BE1031663A1 - Building block for a trench silo and a method for forming a trench silo wall - Google Patents

Abstract

The present invention relates to a building block for a trench silo, comprising a hollow beam-shaped body with a front wall, a rear wall, a bottom surface, an open top surface and two side walls located opposite each other, wherein a first side wall is provided with a male coupling means and the second side wall located opposite it is provided with a female coupling means with a complementary shape so that the first side wall of a first building block and the second side wall of a second adjacent building block can be connected to each other by engagement of the male coupling means in the female coupling means, wherein, viewed in a direction transverse to the side walls, the male coupling means is designed as a protruding part and the female coupling means as a recessed part, wherein, viewed in a direction transverse to the open top surface, the male coupling means and the female coupling means extend beyond the open top surface. The invention also relates to a method and a use.

Description

1 BE2023/5454

BUILDING BLOCK FOR A TRENCH SILO AND A METHOD FOR FORMING IT

FROM A WALL OF A TRENCH SILO

TECHNICAL DOMAIN

The invention relates to a building block for forming a trench silo, more specifically a building block for forming a wall of the trench silo. The invention also relates to a method for forming a wall of a trench silo and a use of the building block for forming a trench silo for storing agricultural bulk goods.

STATE OF THE ART

A trench silo is known from the state of the art. A trench silo is a hardened construction with walls and a covering system, such as a tarpaulin, in which bulk goods can be stored horizontally. Trench silos are often used for the storage of agricultural bulk goods, such as silage grass, silage maize, beets, by-products, compost and manure. The use of trench silos, instead of unhardened storage areas, ensures less loss (during ensiling and removal) and prevents contamination with the soil. In addition, agricultural bulk goods can be stacked more easily and safely to a greater height.

For reasons of simplicity of construction and limited cost, trench silos are usually constructed using L-shaped, T-shaped or U-shaped elements or using modular building blocks. These elements and building blocks are usually made of concrete. L-shaped elements have the disadvantage that bulk goods can only be stacked on one side of the L-shaped element.

With a T-shaped element it is possible to stack bulk goods on both sides. Both elements have the disadvantage that, if they are placed on an already cast floor slab, the foot of the L-shaped or T-shaped element forms an obstacle when digging out the trench silo. In addition, these L-shaped or T-shaped elements have a very limited wall thickness, making it virtually impossible to walk on these elements, for example when sealing and opening the trench silo. The U-shaped element addresses these shortcomings of the L-shaped and T-shaped elements. A U-shaped element is often used as a partition wall to replace a T-shaped element and has the major advantage that the trench silo becomes much more accessible. In addition, the U-shaped element has no

2 BE2023/5454 foot that hinders the excavation of the trench silo. A U-shaped element has the disadvantage of its cost. Due to its weight, the U-shaped element is expensive to transport and also requires a lot of reinforcement.

Another possible solution is solid modular building blocks. These modular building blocks are placed on top of each other in a half-brick pattern and are connected to each other by means of studs on the top and corresponding recesses on the bottom. These blocks are made of unreinforced concrete, but are still stable due to their solid construction. A disadvantage of solid modular building blocks is the high transport costs due to the weight. An additional disadvantage is the many concrete seams. A wall of a trench silo must be sealed airtight, so that contact of the agricultural bulk goods with oxygen is prevented. For this reason, all concrete seams are sealed with a suitable sealant. There are so many seams in solid modular building blocks that an airtight construction cannot be guaranteed.

Another solution can be considered as a combination of U-shaped elements and solid modular building blocks. These are hollow concrete blocks that are first placed on top of each other and then filled with, for example, crushed stone or sand.

Advantages are that here too there is no foot that hinders during the excavation, the wall of the trench silo is wide enough to walk on, the transport costs are lower due to the hollow concrete blocks and the hollow blocks are larger, which means that there are fewer seams between the hollow concrete blocks to seal. A disadvantage of these hollow concrete blocks is that they are simply stacked on top of each other and are therefore less stable and bulk goods cannot be stored as high in the trench silo. The bulk goods cannot be compressed either because this causes too much pressure on the wall of the trench silo. Such hollow concrete blocks can also be stacked in half-brick bond, which results in a reinforcement of the wall of the trench silo. This has the disadvantage that both full and half hollow concrete blocks are required. An additional disadvantage is that such a wall cannot easily be extended in length. It is necessary to partially dismantle the trench silo wall so that the half hollow concrete blocks at one end of the trench silo wall can be replaced with full hollow concrete blocks to expand the wall.

The present invention aims to find a solution to at least some of the above-mentioned problems or disadvantages.

3 BE2023/5454

SUMMARY OF THE INVENTION

In a first aspect, the present invention relates to a building block according to claim 1.

Because the male coupling element and the female coupling element extend beyond the open top surface, building blocks can simply be stacked on top of each other, i.e. joint on joint without a half-brick bond. The male coupling element and the female coupling element not only form a connection between two adjacent building blocks in the same layer, but also a connection between a building block and a building block above it. As a result, a wall of the trench silo, formed by the building blocks, is sufficiently strong even without a half-brick bond.

An additional advantage is that sealing with sealant is easier because vertical joints between building blocks are aligned over the entire height of the wall and do not stagger with each layer, as is the case with half-brick bond.

Also very advantageous is that the building blocks make it possible to extend a wall of the trench silo in length by placing extra building blocks at one end of the wall. It is not necessary to dismantle a part of the wall again in order to respect the half-brick bond.

Preferred forms of the building block are shown in claims 2 to 14.

In a second aspect, the present invention relates to a method according to claim 15.

This method has the advantage that the wall of the trench silo can be formed very quickly by placing building blocks against each other and joint on joint. Because a building block of an upper layer of building blocks is connected to a building block of an underlying layer of building blocks by incorporating the male coupling and the female coupling of the building block of the underlying layer of building blocks in the side walls of the building block of the upper layer of building blocks, a wall is formed that is sufficiently strong even without a half-brick bond. An additional advantage of the method is that it is not necessary to provide half building blocks in addition to full building blocks, which leads to a simpler logistical process. It is also advantageous that the method easily allows the formed wall to be extended in length if necessary by

4 BE2023/5454 simply add building blocks to one end of the formed wall. It is not necessary to partially dismantle the already formed wall in order to respect a half-brick bond. A particularly advantageous aspect is that the method simplifies the sealing of the formed wall, because vertical joints do not stagger every layer.

A preferred form of the method is described in the sub-claim 16.

In a third aspect, the present invention relates to a use according to claim 17.

This use results in a simple and inexpensive trench silo on an agricultural farm, which can be quickly sealed with a sealing compound and which can be extended without demolition work if the agricultural farm is expanded.

DESCRIPTION OF THE FIGURES

Figure 1A shows a front view of a building block according to a first embodiment of the present invention.

Figure 1B shows a top view of the building block according to the first embodiment of the present invention.

Figure 1C shows a cross section of the building block according to the first embodiment of the present invention.

Figure 1D shows a perspective view of two building blocks stacked on top of each other according to the first embodiment of the present invention.

Figure 2A shows a cross-section of the building block according to a second embodiment of the present invention.

Figure 2B shows a perspective view of the building block according to the second embodiment of the present invention.

Figure 3A shows a cross-section of the building block according to a third embodiment of the present invention.

Figure 4A shows a cross-section of the building block according to a fourth embodiment of the present invention.

Figure 4B shows a perspective view of the building block according to the fourth embodiment of the present invention.

Figure 5A shows a cross section of the building block according to the fifth embodiment of the present invention.

Figure 5B shows a perspective view of the building block according to the fifth embodiment of the present invention.

DETAILED DESCRIPTION

Unless otherwise defined, all terms used in the description of the invention, including technical and scientific terms, have the meaning as commonly understood by one skilled in the technical field of the invention. For a better appreciation of the description of the invention, the following terms are explicitly explained. “A,” “an,” and “the” refer in this document to both the singular and the plural unless the context clearly suggests otherwise. For example, “a segment” means one or more than one segment.

The terms “comprise”, “comprising”, “consisting of”, “comprising”, “providing with”, “comprise”, “containing”, “containing” are synonyms and are inclusive or open terms indicating the presence of what follows, and not excluding or preventing the presence of other components, features, elements, members, steps known or described in the prior art.

Quoting numerical intervals through the endpoints includes all integers, fractions, and/or real numbers between the endpoints, including these endpoints.

In the context of this document, a top load is a load applied to stacked bulk goods that is retained by a trench silo wall.

6 BE2023/5454

In the context of this document, bulk goods are unpackaged materials or products that are stored in large quantities. These may include raw materials such as grain, coal, ore, sand, cement and oil, but also foodstuffs such as sugar, rice, coffee beans and flour.

In the context of this document, agricultural bulk commodities are all bulk commodities that are related to agriculture or the production of crops or livestock. These can be harvested crops, such as corn, beets or silage, but also products needed for the production of crops or livestock, such as animal feed, or by-products of crop or livestock production, such as manure.

In a first aspect, the invention relates to a building block for forming a trench silo.

The building block comprises a hollow beam-shaped body with a front wall, a back wall, a bottom surface, an open top surface and two opposite side walls. The beam-shaped body is preferably a concrete body. More preferably, the beam-shaped body is a one-piece concrete body. Preferably, the concrete body is unreinforced, which is advantageous for a simple and cheap construction of the building block. The bottom surface is an open or a closed bottom surface.

A first side wall is provided with a male coupling means. A second side wall, located opposite the first side wall, includes a female coupling means. The female coupling means has a complementary shape so that the first side wall of a first building block and the second side wall of a second adjacent building block can be connected to each other by engagement of the male coupling means in the female coupling means. Adjacent means that the second building block is placed next to and against the first building block. Viewed in a direction transverse to the side walls, the male coupling means is designed as a protruding part. This means that the male coupling means projects from the first side wall and from the hollow beam-shaped body in a direction transverse to the side walls. Viewed in a direction transverse to the side walls, the female coupling means is designed as a recessed part. This means that the female coupling means is recessed in the second side wall in a direction transverse to the side walls.

7 BE2023/5454

The male coupling agent and the female coupling agent are advantageous for automatically connecting adjacent building blocks of the same layer by placing the adjacent building blocks against each other.

It is clear that the building block on the first side wall can comprise multiple male coupling means and that the second side wall can comprise multiple complementary female coupling means. It is also clear that the first side wall can also comprise one or more female coupling means and the second side wall can comprise one or more complementary male coupling means.

Preferably, the one or more male coupling means and the one or more female coupling means extend over the entire height of the side walls.

The hollow beam-shaped body is advantageous for obtaining a light building block, which makes the transport costs for the building blocks low. The open top surface is advantageous for filling the hollow beam-shaped body with a filler after placement. The filler is preferably draining. Non-limiting examples of suitable fillers are crushed stone and sand. By filling the hollow beam-shaped body with a filler, the building block becomes heavier, which means that a wall formed with the building blocks can carry a greater load.

According to a preferred embodiment, the male coupling means and the female coupling means extend beyond the open top surface, viewed in a direction transverse to the open top surface. As a result, the male coupling means and the female coupling means incorporated in the side walls are suitable for coupling to an overlying building block, the male coupling means and the female coupling means being received in the overlying building block.

This allows building blocks to be simply stacked on top of each other, i.e. joint on joint without a half-brick bond. The male coupling agent and the female coupling agent not only form a connection between two adjacent building blocks in the same layer, but also a connection between a building block and a building block above it. This means that a wall of the trench silo, formed by the building blocks, is sufficiently strong even without a half-brick bond. An additional advantage is that sealing with sealant is easier because vertical joints between building blocks are in line over the entire height of the wall and do not stagger every layer, as is the case with a half-brick bond. Also very

8 BE2023/5454 advantageous is that the building blocks make it possible to extend a wall of the trench silo in length by placing extra building blocks at one end of the wall, provided that the correct orientation of the building blocks is maintained. It is not necessary to dismantle a part of the wall again in order to respect the half-brick bond.

According to a further embodiment, the male coupling means and the female coupling means extend beyond the open top surface over a length of at least 3 cm, preferably at least 4 cm, more preferably at least 5 cm. The length is measured in a direction transverse to the open top surface and from the open top surface.

A length of at least 3 cm over which the male coupling and female coupling extend beyond the open top surface is advantageous for transferring forces between two building blocks placed on top of each other.

According to a preferred embodiment, the male coupling means is at least a distance A from edges of the first side wall with the front wall and the rear wall. Said edges are corners formed by the first side wall with the front wall and by the first side wall with the rear wall. The distance

A is at least 11% of the width of the first side wall. The distance A is preferably equal for the edge of the first side wall with the front wall and the edge of the first side wall with the rear wall. The female coupling means is at least a distance B from edges of the second side wall with the front wall and the rear wall removed.

The said edges are angles formed by the second side wall with the front wall and by the second side wall with the rear wall. The distance B is at least 11% of the width of the second side wall. The distance B is preferably the same for the edge of the second side wall with the front wall and the edge of the second side wall with the rear wall. The distance A and the width of the first side wall are measured in the plane of the first side wall and parallel to the bottom surface. The distance B and the width of the second side wall are measured in the plane of the second side wall and parallel to the bottom surface. It is clear that due to the hollow beam-shaped body, the width of the first side wall and the width of the second side wall can only be minimally different.

The distance B is important to ensure that the hollow beam-shaped body has sufficiently strong corners. In the second side wall the female

9 BE2023/5454 coupling element is designed as a recessed part, which means that there is less material present locally. By placing the female coupling element at a distance B from the aforementioned edges, sufficient material remains in the corners to prevent the beam-shaped body from cracking in the corners when loaded. The distance A must be at least as large, so that the male coupling element can be incorporated into the female coupling element. Preferably, the distance A is at least 0.2 cm larger than the distance B, more preferably at least 0.3 cm.

The distance A is preferably at least 12% of the width of the first side wall, more preferably at least 13%, even more preferably at least 14%, even more preferably at least 15%, and most preferably at least 16%.

The distance B is preferably at least 12% of the width of the second side wall, more preferably at least 13%, even more preferably at least 14%, even more preferably at least 15%, and most preferably at least 16%.

According to a further embodiment, the male coupling means extends over at least 55% of the width of the first side wall. The female coupling means extends over at least 55% of the width of the second side wall. The width of the first side wall and the second side wall are measured as previously described.

Preferably, the male coupling means extends over at least 56% of the width of the first side wall, more preferably at least 57%, even more preferably at least 58%, even more preferably at least 59%, and most preferably at least 60%.

Preferably, the female coupling means extends over at least 56% of the width of the second side wall, more preferably at least 57%, even more preferably at least 58%, even more preferably at least 59%, and most preferably at least 60%.

This embodiment is advantageous to prevent the male coupling element and the female coupling element from tearing off when loaded on a wall of a trench silo, because shear forces are distributed over a sufficiently large surface. In the case of a male coupling element, this applies to the entire protruding part of the first side wall, including the part that extends beyond the open top surface

10 BE2023/5454 extends. In the case of the female coupling element, this is particularly important for the part that extends beyond the open top surface.

According to a preferred embodiment, the front wall, the rear wall, the bottom surface, the open top surface and the two side walls define a single hollow volume. A single hollow volume means that the hollow volume is not divided into compartments, for example by intermediate support surfaces. This is advantageous because it results in a simple and light building block. This is also advantageous when filling the hollow beam-shaped body with filler. Due to the absence of intermediate support surfaces, the hollow beam-shaped body can be completely filled. There are no hidden spaces under or next to an intermediate support surface that may not be filled by the filler.

According to a preferred embodiment, the bottom surface is a closed bottom surface. The closed bottom surface is preferably an integrated part of the hollow beam-shaped body. The closed bottom surface is preferably made of concrete. A closed bottom surface is particularly advantageous for a bottom layer of building blocks of a wall of a trench silo. The closed bottom surface forms a solid surface for supporting the wall. The closed bottom surface is advantageous for preventing a filler from flowing away at the bottom of the wall. The closed bottom surface is advantageous for collecting possible liquids that flow away from the trench silo via the wall.

According to a further embodiment, the building block comprises drainage facilities in the closed bottom surface. The building block preferably comprises at least one drainage pipe in the hollow beam-shaped body. The closed bottom surface preferably comprises at least one opening for connecting a drain pipe to the at least one drainage pipe. The drainage facilities in the closed bottom surface are advantageous for the controlled drainage of liquids that flow out of the trench silo via the wall and for rainwater that ends up on the bottom surface of a lower building block via a top side of the wall and through the filler.

According to an alternative embodiment, the bottom surface is an open bottom surface. The hollow beam-shaped body is thus open on both a bottom and a top side.

An open base is particularly suitable for higher layers of building blocks of a trench silo wall. The open base is particularly advantageous for the

11 BE2023/5454 limiting the weight of the building block. The open base is also advantageous for filling a trench silo wall with filler material after all the building blocks have been placed. This allows for faster work compared to filling each building block separately immediately after placement. An open base is also suitable for a lower layer of building blocks if, for example, the lower layer of building blocks is placed directly on a concrete foundation.

According to a further embodiment, the side walls on the side of the bottom surface comprise recesses for receiving the male coupling means and the female coupling means. The recesses are advantageous for receiving the male coupling means and the female coupling means of an underlying building block. As a result, there is not only a good coupling in a longitudinal direction of a wall of a trench silo formed by the building blocks, but also in a — height direction.

It is clear that such recesses are also possible with a closed base, but less useful since a closed base is mainly advantageous for a lower layer of building blocks.

According to a further embodiment, the recesses have a depth that is at least 0.5 mm, preferably at least 1 mm, more preferably at least 1.5 mm and even more preferably at least 2 mm, greater than a length over which the male coupling means and the female coupling means extend beyond the open top surface. The depth of the recesses is measured in a direction transverse to the bottom surface and from the bottom surface.

A recess depth of at least 0.5 mm greater than the length over which the male and female connectors extend beyond the open top surface is advantageous to ensure that the male and female connectors can be fully received within the recess and that overlying building blocks can be fully seated against underlying building blocks, thus creating a minimal joint.

According to a preferred embodiment, the front wall and the back wall each comprise a heel. The heels lie in an extension of the bottom surface. The bottom surface is an open or a closed bottom surface. The heels extend extends in

12 BE2023/5454 a direction away from the hollow beam-shaped body. The heels are preferably one whole with the hollow beam-shaped body. The heels preferably extend from the first side wall to the second side wall. This embodiment is advantageous for forming a high wall for a trench silo, whereby the heels prevent the high wall from tilting under load. A high wall is understood to mean a wall with a height of at least 2.5 m.

According to a preferred embodiment, the building block comprises drainage facilities through the front wall and/or the rear wall. Preferably, the building block comprises at least one drainage pipe in the hollow beam-shaped body. The front wall and/or the rear wall preferably comprises at least one opening for connecting a drain pipe to the at least one drainage pipe. The drainage facilities through the front wall and/or rear wall are advantageous for the controlled drainage of liquids that flow out of the trench silo via the wall and for rainwater that enters the building block via a top side of the wall and through the filler.

According to a preferred embodiment, the building block has a length-width ratio of at least 1.5 and at most 2.2. The length is measured in the plane of the front wall and parallel to the bottom surface. The width is measured in the plane of the second side wall and parallel to the bottom surface. It is clear to a skilled person trained in the technical field that the length can also be measured in the plane of the back wall and the width in the plane of the first side wall.

In combination with a previously described embodiment in which the front wall and the back wall each comprise a heel, the heels are not included in the width.

The length-width ratio is preferably at least 1.6, more preferably at least 1.7, even more preferably at least 1.8 and even more preferably at least 1.9.

The length-width ratio is preferably at most 2.1.

This ratio is advantageous for avoiding the bending of the building block in a plane parallel to the bottom surface when a trench silo wall is loaded. With a larger length-width ratio, the moment on the front and/or side wall when a trench silo wall is loaded provides for such a large

13 BE2023/5454 deflection that there is a risk of cracking and long-term breakage of the building block. With a smaller length-width ratio, the volume of the hollow beam-shaped body is insufficient to be sufficiently heavy after filling with filling material not to be pushed away when the wall of the trench silo is loaded.

In addition, the building block is not wide enough not to tilt when the wall of the trench silo is loaded. This embodiment is particularly advantageous in combination with a previously described embodiment in which the front wall, the bottom surface, the open top surface and the two side walls define a single hollow volume. In this embodiment, it is not possible to provide intermediate support surfaces to prevent deflection, for example.

According to a preferred embodiment, the building block has a length-height ratio of at least 1.5 and at most 2.5. The length is measured as described above. The height is measured from the bottom surface and transversely to the bottom surface. It is clear to a skilled person trained in the technical field that the height can also be measured from the open top surface and transversely to the open top surface.

The length-height ratio is preferably at least 1.55.

The length-to-height ratio is preferably at most 2.4, more preferably at most 2.35.

This ratio is advantageous for avoiding the deflection of the building block in a plane parallel to the side walls when a trench silo wall is loaded. With a larger length-height ratio, the moment on the front and/or side wall when a trench silo wall is loaded causes such a large deflection that there is a risk of cracking and long-term breakage of the building block. With a smaller length-height ratio, too many building blocks are required to be able to form a trench silo wall economically and quickly. This embodiment is particularly advantageous in combination with a previously described embodiment in which the front wall, the bottom surface, the open top surface and the two side walls define a single hollow volume. With this embodiment, it is not possible to provide intermediate support surfaces, for example, to prevent deflection.

14 BE2023/5454

According to a preferred embodiment, the building block has a maximum length of 2.75 m. The length is measured as previously described.

Preferably, the building block has a maximum length of 2.70 m, more preferably a maximum length of 2.65 m, even more preferably a maximum length of 2.60 m and even more preferably a maximum length of 2.55 m.

This embodiment is advantageous for avoiding bending of the building block in a plane parallel to the bottom surface, which could cause the building block to break when loaded by a wall of a trench silo. This embodiment is particularly advantageous in combination with a previously described embodiment in which the front wall, the bottom surface, the open top surface and the two side walls define a single hollow volume. In this embodiment it is not possible to provide intermediate support surfaces to prevent bending, for example. An additional advantage is that the weight of the building block is limited, which minimizes transport costs.

Preferably, the building block has a minimum length of 2.0 m, more preferably a minimum length of 2.1 m, even more preferably a minimum length of 2.2 m, and even more preferably a minimum length of 2.3 m. This is advantageous for reducing the number of building blocks required to form a trench silo wall. This allows a trench silo to be formed quickly and cheaply.

According to one embodiment, the side walls, the front wall and the rear wall of the hollow beam-shaped body have a minimum wall thickness of 8 cm, preferably 9 cm. The second side wall also has a minimum wall thickness of 8 cm at the recessed part of the female coupling means. The minimum wall thickness of 8 cm ensures a sufficiently strong building block.

According to one embodiment, the closed base has a minimum wall thickness of at least 7 cm, preferably at least 8 cm, more preferably at least 9 cm and even more preferably at least 10 cm. This is advantageous for a sturdy base that can absorb the load from a filler and forces from bulk goods in a trench silo.

15 BE2023/5454

According to an embodiment, the protruding portion of the male coupling means has a minimum thickness of 3 cm, preferably a minimum thickness of 4 cm. The thickness is measured from an outside of the first side wall and transversely to the first side wall. The recessed portion of the female coupling means has a depth that is at least 0.5 cm greater than the thickness of the male coupling means, preferably at least 1 cm. The depth is measured from an outside of the second side wall and transversely to the second side wall.

A minimum thickness of 3 cm of the protruding part of the male coupling is advantageous for transferring forces between two adjacent building blocks. A minimum depth of the recessed part of the female coupling that is at least 0.5 cm more than the thickness of the protruding part of the male coupling is advantageous to ensure that the male coupling can be fully received in the female coupling and that adjacent building blocks can be placed completely against each other, creating a minimal joint.

According to a preferred embodiment, the building block in the hollow beam-shaped body comprises hoisting points on the front wall and the rear wall for hoisting the building surface. Preferably, the building block comprises two hoisting points on the front wall and two hoisting points on the rear wall. Preferably, the hoisting points on the front wall and the rear wall are mirror-symmetrical. This is advantageous for an optimal distribution of the weight of the building block over the hoisting points during hoisting.

According to an embodiment, the building block comprises a U-shaped recess in the first side wall and the second side wall from the open top surface. The U-shaped recess is advantageous for forming a walkway on a top side of a wall of a trench silo.

In a second aspect, the invention relates to a method for forming a wall of a trench silo.

The method comprises the steps of: - placing a first layer of building blocks against each other, with side walls of each two adjacent building blocks being connected by means of a male coupling means in a first side wall of a first building block and a complementary female coupling means in a second side wall of a

16 BE2023/5454 second adjacent building block by placing the first building block and the second building block against each other, - placing at least one layer of building blocks on the first layer of building blocks, - at least partially filling the layers of building blocks with a filler.

The first layer of building blocks is placed on a base surface. The first layer of building blocks is preferably placed on a foundation, preferably a concrete foundation.

The filler is preferably draining. Non-limiting examples of suitable fillers are crushed stone and sand.

According to a preferred embodiment, the layers of building blocks are placed on top of each other joint on joint. This means that vertical joints continue over the different layers of building blocks and do not stagger, as in a half-brick bond. A building block of an overlying layer of building blocks is connected to a building block of a lower layer of building blocks by incorporating the male coupling means and the female coupling means of the building block of the lower layer of building blocks in the side walls of the building block of the upper layer of building blocks. This means that the male coupling means and the female coupling means of the building block of the lower layer of building blocks extend beyond a top surface of the said building block. It is clear that each building block of a lower layer of building blocks is connected to an overlying building block of the upper layer of building blocks and that these building blocks touch each other.

In a preferred embodiment, the first layer of building blocks is anchored in a concrete slab. The concrete slab is cast around a bottom side of the first layer of building blocks. This is advantageous to prevent a wall of a trench silo from shifting sideways when the wall is loaded by bulk goods. The concrete slab is also advantageous to prevent liquids from the trench silo from penetrating into the ground. Optionally, the building blocks of the first layer of building blocks comprise feet, whereby the feet are positioned under the concrete slab.

This is beneficial for preventing the trench silo wall from tilting when loads are applied to the wall.

17 BE2023/5454

A person skilled in the art will appreciate that a method according to the second aspect is preferably carried out with a building block according to the first aspect and that a building block according to the first aspect is preferably configured to carry out a method according to the second aspect. Each feature described in this document, both above and below, can therefore relate to any of the three aspects of the present invention.

In a third aspect, the invention relates to a use of a building block according to the first aspect and/or a method according to the second aspect for forming a trench silo for storing agricultural bulk goods.

This use results in a simple and inexpensive trench silo on an agricultural farm, which can be quickly sealed with a sealing compound and which can be extended without demolition work if the agricultural farm is expanded.

In the following, the invention is described by means of non-limiting figures which illustrate the invention, and which are not intended or should be interpreted as limiting the scope of the invention.

18 BE2023/5454

FIGURE DESCRIPTION

Figure 1A shows a front view of a building block according to a first embodiment of the present invention.

The building block (1) comprises a hollow beam-shaped body (2). The hollow beam-shaped body (2) has a front wall (3), a back wall (4), a first side wall (5), a second side wall (6), a bottom surface (7) and an open top surface (8). The back wall (4) is on

Figure 1A not visible. The bottom surface (7) is an open bottom surface (7) in the first embodiment. The hollow beam-shaped body (2) is a concrete body. The first side wall (5) is provided with a male coupling means (9). The male coupling means (9) is designed as a protruding part when viewed in a direction transverse to the first side wall (5). The second side wall (6) is provided with a female coupling means (10). The female coupling means (10) has a complementary shape to the male coupling means (9), so that the first side wall (5) of a first building block (1) and the second side wall (6) of a second building block (1) can be connected to each other by engagement of the male coupling means (9) in the female coupling means (10). The female coupling means (10) is designed as a sunken part when viewed in a direction transverse to the second side wall (6). Viewed in a direction transverse to the open top surface (8), the male coupling means (9) and the female coupling means (10) extend beyond the open top surface (8). The part of the male coupling means (9) that extends beyond the open top surface (8) is designated with reference number (11). The part of the female coupling means (10) that extends beyond the open top surface (8) is designated with reference number (12). The parts (11, 12) have a length of 5 cm, measured from the open top surface (8) in a direction transverse to the open top surface (8). The front wall (3), the back wall (4), the first side wall (5), the second side wall (6), the bottom surface (7) and the open top surface (8) define a single hollow volume (13). The single hollow volume (13) is a volume that is open at both the top and the bottom due to the open bottom surface (7) and the open top surface (8). In the single hollow volume (13) there are no compartments or intermediate support surfaces. The first side wall (5) and the second side wall (6) comprise recesses (14) on the side of the bottom surface (7) for receiving the male coupling means (9) and the female coupling means (10) of an underlying building block (1). It is the parts (11) and (12) of the male coupling means (9) and the female coupling means (10) respectively that are received in the recesses (14). The building block (1) comprises in the hollow beam-shaped body (2)

19 BE2023/5454 lifting points (15). The lifting points (15) are included on an inside of the front wall (3) and the rear wall (4). The building block (1) according to the first embodiment has a length (16) of 250 cm and a width (17) of 120 cm. The width (17) is not indicated in Figure 1A. This means that the length-width ratio is rounded off to 2.1. The building block (1) according to the first embodiment has a height (18) of 107.5 cm. This means that the length-height ratio is rounded off to 2.3.

The front wall (3), the back wall (4), the first side wall (5) and the second side wall (6) have a wall thickness of 9 cm.

Figure 1B shows a top view of the building block according to the first embodiment of the present invention.

Clearly visible are the two lifting points (15) on the inside of the front wall (3) and the two lifting points (15) on the inside of the rear wall (4). Also clearly visible is how the female coupling element (10) is designed as a recessed part in the second side wall (6). The recessed part of the female coupling element (10) has a depth of 5 cm. The depth is measured from an outside of the second side wall (6) and transversely to the second side wall (6). The protruding part of the male coupling element (9) has a thickness of 4 cm. The thickness is measured from an outside of the first side wall (5) and transversely to the first side wall (5). The male coupling element (9) is at a distance A (A) equal to 20.4 cm from the edges of the first side wall (5) with the front wall (3) and the rear wall (4). This is 17% of the width (17) of 120 cm of the first side wall (5). The female coupling (10) is at a distance B (B) equal to 20 cm from the edges of the second side wall (6) with the front wall (3) and the back wall (4) removed. This is 16.7% of the width (17) of 120 cm of the second side wall (6). The male coupling (9) extends over 79.2 cm. This is 66% of the width (17) of 120 cm of the first side wall (5). The female coupling (10) extends over 80 cm. This is 66.7% of the width (17) of the second side wall (6).

Figure 1C shows a cross section of the building block according to the first embodiment of the present invention.

This clearly shows the recess (14) for receiving the part (11, 12) of the male coupling (9) or the female coupling (10). The

20 BE2023/5454 recess (14) has a depth of 6 mm, measured from the bottom surface (7) and in a direction transverse to the bottom surface (7).

Figure 1D shows a perspective view of two building blocks stacked on top of each other according to the first embodiment of the present invention.

The building blocks (1) are stacked joint on joint. This forms a trench silo wall with a length of 250 cm and a height of 215 cm. The wall can easily be extended by placing additional building blocks (1) in line with the already formed wall against the already placed building blocks (1), whereby the male couplings (9) engage in the female couplings (10). The wall can easily be raised by placing additional building blocks (1) joint on joint on underlying building blocks (1), whereby the parts (11, 12) of the male couplings (9) and the female couplings (10) are accommodated in the recesses (14) of the overlying building blocks (1).

Figure 2A shows a cross-section of the building block according to a second embodiment of the present invention.

In the second embodiment, the building block (1) has a closed bottom surface (2).

The closed bottom surface (2) has a thickness of 10 mm. The front wall (3) and the back wall (4) each comprise a heel (19), which lie in the extension of the bottom surface (7). The heels (19) extend 27 mm from the front wall (3) and the back wall (4) transversely to the front wall (3) and the back wall (4). The building block (1) according to the second embodiment has the same length (16) and the same width (17) as a building block according to the first embodiment, but a height (18) of 157.5 cm. The length-height ratio is rounded to 1.59. Because a building block (1) according to the second embodiment is intended for a lower layer of building blocks (1), recesses (14) are missing.

Figure 2B shows a perspective view of the building block according to the second embodiment of the present invention.

It is clearly visible how the heels (19) of the first side wall (5) extend to the second side wall (6).

21 BE2023/5454

Figure 3A shows a cross-section of the building block according to a third embodiment of the present invention.

The building block (1) according to the third embodiment is very similar to a building block (1) according to the first embodiment, with the difference that the height (18) is 157.5 cm and that the bottom surface (7) is closed. The closed bottom surface (7) again has a thickness of 10 mm. This building block (1) is also intended for a bottom layer of building blocks (1), so that there are again no recesses (14).

Figure 4A shows a cross-section of the building block according to a fourth embodiment of the present invention.

The building block (1) according to the fourth embodiment is very similar to a building block (1) according to the second embodiment, with the difference that the height (18) is 107.5 cm and that the bottom surface (7) is open. Although this building block (1) is intended for a bottom layer of building blocks (1), recesses (14) are provided.

This simplifies production of the building blocks (1), because the same mould can be used to produce the building blocks (1), whereby by placing an additional element both the open bottom surface (7) and the recesses (14) are obtained. The recesses (14) have no adverse effect in the fourth embodiment.

Figure 4B shows a perspective view of the building block according to the fourth embodiment of the present invention.

The presence of the recesses (14) is clearly visible.

Figure 5A shows a cross section of the building block according to the fifth embodiment of the present invention.

The building block (1) according to the fifth embodiment is very similar to a building block (1) according to the first embodiment, with the difference that the height (18) is 157.5 cm and that the first side wall (5) and the second side wall (6) have a U-shaped recess (20) for forming a walkway on a top side of a wall of a trench silo. The parts (11, 12) are now minimal, but this is not disadvantageous because this building block (1) belongs to an upper layer of building blocks (1).

22 BE2023/5454

Figure 5B shows a perspective view of the building block according to the fifth embodiment of the present invention.

Clearly visible are the recesses (20) in the first side wall (5) and the second side wall (6) for forming a walking path.

The reference numbers in the figures refer to: 1. Building block 2. Beam-shaped body 3. Front wall 4. Back wall 5. First side wall 6. Second side wall 7. Bottom surface 8. Open top surface 9. Male coupling element 10. Female coupling element 11. Section male coupling element above top surface 12. Section female coupling element above top surface 13. Single hollow volume 14. Recess 15. Lifting point 16. Length 17. Width 18. Height 19. Heels 20. Recess for forming walkway

A. Distance A

B. DistanceB

Claims (17)

23 BE2023/5454 CONCLUSIONS 1. Building block (1) for forming a trench silo, comprising a hollow beam-shaped body (2) with a front wall (3), a rear wall (4), a bottom surface (7), an open top surface (8) and two side walls (5, 6) located opposite each other, wherein a first side wall (5) is provided with a male coupling means (9) and the second side wall (6) located opposite it is provided with a female coupling means (10) with a complementary shape so that the first side wall (5) of a first building block (1) and the second side wall (6) of a second adjacent building block (1) can be connected to each other by engagement of the male coupling means (9) in the female coupling means (10), wherein, viewed in a direction transverse to the side walls (5, 6), the male coupling means (9) is designed as a protruding part and the female coupling means (10) as a recessed part, characterised in that, viewed in a direction transverse to the open top surface (8), the male coupling means (9) and the female coupling means (10) extend beyond the open top surface (8). 2. Building block (1) according to claim 1, characterised in that the male coupling means (9) is spaced at least a distance A (A) from edges of the first side wall (5) with the front wall (3) and the rear wall (4) and the female coupling means (10) is spaced at least a distance B (B) from edges of the second side wall (6) with the front wall (3) and the rear wall (4), the distances A (A) and B (B) being at least 11% of the width of the first side wall (5) and the second side wall (6), respectively, the distances A (A) and B (B) and the width of the respective side wall (5, 6) being measured in the plane of the respective side wall (5, 6) and parallel to the bottom surface (7). 3. Building block (1) according to claim 2, characterised in that the male coupling means (9) extends over at least 55% of the width of the first side wall (5) and the female coupling means (10) extends over at least 55% of the width of the second side wall (6), the width of the respective side wall (5, 6) being measured in the plane of the respective side wall (5, 6) and parallel to the bottom surface (7). 24 BE2023/5454 4. Building block (1) according to any one of the preceding claims 1-3, characterised in that the building block (1) comprises drainage facilities through the front wall (3) and/or the rear wall (4). 5. Building block (1) according to any one of the preceding claims 1 to 4, characterised in that the building block (1) has a length-width ratio of at least 1.5 and at most 2.2, the length (16) being measured in the plane of the front wall (3) and parallel to the bottom surface (7) and the width (18) being measured in the plane of the second side wall (6) and parallel to the bottom surface (7). 6. Building block (1) according to any one of the preceding claims 1 to 5, characterised in that the building block (1) has a length-height ratio of at least 1.5 and at most 2.5, the length (16) being measured in the plane of the front wall (3) and parallel to the bottom surface (7) and the height (19) being measured from the bottom surface (7) and transversely to the bottom surface (7). 7. Building block (1) according to any one of the preceding claims 1-6, characterised in that the building block (1) has a maximum length of 2.75 m, the length (16) being measured in the plane of the front wall (3) and parallel to the bottom surface (7). 8. Building block (1) according to any one of the preceding claims 1 to 7, characterised in that the front wall (3), the rear wall (4), the bottom surface (7), the open top surface (8) and the two side walls (5, 6) define a single hollow volume (13). 9. Building block (1) according to any one of the preceding claims 1-8, characterised in that the bottom surface (7) is a closed bottom surface (7). 10. Building block (1) according to claim 9, characterised in that the building block (1) comprises drainage facilities in the closed lower surface (7). 11. Building block (1) according to any one of the preceding claims 1-8, characterised in that the bottom surface (7) is an open bottom surface (7). 12. Building block (1) according to claim 11, characterised in that the side walls (5, 6) on the side of the bottom surface (7) have recesses for receiving 25 BE2023/5454 include the male coupling means (9) and the female coupling means (10). 13. Building block (1) according to any one of the preceding claims 1-12, characterised in that the front wall (3) and the rear wall (4) each comprise a heel (19), the heels (19) being in an extension of the bottom surface (7). 14. Building block (1) according to any one of the preceding claims 1-13, characterised in that the building block (1) comprises lifting points (15) in the hollow beam-shaped body (2) on the front wall (3) and the rear wall (4) for lifting the building block (1). 15. Method for forming a wall of a trench silo comprising the steps of: - placing a first layer of building blocks (1) against each other, wherein side walls (5, 6) of each two adjacent building blocks (1) are connected to each other by means of a male coupling means (9) included in a first side wall (5) of a first building block (1) and a complementary female coupling means (10) included in a second side wall (6) of a second adjacent building block (1) by placing the first building block (1) and the second building block (1) against each other; - placing at least one layer of building blocks (1) on the first layer of building blocks (1); - at least partially filling the layers of building blocks (1) with a filler; characterised in that the layers of building blocks 1) are placed on top of each other joint on joint, whereby a building block (1) of an overlying layer of building blocks is connected to a building block (1) of an underlying layer of building blocks (1) by incorporating the male coupling means (9) and the female coupling means (10) of the building block (1) of the underlying layer of building blocks (1) in the side walls (5, 6) of the building block (1) of the overlying layer of building blocks (1). 16. Method according to claim 15, characterised in that the first layer of building blocks (1) are anchored in a concrete slab. 26 BE2023/5454 17. Use of a building block (1) according to any of claims 1-14 or the method according to any of claims 15-16 for forming a trench silo for storing agricultural bulk goods.