DE9309087U1 - Seamless floor for a building with pile foundations - Google Patents

Description

The invention relates to a seamless floor for a building with pile foundations.

Such a seamless floor is generally created directly on site by concreting a base plate over the pile heads on the subsoil.

Pile foundations are usually necessary when there are no load-bearing subsoil layers under the lower edge of the planned base plate. If pile foundations are to be avoided in these cases, either the base plate must be lowered to load-bearing subsoil layers, which may involve unreasonable expense, or the insufficiently load-bearing subsoil under the planned lower edge of the base plate must be removed down to the load-bearing subsoil layers and replaced with load-bearing subsoil; in both cases, large amounts of earth must be moved, and additional expense may be required to lower the groundwater to the load-bearing layers.

Combining a seamless floor with pile foundations has, however, caused considerable difficulties so far: the wall and column loads of the finished building are transferred via the piles into the load-bearing, deeper subsoil layers. Until the skin friction gives the piles enough support to take the full weight of the building, the piles usually settle by a few centimeters. Since the floor slab was made seamlessly over the pile heads before the building was erected, it is either connected to the pile heads or between the piles and the load-bearing parts of the building

clamped so that the base plate is pulled downwards in the pile head areas by the settlement distance. However, if the subsoil in the foundation base can only bear a limited load, the subsoil that is pulled downwards experiences resistance, which forces the base plate and deforms it. The resulting bending moments cause cracks in the base plate, which can only be satisfactorily mitigated by significantly strengthening the base plate. In addition, the entire weight of the building is not then placed on the piles, but also on the poorly supporting subsoil of the foundation base via the base plate, which makes long-term changes in the static conditions unpredictable.

In order to avoid the problems mentioned, it has been suggested to initially keep the floor slab separate from the piles, i.e. to leave the pile head areas in the floor slab out during the construction of the building. However, this means that the floor is no longer seamless; after the building has been completed, the joints between the pile heads and the floor slab must be subsequently filled with concrete separately, which affects the long-term stability of the floor slab. If there is groundwater and the floor slab is to be made waterproof, leaks can occur at the joints; in addition, the groundwater must remain lowered throughout the entire construction period of the building, which represents a considerable additional expense.

Based on this state of the art, the invention is based on the object of creating a seamless floor for a building with pile foundations, which meets the above-mentioned

disadvantages and which in particular makes it possible to use a seamless floor slab in which there is no need to fear the formation of cracks due to constraints and bending moments caused by the pile settlement.

This object is achieved according to the invention in that a compressible base is arranged between the building ground and the floor slab, which has a permanently elastic restoring force against the weight of the floor slab. This restoring force causes the compressible base to experience further compression by applying an additional force to the floor slab, whereby the amount of the additional force component in the direction of gravity is less than or equal to the amount of the weight of the building.

Such a compressible base according to the invention is therefore able to bear the weight of the floor slab with relatively little deformation, while at the same time being able to withstand compression under the weight of the building in the order of magnitude of the pile settlement without unacceptably high resistance. The load of the building is therefore essentially transferred via the piles into the load-bearing base layers, with only a negligible part resting on the floor slab. As a result, the floor slab is only subjected to very small constraints and bending moments, so that there is no risk of cracks forming in the floor slab.

Particular advantages arise from the fact that the floor slab is made of waterproof concrete, because very often the lower edge of the floor slab is completely or partially in the fluctuation range of the groundwater. Due to

the compressible base according to the invention between the building ground and the floor slab, no cracks and thus leaks in the floor slab need to be expected during construction of the building; thus, a seamless floor slab made of waterproof concrete represents the simplest and most effective way of sealing the building floor against water penetration. In addition, the sealing effect of the seamless floor according to the invention is already present from the moment the waterproof floor slab is applied to the compressible base, so that a lowering of the groundwater level during the rest of the building's construction period is unnecessary. Avoiding long-term extraction of groundwater is not just a question of cost, because the lowering of the groundwater level also always carries the risk of settlement damage to neighboring buildings.

The base plate is conveniently made of steel-reinforced concrete, which ensures easy manufacture with good stability properties.

It is advantageous if the compressible base has such a compressibility that the magnitude of the additional compression due to the additional force applied to the base plate corresponds at least to the maximum settlement of the pile foundation under the load of the building. This property of the compressible base according to the invention ensures that the bending moments and constraints of the base plate remain negligibly small.

The compressible base according to the invention consists preferably of loosely packed polystyrene balls that are fixed in position relative to one another. The loose packing

This ensures that there is no regular lattice structure, but rather that larger air pockets are statistically distributed, so that the entire compressible base has a smaller modulus of elasticity than solid Styrofoam. The loose packing also allows the Styrofoam balls to rearrange and/or deform under compression that lasts for a very long time, resulting in an overall plastic creep deformation of the compressible base.

The polystyrene balls can have approximately the same or different diameters, with the diameters preferably being between approx. 5 mm and approx. 5 cm.

The compressible base advantageously consists of commercially available Styrofoam drainage panels, which consist of loosely packed Styrofoam balls that are glued together using bitumen. These drainage panels are particularly easy to cut to size on site and can be laid without any problems in any weather. Furthermore, they have a load-deformation behavior that is very advantageous for the purposes of the invention. Due to the very good consistency of the stress-strain behavior at different thicknesses, the drainage panels mentioned can also be made thinner or thicker, depending on requirements.

However, the compressible base can also be made of foam concrete or polystyrene concrete. These materials are also easy to process and simple to manufacture.

According to a preferred embodiment of the invention, a blinding layer is arranged between the compressible base and the base plate. Such a blinding layer usually consists of cheap lean concrete, which, unlike the subsoil, can be cleanly leveled. This is particularly important if the base plate is to be made by concreting on site, especially if steel reinforcement is planned: Since the steel bars must be at least 2 to 3 cm inside the concrete in order to minimize the risk of these bars oxidizing, and since these steel bars are arranged on the blinding layer using spacers and then covered with concrete, precise leveling of this blinding layer is necessary. Furthermore, this blind layer has the advantage that the compressible base underneath is not damaged by walking or driving on it, or by placing small to medium loads on it, which could otherwise be the case, for example, when producing the steel reinforcement or when cutting the pile heads.

However, according to the invention it is also possible for the blind layer to be arranged between the subsoil and the compressible base. In this way, the compressible base cannot be impaired by irregularities in the subsoil surface.

It is advisable to place a film between the subsoil and the compressible base and/or between the compressible base and the floor slab and/or between the compressible base and the blinding layer. This film is intended to protect the compressible

Protect the base from the penetration of soil components or fresh concrete, as well as other foreign material; filling the cavities of the compressible base with incompressible materials such as sand or concrete would severely impair the compressibility of the base itself.

The base plate according to the invention can be connected to the pile heads, which is particularly useful if the base plate is manufactured on site after the pile foundations have been made.

An embodiment is described and explained in more detail below with reference to the drawings.

Show it:

Figure 1 is a schematic side view of a seamless floor with pile foundation,

Figure 2 shows a detail from Figure 1,

Figure 3 shows a section through a Styrofoam drainage plate.

Figure 1 shows how the base plate 1 is clamped between the pile foundation 5 and the building 4. Between the subsoil 2 and the base plate 1, the compressible base 3 can be seen, which was covered with the blind layer 6 before the base plate 1 was concreted.

Figure 2, a detailed representation of detail A according to Figure 1, shows that a film 7 is arranged between the subsoil 2 and the compressible base 3, as well as between the compressible base 3 and the blinding layer 6. The base plate 1 rests on the blinding layer 6.

Figure 3 clearly shows how the polystyrene balls 8 are distributed in the compressible base 3.

List of reference symbols

1 Base plate 2 Building site 3 document 4 Building 5 Pile foundation 6 Subsurface layer 7 FoI ie 8th Styrofoam ball 9 pile head

Claims (16)

- 1 claims 1. Seamless floor for a building with pile foundations, where a floor slab is generally created on site on the building site by pouring concrete over the pile heads, characterized, that a compressible base (3) is arranged between the building ground (2) and the floor slab (1), which has a permanently elastic restoring force against the weight of the floor slab (1) such that the compressible base (3) experiences further compression by applying an additional force to the floor slab (1), the amount of the additional force component in the direction of gravity being less than or equal to the amount of the weight of the building (4). 2. Seamless floor according to claim 1, characterized in that the base plate (1) is made of waterproof concrete. 3. Seamless floor according to claim 1, characterized in that the base plate (1) consists of steel-reinforced concrete. 4. Seamless floor according to claim 1, characterized in that the compressible base (3) is compressible by the additional force applied to the floor slab (1) at least by a distance whose magnitude corresponds to the maximum settlement of the pile foundation (5) under load from the building (4). 5. Seamless floor according to claim 1, characterized in that the compressible base (3) consists of loosely packed polystyrene balls (8) fixed in position relative to one another. 6. Seamless floor according to claim 5, characterized in that the polystyrene balls (8) have approximately the same diameter between approximately 5 mm and approximately 5 cm. 7. Seamless floor according to claim 5, characterized in that the polystyrene balls (8) have different diameters between approximately 5 mm and approximately 5 cm. 8. Seamless floor according to claim 5, characterized in that the compressible base (3) consists of polystyrene drainage panels. 9. Seamless floor according to claim 1, characterized in that the compressible base (3) consists of foam concrete. 10. Seamless floor according to claim 1, characterized in that the compressible base (3) is made of polystyrene concrete. 11. Seamless floor according to claim 1, characterized in that a clean layer (6) is arranged between the compressible base (3) and the base plate (1). 12. Seamless floor according to claim 1, characterized in that a subgrade layer (6) is arranged between the subsoil (2) and the compressible base (3). 13. Seamless floor according to one of claims 1 or 11, characterized in that that a film (7) is arranged between the subsoil (2) and the compressible base (3). 14. Seamless floor according to one of claims 1 or 12, characterized in that a film (7) is arranged between the compressible base (3) and the base plate (1). 15. Seamless floor according to one of claims 11 or 12, characterized in that that a film (7) is arranged between the compressible base (3) and the blind layer (6). 16. Seamless floor according to claim 1, characterized in that the floor plate (1) is connected to the pile heads (9).