NL1037887C2 - FOUNDATION ELEMENT FOR FOUNDING A BUILDING WORK, SUCH AS A HOUSE, METHOD FOR FORMING A FOUNDATION ELEMENT, AND METHOD FOR FOUNDING A BUILDING WORK. - Google Patents

Description

I.

Foundation element for foundation of a building, such as a house, method for forming a foundation element, and method for foundation of a building The present invention relates to a foundation element for the foundation of a building, such as a home.

A foundation serves to support a building. Foundations are made up of a number of foundation 10 elements. For example, a foundation can be formed by a plurality of foundation elements in the form of foundation piles that are driven into the ground on which the structure is to be placed. The structure is then mounted on the foundation piles, so that they support the structure and guide the weight of the structure to the ground.

Box-shaped foundation elements are also known, such as concrete basement boxes. These basement bins consist of a barge with concrete walls that is placed in the ground on which the structure is to be placed. The structure 20 is then mounted on the basement tray, so that the basement tray carries the structure and guides the weight of the structure to the ground. The concrete side walls of the basement must be designed in such a way that they can support the structure. The advantage of a basement bin as a foundation element is that the interior space of the bin that is enclosed by the concrete walls can serve as a basement. In particular in areas where the groundwater level is relatively high, it is moreover important that concrete walls connect with each other and are so thick that the penetration of water into the basement trough through the walls or along the connections between the walls is avoided.

Foundation elements in the form of concrete trays are also used for the floating foundation of a 1037887 2 structure in water. In such an application, a concrete tank is designed such that it floats on the water. In addition, the concrete walls must also connect to each other and be so thick that the penetration of water into the basement trough through the walls or along the connections between the walls is prevented. In addition, the concrete container must have sufficient buoyancy. The buoyancy of such a concrete container can be increased, for example, by arranging floating bodies on the outside of the concrete container. The inner space formed by such a concrete container can also be used, for example, as a cellar or as a living space.

Because of the weight and dimensions of a finished concrete container that serves as a foundation element and moreover as, for example, a cellar or living space, such concrete containers are generally manufactured at the building site where the structure is to be placed. This method of manufacturing the concrete trays at the building site takes a considerable amount of time, and moreover the conditions are generally not ideal for the various manufacturing steps, such as the concrete hardening step.

It is also possible to manufacture the concrete trough into parts in a factory, to transport the parts to the building site where the structure is to be placed and to assemble parts at this building site into a concrete trough. The weight of the parts thereby makes transport of the parts from the manufacturing site to the building site 30 difficult. Moreover, it appears that it is not easy to reliably assemble the various parts into one concrete container. In particular when using the 3 known concrete containers for floating foundations of a structure in water, this can lead to undesirable leaks.

The foundation element according to the invention comprises a tray formed by a number of walls of a plastic material, which walls enclose an inner space that is open upwards in use, and a supporting structure placed in the tray for supporting the structure. Thanks to the supporting structure placed in the trough, it is possible that a number of the walls forming the trough do not have to be able to support the structure, as is the case with the walls of the known concrete troughs that serve as foundation element. The non-bearing walls only have a function as a barrier against penetrating into the inner space enclosed by the walls undesired elements, such as the medium in which the foundation element is placed, such as soil and water. Because these walls do not have to be able to support the structure, these walls of the tray of the foundation element can be designed simply, so that these costs can be manufactured conveniently and easily from plastic material. The use of plastic material for the walls of the trough also makes it possible, compared to the use of concrete for the walls of the known concrete troughs, that better barrier properties of the walls can be realized in combination with a better resistance of the walls against damage to the walls as a result of the environment to which the walls are exposed and a lighter weight. This makes it possible to realize a barrier with the walls of plastic material that functions better and is better adapted to the specific application than is possible with concrete walls. Moreover, walls made of plastic material that are already manufactured are easier to connect to each other than walls made of concrete, for example by means of plastic welding, wherein the connection moreover forms a weak link in the barrier that the walls form to a lesser extent. In combination with the lighter weight of the walls of plastic material 5, it is hereby easier compared to the use of concrete walls to manufacture the walls at a manufacturing site, to transport them to a building site and to connect them to a container at the building site. Because the walls of the container according to the invention form the barrier against penetrating undesirable elements into the inner space enclosed by the walls, the bearing construction does not have to fulfill this function. As a result, the support structure can be specifically designed to support the specific structure for which it will be used without having to take into account the barrier properties of the support structure. The latter is not possible with the known concrete trays, wherein the concrete walls form both the above-described barrier and the supporting structure. This increases the freedom with regard to the design of the support structure. Moreover, the supporting structure as it is used in the invention is protected against damage to the environment in which the foundation element according to the invention is placed, so that such damage is not taken into account in the design of the supporting structure. This results in a further increase of the freedom with regard to the design of the support structure. The increased freedom of design makes it possible, for example, to shape the support structure in such a way that it can easily be manufactured at a manufacturing site, transported to a building site and assembled at the building site. Together with the walls of plastic material that can easily be manufactured at a manufacturing location, transported to a construction site and can be mutually connected at the construction site to form a container, it is thus possible for the foundation element according to the invention to be compared with the known 5 concrete containers as a foundation element are easier to manufacture at a manufacturing location, to transport to a construction site and to assemble at the construction site, and moreover it is better to match the specific structure and the specific medium in which the structure must be founded .

In a favorable embodiment of the foundation element according to the invention, the plastic material is fiber reinforced. The measure makes it possible for the walls of plastic material that form the tray to be made stronger.

In a further favorable embodiment of the foundation element according to the invention, the plastic material is High-density polyethylene (HDPE). This measure makes it possible for the walls forming the container to offer a good resistance to deterioration under the influence of the environment to which the walls are exposed when they are placed in a medium such as water and soil, and moreover can be manufactured cost-effectively. This has the advantage that the foundation element is very suitable for the foundation of a structure in a medium such as water and soil.

In a further favorable embodiment of the foundation element according to the invention, the walls are designed to be fluid-resistant, preferably substantially fluid-tight, at least in the direction from the outside thereof to the inside thereof. This measure makes it possible for the walls to form a good barrier against penetrating a fluid such as, for example, water or air from the outside into the inner space enclosed by the walls. This has the advantage that the foundation element is very suitable for the foundation of a structure in a medium such as water and soil with, for example, a high groundwater pipe. In order to form a barrier against water penetrating into the inner space through the walls of the trough, the walls are preferably designed to be substantially watertight.

In a further favorable embodiment of the foundation element according to the invention, the trough comprises a bottom wall, and at least one side wall extending from the bottom wall, so that the bottom wall and the at least one side wall enclose the inner space open upwards in use. These measures make it possible for the inner space that is enclosed by the walls to be particularly suitable for serving as, for example, basement space or living space. Moreover, these measures make it possible to form the container formed by walls of plastic material from flat plates of the plastic material. This has the advantage that the container formed by walls of plastic material can be manufactured and transported particularly cost-effectively. In this embodiment, the forces due to the weight of the builder can advantageously be distributed over the surface of the bottom wall via the support structure.

In a favorable embodiment of the foundation element according to the invention, a number of stiffening ribs extend, which stiffening ribs extend from at least one of the walls. This measure makes it possible to stiffen the walls of the container. In combination with the use of a flat plate as a wall, this measure can be realized particularly advantageously by means of an extrusion process in which the flat plate and the 7 reinforcing ribs are formed as a whole from a plastic material.

In a favorable embodiment of the foundation element according to the invention, the foundation element 5 comprises adjusting means for putting the foundation element into use relative to the medium in which the foundation element is arranged for use. The measure makes it possible to influence the position of the foundation element relative to the medium in which the foundation element is arranged and thus the position of the part of the structure arranged on the foundation element relative to that medium. This measure is particularly advantageous in the use of the foundation element according to the invention for floating foundation of a structure in water.

In an advantageous embodiment thereof, the adjusting means comprise at least one adjusting walls enclosed by adjusting walls, in use open to the outside of the container. This measure makes it possible, for example, by introducing an adjusting fluid with a density that is smaller than the density of the medium in which the foundation element is arranged into the adjusting space, to realize an upward force which brings the foundation element into a upward direction. When the foundation element is used for floating foundation of a structure in water, for example, air can be used as the control fluid. In use, the opening of the adjusting space directed downwards must be located below the water level. In a favorable embodiment of the foundation element according to the invention, wherein the tray comprises a bottom wall, and at least one side wall extending from the bottom wall, the operating space open underneath is formed by the bottom wall and a number of bottom wall to in use under extending adjusting walls. This measure makes a simple and effective realization of the adjustment space possible.

In a favorable embodiment of the foundation element according to the invention with at least one adjusting wall enclosed by adjusting walls, in use open underneath adjusting chamber on the outside of the container, the foundation element comprises means for introducing an adjusting fluid into the adjusting chamber, preferably an adjusting fluid with a density that is smaller than the density of the medium in which the foundation element is installed in use, more preferably an adjusting fluid with a density that is smaller than water, more preferably air. This measure makes it possible to introduce the adjusting fluid into the adjusting space in a simple manner and thus to adjust the foundation element.

In an additional or alternative embodiment of the foundation element according to the invention which is provided with adjusting means, the adjusting means comprise ballast elements which are preferably arranged in the tray near the bottom thereof. This measure makes it possible to increase the weight of the foundation element. When the foundation element according to the invention is used for floating foundation of a structure in water, ballast elements make it possible to adjust how deep the foundation element lies in the water. Moreover, it is possible with ballast elements to stabilize the foundation element. In combination with the application of the measure of the opening spaces which are open at the bottom, in particular when the foundation element according to the invention is used for floating foundation of a structure in water, a particularly stable and accurate adjustment of the position and the position of the movement behavior of the foundation element in the water possible. The ballast elements are, for example, 9 metal or concrete (rod-shaped) elements, stones, gravel, etc.

In a further favorable embodiment of the foundation element according to the invention, the bearing construction extends from the inner space upwards in use. This measure makes it possible for the walls of plastic material to extend as far as these walls can come into contact with the medium in which the foundation element is placed. It is advantageous to provide additional walls of another (plastic) material around the part of the support structure extending above the walls of plastic material, which walls then preferably extend in the plane of the walls of plastic material. Thus, with a foundation element 15 according to the invention, an inner space enclosed by walls can be realized which is partially enclosed by the walls of plastic material and partly by the additional walls of another (plastic) material.

In a further favorable embodiment of the foundation element according to the invention, the bearing construction comprises a skeleton of mutually connected elements, preferably a skeleton of at least one from the group of steel elements, aluminum elements, wooden elements and plastic elements. Such a skeleton as a supporting structure can easily be adapted to the specific structure to be supported and can easily be assembled at the construction site with the aid of elements that are easy to transport. Moreover, it is possible that the foundation element with such a skeleton as a supporting structure in combination with the container with walls of plastic material is lighter than the known concrete containers as a foundation element. Particularly when a foundation element according to the invention is used for floating foundation of a structure in water, this has the advantage that additional floating means are not necessary to give the foundation element sufficient buoyancy.

In a further favorable embodiment of the foundation element according to the invention, a number of floor elements are arranged on the bearing construction, which floor elements are preferably provided with a concrete cover layer. This measure makes it possible to install a floor in an inner space of the foundation element 10 according to the invention, or to install several floors as storeys.

The present invention also relates to a structure, preferably a house, which is founded on a foundation in a medium, preferably water, the foundation comprising a number of foundation elements according to the invention as described above.

The present invention also relates to a method for forming a foundation element for the foundation of a structure, such as a dwelling, according to the invention as described above, comprising the steps of: - providing a tray formed by a number of walls of a plastic material, which walls enclose an inner space that is open upwards in use, and - placing a supporting structure for supporting the structure in the tray.

The present invention also relates to a method for foundation of a building, such as a dwelling, comprising the steps of - providing at least one foundation element; and - applying the structure to the at least one foundation element; 11, wherein the step of providing the foundation element comprises the steps of: - providing a tray formed by a number of walls of a plastic material, which walls enclose an inner space open upwards in use; - placing a supporting structure in the bin for supporting the structure; and - arranging the tray in a medium in which the structure must be founded; And wherein - the structure is attached to the supporting structure.

In a favorable embodiment thereof, the trough is provided at the construction site where the structure is to be founded and the supporting structure is placed in this trough at this construction site. This embodiment has the advantage that the container and the supporting structure can be transported separately from each other to the construction site.

In a further favorable embodiment of the method for the foundation of a structure according to the invention, the walls of the trough are at least in the direction from the outside thereof to the inside thereof fluid-resistant, preferably substantially fluid-tight, and the medium is designed water. This embodiment allows the floating foundation of a structure in water. In a favorable embodiment thereof, the method comprises adjusting the foundation element relative to the water surface.

In a favorable embodiment of the method 30 for the foundation of a structure according to the invention in which the step of adjusting the foundation element with respect to the water surface is applied, this step comprises the provision of ballast in the container near the bottom 12 thereof. In an alternative or additional embodiment, on the outside of the container below the water surface, at least one wall-enclosed, bottom-opening adjustment space is provided and the step of adjusting the foundation element comprises at least one of the introduction into the adjustment space and withdrawing from the adjusting space a fluid with a density that is smaller than the density of water, preferably air.

In a further favorable embodiment of the method for the foundation of a structure according to the invention, it comprises the steps of: - providing a plurality of foundation elements; - interconnecting the plurality of foundation elements; and - applying the structure to the plurality of mutually coupled foundation elements.

This embodiment makes it possible to use a plurality of foundation elements for the foundation of the structure.

The present invention will be explained in more detail below with reference to exemplary embodiments, which are shown in the accompanying drawing. These are non-limitative exemplary embodiments. In the views, the same or comparable parts, components and elements are indicated with the same reference numbers. In the drawing: Fig. 1 shows a perspective view of a structure that is floatingly founded in water with the aid of two foundation elements according to the invention; Fig. 2 is a perspective view of one of the foundation elements of Fig. 1; Fig. 3 is a cross-sectional view of the foundation element of Fig. 2; Fig. 4 is a longitudinal sectional view of the foundation element of Fig. 2 / Fig. 5 is a partially cut-away side view of the two foundation elements of Fig. 1; and Fig. 6 shows a cross-sectional view of an alternative embodiment of the foundation elements of Fig. 1.

Figure 1 shows a structure designed as dwelling 1 that is floatingly supported in the water 2 with the aid of two foundation elements 3 and 4. The floating dwelling can be reached from the mainland 5 via the bridge 6.

The foundation element 3 is shown in Figure 2. The foundation element 3 is shown with a tray 7 formed by a number of side walls 8a, 8b, 8c and 8d of a plastic material extending from a bottom wall 8e of plastic material, so that the bottom wall 8e and the side walls 8a, 8b, 8c and 8d enclose an inner space 9 open upwards in use. A supporting structure 10 is placed in the trough 7 for supporting the house 1.

In figure 3 the foundation element 3 of figure 2 is shown in cross-section. Shown is bin 7 with bottom wall 8e and side walls 8b and 8d that extend from a bottom wall 8e. The bottom wall 8e and the side walls 8b and 8d enclose the upwardly open interior space 9. The walls 8b, 8d and 8e are of plastic material, in particular

High-density polyethylene (HDPE). Stiffening ribs 11 extend from the bottom wall 8e and the side walls 8d and 8e. The stiffening ribs are made up of a first part 11a extending perpendicularly thereto from the relevant wall and a second part 11b extending perpendicularly to the first part 11a. The stiffening ribs 11 further extend perpendicular to the plane of the drawing along the length of the respective wall.

/ «* 14

The supporting structure 10 is placed in the container 7.

The supporting structure 10 is shown with a skeleton of interconnected elements 12 in the form of steel profile beams 12a, 12b and 12c. The profile beam 12a lies on the stiffening ribs 11 extending from the bottom wall 8e. The profile beams 12b and 12c are connected to the profile beam 12a and extend from the profile beam 12a along the side walls 8b and 8d in the direction of arrow A. A structure can be arranged at the upwardly directed ends 13 of the profile beams 12b and 12c, so that not the side walls 8b and 8d but the profile beams 12b and 12c support the structure. The forces exerted by the structure on the ends 13 are transmitted through and supported by the support structure 10 to the surface of the bottom wall 8e, which, as a result of the stiffening ribs 11 attached thereto, is particularly rigid in the direction of the support structure 10 provided by the support structure. 10 forces exerted on the bottom wall 8e. Instead of steel elements, the skeleton can also be constructed from aluminum elements, wooden elements, plastic elements, or a combination thereof.

A number of floor elements 14, for example floor plates, are arranged on the profile beam 12a, which floor elements 14 are finished with a cover layer 15, for example a cover layer of concrete. The inner space 9 is further finished by means of inner walls 16. It is possible to provide insulating means, such as glass wool, in the intermediate space 17 between the side walls 8b, 8d and the inner walls 16. It is possible to arrange ballast elements in the ballast spaces 18 between the stiffening ribs 11 extending from the bottom wall 8e, such as metal or concrete (rod-shaped) elements, bricks, gravel, etc. It is furthermore possible to open up spaces 19 below, which are formed by bringing the bottom wall 8e and a number of adjusting walls 20, extending from the bottom wall 8e, under use, to an adjusting fluid such as air. The adjusting walls 20 are composed of a first part 20a extending perpendicularly thereto from the bottom wall 8e and a second part 20b extending perpendicularly to the first part 20a. The use of ballast elements and an adjusting fluid as adjusting means for putting the foundation element into use relative to the water level is further described in relation to figure 5.

Figure 4 shows the foundation element 3 of Figure 2 in longitudinal section. Shown is bin 7 with bottom wall 8e and side walls 8a and 8c extending from a bottom wall 8e. The bottom wall 8e and the side walls 8b and 8d enclose the upwardly open interior space 9. Stiffening ribs 11 extend from the side walls 8a and 8c. It has been shown that the stiffening rib 11 extending from the bottom wall 8e also extends along the length L of the bottom wall 8e. The supporting structure 10 is placed in the bin 7. The steel profile beams 12a and 12c of the supporting structure 10 are shown. The profile beams 12a and 12c are interconnected by means of profile beams 12e and 12f and by means of struts 21. The downwardly opening adjustment space 19 is formed by the bottom wall 8e and a number of adjusting walls 20 extending from the bottom wall 8e to use in use The adjusting walls 20 are made up of a first part 20a extending perpendicularly therefrom from the bottom wall 8e and a second part 20b extending perpendicularly to the first part 20a.

In figure 5 the foundation elements 3 and 4 of figure 1 are shown in partly cut-away front view.

The foundation elements 3 and 4 are interconnected by means of a platform construction 21. For the sake of simplicity of the figure, the house 1 of figure 1 is not shown. It has been shown that both foundation elements 3 and 4 float in water 2. Because the bottom wall 8e and the side walls 8b and 8d are fluid-resistant, in particular substantially watertight, the water 2 through the bottom wall 8e and the side walls 8b is prevented. and 8d ends up in the inner space 9. Furthermore, it has been shown that air 22 is pumped into the downwardly-opening adjusting space 19 by means of means designed as an air pump for introducing an adjusting fluid into the adjusting space. Because the bottom wall 8e is fluid-resistant, in particular substantially airtight, it is prevented that the air 22 passes through the bottom wall 8e into the inner space 9. Because the density of the air 22 is lower than the density of the water 2, the air 22 in the adjusting space 19 exerts a force on the foundation element 3 in the direction of arrow B. pumping the adjustment spaces 19, the force exerted by the air 2 on the foundation element 3 increases and the foundation element 3 will be displaced relative to the water level 20a in the direction of arrow B. If the position of foundation element 4 relative to the water level 2a is not displaced, the platform 21 is tilted in the direction of arrow C as a result of the movement of foundation element 3. For example, the position of the foundation element 3 as well as the position of the platform 21 and a structure mounted thereon relative to the water level 2a can be adjusted. By subsequently taking air 19 from the adjusting spaces 19 or, for example, by placing ballast elements in the inner space 9, the position of the foundation element 3 as well as the position of the platform 21 and a structure arranged thereon relative to the water level 2a are back to the situation as shown in Figure 5.

17

Figure 6 shows an alternative embodiment of the foundation elements 3 and 4 of Figures 1 to 5. With the foundation elements 33 and 34 shown in Figure 6, the bearing structure 10 extends from the bottom wall 8e and 5 the side walls 8b and 8d enclose interior space 9 upwards in use. As a result, additional interior space 23 is available in the foundation element 33, 34. To enclose the additional interior space 23, additional walls 24 are provided in line with the side walls 8b and 8d. The side walls 8b and 8d extend to the level indicated by the dashed line. Below that level, the side walls 8b serve as a barrier. Above that level, the additional walls 24 serve as a barrier.

At the ends 13 of the profile beams 12b and 12c a profile beam 12f is arranged which connects the foundation elements 33 and 34 to each other and on which floor elements 25 are arranged. The additional walls 24 extend above the floor parts 25 in the direction of arrow D and thus enclose an inner space 26 above the floor parts 25. The additional walls 24 may be of a different (plastic) material than the walls 8b, 8d and 8th of the container 7 of the foundation elements 33 and 34.

In the figures, the foundation element according to the invention is used for floating foundation of a building. A foundation element according to the invention can also be used for the foundation of a structure in a medium other than water, such as soil.

Figure 1 shows that the house 1 is floatingly grounded in water by means of two foundation elements according to the invention. It is also possible to use more or fewer foundation elements for the foundation.

In the figures, the foundation element is shown with a tray formed by a rectangular bottom wall and four 18 side walls. A different design of the container is also possible, for example with a circular bottom wall and a single side wall. The container can also have a hemispherical shape and be formed from only one wall.

In the figures, the walls of the container are designed to be fluid-resistant, in particular substantially watertight and airtight, so as to form a barrier against water and air penetrating into the inner space from outside through the walls. The walls could also form a barrier against other media. It is not necessary for the walls to be watertight and / or airtight.

15 1037887

Claims (22)

A foundation element for the foundation of a structure, such as a dwelling, comprising: 5. a tray formed by a number of walls of a plastic material, which walls enclose an inner space open upwards in use; and - a supporting structure placed in the bin for supporting the structure. 10 Foundation element according to claim 1, wherein - the plastic material is fiber reinforced. Foundation element according to claim 1 or 2, wherein - the plastic material is High-density polyethylene (HDPE). 4. Fundamental element according to any of the preceding claims, wherein - the walls are designed to be fluid-resistant, preferably substantially fluid-tight, at least in the direction from the outside thereof to the inside thereof. 25 Foundation element according to one of the preceding claims, wherein the tray comprises: - a bottom wall; 30. at least one side wall extending from the bottom wall, so that the bottom wall and the at least one side wall enclose the inside space open upwards in use. 1037887 Foundation element according to one of the preceding claims, further comprising: - a number of stiffening ribs, which stiffening ribs extend from at least one of the walls 5. 7. Foundation element as claimed in any of the foregoing claims, also comprising - adjusting means for putting the foundation element into use relative to the medium in which the foundation element is arranged for use. A foundation element according to claim 7, wherein the adjusting means comprise: 15. at least one wall-enclosed, in use, open-down adjusting space on the outside of the tray. The foundation element according to claims 5 and 8, wherein 20. the adjusting space open downwards in use is formed by the bottom wall and a number of adjusting walls extending from the bottom wall to in use. 10. Fundamental element as claimed in claim 8 or 9, comprising - means for introducing an adjusting fluid into the adjusting space, preferably an adjusting fluid with a density that is smaller than the density of the medium in which the foundation element is installed in use , more preferably an adjusting fluid with a density that is smaller than water, more preferably air. Foundation element according to one of claims 7 to 10, wherein the adjusting means comprise: - ballast elements which are preferably arranged in the tray near the bottom thereof. 5 A foundation element according to any one of the preceding claims, wherein - the bearing construction extends upwards from the inner space in use. 10 A foundation element according to any one of the preceding claims, wherein - the supporting structure comprises a skeleton of interconnected elements, preferably a skeleton of at least one from the group of steel elements, aluminum elements, wooden elements and plastic elements. Foundation element as claimed in any of the foregoing claims, wherein 20. a number of floor elements are arranged on the bearing construction, which floor elements are preferably provided with a concrete cover layer. 15. Method for forming a foundation element for the foundation of a structure, such as a dwelling, according to one of claims 1 to 14, comprising the steps of: - providing a tray formed by a number of walls of a plastic material, which walls enclose an inner space open upwards in use; and - placing a supporting structure for supporting the structure in the bin. - t 16. Method for the foundation of a structure, such as a dwelling, comprising the steps of: - providing at least one foundation element; and 5. applying the structure to the at least one foundation element; wherein the step of providing the foundation element comprises the steps of: - providing a tray formed by a number of walls of a plastic material, which walls enclose an inner space open upwards in use; - placing a supporting structure for supporting the structure in the bin; and - arranging the tray in a medium in which the structure must be founded; and wherein the structure is attached to the supporting structure. A method according to claim 16, wherein - the bin is provided at the construction site where the structure is to be founded; and - the supporting structure is placed in the container at this construction site. 25 18. Method as claimed in claim 16 or 17, wherein - the walls of the tray are designed to be fluid-resistant, preferably substantially fluid-tight, at least in the direction from the outside thereof to the inside thereof; and - the medium is water. <• V A method according to claim 18, further comprising the step of: - adjusting the foundation element relative to the water surface. 5 A method according to claim 19, wherein the step of setting the foundation element comprises applying ballast in the bin near the bottom thereof. 10 21. Method as claimed in claim 19 or 20, wherein - on the outside of the container below the water surface at least one wall-enclosed, opening-up space is arranged; and the step of setting the foundation element comprises at least one of bringing a fluid with a density smaller than the density of water, preferably air, into the adjusting space and taking it out of the adjusting space. The method of any one of claims 16 to 21, comprising - providing a plurality of foundation elements; 25. interconnecting the plurality of foundation elements; and - applying the structure to the plurality of mutually coupled foundation elements. 1037887