NL2008192C2 - FOUNDATION ELEMENT. - Google Patents

Abstract

The invention relates to a foundation element comprising a foundation body which is substantially made of polymer concrete and which comprises a reinforcement element that extends substantially in a longitudinal direction of the foundation body for absorbing pressure forces and tensile forces exerted on the foundation element. The foundation element can be used for forming a foundation pile. This can be done by connecting a first foundation element and a second foundation element together. The connection can be effected in a quick and simple manner. Connecting means for connecting reinforcement elements together may be provided in a simple manner. The foundation bodies can be glued together in a quick and simple manner.

Description

Foundation element

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.

For the purpose of re-founding existing buildings 10, the principle of printing is used according to the prior art. 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 in a watertight manner. If the pipe segments are not watertightly welded, the water penetrates into the pipe and will first have to be emptied. Subsequently, the tube can 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.

It is therefore an object of the invention to provide a foundation element that can be placed faster, simpler and cheaper, in particular when re-building existing buildings.

For this purpose, the invention provides a foundation element according to claim 1. According to the invention, the foundation element comprises a foundation body which is substantially made of a polymer concrete (PC), 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. 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. For absorbing compressive and tensile forces on the foundation element, the foundation body comprises a reinforcing member which extends substantially in a longitudinal direction of the foundation body. This prevents damage to the foundation element as a result of forces in a direction transverse to the longitudinal direction.

The foundation body is preferably a substantially solid foundation body, as a result of which filling up of the interior of the foundation element, after placement, is no longer necessary. The reinforcing member is preferably completely surrounded by the polymer concrete. The reinforcing member can be provided with the aid of an adhesive, such as for example 2-10 component glue or with a sealing ring, so as to make the reinforcing member tensile and waterproof.

The reinforcement element preferably extends substantially the full length of the foundation body. It may protrude slightly near the ends of the foundation body, or may extend to a minimum distance from one end of the foundation body. This simplifies the coupling of different foundation elements to each other, as will be explained below.

In order to be able to absorb the compressive and tensile forces as effectively as possible, it is preferable if the reinforcing element and the foundation body are substantially concentric. The reinforcement element is then located in the center of the foundation body.

The reinforcing element preferably comprises a rod or tube. The rod is preferably solid. The tube is preferably hollow. The rod or tube is preferably made of a metal, such as for example steel or reinforcing steel.

In order to enable coupling of foundation elements already described above, it is very highly preferred if the reinforcing element is provided at one end thereof with a coupling member which is adapted to be connectable with a further foundation element, preferably with a further coupling member of a further reinforcement element of the further foundation element.

This coupling member can comprise a screw thread in a simple manner.

In addition, it is preferred that at least one end of the foundation body also comprises coupling means which are adapted to be connectable to an end of a further foundation element, preferably with further coupling means at an end of the further foundation element.

The coupling means can be of particularly simple design when the coupling means comprise one or more recesses or protuberances in the end face of the foundation body. The foundation body is then preferably designed in such a way that a head surface at a first end is adapted to connect tightly to a head surface of a second end of a further foundation body. In order to promote the modular character of the foundation body, it is preferable if a front face at a first end is arranged to connect tightly to a front face of a second end of the same foundation body. In this way it becomes possible to use a number of the same foundation elements in the manufacture of a foundation pile.

The coupling means can form a part of a male-female connection in a particularly simple manner. For example, the first end face may be in the form of a male clutch, and the second end face may be in the form of a female clutch.

In one embodiment the foundation element can be adapted to serve as a foot for a foundation pile built up from foundation elements.

It is thereby possible that the foundation body has a larger cross-section near an end than at an opposite end, so as to form a widened foot of the foundation pile.

In one embodiment, the larger cross-sectional end is adapted to be drilled or pressed into the bottom. The end may be conical, rectangular, 6 or multiple angular, pyramidal or screw-shaped, depending on the bottom structure to be penetrated.

In another embodiment, the foundation element is provided with a flow tube for passing a flowable medium therethrough from one end of the foundation element to the other end of the foundation element. This flowable medium is preferably a medium that can be injected into the soil, for forming an injected foot, such as, for example, various types of injection mortars.

It is particularly preferred in this case to make the reinforcement element 35 hollow, wherein the reinforcement element is then also arranged as the flow tube. In this way a compact construction is obtained. Because the hollow reinforcement elements can be connectable to each other, the flow tube can extend over the length of a number of foundation elements.

In one embodiment, the flow tube at the other end 5 of the foundation element opens onto an injection opening for injecting the flowable medium into the bottom to form an injected foot for the foundation pile. Such a foundation element can be used to press into the bottom, after which a foot can finally be formed after the desired length of the foundation pile has been reached. This fixes the foundation pile.

According to an aspect of the invention, it provides a foundation pile comprising a number of foundation elements according to the invention stacked on top of each other and connected to each other.

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 instance 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.

Particularly advantageous to the invention is that the fixing of the first foundation element with the second foundation element can take place simply and quickly. The foundation elements can be glued, so that time-consuming welding is no longer necessary. In particular in combination with the embodiment in which the upper end of the first foundation element is arranged to enter into a positive connection with the lower end of the second foundation element, a fast and watertight connection is possible.

The method may comprise 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. However, other connections are also conceivable (additionally), such as, for example, a snap connection, pin closure, rotary coupling, etc.

The method may further comprise the additional step D. of attaching the reinforcement element of the first foundation element to the reinforcement element of the second foundation element. In this way the complete foundation pile is capable of absorbing pressure forces and tensile forces.

The connection can be established in a simple manner by attaching the reinforcing element of the first and of the second foundation element to each other by means of a screw connection in step D.

In an embodiment of the method, the first foundation element is designed to serve as the foot of the foundation pile, or to be moldable as a foot (for example by injection of a foot).

The invention will be explained below for the purpose of illustration with reference to a figure description and associated figures, in which: 1 - a schematic side view of a first embodiment of a foundation pile with foundation elements according to the present invention;

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

FIG. 1 schematically shows a foundation pile 1. The foundation pile 1 comprises a number of superimposed foundation elements 2a-2d. Each foundation element 2a-2d comprises a foundation body 4. This foundation body is essentially made of a polymer concrete (PC). Suitable polymer concrete is, for example, polymer concrete with unsaturated polyester resin (UP), polymer concrete with methyl methacrylate (MMA), 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 reinforcing member 5 which extends substantially in a longitudinal direction L of the foundation body 4. The reinforcing member 5 can be a steel tube or rod, for example of reinforcing steel. In the embodiment shown here, the rod is of solid design, such that a relatively great strength is obtained. The length of a foundation element forms a fraction of the total length of the foundation pile.

The foundation body 4 of the polymer concrete, provided with the reinforcement member 5, provides a foundation element that is very well capable of absorbing pressure forces and tensile forces on the foundation element 2. This makes the foundation element 2 suitable to serve as part of the foundation pile 1.

It can be seen in FIG. 1 that some foundation elements 2 are placed on top of each other. In order to establish a firm connection, the reinforcing element 5 extends beyond the lower end of the foundation body 4. On the upper side of the foundation body 4, a recess is provided precisely in that the reinforcing element extends only at a distance 20 from the upper end of the foundation body 4. The recess and the protruding reinforcement element 5 of two adjacent placed foundation elements 2a and 2b ensures that the coupling of these foundation elements to each other is simpler. This protruding reinforcement element 5 and this recess (together with the end of the reinforcement element 5 in this recess) form, as it were, coupling members 71, 72 which are adapted to be connectable to each other. Preferably the reinforcement members 5 of two adjacent foundation elements 2a and 2b are coupled to each other at the coupling. It is also possible that the coupling members 71, 72 are designed in such a way that they can be easily coupled to each other. Consider, for example, an embodiment in which use is made of screw thread.

The assembly of the lower two foundation elements 2c, 2d in FIG. 1 is adapted to serve as a base for the foundation pile 1 built up from foundation elements 2a-2d. Foundation element 2d has a larger cross-section than the foundation element 2c situated above it. In this way a widened base of the foundation pile 1 is formed. The lower 7 foundation element 2d has a shape that is adapted to be drilled or pressed into the bottom. In this case, its end can be spherical 11, conical 12, rectangular, 6- or multiple-angular, pyramidal or screw-shaped, depending on the bottom structure to be penetrated.

Referring now to FIG. 2, an alternative embodiment of a foundation pile 101 is described. The foundation pile 101 again comprises a number of superimposed foundation elements 102a-102d. Each foundation element 102a-102d comprises a foundation body 104 made essentially of a polymer concrete (PC) with a concentrically placed reinforcing member 105. In the embodiment shown here, the reinforcing member 105 is a tube.

In this embodiment too, some foundation elements 102 are placed on top of each other. In order to establish a firm connection between the foundation elements, use is again made of coupling means 171, 172. These coupling means comprise the reinforcing member 105, analogous to the situation in Figs. 1, where a male-female coupling is provided between two adjacent foundation elements 102a-102b. Referring again to FIG. 2, it can be seen that additionally also the foundation bodies 104 themselves provide an improved and simplified coupling. The foundation body 104 is here embodied such that an upper end face 181 thereof closely connects to the lower end face 182 of the foundation body 104 placed above it, see the coupling between element 102a and element 102b. The lower end face 181 is embodied as a male coupling part, and the upper end face 181 as a female coupling part. When placing the two foundation elements 102 on top of each other, it is advantageous if the male-coupling part is placed on the female-coupling part, because a self-directing guide is thus created.

Another difference with respect to FIG. 1, the reinforcing element 105 is hollow. The reinforcing element 105 can hereby 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. In FIG. 2, the reinforcing element 105 is therefore also designed as a flow tube. It is of course conceivable that, in addition to the reinforcement element 105 (which may be hollow or solid), an additional tube is provided as a flow tube, although with the dual function a relatively compact foundation element 102 is obtained. It also holds that in this way the flow tube can extend over the full length of a number of foundation elements, preferably over the length of the foundation pile, because the hollow reinforcement elements 105 are designed to be coupled to each other.

The flow tube 105 can be used to form an injected foot 111 on the underside of the foundation pile 101. In that case, the flowable medium is a medium that can be injected into the bottom, to form an injected foot 111. Suitable mediums are, for example, various types of injection mortars. The skilled person will be familiar with these 10 mediums.

The two foundation elements described above can be used to form a foundation pile in a bottom. The general method described below can be used for this purpose.

The foundation element 2d, 102c, which is to form the base of the foundation pile 15, is first placed in the ground, by means of pressing, drilling, or pile driving, or another suitable technique. The installation takes place over such a length that the top side 81 of that foundation element is placed at approximately the same height as the bottom surface. A further foundation element 2c, 102b can now be attached to it. Fixing is possible with the aid of the coupling means 71, 72, 171, 172, 181, 182. It is particularly advantageous here that fixing of the first foundation element with the second foundation element can take place simply and quickly. The coupling means can comprise a screw fastening in a simple manner, for instance for the reinforcing member 5, 105. The foundation bodies 4, 104 can be glued together. For example, a 2-component adhesive can be used. However, other (additional) connections are also conceivable, such as, for example, a click connection, pin connection, or rotary coupling or the like. After the attachment, the assembly of the foundation pile thus formed can be pressed into the ground, beaten (driven), or otherwise applied, again until the further foundation element 2c, 102b is placed at approximately the same height as the bottom surface. Now a further foundation element can again be attached to the foundation pile, and this assembly can also be arranged in the ground by pressing it, striking it (pile driving), drilling, or otherwise applying it. The said steps can optionally be repeated again, until the desired length of the foundation pile has been reached.

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For the in FIG. 2, the foot 111 must then be formed. The medium for forming the injected foot 111 is introduced into the flow tube 105 from the top, and will flow down until it reaches the injection outlet 109. Here the liquid medium will flow into the soil. After curing, the base 111 of the foundation pile 101 is formed.

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.

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

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Claims (23)

1. Foundation element, comprising a foundation body which is substantially made of polymer concrete, and which comprises a reinforcing member which extends substantially in a longitudinal direction of the foundation body for absorbing compressive forces and tensile forces on the foundation element. Foundation element according to claim 1, wherein the reinforcement element extends substantially over the full length of the foundation body. Foundation element according to claim 1 or 2, wherein the reinforcement element and the foundation body are substantially concentric. Foundation element according to one of the preceding claims, wherein the reinforcement element comprises a rod or tube, preferably of a metal, such as for example steel. Foundation element as claimed in any of the foregoing claims, wherein the reinforcing element is provided at one end thereof with a coupling member which is adapted to be connectable with a further foundation element, preferably with a further coupling member of a further reinforcement element of the further foundation element. Foundation element according to claim 5, wherein the coupling member comprises a screw thread. 7. Foundation element as claimed in any of the foregoing claims, wherein at least one end of the foundation body comprises coupling means which are adapted to be connectable with an end of a further foundation element, preferably with further coupling means at an end of the further foundation element. Foundation element according to claim 7, wherein the coupling means comprise one or more recesses or protrusions in the head end of the foundation body. Foundation element according to claim 7 or 8, wherein the coupling means form a part of a male-female connection. Foundation element as claimed in one or more of the foregoing claims, wherein the foundation element is adapted to serve as a foot for a foundation pile made up of foundation elements. Foundation element according to claim 10, wherein the foundation body has a larger cross-section near an end than at an opposite end, so as to form a widened foot of the foundation pile. Foundation element as claimed in claim 10 or 11, wherein the end with a larger cross-section is arranged to be arranged in the bottom, and in particular wherein the end is conical, rectangular, pyramidal or screw-shaped. 13. Foundation element as claimed in one or more of the foregoing claims, wherein the foundation element is provided with a flow tube for passing a flowable medium through it from one end of the foundation element to the other end of the foundation element. Foundation element according to claim 13, wherein the reinforcement element is also arranged as the flow tube. Foundation element according to claim 13 or 14, wherein the flow tube at the other end of the foundation element opens onto an injection opening for injecting the flowable medium into the bottom to form an injected foot for the foundation pile. 16. Foundation pile, comprising a number of foundation elements stacked on top of each other and connected to each other according to one of the preceding claims. 17. Foundation pile according to claim 16, wherein a lower foundation element is designed according to one of claims 10 to 12 or 15. or a claim dependent thereon, for forming a foot of the foundation pile. A method for installing a foundation pile in a soil, comprising the steps of providing a first foundation element according to any of claims 1 to 15, as well as providing a second foundation element according to one of claims 1 to 30 and 9, 13 or 14, 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. A method according to claim 18, comprising the additional steps of providing one or more further foundation elements according to one of claims 1 to 9, 13 or 14, and fixing these one or more further foundation elements on the formed foundation pile. . Method according to one or more of claims 18 to 19, wherein in step B. the first and the second foundation element are glued together by means of an adhesive. A method according to claim 18 or 19, comprising the additional step D. of fixing the reinforcement element of the first foundation element with the reinforcement element of the second foundation element. 22. Method as claimed in one or more of the claims 18 to 21, wherein in step D. the reinforcement element of the first and of the second foundation element are attached to each other by means of a screw connection. 23. Method according to any of claims 18 to 22, wherein the first foundation element is designed according to one of claims 10, 11 or 12, or a claim dependent on it, for forming a base of the foundation pile.