NL1029310C2 - Method is for installation of second building component at required height on first building component such as foundation pile, second component formed by beam or wall - Google Patents

Abstract

The method is for the installation of a second building component (6) at a required height on a first building component (1), such as a foundation pile. The second component is formed by a beam or wall. A strip (4) is placed on the first building component which has an adjustment component (5,5') with a thickness necessary for the height installation. The adjustment component has a screw thread for upward rotation relatively to the strip to the required height. The strip is provided with a hole for holding the adjustment component in position and the strip and adjustment component are capable of support of the load of the second building component. The second building component is then placed on the adjustment component. Between the first and second building components a hardenable mass of low-shrinkage mortar is fitted.

Description

Method for placing a building element at a desired height

The present invention relates to a method for placing a second building element on a first building element at a desired height.

When building structures, such as houses, a lot of time is lost in setting building elements, such as piles and walls. For example, a pile cannot be driven into the ground with great precision. The height can thus easily deviate a few centimeters from the desired position. Adjustments are therefore needed before another building element can be placed or connected to the building element mentioned earlier. This is a time-consuming, and therefore expensive, job.

The present invention has for its object to provide a fast and inexpensive method of the above-mentioned type.

To this end, the method according to the invention is characterized in that a) a strip is laid on the first building element, wherein either 20 a) the strip is provided with an adjusting element with a thickness required for raising; or a2) an adjusting element provided with screw thread is brought to the desired height by turning in height relative to the strip; wherein the strip) is provided with a hole for holding the adjusting element in place, and the strip with the adjusting element is capable of bearing the load of the second building element, and b) the second building element is placed on the adjusting element.

The object can thus be achieved in a simple manner. This is done, for example, by placing a strip of metal on the first component, and by placing an adjusting element of the desired thickness on the strip. The adjusting element is chosen such that the top side of the adjusting element is at the desired height necessary for being able to place the second building element. To keep the adjusting element in place, the strip is provided with a hole, and the adjusting element has a protrusion which fits into that hole. Instead of having to choose an adjusting element with a suitable thickness, it is advantageous to use an adjusting element with a height that is adjustable relative to the top of the strip. A bolt or threaded end and a nut can be envisaged here, wherein the end of the bolt or threaded end fits into a hole in the strip. By turning the bolt or threaded end relative to the nut, the height at which the head (or other end if the head of the bolt is below the strip and the nut is above the strip) of the bolt ( wire end) can be varied. Even more attractive embodiments are described in the subclaims. The strength properties of the strip and the adjusting elements are determined by the weight of the second building element to be placed. The ordinary person skilled in the art can simply choose on the basis of calculations or, possibly on the basis of some simple tests, materials and dimensions suitable for the strip and the element. When reference is made in the present application to "being able to bear the load of the second building element", it is not excluded that the adjusting element will bend. After all, the ordinary person skilled in the art can take account of the degree of bending when adjusting the height of the adjusting element.

i

From JP 2002-194.748 a method is known for connecting a column 2 to a pile 1. For this purpose, in contrast to the present invention, it is necessary to provide the head of the pile with a threaded bush in which a bolt 13 is turned. A load-bearing element 6 attached to the column is clamped against the pile by the bolt, which, in contrast to the adjusting elements according to the present invention, is tensioned.

Hereby, filler plates 15 brought between the load-bearing element and the head of the pile provide for the vertical alignment.

In general it will be decided to connect the second building element to the first building element, which is preferably done by applying a curable mass between the first and the second building element, preferably a shrink-free curable mass such as shrink-free mortar.

This preferred embodiment will often be used in practice, since the strip with the adjusting element will indeed be able to support the second building element, but not necessarily also the entire construction placed on the first building element.

Thanks to the curable mass, a higher pressure-resistant structure is obtained. For optimum carrying capacity, the space between the first and the second building element will be completely filled.

j 3

In order to achieve this effectively, formwork can be provided over at least a part of the circumference of the first building element. The curable mass will generally be selected from those curable masses that show little or no shrinkage or expand little on curing. These curable materials are known as "low-shrink" and are known in the art and commercially available.

A preferred embodiment is characterized in that the second building element has a continuous cavity which debouches at the first building element, wherein the curable mass is introduced from above into the cavity up to the first building element.

The gap between the first and the second building element can thus be filled in a simple manner.

To provide a more rigid connection, it is preferable if the first building element has a non-continuous cavity, the curable mass being introduced into the cavity of the second building element for filling the cavity of the first building element and connecting from the first with the second building element.

The non-continuous cavity can either be present before the first building element is placed, or be applied after the first building element has been placed, for example by means of drilling or by closing a through-going cavity at a distance from the top. the first building element.

A preferred embodiment for connecting the first and the second building element is characterized in that a reinforcement element is inserted into the through-cavity of the second building element into the non-continuous cavity of the first building element! such that the reinforcing element protrudes into both cavities, before the curable mass is introduced into the cavity of the second building element for filling the cavity of the first building element and connecting the first to the second building element.

In particular if the strip is made of metal, it will be preferable if the through-going cavity of the second building element debouches near the strip and the curable mass covers the strip.

This protects the strip against corrosion.

In order to ensure that the height determined by the adjusting elements is not easily disturbed during the placing of the second building element and the second element is stably placed on the first building element 4, it is preferable that the strip is provided with two adjusting elements near its ends and the second building element is a wall or beam that is placed transversely to the strip, on both adjusting elements.

For the same reason, it is preferable for the strip to protrude on two sides, and for the adjusting elements to be arranged in both overhanging ends (i.e. 1 adjusting element in each overhanging end).

It is preferred here that the distance between the vertical axes of the adjusting elements is equal to or not much larger than the width of the first building element plus the thickness of 1 adjusting element, so that the strip with the adjusting elements cannot shift easily or rotation. Not much greater depends on the allowable shift or rotation, and depends on the dimensions of the building elements used. If the possible shift or rotation is greater than desired, a strip will be used with which the adjusting elements protrude less far. This is easy to determine experimentally and requires no further explanation.

According to a preferred embodiment, in order to enable continuous adjustment over a large working range, the strip and the adjusting elements are provided with screw thread.

The required height can be adjusted very accurately in this way, and it is also possible to turn an adjusting element that is turned too far back. The adjusting elements in this case are, for example, a thread end or a bolt.

According to an alternative, cheaper embodiment, the strip is provided with holes near its ends and the adjusting element comprises a nut and a matching threaded end or matching bolt, the holes having a diameter at least as large as the outer diameter of the thread of the threaded end or the bolt and smaller than the outside diameter of the nut.

For an easy placement it is preferred in this embodiment if the threaded end / bolt has a length such that the center of gravity of nut + threaded end / bolt lies below the hole 35 of the strip. This helps prevent the adjusting element from falling out of the hole in the strip. In this case, the use of a (relatively expensive) screw thread in the holes of the strip can be dispensed with.

5 ί

In other words, the strip is preferably a strip of which at least one of the holes is not threaded.

The present invention will now be elucidated with reference to the drawing, in which Figs. 1a-f and 2a-f show the successive steps of the method according to the invention, Fig. 1 a top view and Fig. 2 a schematic vertical section proposes.

In Figure 1a, 2a a hollow pile 1 arranged in the bottom A (a first component in the terminology of the description introduction) is shown with a through-going cavity 2. For connecting the hollow pile 1 with a beam 6 (a The second building element in the terminology of the introduction to the description: Figs. le, f and 2e, f) the hollow pile 1, which here has a continuous cavity 2, is provided in a manner known per se with a non-continuous cavity 9 at the top of the hollow pile 1, using a cover or foam plug clamping into the cavity 2, which is covered with concrete, yielding a concrete plug 3 (Fig. 2b). A metal strip 4 (fig. 1c, 2c) is laid on the top of the pile 1 which is provided with two adjusting elements 5, 5 '. In this embodiment, the strip 4 is provided near its ends with two holes 10, 10 '(Fig. 2c) with screw thread into which two adjusting elements in the form of bolts 5, 5' are inserted (Fig. 2d). By turning the bolts 5, 5 'the upper sides of the bolts 5, 5' can be brought to a height, which height (after any bending) is equal to the height that the bottom side of the beam 6 must be. In the embodiment discussed here, the pile 1 is connected to the beam 6. A formwork B is fitted around the pile 1. The formwork B is formed, for example, from cardboard or wood. The wall / beam 6 is placed on the adjusting elements 5, 5 'of the strip 4. In the embodiment shown, the wall / beam 6 is provided with a continuous cavity 7 (Figs. 1e, f and 2e, f). A reinforcing bar 8 is introduced into the through-going cavity 7 up to the concrete plug 3. Subsequently, low-shrinking concrete mortar (e.g., Beamix Shrink-poor Casting Mortar, Beamix, Amsterdam, the Netherlands) is poured into the through-through cavity 7 until the formwork B is filled. The cavity 7 is thereby preferably at least partially filled. After hardening, the formwork B can possibly be removed.

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In order to prevent the strip from sliding, it can be fixed on the first building element, for example with glue, double-sided adhesive tape, etc.

It will be apparent to those skilled in the art in the light of the description that the invention can be varied in various ways within the scope of the appended claims. For example, the adjusting elements do not have to protrude beyond the pile. In general, it will be ensured here that the adjusting elements do not deposit against the top of the pile 1, although in case use is made of a method in which the height of the adjusting elements is chosen. Adjusting elements that do not protrude beyond the pile will be chosen if the second building element placed thereon is no wider than the pile. In the case of a first building element which has no cavity 9 at the top, a non-continuous cavity 9 can be provided by drilling a hole at the top. If desired, a reinforcing bar 8 can be placed or attached in it, for example by means of gluing.

The wall / beam 6 is then placed such that the reinforcing bar 8 protrudes into cavity 7. Mortar can then be used to fill the cavity 7.

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Claims (12)

Method for placing a second building element (6) at a desired height on a first building element (1), characterized in that a) a strip (4) is laid on the first building element (1), wherein i or al) the strip (4) is provided with an adjusting element (5, 5 ') with a thickness required for raising; or a2) an adjusting element (5, 5 ') provided with screw thread is brought to the desired height by turning in height relative to the strip (4); the strip (4) being provided with a hole for holding the adjusting element in place, and the strip (4) with the adjusting element (5, 5) being able to carry the load of the second building element (6), and b) the second building element (6) is placed on the adjusting element (5, 5 '). Method according to claim 1, wherein the second building element (6) is connected to the first building element (1). 20 Method according to claim 2, wherein a curable mass is applied between the first and the second building element (1 and 6, respectively). The method of claim 3, wherein the curable mass is shrink-free mortar. Method according to claim 3 or 4, wherein the second building element (6) has a continuous cavity (7) which ends at the first building element 30 (1), wherein the curable mass is brought into the cavity (7) from above the first building element (1). 6. Method as claimed in claim 5, wherein the first building element (1) has a non-continuous cavity (9), wherein the curable mass is introduced into cavity (7) of the second building element (6) for filling the cavity ( 9) of the first building element (1) and connecting the first to the second building element (1 and 6, respectively). 1029310 Method according to claim 6, wherein a reinforcing element (8) is inserted into the through-hole (7) of the second building element (6) into the non-through-hole (9) of the first building element (1) such that the reinforcing element (8) extends into both cavities (9 and 7), before the curable mass is introduced into cavity (7) of the second building element for filling the cavity (9) of the first building element and connecting the first with the second component (1 or 6). Method according to claim 7, wherein a formwork (B) is provided over at least a part 15 of the circumference of the first building element (1) and at least at the location of the strip (4). The method according to any of claims 5 to 7, wherein the through-going cavity (7) of the second building element (6) debouches near the strip (4) and the curable mass covers the strip (4). A method according to any one of the preceding claims, wherein the strip (4) is provided near its ends with two adjusting elements (5, 5 '), and the second building element (6) is a wall or beam which is transverse to the strip ( 4) is placed on both adjusting elements (5, 5 '). ! | 10. Method as claimed in claim 9, wherein the strip (4) protrudes on two sides, and the adjusting elements (5, 5 ') are arranged in both protruding ends. A method according to any one of the preceding claims, wherein the strip (4) and the adjusting elements (5, 5 ') are provided with screw thread. 30 A method according to any one of the preceding claims, wherein the strip (4) has holes (10, 10 ') near its ends and the adjusting element (5, 5') comprises a nut and a matching threaded end or matching bolt, wherein the holes (10, 10 ') have a diameter at least as large as the outside diameter of the thread of the threaded end or the bolt and smaller than the outside diameter of the nut. 1 029 3 1 0