The present invention relates to the general field of construction, and is more specifically concerned with a construction block anchoring system.
Block wall constructions, particularly the type of block wall constructions anchored to a wall support structure of a building, such as facade or veneer brick walls and the likes that are used for protection, durability and aesthetically purposes, are well known in the general field of masonry works. Such block wall constructions are typically mounted parallelly in a spaced apart relationship in front of the wall support structure by laying and bonding with mortar superposed rows, or courses, of construction blocks, such as bricks, until a predetermined height is reached, such as the next floor level of the building.
At that point, an elongated anchor member made of metal is positioned horizontally along with mortar on an elongated top portion of the block wall construction, and rigidly anchored along a rear portion thereof with the wall support structure using suitable attachment means such wood lag screws, nut and bolts, or the likes.
Then the block wall construction resumes with more rows of construction blocks and mortar until the next floor level is reached, where another anchor member is installed, and so on.
While this block wall construction and method is largely known and used across the world for providing facade and veneer brick walls, it is also largely known for its disadvantages. For example, in parts of the world in which temperature varies between below and above freezing temperatures, the foundation on which is erected the block wall construction may slightly move relative to the wall support structure due to the cyclical freezing and thawing of the ground every winter and spring seasons. Thus, often no more than a few years after the completion of the wall, cracks and the propagation thereof start to appear as seen along the outer surface of the block wall construction, particularly near the anchor members since these are rigidly tied to the more stable wall support structure.
These cracks are then often aggravated due to the infiltration of moisture and rain water which, in turn, freezes and worsens the gap of the cracks. At one point, parts of the block wall constructions may start to crumble and fall on a street walk below and cause damages or injuries.
Such block wall constructions further have an aesthetic disadvantage in that a front longitudinal portion of the anchor members embedded between selected rows thereof are often apparent along the otherwise uniform veneer brick walls of a building.
Against this background, there exists a need in the construction industry to provide an improved system for anchoring construction blocks to a building. An object of the present invention is therefore to provide such an improved device.
In a broad aspect, there is provided a system for anchoring construction blocks to an adjacent structure, and a method of using same.
In an other broad aspect, there is a system for anchoring a wall including superposed rows of construction blocks to an adjacent upstanding structure, each row including a plurality of the construction blocks, the system including: an inter-block element insertable between adjacent ones of the construction blocks and securable thereto; and an anchor including an anchoring portion securable to the upstanding structure and a coupler, the coupler securing the anchor and the inter-block element to each other with the anchoring portion at a predetermined distance from the inter-block element and such that with the anchoring portion operatively secured to the upstanding structure and the inter-block element operatively inserted between the adjacent ones of the construction blocks and secured thereto, the anchoring portion and the inter-block element are movable vertically relative to each other over a predetermined range of motion with the anchor remaining secured to the inter-block element.
There may also be provided a system wherein the anchor includes an anchoring element, the anchoring portion being part of the anchoring element, the anchoring element including a coupling portion opposed to the anchoring portion, the coupler being removably secured to the coupling portion.
There may also be provided a system wherein the inter-block element is substantially plate-shaped and defines opposed top and bottom surfaces and a peripheral edge.
There may also be provided a system wherein the inter-block element defines a body and a tongue protruding from the body, the tongue defining a tongue coupling aperture extending therethrough between the top and bottom surfaces, and wherein, with the inter-block element operatively inserted between adjacent ones of the construction blocks and operatively secured thereto, the body is inserted between the adjacent ones of the construction blocks and the tongue protrudes from the adjacent ones of the construction blocks, the coupler being inserted through the tongue coupling aperture.
There may also be provided a system wherein the coupler is vertically slidable relative to the tongue coupling aperture.
There may also be provided a system wherein the coupling portion defines a vertically extending coupling portion aperture and the coupler includes a stem extending substantially vertically downwardly from a head, the stem being inserted in the coupling portion aperture and slidably inserted through the tongue coupling aperture, the head being larger than the coupling portion aperture and the head being above the coupling portion aperture.
There may also be provided a system wherein the coupling portion aperture is threaded, the coupling portion aperture and the tongue coupling aperture being vertically aligned relative to each other, the stem being threaded, the stem threadedly engaging the coupling portion aperture and the stem being slidable along the tongue coupling aperture.
There may also be provided a system wherein the inter-block element defines a body and at least two tongues protruding from the body in a spaced apart relationship relative to each other, the coupler including a link secured to the two tongues and defining a link aperture extending vertically therethrough between the two tongues, wherein, with the inter-block element operatively inserted between adjacent ones of the construction blocks and operatively secured thereto, the body is inserted between the adjacent ones of the construction blocks and the tongues and link protrude from the adjacent ones of the construction blocks, the coupler including a stem extending substantially vertically downwardly from a head, the stem being inserted in the coupling portion aperture and through the link aperture, the head being larger than the link aperture and the head being above the link.
There may also be provided a system wherein the inter-block aperture defines at least one bonding aperture extending between the top and bottom surface for inserting a bonding material thereinto to bind the two adjacent ones of the construction blocks to each other with the inter-block element therebetween.
There may also be provided a system wherein the bonding aperture defines a neck at a location intermediate the top and bottom surfaces.
There may also be provided a system wherein the body further defines draining apertures extending between the top and bottom surfaces.
There may also be provided a system wherein the bottom surface defines draining channels extending therealong in fluid communication with at least one of the draining apertures, the draining channels being open at the peripheral edge.
There may also be provided a system wherein at least part of the peripheral edge is corrugated.
There may also be provided a system wherein the anchoring and coupling portions are made of different metals having different galvanic potentials, the anchor element further comprising an intermediate portion provided between the anchoring and coupling portions separating the anchoring and coupling portions from each other.
There may also be provided a system wherein the anchoring portion is threaded and screwable to the adjacent structure.
In another broad aspect, there is provided a building including: an upstanding structure defining a substantially vertical upstanding structure face; and a wall made of superposed rows of construction blocks erected substantially parallel to the upstanding structure face, the wall including a plurality of rows, each row including a plurality of construction blocks, the wall including an inter-block element inserted between two adjacent ones of the construction blocks, each in a respective one of the rows, and secured thereto; and an anchor including an anchoring portion secured to the upstanding structure and a coupler, the coupler securing the anchor and the inter-block element to each other with the anchoring portion at a predetermined distance from the inter-block element; wherein the anchoring portion and the inter-block element are movable vertically relative to each other over a predetermined range of motion with the anchor remaining secured to the inter-block element.
There may also be provided a building wherein the anchor includes an anchoring element, the anchoring portion being part of the anchoring element, the anchoring element including a coupling portion opposed to the anchoring portion, the coupler being secured to the coupling portion; and the inter-block element is substantially plate-shaped and defines opposed top and bottom surfaces and a peripheral edge, the inter-block element defining also a body and a tongue protruding from the body, the tongue defining a tongue coupling aperture extending therethrough between the top and bottom surfaces, the body being inserted between the rows and the tongue protruding from the wall between the wall and the upstanding structure face, the coupler being inserted through the tongue coupling aperture and vertically slidable relative thereto.
There may also be provided a building wherein the coupling portion defines a vertically extending coupling portion aperture and the coupler includes a head and a stem extending substantially vertically downwardly from the head, the stem being inserted in the coupling portion aperture, the head being larger than the coupling portion aperture.
There may also be provided a building wherein the body defines at least one bonding aperture extending vertically therethrough, the wall further comprising a bonding material in the at least one bonding aperture, the bonding material being bound to the two adjacent ones of the construction blocks.
There may also be provided a building wherein the wall includes a plurality of the inter-block elements and a plurality of horizontal and vertical spacing elements provided between the construction blocks, the inter-block elements and the horizontal and vertical spacing elements having a front end that is short of a front surface of the wall, the wall also including a bonding material provided in front of the inter-block elements and the horizontal and vertical spacing elements between the construction blocks.
Advantageously, in some embodiments, the present invention discloses a device and method for spacing and anchoring a block wall construction to an adjacent structure wherein the block wall construction can be mortarless, that self-drain itself of any moisture or rain water infiltration, and which allows a relative vertical movement between the wall and the adjacent structure. Hence, the present invention advantageously provide facades and veneer brick wall constructions that are significantly less prone to cracks, crack propagations or, worse, crumbling down hazardously on a crowded sidewalk, than known devices and methods of the prior art.
The present application claims benefit from UK request application 1616976.5 filed Oct. 6, 2016, the contents of which is hereby incorporated by reference in its entirety.
Other objects, advantages and features of the present invention will become more apparent upon reading of the following non-restrictive description of some embodiments thereof, given by way of example only with reference to the accompanying drawings.
The term “substantially” is used throughout this document to indicate variations in the thus qualified terms. These variations are variations that do not materially affect the manner in which the invention works and can be due, for example, to uncertainty in manufacturing processes or to small deviations from a nominal value or ideal shape that do not cause significant changes to the invention. These variations are to be interpreted from the point of view of the person skilled in the art.
Directional terminology, such as right, left, top, bottom, forward and backward, among others, refers to the orientation relative to an upstanding wall on level ground. This terminology is used for clarity reasons and should not be used to restrict the scope of the claims unless explicitly claimed.
Broadly, the present patent application concerns systems and parts thereof that allow anchoring construction block walls, such as brick walls, to adjacent structures so that the construction block wall can move vertically relative to the adjacent structure while remaining anchored thereto. While the present patent application describes the system in use with a specific type of construction blocks, namely bricks, the system is usable with any other type of construction blocks. In some embodiments, spacing elements may be also used. However, use of the system without the spacing elements is also within the scope of the invention. In some embodiments, the system and the spacing elements together allow construction of a construction block wall, such as a brick wall, that replaces the conventional layer of mortar between adjacent rows of the wall and between the construction blocks within each row with inter-block elements and spacing elements, made for example, and non-limitingly, of a polymer, and a bonding material.
Referring to
Referring to
Returning to
In some embodiments, the corrugated portion 114 extends longitudinally along the at least one edge of the horizontal spacing element 102 in the form of a series of teeth distributed in an equidistantly spaced apart relationship therealong and oriented perpendicularly relative to the at least one spacing element edge. For example, the corrugated portion 114 extends substantially the whole length of the spacing element front edge 104, as illustrated in
Returning to
In some embodiments, the horizontal spacing element 102 defines a plurality of equally sized and spaced apart draining apertures 116 distributed along a substantial portion of the planar configuration of the horizontal spacing element 102. Furthermore, in some embodiments, a suitable number and size of draining apertures 116 are spaced apart from one another a distance that is at least slightly less than the radius of each one thereof. Other configuration and disposition for the draining apertures 116 are also possible.
In some embodiments, the at least one bonding aperture 118 defines top and bottom opening portions at each end thereof having each a relatively greater radius than an intermediate portion of the bonding aperture 118 that is extending vertically therebetween. In other words, the bonding aperture 118 defines a neck 119 at a location intermediate the top and bottom surfaces 110 and 112.
In some embodiments, as seen in
Typically, the horizontal spacing element 102 thickness dimension is equal to a typical vertical spacing dimension commonly used in the masonry industry between two superposed rows 510 of the construction blocks 512 for a given format, dimension and weight of construction blocks. Other relative thickness dimensions for the horizontal spacing element 102 are also possible.
The horizontal spacing element 102 may have a length dimension between the spacing element side edges 108 that is roughly equivalent to the length of a typical brick, or the length of a typical concrete block, for example twelve inches (about 30.5 cm), four feet (1.22 meters) or eight feet (about 2.44 meters). Other relative length dimensions for the horizontal spacing element 102 are also possible. The horizontal spacing element 102 is made of a substantially rigid material, or combination of materials having suitable load compression, ductility and wide range thermal stability characteristics. For example, the horizontal spacing element 102 is a one piece element made of a suitable polymeric material that meets these characteristics. Other known rigid materials meeting these characteristics are also possible.
In some embodiments, the spacing element front and rear edges, 104 and 106 respectively, each have a longitudinal shape suitably configured such that, when the horizontal spacing element 102 is positioned on top of the at least one construction block 512, the spacing element rear edge 106 typically extends parallelly in register with the top rear edge of the at the at least one construction block 512, while the spacing element front edge 104 extends parallelly in an adjacently inwardly spaced apart relationship relative to the top front edge of the at least one construction block 512.
Typically, the spacing element front and rear edges, 104 and 106 of the horizontal spacing element 102 are suitably configured for one or more regular shaped bricks having each a rectangular shaped top surface 514. Other shapes of construction blocks 512 are also possible such as a custom shaped masonry block or brick having a top surface with a profiled front edge.
In some embodiments, as illustrated through another embodiment of an inter-block element 202′ in
Also,
In some embodiments, the main difference between the inter-block element 202 and the horizontal spacing element 102 resides in that inter-block element 202 is securable to the anchor element 226 using the coupler 228 so as to be able to anchor the inter-block element 202, and thus the wall 500, to the upstanding structure 516 extending typically vertically adjacently in a spaced apart relationship behind the wall 500, as best illustrated in
To that effect, with reference to
Typically, but not necessarily a plurality of tongues 222, each with a tongue coupling aperture 224, may occupy substantially the whole length of the inter-block element rear edge 206 in a side by side configuration. This arrangement of tongues 222 and tongue coupling apertures 224 are for maximizing the corresponding occurrences with spaced apart positions of support beams within the adjacent upstanding structure 516, which are not always at regular interval positions therealong. In use, the anchor element 226 has its anchoring portion 230 rigidly engaged with the adjacent upstanding structure 516.
Referring for example to
The coupler 228 includes a stem 234 and is typically terminated at the top by a head 235 of a larger diameter than the stem 234. In some embodiments, the coupling portion apertures 233 are such that the stem is slidably engaging along the vertical axis the coupling portion aperture 233 of each anchor element 226, which are interposed by the tongue coupling aperture 224. The head 235 is above the coupling portion aperture 233. A non-limiting example of such a coupler 228 would be a suitably sized screw or bolt. However, any other suitable coupler 228 is usable in the present invention. In other embodiments, one or both coupling portion apertures 233 and the stem 234 may be compatibly threaded so as to have a threaded engagement therebetween, yet allowing the inter-block element 202 to slidably move vertically relative thereto.
As would be obvious to someone familiar with hardware components, other known equivalent assembly providing a vertically movable anchor are also possible. For example (not shown in the drawings), a single square screw hook (e.g. a lag screw having a right angle stem as a head portion), may be used as a combination anchor element 226 and coupler 228, with the right angle stem acting as the coupler 228. Thus, the anchor 220 may be made of a single integral piece of material in some embodiments.
With the system 200, the wall 500 may at least slightly move vertically relative to the more stable adjacent upstanding structure 516 due to a thermal difference between them and/or their respective foundations, such as when the ground swells at below freezing temperatures. Hence, damage to the wall 500, including its brick sealant 520 or mortar joints, may be reduced or avoided when compared to known methods and technologies commonly used to erect a block wall construction.
In some embodiments, the system 200 may further comprise a guide tool 300. Referring to
Thus, the first planar portion 302 may be conveniently used for horizontally spacing two adjacent construction blocks 512 in a row 510, as illustrated in
The guide tool 300 further includes a second planar portion 304 extending perpendicularly from one end of the first planar portion 302 a distance that is at least slightly greater than the sum of the vertical dimension of a construction block 512 and the predetermined distance of the anchor element 226 above the tongue coupling aperture 224 of a inter-block element 202 positioned on the top surface 514 of the construction block 512.
The second planar portion 304 defines a pair of vertically spaced apart guide tool apertures 306 extending perpendicularly therethrough. The pair of guide tool apertures 306 are positioned such that they are in register with the vertical position of each one in the pair of anchor elements 226 above and below of an inter-block element 202 to be positioned on top of a next row 510 of construction blocks 512, when the guide tool 300 has its first planar portion 302 resting coplanarly on top of the previous, or underlying row 510, as illustrated in
Thus, the second planar portion 304 may be conveniently used for drilling suitably positioned pilot holes through each guide tool aperture 306 thereof and into the adjacent upstanding structure 516, for anchoring the inter-block element 202 that will be positioned on top of the next row of construction blocks 512 to be mounted.
In some embodiments, the guide tool 300 further includes a spirit level element 308 embedded in an aperture extending perpendicularly through the second planar portion 304 and is configured for indicating the true vertical level of the pair of guide tool apertures 306 before drilling the pilot holes.
With reference to
In a second step, a sufficient number of horizontal spacing elements 102 are positioned end to end and in register on the top surfaces 514 of the construction blocks 512 of the row 510 such that the corrugated portions 114 thereof are oriented away from the upstanding structure 516. In a third step, each one of the bonding aperture 118 is slightly overfilled with a suitable bonding material 520. In a fourth step, the first, second and third steps are repeated in sequence until a predetermined height is reached such as, for example, and non-limitingly, about two feet high (about 61 cm).
In a fifth step, the guide tool 300 is used to drill pairs of vertically corresponding pilot holes at suitably spaced apart positions in the upstanding structure 516 above the top row 510 of construction blocks 512, followed with suitably engaging an anchor element 226 in each pilot hole with its coupling portion aperture 233 oriented vertically. In a sixth step, a sufficient number of inter-block elements 202 are positioned end to end and in register on the top surfaces 514 of the last row 510 of construction blocks 512 such that the corrugated portions 214 thereof are oriented away from the upstanding structure 516. In a seventh step, a coupler 228 is engaged through each pairs of vertically corresponding coupling portion aperture 233, with the tongue coupling aperture 224 of the corresponding inter-block element 202 in between. In an eight step, each one of the bonding apertures 218 is slightly overfilled with a suitable bonding material. In a ninth step, the first to seventh steps are repeated until the block wall construction 500 has reached a desired height.
In a tenth step, a suitable bonding material such as a brick sealant or mortar is used for filling both the vertical and horizontal interstitial front spaces between the construction blocks 512 so as to fill, bond and, thus, seal these spaces, and also to obtain the look of a finished brick wall construction. As would be obvious to someone familiar with masonry work, the tenth step may be executed more often between previous steps of the method as construction of the wall 500 progresses in height. Furthermore, during the laying of a row of construction blocks 512, a bonding material may be applied in a conventional manner between the opposed side surfaces of each construction block 512 as it is added to the horizontal row 510 of construction blocks 512. Furthermore, it is to be understood that the height dimension between two rows 510 where inter-block elements 202 with anchors 220 are used may have other height dimension values, which is generally a factor of the building block format, size and weight.
Referring to
The coupling portions 632 may have a generally square configuration. If suitably sized, this configuration may facilitate alignment of the construction blocks 512 (not shown in
Another difference between the system 600 and the system 200 resides in that in the system 600, there are two rows of bonding apertures 618 instead of one. Also, the draining apertures 616 are relatively smaller and spaced apart by a larger distance than in the system 200. The body 603 may also, in some embodiments, include cavities (not shown in
More specifically,
Although the present invention has been described hereinabove by way of exemplary embodiments thereof, it will be readily appreciated that many modifications are possible in the exemplary embodiments without materially departing from the novel teachings and advantages of this invention. Accordingly, the scope of the claims should not be limited by the exemplary embodiments, but should be given the broadest interpretation consistent with the description as a whole. The present invention can thus be modified without departing from the spirit and nature of the subject invention as defined in the appended claims.
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