The present application is a § 371 national stage of International Application PCT/EP2019/074063, filed Sep. 10, 2019, which claims priority benefit to U.K. Pat. Application Ser. No. 1815813.9, filed Sep. 28, 2018, both of which are hereby incorporated herein by reference in their entireties.
The present invention relates to building materials, in particular to a modular building block apparatus and in particular to a modular building block apparatus for forming a coastal or river bank erosion defence or protection structure.
Water barriers are typically installed along stretches of the coast or river banks where high water levels can pose a significant risk to surrounding structures. Furthermore the constant battering from waves can cause significant damage to coastlines and as a result barrier apparatus are typically installed to both protect the coastline from erosion and also protect nearby homes. Examples of this type of apparatus include seawalls, levees and gabions. It is well known that the construction of these structures can be a long and tedious process as the construction depends on how much of the structure can be built in between high and low tide, with certain sections having to be completed before the high tide returns. This means that construction has to be run on a very restricted schedule and delays are a common occurrence. Furthermore these structures all require a significant amount of labour to install.
Alternative defences have also typically been employed to a somewhat limited effect. These include the use of sheet iron piling which is installed along a coastline. This form of sea defence has a significantly reduced capability because, when waves crash against the structure, a portion of the water falls behind the structure and over time this water accumulates with the resultant force of this water pushing the structure forward until it eventually collapses. Another alternative defence is the use of sandbags which are typically used to create artificial dunes. However sandbags are inefficient because they readily become saturated and allow for the ingress of water, when placed along a coastline. Furthermore, the constant battering of the waves is prone to tearing the sandbags apart, rendering them substantially redundant as a barrier structure.
The present invention provides a modular building apparatus that is relatively easy to install, is customisable to the user's needs, and creates a barrier capable of withstanding the constant battering of waves along a coastline when installed.
According to a first aspect of the present invention there is provided a modular building block apparatus for the construction of a coastal or river bank erosion defence or protection structure, the apparatus comprising a plurality of blocks arranged in stacked rows, the blocks in each row having cooperating formations whereby the blocks in each row are interconnected with one another, apertures being formed in each block extending perpendicular to the rows, a plurality of connector members extending through aligned apertures in adjacent rows of the blocks to interlock the rows to one another.
The cooperating formations of each block may comprise at least one male engagement portion extending laterally from the body of the block and at least one cooperating female engagement portion provided in the body of the block for receiving the male engagement portion of an adjacent block.
In one embodiment a plurality of the rows of blocks are layered on top of one another in staggered or stepped relationship.
The female engagement portion of each block may be shaped to prevent the lateral movement of the cooperating male engagement portion of an adjacent block in a respective row when received therein.
The male engagement portion may comprise an exterior projection which extends laterally from the body of each bock.
In one embodiment each block may comprise first and second sides and first and second ends along with a base and top, the first and second sides being substantially parallel to each other and the first and second ends being substantially parallel to each other such that each block has a substantially cuboid shape.
Optionally, at least one channel extends substantially across at least one face of each block to define a drainage channel between adjacent rows of the blocks when the blocks are in abutting stacked relationship. The channel may comprise an elongate groove formed in a face of each block.
In one embodiment at least one of the apertures of each block of each row is aligned with an aperture of a block in an adjacent row, a respective connector member extending through the aligned apertures to interconnect the rows of blocks. Each of the connector members may comprise an elongate post, rod or pin dimensioned to fit through the aligned apertures in the blocks. Optionally, each connector member has a pointed or tapered end adapted to be inserted into a surface upon which the blocks are located. Each aperture of each block may have tapered walls such that a respective connector member is an interference fit therein.
Optionally, each block is made from an impermeable material. In one embodiment each block may be made from geopolymer cement, for example.
At least one layer of fabric or mesh may be located between adjacent rows of the blocks, the layer of fabric or mesh extending laterally from the blocks to be embedded in a body of material against which the apparatus is located, in use, to anchor the apparatus to the body of material.
According to a further aspect of the present invention there is provided a coastal or river bank erosion defence or protection structure comprising a modular building block apparatus in accordance with the first aspect of the invention.
These and other objects, advantages and features of the invention will become apparent upon review of the following specification in conjunction with the drawings.
An embodiment of the invention is now described by way of example and with reference to the following drawings in which:
In the illustrated embodiment the block 2 has at least one male engagement portion 22 and at least one female engagement portion 24. The at least one male and female engagement portions may be located on any of the exterior faces of the block 2. The at least one male and female engagement portions are shaped to have substantially corresponding dimensions. One end 8 of the block 2 has a male engagement portion 22 which extends from the body of the block 2 in a substantially lateral direction. The male engagement portion 22 comprises an exterior projection. In the illustrated embodiment the male engagement portion is substantially cylindrical shaped. The male engagement portion 22 is approximately the same height as the block 2. At least one end 10 of the block 2 has a female engagement portion 24. The female engagement portion 24 is typically shaped and dimensioned to define a recess. In the illustrated embodiment the female engagement portion 24 is substantially cylindrically shaped. The female engagement portion 24 is typically shaped and dimensioned to correspond to and receive the male engagement portion 22.
Optionally, the block 2 may be made from a substantially impermeable material. For example, the block 2 may be made from rubber, plastics, cement, wood any combination thereof. In a preferred embodiment each block 2 may be made from geopolymer concrete. In one embodiment each block is made from a polypropylene fibre/concrete mix or a stainless steel fibre/cement mix as follows:—
Polypropylene Fibre Mix:—
OP Cement to BS EN 197-1 225 kg/m3
PFA/GGBS 155 kg/m3
Total=380 kg/m3
W/C=0.45
With 4 kg/m3 ADFIL Micro Fibre Durus S400
Stainless Steel Fibre Mix:—
OP Cement to BS EN 197-1 225 kg/m3
PFA/GGBS 155 kg/m3
Total=380 kg/m3
W/C=0.45
With 30 kg/m3 S/S Draymix I/d 45
The block 2 typically incorporates at least one channel 3. The at least one channel 3 typically extends substantially across at least one face of the block 2. In one embodiment, the block 2 may have first and second channels 3 which extend across the base 12, the channels 3 extending parallel to ends 8 and 10. Advantageously, the (or each) channel 3 allows for the flow of water through the and/or under the block 2 in use. The at least one channel 3 typically comprises an elongate groove. In an alternative embodiment the block 2 may be shaped to incorporate one or more channels which may extend laterally through the body of the block.
In the first embodiment the block 2 incorporates a plurality of apertures 26. The apertures are typically located on the base and top faces 12, 14. The apertures 26 typically extend the full height of the block 2. One or more connector members, each in the form of an elongate pin or rod 28 (hereinafter referred to as a “connector rod”), are insertable into, and preferably through, any one or more of the apertures 26. Each connector rod 28 is typically of substantially greater height than the aperture 26. The connector rods 28 may each extend the height of a plurality of modular blocks 2. Each connector rod 28 may be insertable through a plurality of adjacent modular blocks 2 in use to secure the blocks together. Each connector rod 28 may have a tapered point 29 to allow it be to driven into the ground beneath the blocks. Each connector rod 28 may comprise an elongate rod or post made from wood, metal, rubber, plastic, stone or concrete. In one embodiment each connector rod may comprise a metal pipe, more preferably formed from stainless steel for corrosion resistance, and may be infilled with concrete for additional ballast. In an alternative embodiment each connector rod 28 may comprises an elongate rod or post manufactured from wood, such as oak.
As illustrated in
The connection between adjacent blocks 2 in each row is formed by the engagement of the corresponding male and female engagement portions 22, 24 of the blocks 2. In the illustrated embodiment the male engagement portion 22 is slidably connectable with the female engagement portion 24. The female portion 24 only allows for the longitudinal movement of the male engagement portion 22 when connected. The female engagement 24 portion prevents lateral movement of the male engagement portion 22 when connected. Alternatively, the male and female engagement portions may be shaped and dimensioned to form an interference fit when engaged. A plurality of adjacent modular blocks 2 can be connected together in this manner to form an elongate section of connected blocks.
The plurality of blocks 2 may be adapted to be connected at various angles with respect to one another. Advantageously, this allows the blocks 2 to be connected into a shape corresponding to the user's requirements. Furthermore, in the illustrated embodiment a plurality of elongate block sections or rows can be layered on top of one another to form a wall like structure 25. The height and width of the wall 25 may be determined by the number of layers of connected block sections or rows. In the illustrated embodiment a plurality of rows of connected blocks are layered on top of one another with each alternating layer of blocks being staggered. The arrangement of the holes 26 in each block 2 facilitates such staggered or stepped arrangement. Advantageously, when the connected block sections are layered on top of one another the at least one aperture 26 of each block 2 aligns with the aperture of the block 2 layered above and/or below. The alignment of the apertures 26 of various layers of blocks 2 allows for the connector rods 28 to be inserted through the plurality of apertures 26.
The connector rods 28 prevent the disconnection of the connected block sections or rows in use. Further advantageously the at least one channel 3 of each block 2 allows for water to be able to flow through the wall like structure 25 in use.
As illustrated in
The channels 3 formed in the lower faces of the blocks allow water to drain between the layers of blocks to prevent the build up of water behind the blocks, which might otherwise undermine the structure.
Geotextile grids 42 may be provided between the layers of blocks 2, extending into the bank/backfill 40, to anchor the blocks to the bank/backfill 40.
A lowermost row of blocks defining the bottom of the structure may include an enlarged toe 45, defining a downwardly extending projection preferably depending from the front side of the blocks, the toe 45 being received in a trench 44 at the bottom of the bank 40 to reduce scouring and enhance the stability of the structure and the underlying bank/layer of backfill 40.
The stepped arrangement of the blocks 2 may facilitate pedestrian access to the adjacent location, for example to a beach.
As well as receiving the connector rods 28 for securing the rows of blocks 2 to one another, the apertures 26 in the blocks 2 may be used to receive posts 50 upon which may be mounted handrails 52, as shown in the drawings.
Unused apertures 26 in the blocks 2 may be plugged if desired, for example to reduce turbulence.
The width of each building block 2, (from side 4 to side 6) may be approximately 1000 mm. The length of each building black including the male engagement portion 22, may for example be approximately 1820 mm. The height of each building block 2 may for example be approximately 200 mm. It may be desirable that the length of the male engagement portion 22 is substantially the same or similar as the length of the recess of the female engagement portion 24. In the case of the corner building blocks it is desirable that the length and height of the blocks 32, 52 is substantially the same or similar as the length and height of the block 2. The at least one channel 3 is typically 70 mm wide with a depth of 50 mm. The channel 3 typically extends the total width (1000 mm) of the block 2. The connector rods 28 may have a length of approximately 600 mm and a diameter of approximately 150 mm. Optionally, the blocks 2 and connector rods 28 may be of substantially greater or lesser dimension.
In the embodiments described above the blocks 2 are preferably solid blocks. Alternatively, the blocks 2 may be hollow with an inlet (not shown) for the intake and removal of a ballast material, such as sand or water.
In the embodiment described above the apparatus is described for use as a coastal or river bank erosion defence or protection structure. However, numerous other applications are envisaged, such as for use as embankments, retaining walls or bunding in the form of a retaining wall around storage where potentially polluting substances are handled, processed or stored, for the purposes of containing any unintended escape of material from that area until such time as remedial action can be taken, for example to prevent oil spillage around an oil well, or as a flood defence.
When used as bunding or flood defence barriers, the drainage channels 3 may be omitted so that the blocks can define a water/oil impervious barrier. For such application the blocks may be supplied as hollow bodies, such as formed from a plastic and produced by a blow moulding or rotational moulding process, such that the blocks may be filled with a ballast material, such as water or sand, preferably on site, via a suitable filler opening.
The blocks may be any size, may be solid or hollow and may be made of any material, including plastic, rubber, recycled materials or concrete.
The invention is not limited to the embodiments described herein but can be amended or modified without departing from the scope of the present invention, which is intended to be limited only by the scope of the appended claims as interpreted according to the principles of patent law including the doctrine of equivalents.
Number | Date | Country | Kind |
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1815813 | Sep 2018 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/074063 | 9/10/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/064321 | 4/2/2020 | WO | A |
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Number | Date | Country |
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2015176084 | Nov 2015 | WO |
Entry |
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US 6,089,793 A, 07/2000, Rainey (withdrawn) |
International Search Report of corresponding PCT Application No. PCT/EP2019/074063, dated Nov. 7, 2019. |
Number | Date | Country | |
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20220002960 A1 | Jan 2022 | US |