NL2015482B1 - Foundation element made of polymer-reinforced concrete. - Google Patents

Abstract

The invention relates to a foundation element made of a polymer-reinforced concrete and consisting of an elongated foundation body which comprises a tapered coupling projection in an axial direction at a first end, and which has a corresponding tapered coupling recess at the opposite second end end. The foundation body is provided with a continuous bore extending in the axial direction of the foundation body. A foundation pile can be molded with the foundation element. A first foundation element can herein be connected to a second foundation element. The connection can be made easily and quickly. The foundation bodies can be glued together easily and quickly.

Description

Brief description: Foundation element made of polymer-reinforced concrete Description

The invention relates to a foundation element for forming a foundation pile for a foundation of a building, as well as a foundation pile and a method for forming a foundation pile.

Foundation piles and methods for placing them in a soil are generally known.

According to the prior art, the principle of printing is used for the re-foundation of existing buildings. Because the available space at existing buildings is limited, the foundation piles must be formed from segments. The segments are pressed into the ground one by one. Steel pipe segments are used, which are then filled with concrete and possibly with reinforcement.

It is a drawback of the known foundation pile that the placing thereof is time-consuming, since the used steel pipe segments must be welded together precisely watertight. If the pipe segments are not watertightly welded, the water penetrates into the pipe and will first have to be emptied. The tube can then be filled with concrete to obtain the necessary strength for the pressure load. This makes the known foundation pile and the known method relatively expensive.

From EP 2 620 552 B1 a foundation element is known, with a polymer concrete foundation body, which is provided with a metal rod or tube. The rod or tube serves as a reinforcing element for absorbing pressure forces and tensile forces on the foundation element. Although this foundation element provides considerable improvements, in particular in being able to place a foundation pile faster, simpler and cheaper, this foundation element can be improved.

It is therefore an object of the invention to provide an improved foundation element with which it is possible to work even faster, simpler and cheaper, in particular when re-building existing buildings.

With this aim in mind, the invention provides a foundation element made of a polymer-reinforced concrete according to claim 1. According to the invention, the foundation element consists of a polymer concrete (PC), a concrete using polymers for supporting or replacing cement as binder, such as, for example, polymer concrete with unsaturated polyester resin (UP), polymer concrete with methyl methacrylate (MMA), polymer concrete with epoxy resin (EP), or another similar or related composite. HSB (high-strength concrete), also known to the person skilled in the art as polymer-Portland cement concrete, is particularly suitable, preferably in a high quality class. The polymer concrete or related composite is highly resistant to pressure loads, making it a particularly suitable material to be used as a foundation element. The polymer concrete is also resistant to corrosion. The polymer concrete is furthermore relatively easy to manufacture, for example as a prefab element. According to the present invention, the foundation body has a tapered projection in the axial direction at a first end, and a corresponding tapered recess at the opposite second end. The coupling projection is arranged to fit accurately into the coupling recess. Furthermore, the foundation body is provided with a continuous bore extending in the axial direction of the foundation body. This in fact results in a hollow foundation element made of polymer concrete, which is provided with tapered coupling connections at both ends. By tapering into the connection, and making the foundation body hollow, the foundation element consisting only of polymer concrete will be suitable for absorbing compressive forces and tensile forces, with which damage to the foundation element, due to forces in a direction transverse to the longitudinal direction. It is noted here that, unlike in EP 2 620 552 B1, no metal rod or tube has to be provided with the foundation element according to the present invention, but that due to the special design as described above, a foundation element consisting of polymer concrete suffice. The foundation element according to the present invention is therefore designed free of a reinforcement element, so that the foundation element can be made cheaper, but is also less heavy than the currently known foundation element with the same length.

The foundation body according to the present invention is hollow because of the continuous bore, for example substantially tubular or tubular, so that the hollow part of the foundation element can serve as so-called recess for possibly required or desired pipes, in particular for applications in, for example, geothermal energy, or extraction of liquid or gaseous substances and / or materials at a moderate depth. If desired, the interior of the foundation element can be filled after placement.

When manufacturing the round shape, use can be made of a tubular jig with a pouring opening at the top thereof. The polymer concrete is poured in via the pouring opening, and the pouring opening is closed with a valve. After hardening at the location of the pouring opening, the outside of the foundation element is not really round but flat. A further disadvantage is that cleaning of the tube mold is relatively time-consuming.

In a particularly preferred embodiment, the foundation element has a substantially rectangular outer circumference. This means that the outer circumference of the foundation element is rectangular, in particular square. The bore is in this case particularly round. The manufacture can take place with the aid of a rectangular tubular mold with pouring opening. This embodiment is, from a cost point of view, about 25% to 30% more advantageous than the above-mentioned round outer circumference of the foundation element, in particular because cleaning of the tubular mold is simpler.

In another embodiment, the through bore forms a flow tube for passing a flowable medium therethrough from one end of the foundation element to the other end of the foundation element. The wall of the through bore can be provided for this purpose with a coating suitable for this purpose.

According to the invention, the foundation body is designed in such a way that the coupling projection at the first end is adapted to connect closely to a coupling recess of a second end of a further foundation body. By gluing the end face of a first foundation body to the tail face of a second foundation body, a fast, watertight and form-fitting connection between the foundation bodies can be obtained.

To promote the modular character of the foundation body, it is preferable if a front face at a first end is arranged to connect with some play to a front face of a second end of the same foundation body. With some play is meant that there is a small space between the end faces, in particular of only a few millimeters, which can be used for applying an adhesive. By using this, the fixing of the first foundation element with the second foundation element can take place simply and quickly by gluing, wherein the glue fills the clearance for obtaining a positive connection with the lower end of the second foundation element. This makes a fast and watertight connection possible. A suitable type of glue is, for example, a suitable mortar or two-component kit. To obtain some clearance, in one embodiment the axial dimension of the torque projection can be greater than the axial dimension of the torque recess.

Optimal absorption of compressive and tensile forces will be possible when the ratio between a diameter (cross-section) of the through-bore and the diameter (cross-section) of the foundation body is in the range of 1: 2 and 1: 4, and in the particularly substantially equal to about 1: 3. By using a bore of such a size, the foundation element will be able to better absorb pressure and tensile forces, in particular because relatively less stress differences occur in the foundation element due to the release of the central part of the foundation element from polymer concrete, as a result of which the foundation element according to the present invention will break and / or crack less quickly.

In order to be able to absorb the compressive forces and tensile forces as effectively as possible, it is preferable if the bore, the coupling projection, the coupling recess and the foundation body are of substantially concentric design, for obtaining a substantially symmetrical foundation element. The continuous bore is particularly concentric with the axial axis of the foundation element.

For the proper transmission of forces and stresses between a plurality of foundation elements connected to each other, it is preferable if the coupling projection and the coupling recess are tapered at an angle with respect to the longitudinal axis of the foundation body, which angle is in the range of 8 ° to 12 °.

According to an aspect of the invention, it provides a foundation pile comprising a number of foundation elements according to the present invention stacked and connected to each other. The foundation pile can in particular be a foundation pile made of a polymer-reinforced concrete. The through-bores of the foundation elements used may be filled, in particular with concrete or polymer-reinforced concrete or similar material.

According to an aspect of the invention, it provides a method for installing a foundation pile in a bottom, comprising the steps of providing a first foundation element according to the invention, as well as providing a second foundation element according to the invention. The method comprises the further steps of: A. arranging the first foundation element in the ground; B. attaching a second foundation element to the first foundation element to form at least a portion of a foundation pile; and C. installing the foundation pile obtained in step B in the soil.

The application can be made with a suitable technique, such as for example pressing, punching (pile driving) or drilling, or a related technique. Combinations of these techniques may also be conceivable. The skilled person will be able to use a suitable technique. However, in one embodiment, printing is preferred.

The mounting comprises placing the coupling projection of the second foundation element on the coupling recess of the first foundation element. The fixing may include the step of gluing.

The method may include the additional steps of providing one or more further foundation elements according to the invention, and attaching these one or more further foundation elements to the formed foundation pile.

As already mentioned, it is preferable if in step B. the first and the second foundation element are glued together by means of an adhesive, such as, for example, 2-component adhesive.

The invention will be explained below for the purpose of illustration with reference to a figure description and associated figures, in which:

FIG. 1 - a schematic side view of a first embodiment of a foundation element according to the present invention;

FIG. 2 - a schematic side view of a second embodiment of a foundation element according to the present invention.

FIG. 3 - a schematic side view of a foundation pile with foundation elements according to the present invention.

FIG. 1 schematically shows a side view of a foundation element 2. According to the invention, the foundation element 2 consists of only one foundation body 4. This foundation body is essentially made of a polymer-reinforced concrete. Suitable polymer-reinforced concrete is, for example, polymer concrete (PC), polymer concrete with unsaturated polyester resin (UP), polymer concrete with methyl methacrylate (MMA), High Strength Concrete (HBS) or polymer concrete with epoxy resin (EP). Other similar or related composites can of course be used. The foundation body 4 further comprises a concentrically placed through-hole 5 (shown in broken lines), which extends substantially in a longitudinal direction L of the foundation body 4. On a top side of the foundation body 4 it is provided with a tapered coupling recess 8. At an opposite end face the foundation body 4 is provided with a tapered coupling projection 9. The coupling projection 9 and the coupling recess 8 are tapered correspondingly at an angle with respect to the longitudinal axis L, that is, the respective outer walls 18, 19 of the coupling recess 8 and the coupling projection 9 extend at an angle with respect to the longitudinal axis, wherein the angle may be in the range of 8 ° to 12 °. The coupling projection 9 is preferably provided with smaller dimensions than the coupling recess 8, such that the coupling projection 9 fits with some play in the coupling recess 8 of a further foundation element 2, wherein said play can be filled by means of an adhesive for obtaining closely fitting foundation elements 2. For this reason also the coupling projection 9 preferably has a larger axial dimension (in the direction of arrow L) than the axial dimension of the coupling recess 8. This means that there is also a clearance between adjacent end faces A, B, which can be filled with an adhesive. Precisely because a clearance between end faces is present here, the adhesive applied will not be able to be pushed away during the assembly of the foundation pile, but will remain in place, which benefits the mutual connection.

FIG. 2 shows a section through the longitudinal axis of the foundation element 2 of FIG. 1. Here it can be clearly seen that the foundation element 2 consists of a foundation body 4 with coupling projection 9 integrally formed therein, coupling recess 8 and a continuous bore 5 extending over the entire axial length of the foundation body 4, including the coupling projection 9 and up to at the torque recess 8. As can be seen in FIG. 2, the through bore 5, the coupling projection 9, the coupling recess 8 and the foundation body 4 are substantially concentric. The foundation body 4 can be tubular or tubular in that the outer circumference 14 of the foundation body has a circular or rectangular (square) cross-section. However, other hollow shapes are also conceivable for the foundation body 4. The through-hole 5 (bounded by wall 15 in Fig. 2) preferably has a circular cross-section. Because of this shape, the foundation element 2 can be manufactured integrally from polymer concrete relatively easily.

The foundation body 4 of the polymer-reinforced concrete, provided with the through bore 5 and with the coupling projection 9 and coupling recess 8 as described above, surprisingly provides a foundation element that is well able to withstand pressure forces and tensile forces on the foundation element 2. without the need for a metal reinforcing member. This makes the foundation element 2 according to the present invention suitable to serve as part of the foundation pile 1.

Such a foundation pile 1 is shown in FIG. 3. It can be seen that some foundation elements 2a-c are placed on top of each other. Each foundation element 2a-2c comprises a foundation body 4a-4c made entirely from polymer concrete (PC) with a concentrically provided through-hole 5a-5c. The foundation elements 2a-2c are placed on top of each other. In order to establish a firm connection between the foundation elements, use is made of a coupling between the coupling projection of an upper foundation body on a coupling recess of a foundation body located below. For example, the connection 22 is established by placing coupling of the projection of foundation body 4b on the coupling recess of foundation body 4c, and connection 21 is established by placing coupling of the projection of foundation body 4a on the coupling recess of foundation body 4b. The adjacent foundation bodies with the coupling projections and recesses ensure an improved and simplified coupling, which is nevertheless resistant to compressive and tensile forces. Adjacent end faces of adjacent foundation bodies 4a-4c are provided with some play in relation to each other, in order to provide room for good and firm mutual bonding.

In the foundation pile 1 of FIG. 3, the through bore 5a-5c can function as a flow tube, for passing a flowable medium therethrough from one end of the foundation element to the other end of the foundation element. The through bore 5a-5c can further be used for passing conduits through it, for example liquid conduits and / or electrical conduits, for example for the purpose of geothermal heat technologies.

The method described below can be used to form a foundation pile in a soil.

First, a first foundation element is provided in the ground as desired, by means of pressing, drilling, or pile driving, or another suitable technique. This first foundation element 2c can be designed according to the present invention, but can also be designed as a foundation element with foot, which is known per se to a person skilled in the art. This first foundation element with base can consist entirely of polymer concrete, although this is not essential for the invention. The installation of the first foundation element 2c takes place over such a length that the top side of the first foundation element 2c is placed at approximately the same height as the bottom surface B (ground level). A further foundation element 2b can now be attached to it. Fixing is done by gluing the coupling projection with the coupling recess, for establishing a glued connection 22. Particularly advantageous here is that the fixing of the first foundation element with the second foundation element can take place simply and quickly. For example, a 2-component adhesive can be used. After the mounting, the assembly 4c, 4b of the foundation pile 1 thus formed can be pressed into the ground, beaten (driven), or otherwise applied, again until the further foundation body 4b is placed at approximately the same height as the bottom surface B. Now a further foundation element 2a can again be attached to the foundation pile 1, and this assembly can also be arranged in the ground by pressing it, hitting it (pile driving), drilling it or otherwise applying it. The steps mentioned can possibly be repeated again, until the desired length of the foundation pile has been reached.

For the in FIG. The embodiment shown in Fig. 3 then still holds that an injected foot 11 can be formed by introducing a medium suitable for this from the top B via the through bore, which medium will flow downwards until it reaches the end of the through bore 5c. Here the liquid medium will flow into the soil. After curing, the base 11 of the foundation pile 1 is formed. The foot can be designed in a manner known to the skilled person, for which reference is made, for example, to the aforementioned EP 2 620 552 B1.

Typical dimensions of the in FIG. 1 and 2, foundation bodies shown are described for illustration. The length can be approximately 500 mm, with an outer diameter of approximately 160 mm. The diameter of the through bore can be approximately 50 mm. The torque projection extends in axial direction beyond the end face by approximately 30 mm. The distance between the two end faces is therefore approximately 470 mm. The torque projection has, for example, a base diameter of 120 mm and a top diameter of 116 mm. The coupling recess can be situated about 25 mm deeper with respect to the associated end face. The base diameter is approximately 120 mm, and the diameter near the end face is approximately 124 mm. With these dimensions, the ratio between a diameter of the through bore and the diameter of the foundation body is approximately equal to 1: 3. According to the invention, however, the ratio may in particular be in the range of 1: 2 and 1: 4. Furthermore, the ratio between an axial dimension of the torque projection and a diameter of the through-bore is equal to about 1: 2, but it can be in the range of 1: 1 and 1: 3.

It is noted that the foundation elements as described above can be installed in the soil in a variety of ways, and that pressure, punching, pile-driving, drilling or other arrangements have been mentioned for illustrative purposes only. However, the invention is not limited to the manner of mounting the foundation element.

The foundation element according to the present invention is suitable for renovation work, for replacing a foundation for an existing building. However, the foundation element is also suitable for new construction, in particular for new construction on small inner-city plots where only low-noise and vibration-free foundations are permitted. A foundation element with dimensions larger than those mentioned above can thereby serve excellently as a foundation element for the foundation piles to be fitted. The invention is not limited to the dimensions mentioned above.

It will be clear to a person skilled in the art that the invention has been described above with reference to a few preferred embodiments, and that various alternative and / or equivalent embodiments are conceivable within the scope of the invention, which may be within the required scope of protection of the following. conclusions.

Claims (12)

A foundation element made of a polymer-reinforced concrete and consisting of an elongated foundation body of polymer-reinforced concrete which comprises a tapered coupling projection at a first end end and which has a corresponding tapered coupling recess at the opposite second end end , wherein the foundation body is provided with a continuous bore extending in the axial direction of the foundation body. Foundation element according to claim 1, wherein the ratio between a diameter of the through bore and the diameter of the foundation body is in the range of 1: 2 and 1: 4, and in particular is substantially equal to about 1: 3 . Foundation element according to claim 1 or 2, wherein the ratio between an axial dimension of the coupling projection and a diameter of the through-bore is in the range of 1: 1 and 1: 3, and in particular is substantially equal to 1: 2. Foundation element according to one of the preceding claims, wherein the through-bore, the coupling projection, the coupling recess and the foundation body are substantially concentric. Foundation element according to one of the preceding claims, wherein the foundation body is substantially tubular or tubular. Foundation element according to claim 5, wherein the foundation element has a rectangular outer circumference, and wherein the bore has a round cross section. Foundation element as claimed in any of the foregoing claims, wherein the coupling projection and the coupling recess are tapered at an angle in the range of 8 ° to 12 ° with respect to the longitudinal axis of the foundation body. Foundation element according to one of the preceding claims, wherein the axial dimension of the coupling projection is larger than the axial dimension of the coupling recess. 9. Foundation pile from a polymer-reinforced concrete, comprising a number of foundation elements stacked on top of each other and connected to each other according to one of the preceding claims. A method for installing a foundation pile made of polymer concrete into a bottom, comprising the steps of providing a first foundation element according to any of claims 1 to 8, as well as providing a second foundation element according to one of the claims 1. to 8, the method comprising the further steps of; A. arranging the first foundation element in the soil; B. attaching a second foundation element to the first foundation element to form at least a portion of a foundation pile; and C. arranging the foundation pile thus formed in the soil. Method according to claim 10, wherein in step B. the first and the second foundation element are glued together by means of an adhesive. Use of a foundation element according to one of claims 1 to 8 as a jack element for vertically raising an object or construction.