a first side surface extending between a first edge and a second edge, the first side surface being irregular and having a first half and a second half that are congruent, the first side surface having a profile length; a second side surface extending between the second edge and a third edge, the second side surface having a first half and a second half that are congruent; a third side surface extending between the first edge and a fourth edge, the third side surface being congruent with a first portion of the first side surface, the third side surface having a profile length; a fourth side surface extending between the third edge and a fifth edge, the fourth side surface being congruent with a second portion of the first side surface, the fourth side surface having a profile length, the profile length of the first side surface corresponding to the profile length of the third side surface added to the profile length of the fourth side surface; and a fifth side surface extending between the fourth edge and the fifth edge, the fifth side surface having a first half and a second half that are congruent.
These and other aspects of the invention will now become apparent to those of ordinary skill in the art upon review of the following description of embodiments of the invention in conjunction with the accompanying drawings.
A detailed description of embodiments of the present invention is provided below, by way of example only, with reference to the accompanying drawings, in which:
It is to be expressly understood that the description and drawings are only for the purpose of illustrating certain embodiments of the invention and are an aid for understanding. They are not intended to be a definition of the limits of the invention.
A given concrete block 12j of the concrete blocks 121 . . . 12N (1≦j≦N) will be described in further detail with additional reference to
In this embodiment, the concrete block 12j is a dry-cast concrete block, i.e., it is made of no-slump concrete. No-slump concrete (also known as zero-slump concrete) can be viewed as concrete with a slump of 6 mm or less. It will be appreciated that various types of no-slump concrete are possible and may be used. It will also be appreciated that other types of concrete (e.g., measurable-slump concrete) may be used in other embodiments.
The concrete block 12j comprises a front surface 14, a rear surface 15, and five (5) side surfaces located between the front surface 14 and the rear surface 15, namely a first side surface 181, a second side surface 182, a third side surface 183, a fourth side surface 184 and a fifth side surface 185. The front surface 14 is intended to be exposed when the concrete block l2j is placed in the paved surface 10.
The side surfaces 181 . . . 185 are configured such that the concrete block 12j has an irregular shape that gives it a natural appearance. When placed in the paved surface 10, the concrete block and other ones of the concrete blocks 121 . . . 12N provide a natural and aesthetic look to the paved surface 10, which appears to be made of several highly randomly shaped natural stones. Also, the side surfaces 181 . . . 185 are configured such that the concrete blocks 121 . . . 12N can be easily installed in courses in a running bond (also known as a “stretcher bond”) or other linear bond.
In order to allow the concrete block 121 with its irregular shape to interlock with other ones of the concrete blocks 121 . . . 12N and to allow these blocks to be installed in courses, the side surfaces 181 . . . 185 are configured according to a set of rules which ensure that each of these side surfaces can register with a mating side surface of an adjacent one of the concrete blocks 121 . . . 12N, as further discussed below.
As best shown in
In accordance with the aforementioned set of rules, the first side surface 181 has a first half 241 and a second half 242 that are congruent. More specifically, when viewing the first side surface 181 as a two-dimensional locus of points, the second half 242 of the first side surface 181 corresponds to a rotated version of the first half 241 of the first side surface 181, i.e., the second half 242 corresponds to the first half 241 rotated by 180°. With this congruence, the irregularity 191 is congruent with the irregularity 194 and the irregularity 192 is congruent with the irregularity 193.
The second side surface 182 extends between the edge 162 and an edge 163 and, in this case, is irregular, i.e., it has an irregular profile which deviates from an imaginary plane P2 extending between the edges 162 and 163. More particularly, the second side suffice 182 has irregularities 211 and 212, in this case angled portions, which provide its irregular profile.
In accordance with the aforementioned set of rules, the second side surface 182 has a first half 261 and a second half 262 that are congruent. More particularly, when viewing the second side surface 182 as a two-dimensional locus of points, the second half 262 of the second side surface 182 corresponds to a rotated version of the first half 261 of the second side surface 182, i.e., the second half 262 corresponds to the first half 261 rotated by 180°. With this congruence, the irregularities 211 and 212 are congruent.
The first and second side surfaces 181, 182 have respective projected lengths L1, L2 measured along the imaginary planes P1 and P2, which define an angle α therebetween. The projected lengths L1, L2 as well as the angle α can be selected as desired.
The third side surface 183 extends between the edge 161 and an edge 164. In accordance with the aforementioned set of rules, the third side surface 183 is congruent with a portion 31 of the first side surface 181. More specifically, when viewed as a two-dimensional locus of points, the third side surface 183 corresponds to a rotated version of the portion 31 of the first side surface 181, i.e., the third side surface 183 corresponds to the portion 31 of the first side surface 181 rotated by an angle β about the edge 161. In this case, as the portion 31 of the first side surface 181 includes the irregularity 191, the third side surface 183 has an irregularity 27 congruent with the irregularity 191 and is thus irregular.
The portion 31 of the first side surface 181 can be selected and rotated as desired to generate the third side surface 183. More specifically, the portion 31 of the first side surface 181 has a projected length L′ measured along the imaginary plane P1, and the projected length L′ and the angle β can be selected as desired.
The fourth side surface 184, which extends between the edge 163 and an edge 165, is opposite to the third side surface 183. In accordance with the aforementioned set of rules, the fourth side surface 184 is congruent with a portion 33 of the first side surface 181 such that the portion 33 and the portion 31 of the first side surface 181 together constitute the first side surface 181. In other words, the first side surface 181 is made of both portions 31, 33.
When viewed as a two-dimensional locus of points, the fourth side surface 184 corresponds to a rotated and translated version of the portion 33 of the first side surface 181, i.e., the fourth side surface 184 corresponds to the portion 33 of the first side surface 181 rotated by an angle γ about the edge 162 and translated to locate its end at the edge 163. In this case, as the portion 33 of the first side surface 181 includes the irregularities 193, 194, the fourth side surface 184 has irregularities 291, 292 respectively congruent with the irregularities 194, 193 and is thus irregular.
As it is complementary to the portion 31 of the first side surface 181, the portion 33 of the first side surface 181 has a projected length L″ measured along the imaginary plane P1 such that the projected length L″ added to the projected length L′ of the portion 31 of the first side surface 181 corresponds to the projected length L1 of the first side surface 181 (i.e., L1=L′+L″). Also, the angles β and γ are supplementary angles (i.e., β+γ=180°).
While the projected length L1 corresponds to the projected length L′ added to the projected length L″, it is also understood that the length of the first side surface 181 equals the length of the third side surface 183 added to the length of the fourth side surface 184, when such lengths are measured along the profile of the respective side surfaces 181, 183, 184 (e.g., with a ruler or a measuring tape). Hence, in accordance with the aforementioned set of rules, the first side surface 181 has a profile length (i.e., an actual length) that corresponds to the profile length of the third side surface 183 added to the profile length of the fourth side surface 184.
The fifth side surface 185 extends between the edges 164, 165 and, in this case, is irregular, i.e., it has an irregular profile which deviates from an imaginary plane P5 extending between the edges 164, 165. More particularly, the fifth side surface 185 has irregularities 371 . . . 374, in this case angled portions, which provide its irregular profile.
In accordance with the aforementioned set of rules, the fifth side surface 185 has a first half 391 and a second half 392 that are congruent. More particularly, when viewing the fifth side surface 185 as a two-dimensional locus of points, the second half 392 of the fifth side surface 185 corresponds to a rotated version of the first half 391 of the fifth side surface 185, i.e., the second half 392 corresponds to the first half 391 rotated by 180°. With this congruence, the irregularity 371 is congruent with the irregularity 374 and the irregularity 372 is congruent with the irregularity 373.
It will thus be appreciated that, with its side surfaces 181 . . . 185 configured as described above, the concrete block 12j has an irregular shape that gives it a natural appearance and that allows it to be interlocked with other ones of the concrete blocks 121 . . . 12N when placed in the paved surface 10, thereby resulting in the paved surface 10 appearing to be made of several randomly shaped natural stones. In particular, with its five (5) side surfaces 181 . . . 185 which, in this embodiment, are shaped differently from one another (i.e., have five (5) mutually different profiles), each of the concrete blocks 121 . . . 12N appears to have a highly random shape which, when patterned with other ones of the concrete blocks 121 . . . 12N, contributes to imparting to the paved surface 10 a highly natural and random look. In addition, with their side surfaces 181 . . . 185 configured as described above, the concrete blocks 121 . . . 12N can be easily installed in courses in a running bond or other linear bond.
In this embodiment, in order to further enhance a natural appearance of the paved surface 10, the front surface 14 of the concrete block 12; comprises two (2) portions 201, 202 that represent two (2) natural stones. Each of the portions 201, 202 of the front surface 14 has a texture with a natural stone appearance, i.e., an aged, worn, or weathered appearance that resembles natural stone. More particularly, in this embodiment, this texture is a cast texture that is realized during casting of the concrete block 12; and that may be based on a natural stone's surface which has been used to produce a mold for casting the concrete block 12j. For ease of reference, the portions 201, 202 of the front surface 14 and their cast texture with a natural stone appearance will hereinafter be referred to as the “natural-stone-like surface portions” 201, 202.
The natural-stone-like surface portions 201, 202 are separated from each other by a depression 30 of the front surface 14 that can serve as a false joint. When the concrete block 12; is placed in the paved surface 10, the natural-stone-like surface portions 201, 202 result in an area of the paved surface 10 being perceivable as including plural (in this case, two (2)) natural stones of different sizes and configurations.
Although the front surface 14 comprises a plurality of natural-stone-like surface portions (in this case, two (2)), it is to be understood that, in other embodiments, any number of natural-stone-like surface portions may be provided. For example, in
With additional reference to
The natural-stone-like surface portion 20k has a visually discernible boundary 22. In cases where the natural-stone-like surface portion 20k is contiguous to a chamfered, rounded, or otherwise unnatural-looking edge portion of the concrete block 12j, the boundary 22 of that natural-stone-like surface portion would be considered to be configured such that the chamfered, rounded or otherwise unnatural-looking edge portion is not part of that natural-stone-like surface portion.
The natural-stone-like surface portion 20k includes a pattern of cast relief elements 231 . . . 23M formed during casting of the concrete block 12j. This pattern of cast relief elements 231 . . . 23M includes a plurality of peaks and a plurality of valleys, which are sized so as to be visually distinguishable when the concrete block 12j is placed in the paved surface 10. It is to be understood that various other patterns of cast relief elements are possible.
The cast texture of the natural-stone-like surface portion 20k defines a “surface level difference” ΔL, which refers to the normal distance between a maximum level Lmax and a minimum level of that surface portion. As shown in
In this example, the minimum level Lmin of the natural-stone-like surface portion 20k is located at its boundary 22. Generally, the minimum level Lmin of a natural-stone-like surface portion may be located anywhere on that surface portion, including at a location away from its boundary 22. The maximum level Lmax of a natural-stone-like surface portion may also be located anywhere on that surface portion, including at its boundary 22.
With the concrete block 12j being used in a paving application, in some embodiments, the surface level difference ΔL may be greater than 4 mm, for example, between 4 mm and 12 mm. For instance, in one embodiment, the surface level difference ΔL may be about 8 mm. This enables the natural-stone-like surface portion 20k to exhibit desired natural stone appearance characteristics, while maintaining a degree of surface irregularity suitable for supporting pedestrian or other traffic. In other embodiments, the surface level difference ΔL may be greater, for example, between 10 nun and 30 min. For instance, in one embodiment, the surface level difference ΔL may be about 20 mm.
It is to be noted that the natural-stone-like surface portions 201 and 202 of the concrete block 12j may define a common surface level difference ΔL or distinct surface level differences ΔL, a common maximum level Lmax or distinct maximum levels Lmax, and/or a common minimum level Lmin or distinct minimum levels Lmin.
Each of the cast relief elements 231 . . . 23M of the natural-stone-like surface portion 20k reaches a respective level L that is either the maximum level Lmax, the minimum level Lmin, or a level therebetween. In this embodiment, plural ones of the cast relief elements 231 . . . 23M are seen as extending to the maximum level L, of the natural-stone-like surface portion 20k and separated from each other by other ones of the cast relief elements 231 . . . 23M that only extend to lower levels.
Also, each of the cast relief elements 231 . . . 23M of the natural-stone-like surface portion 20k that is a valley (e.g., the cast relief element 232) can be viewed as having a respective depth D, which refers to the normal distance between the maximum level Lmax of that surface portion and that valley's deepest point. Depending on the surface level difference ΔL, in some cases, the depth D of each of one or more valleys of the natural-stone-like surface portion 20k may be greater than 4 mm, for example, between 4 mm and 10 mm. This may further enhance natural stone appearance characteristics exhibited by the natural-stone-like surface portion 20k.
The natural-stone-like surface portion 20k interacts with ambient light to create shadows that further contribute to its natural stone appearance. More particularly, each point of the cast texture of the natural-stone-like surface portion 20k defines a respective “texture angle” θ, which refers to the angle between a plane parallel to the X-Y plane and a plane tangent to the natural-stone-like surface portion 20k at that point. In some embodiments, the texture angle θ of each of a plurality of points of the natural-stone-like surface portion 20k may be between 75° and 90°. This may contribute to creation of shadows on the natural-stone-like surface portion 20k that further enhance its natural stone appearance. Configuring a dry-cast concrete block with a surface level difference ΔL in the above-mentioned ranges has been found to facilitate formation of such texture angles θ during casting. It is noted, however, that the above-mentioned values of texture angle θ are presented for example purposes only and are not to be considered limiting in any respect.
The depression 30 of the front surface 14 that separates the natural-stone-like surface portions 201,202 can be viewed as having a depth, which refers to the normal distance between the maximum level Lmax of either of these surface portions and that depression's deepest point. Depending on the surface level difference ΔL, the depth of the depression 30 may take on various values. For example, in some embodiment, the depth of the depressions 30 may be at least 10 mm, for instance, between 10 mm and 30 mm. This may further enhance natural stone appearance characteristics exhibited by the natural-stone-like surface portions 201, 202 of the concrete block 12j.
It will thus be appreciated that, when placed in an interlocking pattern in the paved surface 10, the concrete blocks 121 . . . 12N, with their irregular shapes defined by their side surfaces 181 . . . 185 and with their natural-stone-like surface portions, provide a natural and aesthetic look to the paved surface 10, which appears to be made of several highly randomly shaped natural stones.
In addition, with their side surfaces 181 . . . 185 configured as described above, the concrete blocks 121 . . . 12N can be efficiently and conveniently installed in courses in a running bond or other linear bond. Furthermore, owing to their side surfaces 181 . . . 185, adjacent ones of the concrete blocks 121 . . . 12N may be rotated by 180° when installed in the paved surface 10, thereby providing additional flexibility in creating highly random-looking patterns.
Also, as they may be made of no-slump concrete and have their natural stone appearance realized during casting without requiring any subsequent mechanical artificial aging/weathering process (e.g., tumbling, object impacting, etc.), concrete blocks such as the concrete blocks 121 . . . 12N may be mass-produced with high efficiency. An example of implementation of a process for manufacturing concrete blocks such as the concrete blocks 121 . . . 12N will be presented later on.
While in this embodiment the concrete blocks 121 . . . 12N have a particular irregular shape defined by their side surfaces 181 . . . 185, it will be appreciated that the concrete blocks 121 . . . 12N may have various other irregular shapes in other embodiments. In particular, by configuring their side surfaces 181 . . . 185 according to the aforementioned set of rules, the concrete blocks 121 . . . 12N may have a virtually infinite number of irregular, highly random-looking shapes. For instance,
The aforementioned set of rules according to which the side surfaces 181 . . . 185 of each of the concrete block 121 . . . 12N are configured may also be used to provide larger, irregularly, random-looking shaped concrete blocks that can be placed into an interlocking pattern.
For example,
It will be appreciated that, in other embodiments, a concrete block may be conceptually formed of any other number of contiguous instances of a basic shape configured according to the aforementioned set of rules. Also, although not shown, concrete blocks such as the concrete blocks 12A and 12B may have a front surface with one or more natural-stone-like surface portions similar to the natural-stone-like surface portions 201, 202 of the front surface 14 of the concrete block 12j.
Turning now to
At step 200, no-slump concrete is placed into a mold. To facilitate mass-production, in one embodiment, the mold has a plurality of cavities. In other embodiments, a plurality of molds each with a single cavity or each with a respective plurality of cavities may be used. To further facilitate mass-production, the mold may be located such that concrete blocks are placed on a production board when removed therefrom.
Each cavity of the mold is configured to form a respective concrete block comprising side surfaces configured according to the aforementioned set of rules (such as the side surfaces 181 . . . 185 of the concrete block 12j), and, optionally, a front surface with one or more natural-stone-like surface portions (such as the front surface 14 of the concrete block 12j with its two (2) natural-stone-like surface portions 201 and 202). To that end, each cavity is associated with a surface of the mold that includes at least one portion with a surface texture corresponding to the desired natural stone appearance (hereinafter referred to as “the at least one natural-stone-like surface portion of the mold”). In embodiments directed to producing concrete blocks with a plurality of natural-stone-like surface portions (such as some of those shown in
In order to closely simulate natural stone, in some embodiments, each given natural-stone-like surface portion of the mold, and thus the corresponding natural-stone-like surface portion of concrete blocks to be formed by the mold, may be based on a natural stone's surface. For example, data representative of at least a portion of the natural stone's surface may be obtained, for instance, via three-dimensional scanning of the natural stone's surface. The obtained data may then be computer processed using software in order to generate data representative of the given natural-stone-like surface portion of the mold. In some cases, this processing may include modifying the obtained data representative of at least a portion of the natural stone's surface to set the desired surface level difference ΔL′ and texture angles θ′ of the given natural-stone-like surface portion.
As another possible consideration, in embodiments where individual ones of the cavities of the mold are intended to form concrete blocks of similar overall dimensions but with natural-stone-like surface portions that have different configurations (e.g., different patterns of cast relief elements), these individual cavities may be designed to each have a common volume in order to facilitate production. In other words, a first cavity intended to form concrete blocks with natural-stone-like surface portions having a first configuration may have a first volume, and a second cavity intended to form concrete blocks with natural-stone-like surface portions having a second configuration different from the first configuration may have a second volume substantially corresponding to the first volume. This facilitates provision of substantially the same quantity of concrete into each cavity of the mold, which in turn facilitates efficient casting of concrete blocks in the mold and subsequent removal of the concrete blocks therefrom. In embodiments where individual ones of the cavities of the mold are intended to form concrete blocks of significantly different overall dimensions and with natural-stone-like surface portions that have different configurations (e.g., different patterns of cast relief elements), similar production benefits may be achieved by designing these individual cavities to each have a common volume per unit area.
The mold may be manufactured via computer-aided manufacturing based on the data representative of each given natural-stone-like surface portion of the mold. Since no-slump concrete can be used, the mold may be made of metal or other rigid material. There is no requirement for one or more portions of the mold to be made of elastomeric material (e.g., rubber), which is typically used in molds for casting wet-cast concrete blocks with a natural stone appearance.
Thus, during step 200, each cavity of the mold is filled with no-slump concrete in order to form a concrete block comprising side surfaces configured according to the aforementioned set of rules, and, optionally, a front surface with one or more natural-stone-like surface portions.
At step 202, the no-slump concrete in the mold is consolidated. Consolidation may include inducing vibration of the no-slump concrete in the mold so as to cause it to compact itself and closely conform to each cavity of the mold. A pre-vibration phase may be effected during step 200 to facilitate filling of the no-slump concrete in the mold and its eventual consolidation. Consolidation may also include application of pressure on the concrete in combination with its vibration. It will be appreciated that consolidation may be effected using various other techniques.
Upon completion of step 202, the no-slump concrete in each cavity of the mold has formed into a concrete block comprising side surfaces configured according to the aforementioned set of rules, and, optionally, a front surface with one or more natural-stone-like surface portions.
At step 204, the concrete block in each cavity of the mold is removed therefrom and continues on the production board. The concrete blocks may be directly stored for curing purposes. Since provision of a natural stone appearance may be effected during casting, the concrete blocks do not require a subsequent mechanical artificial aging/weathering process (e.g., tumbling, object impacting, etc.) to impart them with such an appearance. Since the concrete blocks can be made of no-slump concrete, curing times are relatively short such that they can be available for use within a short period of time (e.g., one day).
At step 206, each cavity of the mold is cleaned such that casting of new concrete blocks may be effected. In one embodiment, a cleaning unit uses a fluid to clean each cavity of the mold. The fluid may be a gas (e.g., compressed air) or a liquid whose flow relative to each cavity of the mold, and particularly each natural-stone-like area of the mold, removes therefrom substantially any remaining no-slump concrete. Such a fluid-based cleaning action advantageously enables rapid cleaning of each cavity of the mold, thereby increasing production efficiency. In some cases, the cleaning unit may also use, in addition to the fluid, one or more brushes to clean each cavity of the mold, whereby the fluid-based cleaning action is combined with a brushing cleaning action. It will be appreciated that other embodiments may employ various other types of cleaning action.
In this example, the process returns to step 200 where a new production cycle begins. In some embodiments, utilization of no-slump concrete in combination with rapid cleaning of the mold and other elements of the process may enable a production cycle to take a relatively short period of time (e.g., 15 to 20 seconds per square meter of finished products in some cases).
While this example illustrates one possible process that can be used to produce concrete blocks such as the concrete blocks 121 . . . 12N, 12A and 12B, it will be appreciated that various other processes may be used to manufacture such blocks.
Although in embodiments considered above the concrete blocks 121 . . . 12N are used in an arrangement whereby they are interlocked to form part of the paved surface 10, in other embodiments, concrete blocks configured according to principles discussed herein may, even though they are capable of interlocking with one another, be placed in an arrangement whereby there is some space between side surfaces of adjacent blocks (e.g., to let grass grow in between them).
Also, while in embodiments considered above the concrete blocks 121 . . . 12N are used in an arrangement, in other embodiments, a concrete block configured according to principles discussed herein may, even though it is suitable for use in an arrangement of blocks, be used individually (e.g., as a stepping stone) without being arranged with other similar concrete blocks.
In addition, although in embodiments considered above the concrete blocks 121 . . . 12N are paving units used in the paved surface 10, in other embodiments, concrete blocks configured according to principles discussed herein may be used in various other types of structures. For example, in some embodiments, concrete blocks configured according to principles discussed herein may be wall units for use in walls (e.g., building walls, retaining walls and other landscaping walls, acoustic walls, etc.), steps unit for use in steps, or blocks for use in other types of structures.
Furthermore, while embodiments considered above relate to concrete blocks, in other embodiments, and depending on their application, blocks configured according to principles discussed herein may be made of various other materials (e.g., polymers, metals, etc.).
Although various embodiments and examples have been presented, this was for the purpose of describing, but not limiting, the invention. Various modifications and enhancements will become apparent to those of ordinary skill in the art and are within the scope of the invention, which is defined by the appended claims.
This application claims priority from U.S. Provisional Patent Application No. 60/987,459 filed on Nov. 13, 2007 by Marcel Thomassen et al. and hereby incorporated by reference herein.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/CA2008/000387 | 2/28/2008 | WO | 00 | 9/11/2008 |
Number | Date | Country | |
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60987459 | Nov 2007 | US |