NL2003248C2 - DRY STACK CONNECTION OF FLOOR AND WALL FOR THE FORMATION OF A CONSTRUCTION OF A BUILDING. - Google Patents

Description

Dry pile connection of floor and wall for the formation of a load-bearing construction of a building

The present invention relates to a load-bearing construction of a building, as well as a floor and a wall for such a construction. The invention further relates to a composition for mutually adjusting floor and wall, as well as to a method for building a load-bearing structure of a building.

In the construction of a load-bearing structure of a building, it is a problem to place the heavy wall or wall parts in the correct position of the floor. A solution to this problem involves the use of metal cuttings or pins which are arranged in, for example, the floor. If the wall is provided with corresponding holes (gains), a simple alignment can be obtained. An important disadvantage of this technique is the tolerance that must be used to be able to correct for inaccuracies during the application of the pins and / or the holes. In order to obtain a correct placement, manual adjustment during placement is therefore often required. Given the weight of the wall, this is a labor-intensive and time-consuming process.

Another problem is that the floor on which the wall 25 is to be placed is often not completely flat. Direct placement of the wall will therefore lead to damage to the wall and floor because the wall will initially rest only on the projecting parts. A solution for this problem is the so-called wet stacking. A wet joint, often based on mortar, is used for fixing the wall and floor. Mortar is used as an intermediate layer between the floor and the wall. Since this product is applied in the liquid state 2, it is able to eliminate the unevenness between floor and wall, which results in a good pressure distribution.

In practice, a bed of mortar is applied to the floor prior to placing the wall. After this the wall will be placed in the mortar. It is also possible to saberize the wall after installation with shrink-free mortar or to pour this on later. Since the mortar needs some time to cure, for example a few hours to days, it is not possible to use this wall in the short term as a supporting element for, for example, a floor to be placed on it. A shorter curing time is often linked to higher costs for the material to be used. Another disadvantage is that the curing itself is dependent on the weather conditions. The use of a wet connection is also time-consuming, requires a lot of set material and produces a lot of waste at the construction site.

It is an object of the present invention to provide a connection technique between wall and floor which makes it possible to place the wall on the floor by means of dry stacking, as a result of which the above drawbacks will not occur, or at least to a lesser extent.

This object has been achieved by a load-bearing construction of a building comprising a floor with a wall placed thereon. This construction further comprises a plurality of compositions for positioning the wall on the floor. Here, at least one composition comprises an adjusting body collapsed in the floor and an adjusting element which engages in the adjusting body and which extends beyond a surface of the floor towards the wall. The adjusting element herein engages the wall for mutual stabilization of wall and floor. A special aspect of the present invention is that the adjusting element, at least prior to placement of the wall on the floor, is adjustable relative to the adjusting body. It is therefore possible to carry out the adjustment at the place where the wall will be placed.

5 The above measures make it possible to reduce tolerance. After all, because the adjusting element is adjustable prior to placement, this element can be aligned with respect to the wall and the edge of the floor, as well as with respect to other adjusting elements. It is preferred here if the floor is provided with several compositions. It is then possible, for example, to tension a cord or to use a laser with which all the adjusting elements are placed in one line. This alignment can be done before the heavy wall is placed.

In a preferred embodiment the wall is provided on a side facing the floor with a pressure distributor for distributing pressure exerted on this side of the wall. An example of such a pressure distributor is a rubber profile that at least partially covers the side facing the floor. The use of a pressure distributor reduces the requirements that must be made of the flatness of the wall and floor. Unevenness in these components can be absorbed by the pressure distributor. The pressure distributor ensures that the pressure not only concentrates to the location of the unevenness, but that it distributes over a larger surface, so that the risk of damage is considerably reduced. Another advantage of a pressure distributor is that it further reduces the aforementioned required tolerance.

The pressure distributor can be arranged on the adjusting element and or on the side of the wall facing the floor. With walls or wall parts to be poured, it is possible to arrange the pressure distributor 4 in the formwork, so that it will form an integral part of the wall.

In a favorable embodiment of the load-bearing construction according to the invention, the wall is provided in a side facing the floor with a wall recess which at least after placement connects to the said adjusting element. The pressure distributor can herein be arranged in the wall recess, preferably already before the placement of the wall. After placement of the wall, the pressure distributor is then located between the wall recess and the adjusting element. The wall cavity and the adjusting element preferably have a semi-cylindrical profile. Such a profile ensures good self-alignment and good pressure distribution.

It is advantageous if the adjusting element is detachably connected to the adjusting body prior to placement of the wall on the floor. In this embodiment, the adjusting body is arranged in the floor and this body does not extend beyond the floor surface. This facilitates the transport and stacking of the floor (parts). After the floor has been installed on the building, the adjusting elements are installed in the adjusting body and aligned with each other.

The adjusting element is preferably fixed with respect to the adjusting body by hardened material poured into the adjusting body, wherein the hardened material surrounds the adjusting element at least in part. After placement of the wall, for example, mortar is poured into the adjusting body in a later phase. The adjusting element is then fixed. This pouring can take place simultaneously with the pouring of the screed.

A floor usually comprises several floor parts and a wall comprises several wall parts. It is preferred here to apply the above measures to each wall and floor part. Furthermore, it is preferable if at least two compositions are used per placed wall part.

The functionality of the wall and the floor can be expanded if the floor is provided with a floor cavity on a side facing away from the wall and the wall on a side directed away from the floor of a bulge. Such a wall and / or floor can be used for stacking wall and floor on top of each other. This is possible because the floor recess and the protrusion of the wall are matched to each other. In this case, it is preferable if a pressure distributor is again applied between the wall protrusion and the floor recess. This may concern the same type of pressure distributor as previously discussed. With walls or wall parts to be poured, it is also possible with this pressure distributor to arrange the pressure distributor in the formwork, so that it will form an integral part of the wall.

Multiple floors can easily be realized with these elements. First of all, the floor of the ground floor is hereby placed. This does not necessarily have to be provided with floor cavities.

The walls are then placed in the above-mentioned manner. After placement, a storey floor can be placed on top of the walls 25. The bulges of the walls will hereby connect to the floor cavities of the floor. As already noted, a storey floor, as well as the walls on which it is placed, will consist of a plurality of parts or plates in which the composition, the protrusions, and the recesses are applied.

A further advantage of this type of walls and floors is that the number of different components required to build a load-bearing structure can be reduced. The use of standard parts reduces the production costs, the design effort, the logistics costs, and gives the possibility of scaling up.

Preferably, an axis is received in the adjusting body along which fixing means are movable for fixing the adjusting element. The use of an axis limits the adjustability of the adjusting element to one direction. The shaft is herein preferably perpendicular to the edge of the floor. However, it is also conceivable that the adjusting element rotatably engages the shaft, so that also rotation in the plane of the floor becomes possible.

The shaft can further be provided with a thread. The fixing means can for instance comprise two plate parts between which the adjusting element can be clamped at least prior to placement of the wall on the floor. The plate parts are hereby fixable by engagement with the said thread. An example is plate parts which are in contact with or connected to nuts arranged on the shaft. By turning these nuts, the plate parts can be moved over the shaft. The adjusting element can also be clamped in this way.

It is advantageous if the movement of the adjusting element can be fixed in a plane of the floor at least prior to placement of the floor and wherein the adjusting element extends in this plane beyond the adjusting body. In this embodiment, the shape of the adjusting element ensures that the movement perpendicular to the floor is limited. This is because the adjusting element extends over the adjusting body, so that it rests on the floor. Movement in the plane of the floor is limited by the aforementioned fixing means, for example the plate parts which engage the shaft.

7

The present invention is particularly suitable for the use of prefab components. These parts have more accurate dimensions than parts deposited at work. With prefabricated parts, for example, the cavities in wall and floor in a factory environment can be formed by the use of reusable molds in which corresponding profiles are arranged.

The invention further provides a floor and wall as described above. It will be clear to the skilled person that a floor part or wall part is not excluded and that the invention also relates to these parts.

The invention further provides a composition for mutually adjusting a wall and a floor as described above. Hereby it is possible that the adjusting element is detachably or non-releasably connected to the adjusting body. It is also possible that the adjusting body and the adjusting element are processed and / or traded as separate parts.

The present invention also provides a method for building a load-bearing structure of a building. The method herein comprises providing a floor with an adjusting body collapsed therein, providing a wall, and providing an adjusting element which can engage the adjusting body. The method further comprises adjusting the adjusting element after placing the adjusting element in the adjusting body. The adjusting element can already be coupled to the adjusting body.

Placing the adjusting element in or on the adjusting body can also be part of the method. According to the method, the wall is then placed on the floor, the adjusting element engaging the wall for mutual stabilization of wall and floor.

8

It will be clear to a person skilled in the art that the floor, the wall, the adjusting body and the adjusting element can be designed as described earlier.

In a preferred method, building a load-bearing structure of a building comprises repeatedly applying the foregoing method for forming multiple floors. A wall associated with a floor is herein coupled to a floor part associated with a higher floor by an engagement between a wall protrusion of the said wall and a floor recess in the said floor, preferably with the intervention of a pressure distributor.

In the following, the invention will be further explained by a description of embodiments thereof with reference to the accompanying figures, wherein identical numbers are used to indicate identical or similar components, and wherein:

Figures 1A-1C show a view of an embodiment of an adjusting body and adjusting element in the coupled and uncoupled state;

Figure 2 shows an overview of an adjusting body placed in a floor; and

Figure 3 shows a cross-sectional view of a construction of a floor using the adjusting body and adjusting element from figure 1.

Figure 1A shows the structure of a adjusting body 1. Adjusting body 1 comprises a metal housing 2 in which a threaded shaft 3 is received. Around plate 3 two plate parts 4, 4 'are arranged which are displaceable along axis 3. Two nuts 5 (only one visible) are used to limit the movement of plate parts 4, 4'. Anchoring rods 6, 6 'are further arranged which provide a further anchoring in the floor. Figure 1B shows a 9 adjusting element 7. Furthermore, figure 1C shows adjusting body 1 and adjusting element 7 in coupled condition. Adjusting element 7 comprises a plate part 8 with a recess 9 arranged therein, as a result of which the adjusting element 7 can be placed around axis 3 between plate parts 4,4 '. Furthermore, the adjusting element 7 extends in the lateral direction. As a result, when positioning element 7 is placed this element will rest on the floor. As a result, the pressure is exerted by a wall spread over the floor and this pressure does not fall, or at least not completely, over shaft 3. See for example figure 2 for a view of the adjusting body 1 placed in a floor 10.

Figure 3 shows a cross-sectional view of a floor in which the cross-sectional area per component is shifted to clarify the mutual cohesion. In figure 3 a wall 11 is placed on floor 10.

A floor 12 is again placed on top of wall 11, which floor preferably has the same structure as floor 10. Wall 11 is provided with a recess 13 on a side facing floor 10. Adjustment element 7 connects to wall recess 13 through a pressure distributor 14 , in the form of a rubber profile.

A protrusion 15 is provided on the top of wall 11. Projection 15 connects to a floor recess 16 in floor 12 through the intervention of a pressure distributor 17.

This pressure distributor is also in the form of a rubber profile. A mutual stabilization of floor and wall is achieved by said connection or engagement.

As a finish, mortar can be poured into this element via opening 18 in adjusting body 1. As a result, the mortar 30 will enclose the adjusting element 7, and in particular plate parts 4, 4 ', whereby adjusting element 7 is further fixed. This pouring can take place simultaneously with the pouring of the screed.

10

The rubber profile used according to the invention must be resistant to weather, ozone and aging. Furthermore, the properties of the profile must be guaranteed in a wide temperature range, for example from -20 5 degrees Celsius to + 60 degrees Celsius. Furthermore, mechanical (load) requirements apply such as the tensile strength (preferably greater than 15 N / mm 2), the elongation at break (preferably greater than 250%), the hardness (preferably greater than a shore A hardness of 70%) ), the shear stress (preferably greater than 0.2 N / mm) and the maximum compressive stress (preferably greater than 7.5 N / mm).

Neoprene or polychloropene rubber has been found to be a suitable material for the rubber profile in view of the requirements.

It should further be noted that the walls and floors, or parts thereof, discussed within the context of the present invention, are often embodied in a concrete type optionally provided with reinforcement. However, the present invention is also applicable to walls and floors which are made from other material.

In the above, the invention has been discussed inter alia by means of a description of an embodiment thereof. It will be clear to the skilled person that various changes are possible without departing from the scope of protection which is defined by the appended claims.

Claims (19)

A load-bearing construction of a building comprising a floor with a wall placed thereon, wherein the construction comprises a plurality of compositions for positioning the wall on the floor, wherein at least one composition of said plurality of compositions comprises: the collapsed adjusting body; 10 an adjusting element which engages the adjusting body and which extends beyond a surface of the first floor towards the wall, wherein the adjusting element engages the wall for mutual stabilization of wall and floor; wherein the adjusting element is adjustable in place relative to the adjusting body at least prior to placement of the wall on the floor. 2. A load-bearing construction of a building according to claim 1, wherein the wall is provided on a side facing the floor with a pressure distributor for distributing pressure exerted on this side of the wall. 3. Load-bearing construction of a building according to claim 2, wherein the pressure distributor comprises a rubber profile which at least partially covers the side facing the floor. 4. A load-bearing construction of a building according to any one of the preceding claims, wherein the wall is provided in a side facing the floor with a wall recess 30 which at least after placement connects to said adjusting element. A load-bearing structure of a building according to any one of the preceding claims, wherein the adjusting element is releasably connected to the adjusting body prior to placing the wall on the floor. 5 6. A load-bearing structure of a building according to any one of the preceding claims, wherein the adjusting element is fixed relative to the adjusting body by hardened material poured into the adjusting body, wherein the hardened material surrounds the adjusting element at least in part. 7. Load-bearing construction of a building according to one of the preceding claims, wherein the floor comprises a plurality of floor parts and the wall comprises a plurality of wall parts, wherein at least two compositions are applied per wall part placed. 8. Load-bearing construction of a building according to one of the preceding claims, wherein the floor is provided with a floor recess on a side facing away from the wall and the wall on a side of a protrusion facing away from the floor. 9. The load-bearing structure of a building as claimed in claim 8, wherein the load-bearing structure comprises a plurality of linked floors, the coupling between a wall belonging to a floor with a floor part belonging to a higher floor being formed by an engagement between a wall protrusion of said wall and a floor cavity in said floor, preferably with the intervention of a pressure distributor. 10. A load-bearing structure of a building according to any one of the preceding claims, wherein an axis is received in the adjusting body along which fixing means for fixing the adjusting element can be moved. 5 11. Load-bearing construction of a building according to claim 10, wherein the shaft is provided with screw thread and wherein the fixing means comprise two plate parts between which the adjusting element can be clamped at least prior to placement of the wall on the floor, the plate parts being fixable by engagement on the mentioned thread. 12. Load-bearing construction of a building according to any of the preceding claims, wherein movement of the adjusting element 15 can be fixed in a plane of the floor at least prior to placement of the floor and wherein the adjusting element extends in this plane beyond the adjusting body. 13. Load-bearing construction of a building according to any of the preceding claims, wherein at least one of said wall and floor is prefabricated. A floor as defined in any one of the preceding claims. 25 Wall as defined in any one of the preceding claims. A composition for interlocking a wall 30 and a floor as defined in any one of the preceding claims. A method for building a load-bearing structure of a building, comprising: providing a floor with an adjustable body collapsed therein; 5 providing a wall; providing an adjusting element which can engage the adjusting body; adjusting the adjusting element after placing the adjusting element in the adjusting body; 10 placing the wall on the floor, the adjusting element engaging the wall for mutual stabilization of wall and floor. 18. Method for building a load-bearing structure of a building according to claim 17, wherein the floor, the wall and / or the adjusting body are designed as defined in any one of claims 1-16. A method of building a load-bearing structure 20 of a building according to claim 17 or 18, wherein the floor, the wall and the adjusting body are designed as defined in claim 9, further comprising repeatedly applying the method of claim 17 for the formation of multiple floors, wherein a wall associated with a floor is coupled to a floor part associated with a higher floor by an engagement between a wall protrusion of the said wall and a floor recess in the said floor, preferably with the intervention of a pressure distributor. 30