NL1017276C2 - Reinforced concrete construction method with integrated thermal break and construction obtained by this method. - Google Patents

Description

Construction method in reinforced concrete with integrated thermal break and construction obtained with this method.

5 DESCRIPTION:

Field of the invention.

The present invention relates to a reinforced concrete construction method with integrated thermal break, which is particularly suitable for building structures in which the insulation is provided on the inside, as will be described below.

The invention also relates to the construction obtained with the said method.

15 State of the art.

Today, construction techniques increasingly take into account the general insulation of buildings, both thermal and sound insulation. A particular problem here arises from the need to eliminate thermal bridges, which result from the non-continuity of the insulation imposed by the specific requirements of the building structure.

Insulation elements are generally designed as rigid or semi-rigid insulating plates and are mounted either on the inside of the building, these plates forming the inner wall which must then be finished later with a decorative covering (filler, paint or carpet), or on the outside, where these insulating elements are generally located in the space between the two walls of a double wall.

The present invention focuses primarily on the first type of construction.

Regardless of the type of construction, one of the main difficulties is the thermal bridges created by the local interruption of the insulation by the concrete structure.

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The adverse effects of these thermal bridges, especially due to condensation and mold, make the introduction of thermal breaks indispensable.

The document EP 0 822 299 A describes an element intended to make the connection between two concrete building elements with a separating space between them.

This element aims to support balconies with a view to absorbing different forces, such as the bending moment, the tensile and compressive forces, and the shear.

As this element has been described, it essentially consists of a plate serving as a connecting piece, which is connected to two parts of a thickness greater than the plate, these parts each being provided with extensions at least on one side.

It is important to note that this document does not relate to a reinforced concrete construction method with integrated thermal break, and that the description of this document makes no allusion to the processing of an insulation, nor of the relative insertion of this insulation in the construction.

Document EP 0 959 188 A also describes a reinforcing element for joints that can expand, including a tubular section. This document is not intended to avoid thermal bridges.

Document US 2,608,141 refers to an element intended to transfer forces when joining floors, without making direct reference to thermal bridges.

Document DE 84 17 440 U (utility model) describes a connecting element (console) for connecting a balcony slab to walls, etc.

Object of the invention

The object of the invention is to propose a construction method with a thermal break by means of concrete elements that run through the insulation, in a simple and efficient manner, without requiring fundamental changes to the construction method.

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The method is designed in such a way that significant additional costs are avoided, both in terms of materials used and in terms of stability requirements imposed on the construction.

Main features of the invention.

The invention relates to a construction method in reinforced concrete with integrated thermal break, characterized in that reinforcements or reinforcement reinforcements are placed in a head box on either side of an insulation, while a pin is inserted between spacer elements of the reinforcement and this pin is designed to absorb the shear of the structure, and further characterized by pouring the concrete so that it envelops the reinforcements, the spacers and the pin.

According to a preferred embodiment of the invention, the assembly formed by the reinforcements, the spacers, the pin and the insulation is prefabricated.

It is sufficient to bring the prefabricated element on site as the construction progresses. Nothing stands in the way of assembling the elements on the construction site.

The configuration of the prefabricated element is preferably symmetrical with respect to a transverse plane, this in order to avoid possible incorrect placement of the whole in the head box.

It is advantageous if the pin consists of a tubular element. These elements can have a round or polygonal cross section, and preferably a square cross section.

The tubular element can be filled with an insulating foam.

Preferably spaced elements in serrated stainless steel are used.

The placement of the pin relative to the spacers can be ensured by welding, tying, or clamping, or by any other method.

In one embodiment, the insulation is located on the inside of the structure.

In another embodiment, the insulation is on the outside of the structure.

The invention also relates to a construction obtained using 1017276¾4 of the method according to the invention.

Brief description of the drawings.

FIG. 1 shows a schematic view of a vertical section in side view (in part) of the embodiment of the reinforcement, the insulation and a connecting pin according to the invention for the part of the construction comprising a floor and a side wall.

Fig. 2 is a sectional view along A-A of FIG. 1.

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Detailed description of the invention.

According to the method recommended by the invention, reinforcements or reinforcement reinforcements 7 are provided on both sides of the insulation 3, which are folded in "U" shape 15 and which consist of two parts 7A and 7B, connected by a central part 7C. The central part 7C is kept at a distance from the insulation 3 by means of the spacers 5 located between the insulation 3 and the central part 7C of the reinforcement.

However, in order to be able to absorb the transverse forces (shear) resulting from the interruption of the reinforcement 7, a pin 1 is arranged between the sections 7A and 7B of the reinforcement, and between the spacing elements 5, in the manner shown in figure 2.

The figures show a floor 9 which is poured in a head box (not shown) and a side wall 11 which can for instance be formed by a wall in reinforced concrete or by a masonry wall.

The spacers 5 are depicted as slightly deformed such that they allow the pin 1 to be centrally positioned equidistant from the portions 7A and 7B of the armament.

The pin 1 itself is preferably a tubular element shown in the figures as a tube of square cross-section.

However, it is easy to imagine that other shapes, both of the spacers 5 and of the pin, are possible, while also the positioning of the pin 1017276 <5 can be done by various means, such as welding, tying or clamping, etc.

The use of a tube of square cross-section, which is customary in commercial construction, lends itself particularly to the configuration of the spacer elements 5 shown in Figure 2.

5 The stability calculation for the pin 1 primarily involves the absorption of the shear by this pin, as well as any tensile or compressive force (generally weak) that may result from thermal expansion and climatic effects. Calculation of the reinforcement incorporated in the concrete on both sides of the insulation is done independently and individually for the parts on either side of the insulation.

It should be noted that the recommended method does not fundamentally change the actual construction method, while still obtaining an efficient thermal break that avoids the effect of thermal bridges.

It is not excluded that additional insulation is applied between metal parts in contact with each other, for example in the form of a PVC jacket of the pipe 1.

Practical implementation example of the method.

20 Reinforcements with a diameter of 10mm BE500S, which are calculated on a concrete floor of 18cm thickness, are fitted as shown in the figures, using spacers 5 with a diameter of 14mm in serrated stainless steel.

In addition to its known function, this knurled design has the advantage of improving the adhesion of the concrete and limiting the local pressure on the concrete, while ensuring the correct positioning of the pin 1 between the reinforcements 7 as well as the covering of the parts 7C relative to the insulation 3.

The pin 1 consists of a tube with a square cross section (40 X 40 mm) in stainless steel with a wall thickness of 3 mm.

The thickness of the insulation is sufficient to ensure thermal and acoustic insulation.

Usually, a distance of the order of 1 meter between adjacent pipes in a floor is sufficient to absorb the shear forces.

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Although a preferred embodiment of the invention is described here, it should be emphasized that this is only an embodiment which is advanced by way of illustration, without limiting this invention. Several different embodiments, depending on the choice of materials, the shape and the assembly of the structural elements, remain within the scope of the invention.

It is true that the drawings and the preferred embodiment refer to a floor and a side wall. Other configurations are possible which also have the features of the invention, such as an inner wall and a side wall.

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Claims (10)

Reinforced concrete construction method with integrated thermal break, characterized in that reinforcement or reinforcement reinforcement (7) is placed in a head box on either side of an insulation (3), while a pin (1) is placed between 5 spacing elements (5) of the reinforcement which runs through the insulation (3) and where this pin (1) is designed to absorb the shear of the construction, and further characterized by pouring the concrete so that it reinforces the reinforcements (7), the spacers (5) and the pin (1). Method as described in claim 1, wherein the assembly formed by the reinforcements (7), the spacer elements (5), the pin (1) and the insulation (3) is prefabricated. The method as described in claim 2, wherein the configuration of the prefabricated element is symmetrical with respect to a transverse plane. Method as described in any one of claims 1 to 3, wherein the pin (1) 15 consists of a tubular element. Method as described in claim 4, wherein the cross section of the tubular element is polygonal, preferably square. Method as described in claim 4 or 5, wherein the tubular element is filled with an insulating foam. Method as described in any of the preceding claims, wherein spacers (5) are used in serrated stainless steel. A method as claimed in any one of claims 1 to 7, wherein the insulation (3) is located on the inside of the structure. Method as described in any one of claims 1 to 7, wherein the insulation 25 (3) is located on the outside of the structure. Construction obtained using the method according to any of the preceding claims. 1017276 «