1. Related Field
The present invention relates to the fields of structural walls and soil-retaining walls.
2. Description of the Related Art
Masonry wall construction is a well-established art. Traditional masonry construction requires the effort of skilled masons to lay hollow concrete block units with mortar to later be grouted in place with continuous reinforcing cast into the system. The process is laborious, expensive, and time consuming. The traditional grouted masonry system is typically used for supporting high lateral load demands such as earth retaining walls and seismic resisting walls. An alternative approach involves bolting systems for stackable masonry systems. Such stackable systems are often preferable to traditional grouted masonry for ease, speed, and economy of installation. Previously-described stackable masonry systems rely on pre-tensioning or post-tensioning attachment of bolts clamped at top and bottom of wall assemblies or to the blocks themselves. These systems transfer tension forces to bearing connections that compress the masonry units. Since the blocks are held in place by compressing the block above and below each individual block unit or above and below the entire wall, the blocks require pre or post-tensioning of the rods, or the wall system would have no lateral restraint capacity. Moreover, the strength of a tension clamped system is difficult to predict or control because of the difficulty in accurately determining the bolt pre or post-tension load. These factors render such walls incapable of resisting lateral loads from forces such as wind, seismic or soil. Because of this, these systems are typically only used in applications where lateral load demand is low.
Related literature includes U.S. Pat. No. 6,915,614, entitled “Bricklaying Structure, Bricklaying Method, and Brick Manufacturing Method”; U.S. Pat. No. 6,282,859, entitled “Building System Comprising Individual Building Elements”; U.S. Pat. No. 5,537,794, entitled “Shear Bolt Connected Structural Units”; U.S. Pat. No. 6,088,987, entitled “Modular Building Materials”; U.S. App. No. 2007/0186502, entitled “Unitized Post Tension Block System For Masonry Structures”; U.S. App. No. 2006/0272245, entitled “Wall Construction of Architectural Structure”; U.S. Pat. No. 6,178,714, entitled “Modular Temporary Building”; U.S. Pat. No. 5,787,675, entitled “Method of Assembling Log Walls For Log House And Clamping Bolt To Couple The Wall”.
The present disclosure describes a wall system that is as easy and quick to install as a stackable system, but which avoids the downfalls of those systems and provides the lateral strength and stability of a traditional block and mortar system. Certain embodiments of the present invention provide preferable alternatives to both traditional masonry construction, and to previous stackable systems. Such embodiments provide for walls (e.g. soil-retaining walls) that enjoy the benefits of both previously-known systems, but that do not suffer from the disadvantages of either. Walls as described herein can be quickly and easily assembled and also have a high resistance to lateral forces.
Some embodiments described herein include a wall system comprising a first block having a first top face and a first bottom face, the first block comprising a first coupler and a second coupler, each of the first coupler and the second coupler disposed within the first block; an interconnect element, wherein the interconnect element is attached to each of the first coupler and the second coupler, and wherein the interconnect element is substantially enclosed within the first block; a first channel formed at least partially within the first block, and at least partially within the first coupler, wherein the first channel terminates on one end at an opening in the first top face, and wherein the first channel terminates on the other end at an opening in the first bottom face; a second block having a second top face and a second bottom face, the second block comprising a third coupler disposed within the second block; a second channel formed at least partially within the second block and at least partially within the third coupler, wherein the second channel terminates on one end at an opening in the second top face, and wherein the second channel terminates on the other end at an opening in the second bottom face; a first rod extending into both the first channel and the second channel, and coupling to the first coupler and the third coupler.
In some embodiments, the wall system further comprises a footing having a fourth coupler coupled to the second block and wherein the first rod is further configured to pass into a third channel in the footing, and wherein the first rod is further configured to couple to the fourth coupler.
In some embodiments, the first rod is a threaded bolt, and the first coupler and the third coupler are internally threaded, and wherein the first rod is further configured to couple to each of the first coupler and the third coupler, by engagement of its threads with the internal threads of each of the first coupler and the third coupler.
In some embodiments, the first rod is formed having protrusions or deformations, and wherein the first coupler and the third coupler comprise a receiver, the receiver having internal dimensions configured to receive the first rod in limited rotational positions and securely retain first rod within the receiver.
In some embodiments, the first rod is formed having grooves and wherein the first coupler and the third coupler comprise a receiver, the receiver having internal dimensions configured to receive the first rod in limited rotational positions and securely retain first rod within the receiver.
In some embodiments, at least a portion of the first bottom face is non-planar, and wherein at least a portion of the second top face is non planar, and wherein the first bottom face forms substantially the minor image of the second top face.
In some embodiments, any one of the first coupler, second coupler or third coupler comprises protrusions configured to anchor the first coupler, second coupler, or third coupler within the block in which the first coupler, second coupler, or third coupler is disposed.
In some embodiments, the first coupler is cast within the first block.
In some embodiments, the second coupler is coupled to a third block by a second rod.
In some embodiments, the first block comprises a masonry material.
In some embodiments, the first block comprises a material other than masonry material.
In some embodiments, at least a portion of the first bottom face is conical.
In some embodiments, each of the first rod and the second rod has a protrusion in the form of a nut.
In some embodiments, each of the first rod and the second rod has a hexagonal concavity configured to receive a male driving socket.
In some embodiments, the second block comprises approximately half of the volume of the first block.
Some embodiments described herein include a wall constructed from the wall system comprising a plurality of staggered rows of blocks; a plurality of columns of couplers located within the blocks; a plurality of rods, wherein each rod is coupled to one coupler in each of the plurality of staggered rows of blocks, and wherein each rod is coupled to a coupler within a footing.
Some embodiments described herein include a system for constructing a wall comprising a plurality of blocks adapted to stack together; one or more couplers located inside each of the blocks; and a plurality of rods, each adapted to be inserted into or through couplers in at least two blocks stacked upon each other.
In some embodiments, the one or more couplers are threaded couplers and the one or more rods are threaded rods.
In some embodiments, the one or more rods are dual-headed rods, and the one or more couplers have an internal structure configured to receive and retain a portion of the one or more dual-headed rods.
In some embodiments, the couplers are affixed inside each of the blocks.
In some embodiments, the couplers are formed inside each of the blocks.
In some embodiments, the couplers are cut inside each of the blocks.
Some embodiments described herein include a construction block, comprising a top, a bottom, a front side, a back side, a first end, and a second end; two parallel channels extending inside the block from the top to the bottom; and a connector located in each of the channels.
In some embodiments, the connector is cast in each of the channels.
In some embodiments, the connector is cut in each of the channels.
In some embodiments, the connector is a threaded connector.
In some embodiments, the top and the bottom comprise mating structures adapted to hold the block in alignment with a matching second block when stacked on such a second block.
Some embodiments described herein include a method of forming a wall comprising providing a wall system as described herein; stacking the first block in a staggered position relative to the second block such that the first channel aligns with the second channel; inserting the first rod into the first channel and the second channel such that the first rod passes into the first coupler and into the third coupler; and rotating the first rod within the first coupler and the third coupler to securely fasten the first block to the second block.
Beginning with reference to
It will be appreciated by a person of ordinary skill in the art that the convex portion 101, and concave portion 102 of each block 100 can occur on any face. For instance, in some embodiments the convex portion 101 can be on top and the convex portion 102 on the bottom as shown in
In some embodiments the blocks 100 are comprised of traditional masonry materials such as brick, concrete, cement, asphalt, stone, or other similar materials. In other embodiments, alternative natural or man-made materials such as ceramics, plastics, rubbers, composites, woods, acrylics, fiber-reinforced polymers such as fiberglass, or other appropriate substances can be used to form the solid blocks 100. Fibers can be used in some applications to increase the strength or reduce the weight of the blocks. In some embodiments the blocks 100 have a tongue and a groove channel which are configured to interlock with an associated tongue or groove on an adjacent block. The interlocking tongue and groove structures may be disposed along the entire length of the blocks to prevent wind or moisture from penetrating through the wall joints. In some embodiments textures may be cast into the block faces for aesthetic or functional benefit. In some embodiments the blocks 100 are solid. In some embodiments, the blocks 100 can be porous, honeycombed, latticed, foamed, woven, hollow, or of any other suitable form, in configurations that provide sufficient support for the receiving elements 105 described below.
As can be appreciated by a person of ordinary skill in the art, in applications in which weight of the blocks 100 is a concern, the solid masonry units can be cast with lightweight concrete or composites to mitigate increased weight that could result from installing solid as opposed to hollow units 100. For example, any of the known lightweight concrete materials can be used, including lightweight aggregates, foamed concretes and those incorporating fly ash, ceramic spheres, glass spheres, wood fiber, and the like. Furthermore, materials used to form the blocks 100 may be selected to provide desired properties, such as weather resistance, heat resistance, resistance to solvents, acids, bases, oxidants, or other harmful agents present in the environment, aesthetic preference, resistance to mechanical load, vibrations, or other stresses, or other practical considerations as would be apparent to a person of ordinary skill in the art.
In certain embodiments, the blocks 100 are stacked vertically so that the concave portion 102 of one block 100 interfaces flush with the convex portion 101 of another block 100. In some embodiments, the blocks are stacked such that a tongue on one block interfaces with a groove on another block. In some embodiments, the blocks 100 can be staggered so that a first concave portion 101 of a first block 100 interfaces with a first convex portion 102 of a second block 100 and so that a second concave portion 101 of the first block 100 interfaces with a second convex portion 101 of a third block 100. As can be appreciated, the locations of concave 102 and convex 101 portions can be in any other permutation. A person of ordinary skill in the art will appreciate that different staggering patterns and different patterns of concave and convex portions 101, 102 can provide advantages in various applications, including tying a wall together and avoiding vertical propagation of cracks or movement of the finished wall.
In some preferred embodiments, the concave and convex portions 102, 101 are conical, truncated conical, or substantially conical in shape. Optionally, channels 106 pass through the apex of these conical portions 101, 102. In a stacked vertical wall, for example, in one preferred embodiment the hollow channels 106 run vertically, as illustrated, passing entirely through the blocks 100 from top to bottom
In some preferred embodiments, interconnect elements 104 are provided that connect to and preferably support receiving elements 105, which preferably are located in the channels 106. Thus, in one preferred vertical wall embodiment illustrated in
Now with reference to
For optimal stability, the wall is preferably connected to a footing 204, extending down into the earth or otherwise in or on a stable bearing material. The footing 204 may be equipped with anchor assembly comprising a support rod 207, 205, an anchor 201, and a coupling 206. Anchor structure 201, may be attached within the footing 204. For instance, the anchor 201 can be cast into a concrete footing 204. The anchor provides a mechanical coupling to one or more support rods 207, 205. In the case that there are multiple support rods, the rods 207, 205 may be connected to one another by a coupling 206. In such cases, the coupling 206 may optionally provide anchor support with respect to the footing 204, for instance with protrusions (not shown). The entire anchor assembly is preferably attached, either through a coupling 206, or directly from the anchor 201, to the rods 103 or coupling devices 200 of the wall system. Thus, with reference to
In some preferred embodiments, the rods 103, 205, 207, are not distinct units but comprise single units that can be driven, turned, or threaded from the top of the constructed wall completely through into the footing 204. In such embodiments, these interlocking rods 103 create a continuous and unbroken vertical tie between all of the couplings 105, 206, 201. Such continuous rods 103 may also be integrally tied to or threaded to the blocks 100 through casting of the coupler assembly 104, 105, into each of the blocks 100 and then turning or threading the rods 103 through those couplers. The running bond configuration of the masonry construction with the interconnect members 104, along with the continuous nature of the rod 103, also provides a horizontal interlock between masonry units.
Referring now to
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In assembling a wall from the blocks 100 as described herein, one exemplary embodiment is as follows: A footing 204 is formed, with threaded anchors 201 (and/or 206) cast thereinto. The anchors are accessible from the top of the footing so that threaded rod 103 (or 205, 207) can be inserted thereinto from above the footing 104, and such accessibility can be provided, e.g., by channels formed in the footing 104 at the time it is poured or thereafter, or through sleeves extending upward from the threaded anchors 201 or 206. The horizontal spacing of the anchors is the same as or is a multiple of the spacing of channels 106 in the stacked blocks 100. Thereafter, blocks 100 are stacked on the footing 104, with channels 106 in the block lining up with the anchors 201 in the footing. In one embodiment, after each layer of block 100 is stacked, a threaded rod 103 is driven through a threaded coupling device 105 in that block and into the coupling device 105 or anchor 201 or 206 in the block or footing immediately below, leaving the top of the threaded rod 103 preferably about half way through the coupling device 105 in the top-most block. Then the next layer of block 100 is stacked, using the convex and concave portions 101 and 102 to align the blocks and the channels 106, and the threaded rods 103 are inserted as above to tie that layer to the layer beneath. Alternatively, several layers can be stacked at once, and then a longer rod 103 can be driven through all of the layers. Note that unlike prior proposed building block systems, this building system does not rely on tension in rods 103 to maintain the system in place and to provide structural strength. Note also that although the full blocks 100 in the exemplary embodiments are approximately half as high as they are long, and have two vertical channels 106 running therethrough, other ratios of height to width are contemplated, as are other numbers of channels, e.g., 1, 3, 4, or more channels. Moreover, although the depth of an individual full block can advantageously be the same as the height and half of the width, with a half block being cubical, those ratios can also be varied as desired.
Another embodiment of wall assembly is similar to the process described in the exemplary embodiment above. The second embodiment differs only by the substitution of the dual-headed rod 900 for the threaded rod 103, and the substitution of the coupling element 900 for the threaded coupling device 105. According to this embodiment, installation is simplified by installing the dual-headed rod with a short manual turn rather than the driving of a threaded rod.
One embodiment of fabricating a block 100 includes the use of moveable mold liners with a traditional dry cast block making machine such as the system presented in U.S. Pat. No. 7,156,645 B2. Dry cast block machines utilize a zero-slump concrete mix formed with vibration and pressure to reach high production rates of traditional concrete block. Using a moveable mold liner system in conjunction with the dry-cast block machine enables the incorporation of textures and the imprinting of concave and convex portions as well as any tongue and groove channels desired in the various iterations of this block product
Another method of block fabrication includes the casting of wet mix concrete into molds that incorporate textures, the imprinting of concave and convex block mating features, tongue and groove channels for various facets of utility previously detailed, and casting of the internal coupling system, as well as other channels for various functions. As can be appreciated by a person of ordinary skill in the art, many of the embodiments discussed above provide for systems that have the advantages of the traditional grouted concrete masonry system as well as the advantages of a mortarless, stackable system. Various embodiments have the ability to resist vertical and lateral loads in the same fashion as the traditional grouted masonry wall with a continuous tension resisting element cast into the units, while also retaining the advantage of quick, simple and inexpensive installation of pre-manufactured boltable units. Unlike previous systems, the connection of the rods and couplers in the various embodiments require no tension. This is because the couplers are fixed, formed, or cut into the blocks so that they cannot rotate or move within the blocks as the bolts are connected to the couplers. Tension only develops during lateral loading as is the case in traditional masonry construction. The blocks retain the benefit of being cast integrally with the block and also have the advantage of being solid cast units requiring no mortar or grouting for installation. The structural analysis for determining the lateral strength of walls of various embodiments is no different from the traditional grouted wall design since the structural mechanism is the same. The relevant material property of the block is compressive strength. High compressive strength lightweight materials such as wood, plastics, fiberglass, and composites represent viable alternatives to concrete blocks, and provide the required compressive strength to equal traditional concrete masonry compressive strengths while allowing a solid block weight to be similar to that of the hollow concrete masonry block weight of some stackable systems. Where the importance of heat resistant materials supersedes the need for lightweight blocks, conventional or lightweight concrete may be used.
The present application is a continuation of U.S. application Ser. No. 13/569,126, entitled “MASONRY REINFORCEMENT SYSTEM” filed Aug. 7, 2012, which claims the benefit of priority to U.S. Application No. 61/521,508, filed Aug. 9, 2011, both of which are hereby incorporated by reference in their entireties.
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Number | Date | Country | |
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Parent | 13569126 | Aug 2012 | US |
Child | 14159792 | US |