DE202023107019U1 - A flood protection block - Google Patents

Abstract

Flood protection block for protecting a place from the effects of a water flow, the flood protection block comprising:
- a body having a proximal end and a distal end;
- wherein the proximal end of the block is configured to engage the distal end of a second block;
- wherein the distal end of the block is configured to engage with a proximal end of a third block;
- where the body has a density greater than 950 kg/m ³ .

Description

Technical area

The present application lies in the field of flood protection barriers. This can be to contain a body of water in a limited area or to divert flowing water away from houses, roads and businesses.

background

Drainage systems can fail, pipes can burst and rivers can burst their banks. As a result, flooding can occur suddenly and from a number of different sources and locations - some of which are not always the most accessible. It is therefore imperative that flood defence systems are quick and easy to implement so that an immediate or proactive response can be achieved under time pressure.

Conversely, floods can recede and return to normal water levels just as quickly as they were previously exceeded. It is therefore important that flood defences can be easily dismantled and stored and that they are able to be deployed only when and where they are needed. Achieving this balance between effective flood safety and the resumption of normal daily life is crucial.

Modular barriers such as sandbags and concrete blocks are commonly used to form a physical barrier between the flood water and the area to be protected and are known in the art.

Both sandbags and concrete blocks come with technical and logistical issues. Sandbags tend to spill residue when used and can attract pests when stored for long periods. Structures formed by stacking sandbags also lack uniformity and are therefore weaker than other alternatives. These structures can also have gaps between sandbags, allowing water to leak into protected areas. Concrete blocks are large, heavy and hard. As a result, they are difficult to transport in large quantities and require more labor to place them in desired locations. These characteristics can also cause the blocks to erode the ground when moved under the force of flood waters, as well as making them difficult to store. Concrete blocks can therefore cause additional damage to road surfaces on which they are placed during flood-like situations.

Aspects of the present invention aim to address at least some of the above problems.

Statements on the invention

Aspects of the invention are set out in the independent claims. Optional features are set out in the dependent claims.

According to a first aspect of the invention there is provided a flood protection block for protecting a site from the effects of water flow, the flood protection block comprising: a body having a proximal end and a distal end; the proximal end of the block being configured to interlock with the distal end of a second block; the distal end of the block being configured to interlock with a proximal end of a third block; the body having a density greater than 950 kg/m ^3. Advantageously, flood protection blocks having a density greater than 950 kg/m ³ have been found to have far greater benefit in preventing damage during flood events. This is because they are less susceptible to movement in response to water flow and are therefore more likely to remain in their intended position and limit water ingress as intended.

Optionally, the density is greater than 1000 kg/m ³ . This has the advantage of further reducing the risk of movement in response to water flow and thus providing a safer placement. Blocks with this density can therefore also withstand greater flood forces.

Optionally, the density is greater than 1050 kg/m ³ and further optionally the density is 1077 kg/m ³ . These higher densities further reduce the likelihood of movement under the force of water and therefore increase the forces that the block can withstand before it moves. It is noted that 1077 kg/m ³ is optimal to strike a balance between minimizing block movement and soil erosion.

Optionally the density is less than 1300 kg/m ³ .

Optionally, the density is less than 1200 kg/m ³ and further optionally, the density is less than 1100 kg/m ³ . Limiting the densities to the values mentioned prevents the block from erosion of the soil If this is the case, the block should move under the force of the water.

Optionally, the proximal end of the block is pivotable with respect to the distal end of the second block when the proximal end of the block and the distal end of the second block are interlocked; and/or the distal end of the block is pivotable with respect to the proximal end of the third block when the distal end of the block and the proximal end of the third block are interlocked. This advantageously allows the blocks to be formed into an adjustable shape that follows a particular geometry, such as the curve of a road, or into a shape that can direct water flow in a particular preferred direction.

Optionally, the distal end includes a convex part and the proximal end includes a concave part. This can enable optimal mosaicing of the blocks with each other.

Optionally, the convex part is a rounded protrusion, optionally forming part of a circle. This shape is advantageously more wear-resistant compared to a geometry with corner points, which is likely to be damaged during use or storage.

Optionally, the concave portion includes a rounded recess, with the recess optionally forming part of a circle. Advantageously, this is complementary in shape to the distal end and significantly more wear-resistant than a sharper, non-rounded geometry.

Optionally, the convex part is equal in shape and size to the space formed by the concave part. Such an arrangement allows for a compact male-female fastener.

Optionally, the body includes a side face, and the side face includes a reflective area. The reflective area is particularly advantageous when used at the roadside to mark the location of hazard areas and to alert road users to the presence of the flood protection blocks themselves.

Optionally, the reflective region comprises a plurality of glass beads. Advantageously, the bed of glass beads allows light to be reflected back to the viewer from any (or at least a wide range of) angles of incidence. Compared to a flat surface, the spherical beads provide a much more practical reflective benefit. According to the law of reflection, the angle of reflection is equal to the angle of incidence with respect to a normal to that surface. Therefore, a flat surface would only reflect light away from a light source, such as a person in a car, unless positioned perpendicular to it. This is not possible to ensure in practice, and so spherical glass beads are much more advantageous in increasing the likelihood of light being reflected back to a light source.

Optionally, the glass beads sit under a protective layer, e.g. a polyurethane layer. This encloses the glass beads very comfortably and prevents them from becoming loose and detaching from the block.

Optionally, the glass beads sit on a bedding layer configured so that the vertical extent of the glass beads is uniform, optionally the bedding layer includes a rubber conforming layer. Advantageously, the flat surface can allow reflected light from bead one to form the incident light for bead two. This results in reflection of light at a wide range of angles from any angle of incidence. A flat surface can also be obtained.

Optionally, the glass beads are adhered to the block, optionally by a pressure-sensitive adhesive, further optionally the pressure-sensitive adhesive is arranged between the block and the bedding layer. Therefore, a firm connection is achieved without the need for fasteners. Such an arrangement also has the advantage of being easy to manufacture and implement.

Optionally, the body comprises at least one central lumen configured to allow a retaining device to be housed therein, the retaining device configured to hold the block in an intended position. This may reduce wear caused by the block on the road.

Optionally, the body includes a second central lumen, the first and second central lumens being aligned along a longitudinal centerline of the block. Advantageously, this allows the blocks to be stacked with more than one attachment point, preventing unwanted rotation with respect to stacked blocks, and thus a much more uniform structure.

Optionally, the block is configured to be stacked on a fourth block. This can allow the vertical extension of a block-built structure to be adjusted to the requirements. resulting from the predicted extent of the flood.

Optionally, the block comprises a base and an upper portion, the base of the block being configured to interlock with an upper portion of a fourth block. Advantageously, this enables vertical structures to be formed without the need for external fastening means.

Optionally, the upper part of the block is configured to interlock with a base of a fifth block. This advantageously allows structures to be formed without height restrictions and can thus provide effective flood protection at high water levels. The structure height can also be adjusted to suit water levels.

Optionally, the block is 60 cm long, 30 cm wide and 10 cm high. Advantageously, these dimensions are of a size that is comfortable enough to be carried by a single person with a single hand. Many blocks can also be stacked as they are thin enough and carried with both arms as the 60 cm is well within the arm span of a normal person. The width of the blocks is also suitable for such actions.

Optionally, the reflective surface is 10cm long and 3cm high and is located centrally on the side of the block. Advantageously, this size of reflector is large enough to allow a person to see the block from a considerable distance. This size is also small enough to be a cost-effective solution for achieving reflective means.

Optionally, the radius of the concave part and the radius of the distal part are 15 cm. This size allows for an easy fixing procedure as the fit tolerance is high.

Short description of the characters

• 1 is a perspective view of a flood protection block in a first embodiment seen from the distal end.
• 2 is a perspective view of the flood protection block of the 1 seen from the proximal end.
• 3a is a side view of the flood protection block of the 1 and 2 with optional dimensions.
• 3b is a frontal view of the flood protection block of the 1 and 2 with optional dimensions.
• 3c is a bird's eye view of the flood protection block of the 1 and 2 with optional measurements.
• 4 shows a perspective view of a flood protection block of the 1 to 3 constructed movable structure.
• 5 is a perspective view of three movable structures of the 4 in a stacked formation.
• 6 is an enlarged perspective partial cutaway view of an exemplary reflective substrate used in conjunction with the flood protection block of 1 to 3 can be used.

Detailed description

1 and 2 show a flood protection block for protecting a location from the effects of water flow, the flood protection block comprising: a body having a proximal end and a distal end; wherein the proximal end of the block is configured to interlock with the distal end of a second block; wherein the distal end of the block is configured to interlock with a proximal end of a third block; wherein the body has a density of greater than 950 kg/m ³ .

Flood protection block 1, as it is in the 1 and 2 is a three-dimensional structure defined by straight, parallel side edges and rounded, parallel longitudinal ends. In dimensions, the flood protection block 1 is significantly greater in length and width than in height and is approximately and optionally twice its width in length.

At its distal end, the flood protection block 1 comprises a convex part 3 configured to act as a male fastener. The convex part 3 may, as shown, occupy the entire width of the distal end, or it may optionally occupy only a part of this width. In the embodiment shown, the convex part 3 is a rounded protrusion formed by an arc with a radius equivalent to half the width of the flood protection block 1. In a separate embodiment, the convex part 3 could be replaced by a triangular part or another protruding shape. However, the convex shape implemented in the present embodiment offers advantages in terms of wear protection and protection against chipping due to its rounded and circular geometry.

Also in 1 and more clearly in 2 shown is a concave, rounded recess at the proximal end of the flood protection block 1. The concave part 5 is complementary in shape and size to the convex part 3. Alternatively, the convex part 3 can be described as corresponding in shape and size to the space formed by the concave part 5 and the latter is therefore configured to serve as a female fastener. In the present embodiment, the recess forms part of a circle mimicking the circular shape of the distal end. However, in alternative embodiments it is entirely possible to deviate from the shape shown as long as a complementary fit with the distal end is achieved. It is worth noting that the parallel relationship of the distal and proximal ends enables an important uniformity and symmetry which leads to benefits when stacking and storing the blocks as well as during their manufacture. The corner points of the concave part 5 may be rounded for wear protection reasons.

The 1 and 2 show side surfaces 7 which provide a surface for the reflective area 11. The reflective surface 11 has sufficient height and longitudinal length to define a conspicuously large reflective surface visible from a considerable distance. The reflective surface 11 of this embodiment does not have a substantial thickness which would require a cavity in the side surface 7, however, a slot 13 may optionally be used to better define the reflective surface as shown. The slot 13 projects from the upper part 9 by a distance which is approximately half the thickness of the flood protection block 1. The slot 13 does not project a substantial distance transversely into the flood protection block 1.

Flood protection block 1 also includes the central lumen 15. The 1 and 2 show an embodiment with two central lumens 15 aligned along a longitudinal centerline of the flood protection block 1 and separated from each other. However, it is quite possible that in another embodiment only one central lumen 15 is used. Such an arrangement is an optional variation of the embodiment shown and falls under the same inventive concept. Each lumen 15 is a through hole configured to accommodate a retaining device therein and thus forms a free passage from the upper part 9 to the base part of the flood protection block 1. Such a retaining device can come into direct contact with the surface beneath the flood protection block, such as a road surface.

Said holding means may be any means configured to hold the flood protection block 1 in a particular location. It may also be a means to provide a connection between layers of stacked blocks, as will be described later. For such an arrangement it is a great advantage to have two central lumens 15 as this allows the blocks to be stacked on top of each other with more than one attachment point. This prevents unwanted rotation with respect to stacked blocks and thus forms a much more uniform structure. A plurality of central lumens 15 would also directly enable a more robustly anchored structure to the ground or to other blocks in a stacked formation.

Another important aspect of the 1 and 2 is its density. The density of the flood protection block 1 is designed to be greater than 950 kg/m ³ . Blocks with such a density have far greater benefit in preventing damage during flood events. This is because they are less susceptible to movement by water flow and are therefore more likely to remain in their intended position and limit water ingress as intended. These benefits can be further enhanced by blocks with a density greater than 1000 kg/m ³ , for example blocks with a density of 1050 kg/m ³ and 1077 kg/m ³ . In developing the present flood protection block, increased density (to the value mentioned above) has been found to be extremely advantageous, particularly in the event of high velocity flooding, such as surface runoff on road surfaces. Such high velocity water can move less dense material and therefore this increased density is particularly useful in some embodiments. This density is particularly advantageous when combined with the blocks made from a rubberized material such as rubber or plastic. Rubber can be particularly advantageous and recycled rubber, recycled rubber granules or new rubber can be used. This material is capable of achieving such increased density but does not tend to cause erosion of road surfaces.

However, there is an upper limit that the density of the flood protection block 1 can have in some embodiments. To prevent the flood protection block 1 from eroding the soil, its density is preferably less than 1300 kg/m ³ . Alternative embodiments may limit the density values to less than 1200 kg/m ³ or 1100 kg/m ³ to ensure minimal soil erosion (e.g. for use on particularly vulnerable or valuable soil, such as the surface of car racing tracks). It is noted that 1077 kg/m ³ is optimal for a balance between minimal block movement and soil erosion. This density value for the block is therefore very advantageous in balancing these two opposing requirements for the block. Other embodiments (e.g. for use on surfaces where erosion is not a problem) may not have a maximum density.

Particularly useful ranges for density include 950 kg/m ³ to 1300 kg/m ³ , 1000 kg/m ³ to 1200 kg/m ³ and 1050 kg/m ³ to 1100 kg/m ³ . These ranges may depend on the severity of the water flow, the nature of the soil surface and its tendency to erode. For example, for a soil surface where erosion is less of a problem and low water flow is expected, the first range may be sufficient. For a soil surface prone to erosion, and where high water flow is expected, the narrowest range may make the most sense. The second range is more intermediate and should be suitable for most applications.

It should be noted that there may be some embodiments where the density is outside the ranges described above.

3 a , b and c show the dimensions of the various features of a first embodiment of the flood protection block 1 mentioned so far. The dimensions can be widely modified for other embodiments. It should be noted, however, that the dimensions shown are on a scale that can be comfortably carried by a person in one hand. These dimensions are also ergonomic for carrying several blocks stacked vertically.

The length of 60 cm, as in 3c is within the arm span of most people and ensures a controlled grip. Assuming a person carries the blocks at a comfortable navel height, the 3b highlighted thickness of 10.5 cm per block that a row of blocks can be stacked up to the chin. Stacking up to chin height ensures an unobstructed view of the person carrying the blocks and also allows the chin to be used as a support/balancing device when resting on the top block of the stack. The width of the blocks of 30 cm is also favorable for a safe transport technique, as the center of mass of the block stack never acts too far in front of the body of the person carrying the blocks.

Others in 3c Dimensions shown are from the central lumen 15 and the reflecting surface 11 in 3a . The longitudinal distance between the two central lumens 15 is ample enough so that when stacked with a holding means, the rotation between upper and lower blocks can be restricted. This results in a much more uniform and therefore more stable structure. Optionally, the dimensions of the reflective area are 10 cm in length and 3 cm in height. As mentioned, this is a sufficient size to ensure visibility from a distance while being cost-effective by not being excessive in size.

3c also shows that the radius of the distal part is 15 cm. This size allows for an easy attachment procedure, since the fit tolerances are high at this scale.

4 shows a mobile structure consisting of five flood protection blocks 1 as described above, each flood protection block 1 forming a module of the mobile structure. It can be seen that the distal end of a first block is interlocked with the proximal end of a second block. The interlocking is made possible by the tight fit of the convex part 3 of the block 1 in the space formed by the recess of the concave part 5 of a second block. This connection is repeated for the three remaining blocks in 4 repeated.

A key feature of the connection described is that there is a pivoting movement in the transverse direction between two blocks. This is due to the circular geometry of the interlocking. The distal end of a first block has clearance to yaw (pivot in the transverse direction) in the recess of a proximal end of a second block. This yaw freedom allows the two interlocking blocks to be angularly separated from each other, but still to be flush against each other over most of the surface of the convex (3) and concave (5) parts. This contact maintains the impermeability of the structure to flood water. Although this pivoting movement is restricted to a narrow angular range for each connection point, it still allows sufficient manipulation of the movable structure by the combined action of many connection points. The 4 The linear structure shown can therefore be adapted to give a transversely curved structure. This is particularly advantageous when attempting to direct water towards or away from a particular location by providing a barrier path that takes advantage of the flow. It is also worth noting that, since there are no obstructions at the top and bottom edges of the joint surfaces, vertical flexibility is provided to accommodate the profile of hilly and uneven terrain.

5 shows the three movable structures from 4 in a stacked formation. A first flood protection block 1 is configured to be stacked on a second flood protection block 200. Similarly, a third flood protection block 300 is configured to be stacked on a first flood protection block. This is made possible by each block having a flat base portion 17, a flat top portion 9 and evenly spaced central lumens 15.

Once the blocks are placed on top of each other, the flat base and top portions allow for flush contact while the central lumens 15 are aligned to provide an unobstructed circular cavity through both blocks. This through opening is configured to receive a retaining means (not shown), preferably of a rod-like nature. The retaining means is configured to block longitudinal and transverse movement of the stacked blocks relative to each other. A plurality of central lumens 15 will also limit rotational movement of the blocks and prevent any unwanted rotation relative to the stacked blocks, thus forming a much more uniform structure. In some embodiments, retaining means may be unnecessary and friction or other fastening means may be sufficient to hold the blocks together.

The uniformity and symmetry of the flood defence block 1 ensures that structures can be stacked without height limitations. There is no structural constraint limiting the height of stacked structures as each module is identical and thus the same connection can be repeated block by block. The blocks can be stacked to form very tall structures and so can form effective flood defences when water levels are high. The width of 30 cm ensures a relatively low centre of mass and this means that the stacked structures are very stable. The retaining means through the central lumen 15 can also be used as a stability enhancing feature, similar to reinforcements in other mechanical structures.

6 shows a perspective view of an exemplary reflective substrate 19 that can be used in conjunction with the flood protection block 1 to serve as a reflective area 11. The substrate 19 includes a bedding layer 21 in which a plurality of glass beads 23 are partially immersed. In the embodiment shown, this bedding layer 21 consists of a rubber conforming layer, wherein the vertical extent of the glass beads 23 is uniform. The rubberized nature of the bedding layer 21 conveniently accommodates the glass beads 23 by simply allowing the beads 23 to be pressed into the bed 21. This requires only minimal preparation of the rubber bed 21 to achieve the flat surface (uniform vertical protrusion). Were the bedding layer 21 made of a harder (non-rubberized) substance, a cavity would have to be defined for each glass bead 23 prior to insertion. Such embodiments, although possible, require greater manufacturing and assembly effort than those shown in 6 shown.

The bedding layer 21 (with the glass beads 23 distributed therein) is attached to side surfaces 7 of the flood protection block 1 with an adhesive 25. This adhesive may be a pressure sensitive adhesive applied between the side surface 7 and the bedding layer 21. In this way, a strong bond can be achieved without the need for external or additional fastening means. Such an arrangement also has the advantage of being simple to manufacture and implement with minimal user knowledge. It is further advantageous if the adhesive is waterproof to prevent the reflective area 11 from being torn away by flood water during use.

The implementation of glass beads 23 over other media allows for the reflection of light towards the viewer from any angle of incidence. The spherical nature of the beads 23 reflects incident light at multiple angles. This increases the likelihood that the reflected light will be directed towards the user. Should a non-spherical or flat medium be used, the light will be reflected away from the incident source according to the law of reflection, unless, of course, the surface is perpendicular to the incident light. In practice, it is not possible to ensure this orthogonality between reflecting surface and the source of incidence. Therefore, the spherical beads provide a much more convenient solution to reflect light in a street and urban environment by reflecting light in all directions over a wide range of angles. This increases the likelihood that the reflected light will enter the eyes of a person located close to a light source. Configuring the beads 23 so that their vertical extent is uniform assists in this function, since the light reflected from bead one forms the incident light for another bead, and so on and so forth for the remaining beads. This means that each reflected ray of light is reflected multiple times, resulting in the increased area of angular reflection that is so advantageous.

A protective layer (not shown), optionally a polyurethane layer, covers the glass beads so that they are attached to the bedding layer 21. Such a layer holds the glass beads 23 to the bedding layer 21 and prevents them from detaching without affecting the transparency and reflectivity of the glass beads 23.

The above embodiments are intended to be illustrative examples. Other embodiments are also contemplated. It is to be understood that any feature described with respect to any embodiment may be used alone or in combination with other described features, and may also be used in combination with one or more features of any other of the embodiments or any combination of any other of the embodiments.

Furthermore, equivalents and modifications not described above may also be used without departing from the scope of the invention as defined in the appended claims.

Claims (22)

A flood protection block for protecting a location from the effects of a water flow, the flood protection block comprising: - a body having a proximal end and a distal end; - wherein the proximal end of the block is configured to interlock with the distal end of a second block; - wherein the distal end of the block is configured to interlock with a proximal end of a third block; - wherein the body has a density greater than 950 kg/m ³ . Flood protection block according to Claim 1 , wherein the density is greater than 1000 kg/m ³ , optionally, wherein the density is greater than 1050 kg/m ³ and further optionally, wherein the density is 1077 kg/m ³ . Flood protection block according to Claim 1 or 2 , wherein the density is less than 1300 kg/m ³ , optionally, wherein the density is less than 1200 kg/m ³ , further optionally, wherein the density is less than 1100 kg/m ³ . A flood protection block according to any preceding claim, wherein the proximal end of the block is pivotable relative to the distal end of the second block when the proximal end of the block and the distal end of the second block are interlocked; and/or the distal end of the block is pivotable relative to the proximal end of the third block when the distal end of the block and the proximal end of the third block are interlocked. Flood protection block according to one of the preceding claims, wherein the distal end has a convex part and the proximal end has a concave part. Flood protection block according to Claim 5 , where the convex part is a rounded projection, optionally forming part of a circle. Flood protection block according to Claim 5 or 6 , wherein the concave part comprises a rounded recess, the recess optionally forming part of a circle. Flood protection block according to one of the Claims 5 until 7 , where the convex part is equal in shape and size to the space formed by the concave part. A flood protection block according to any preceding claim, wherein the body comprises a side surface and the side surface comprises a reflective region. Flood protection block according to Claim 9 , wherein the reflective region comprises a plurality of glass beads. Flood protection block according to Claim 10 , where the glass beads sit under a protective layer, for example a polyurethane layer. Flood protection block according to Claim 10 or 11 , wherein the glass beads sit on a bedding layer configured such that the vertical extent of the glass beads is uniform, the bedding layer optionally comprising a rubber conformation layer. Flood protection block according to one of the Claims 10 until 12 , wherein the glass beads are glued to the block, optionally by a pressure-sensitive adhesive, further optionally wherein the pressure-sensitive adhesive is arranged between the block and the bedding layer. A flood protection block according to any preceding claim, wherein the body comprises at least one central lumen configured to receive a retaining device therein, the retaining device configured to hold the block in an intended position. Flood protection block according to Claim 14 , comprising a second central lumen, wherein the first and second central lumens are aligned along a longitudinal centerline of the block. A flood protection block according to any preceding claim, wherein the block is configured to be stacked on top of a fourth block. Flood protection block according to Claim 16 , the block comprising a base and an upper portion, the base of the block configured to engage an upper portion of a fourth block. Flood protection block according to Claim 16 or 17 wherein the upper portion of the block is configured to interlock with a base of a fifth block. Flood protection block according to one of the preceding claims, wherein the block is 60 cm long, 30 cm wide and 10 cm high. Flood protection block according to Claim 19 , with the reflective area being 10 cm long and 3 cm high and located centrally on the side of the block. Flood protection block according to one of the preceding claims, wherein the radius of the concave part and the radius of the distal part is 15 cm. A flood protection block according to any preceding claim, wherein the body is made of rubber or a rubberized composition.

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