BE1030560B1 - Method for constructing a wall, construction elements intended for the application of the process, and building obtained by application of said process - Google Patents

Abstract

Method of constructing a wall of a building where use is made of a range comprising at least five types of construction elements (p(1) to p(5i)) which are different in height from each other, four of these types of construction elements having per type a predetermined height (h(1), h(2), h(3), h(4)) and the at least a fifth type is composed of construction elements forming part of a first set (p(5i)) of prefabricated construction elements having heights (h(5i)) different from each other, and in that before constructing the wall of a predetermined height H under ceiling and taking into account a screed having a height h(c) applied to a slab on which the wall will be built, we select from said range of construction elements those which are necessary to obtain said height H by making use of a first mathematical formula f1 H= h(1)+h(2)+h(3)+h(4)+h(5i)-h( c ).

Description

Method for constructing a wall, construction elements intended for the application of the process, and building obtained by application of said process

The present invention relates to a method of constructing a wall of a building, in particular a residential building, which wall is constructed using prefabricated construction elements forming part of a range comprising at least five types of elements construction elements which are different in height from each other, four of these types of construction elements having per type a predetermined height and the at least a fifth type is composed of construction elements forming part of a first set of prefabricated construction elements having different heights between them.

Such a construction method is known from US patent 1,857,995.

Following this known process, a range of different types of construction elements are used where the construction elements of each type have a different height. The aim of this process described in this US patent is to produce a wall which gives the appearance that it would be constructed of raw stones whereas it is constructed using prefabricated construction elements.

It should also be noted that French patent application 2,590,299 describes a construction process according to which prefabricated panels are used, for example concrete, having the height of one floor and a length of 30 cm. The panels are mounted like a palisade, by gluing the vertical fields of the panels provided with rebates and by locking them with pins.

It should also be noted that building walls on site using conventional blocks has several disadvantages, such as for example a long completion time, a significant amount of labor, a large physical demand on masons and above all the obligation to cut blocks necessary to arrive at the correct heights of the desired walls. Manufacturing complete, custom-made walls in the factory also presents a series of disadvantages, such as high final costs, long lead times, significant means of transport and handling, as well as reduced constructive flexibility.

The aim of the invention is to produce a construction process which is easy to carry out, industrializable, economical and ecological, even allowing reuse of construction elements after dismantling of the wall at the end of the life of the building.

To this end, a method of constructing a wall according to the invention is characterized in that, before constructing the wall, a predetermined height H under the ceiling and taking into account a screed having a height h(c) applied on a slab on which the wall will be built, we select from said range of construction elements those which are necessary to obtain said height H by using a first mathematical formula f1

H= h(1)+h(2)+h(3)+h(4)+h(51)-h(c) which wall being constructed by applying a layer of binder to the slab, on which layer of binder we place the selected construction elements of type p(1) and height h(1), then we place on the elements of type p(1) the selected elements of type p(2) and height h(2) > h(1) by using a layer of binder applied between the elements of type p(1) and p(2), we then place on the elements of type p(2) a succession either in order, or in disorder, of the type of construction elements, composed of selected elements of type p(3) and selected elements of type p(5), and each time a layer of binder is applied between two superimposed elements, and in that we finalize the construction of the wall by placing on said succession the selected elements of type p(4), which elements of type p(4)

being elements designed to take up loads exerted in line with the openings present in the wall and ensure a belt around said walls.

The use of a range comprising at least five types of construction elements and the fact of constructing the wall by super- and juxtaposition of these elements makes it possible to use prefabricated elements which are easy to manufacture, transport and install. and if necessary dismantle. The method according to the invention makes it possible to produce walls of different desired heights without it being necessary to cut fractions of the construction elements horizontally. The use of the mathematical formula f1 makes it possible not only to select the construction elements necessary to obtain the desired height of the wall, but also to compensate for a variation in the screed height and to arrive at the correct opening height and ceiling height. . The use of a binder between two superimposed elements makes it possible to compensate for dimensional manufacturing tolerances and to avoid punching effects. We also considerably limit the waste that would have been generated by cutting known construction elements.

Preferably, for the first set (p(5i)) of prefabricated construction elements, elements having heights (h(51)) different from each other located between 1cm < h(5i) = 49cm are used. This makes it possible to cover most cases of screed and wall height.

A first embodiment of a method according to the invention is characterized in that each type of construction element has a predetermined length |(x) and in that to build the wall of a length L, we makes use of a second mathematical formula f2

L = nl(x) + gl(x) where n is an integer and 0 < g <1 indicates the fraction of the length (x), and we juxtapose the n construction elements of the same type and in case g#0 we finalize a row of juxtaposed construction elements by adding a fraction of length gl(x). This makes it possible to determine in advance the number of construction elements necessary for the construction of the wall and thus to optimize construction and reduce transport costs.

The invention will now be described using the drawings which illustrate examples of wall constructions constructed by applying the process according to the invention. In the drawings:

Figure 1 shows a first example of two walls constructed by applying the process according to the invention;

Figure 2 shows a second example of two walls constructed by applying the process according to the invention;

Figure 3 illustrates an example of the application of the mathematical formula f1 which makes it possible to select the construction elements;

Figure 4 shows a third example of two walls constructed by applying the process according to the invention; And

Figure 5 shows a fourth example of two walls constructed by applying the process according to the invention. ;

In the figures the same reference has been assigned to the same element or to a similar element.

Figure 1 illustrates an exterior wall 1 and an interior wall 2 of a building, in particular a residential building. It will however be clear that the invention is not limited to the construction of residential buildings and that other types of buildings such as offices, commercial or industrial spaces can also be constructed by application of the present invention. The two walls are built on a slab 3. Preferably the slab is built by pouring concrete. The construction elements used are part of a range comprising at least five types of construction elements (p(1) to p(5)).

Four of these types of building elements (p(1), p(2), p(3), p(4))

having by type a predetermined height (h(1), h(2), h(3), h(4)) which is different in height from the others. The p(4) type elements are elements designed to take up loads exerted in line with the openings present in the wall and ensure a belt around the walls. The at least fifth type of construction element (p(5i)) is composed of a first set of prefabricated construction elements having different heights preferably located between 1cm < h(5i) = 49cm. In the example shown in Figure 1 the construction elements p(1), p(2), p(3) and p(5i) were all manufactured to a length |(x) determined according to the length of the segment of wall to be built of which they are part. Of course it is also possible to manufacture construction elements having a predetermined length. The length of the construction element p(4) will preferably be determined by the total length of the wall to be constructed.

The fact of using at least five types of construction elements allows, before building the wall on slab 3, to be selected from the range of construction elements, for a wall having a predetermined height H under ceiling, a predefined bay height and for a screed 4 having a height h(c), the types of construction elements to use. For this purpose we use a first mathematical formula f1

H= h(1)+h(2)+h(3)+h(4)+h(5i)-h(c) .

This selection allows on the one hand to make use of the range of prefabricated construction elements which can therefore be stored, and on the other hand to construct the wall, so to speak, by assembly.

This will facilitate construction and make it faster, more economical and more ecological, because it will not be necessary to make horizontal cuts to achieve the height H of the wall.

The use of the range of prefabricated construction elements also allows them to be reused for subsequent construction. Indeed, as the wall is erected by superimposing and juxtaposing the construction elements, these same elements can be dismantled when the building must either be redeveloped or disappear from the place where it was placed. The parts having determined heights, they can easily be re-used for a subsequent construction which will be built with the application of the first mathematical formula fl.

The construction elements in the range are sized to meet the standards for screed heights, openings and ceiling heights used in the countries in which they will be used and are of density, shape, hollow or solid, reinforced or not. to maintain optimal constructive flexibility. The process according to the invention makes it possible to reduce the cost of walls and construction times, to improve safety on site and quality, to respond directly to demand by storing standardized elements from the range, to not generate cutting waste, and be reusable at the end of the masonry's life. The construction elements preferably have smooth side walls without grooves or ribs, which facilitates their manufacture.

In the example of Figure 1, the construction of the wall begins with the application of a layer of binder or another pasty and sticky substance on the slab 3. Preferably the layer of binder or the pasty and sticky substance will have a low adhesion sufficient to connect the construction elements together and allowing easy dismantling later when the building must be dismantled. On this layer we place a construction element of type p(1) and height h(1) selected using the formula f1. Then we place on the element of type p(1) an element of type p(2) and of height h(2) >h(1) selected using the formula f1. The p(2) type element is applied to the p(1) type element using a layer of binder preferably having a thickness between 3 mm and 15 mm. We then place on the elements of type p(2) a succession, either in order or in disorder, of the type of construction elements composed of selected elements of type p(3) and selected elements of type p( 5) using the mathematical formula f1. We finalize the construction of the wall by placing the elements of type p(4) on said succession. Between two superimposed elements, a layer of binder is applied each time which preferably will have a thickness between 3 mm and 15 mm.

In the example illustrated in Figure 1, the construction element of type p(3) and that of type p(5) are each formed in one piece and the element of type p(5) is placed on the element of type p(3). Of course it is also possible to place the element of type p(5) on that of type p(2) and to place the element of type p(3) on the element of type p(5).

Figure 2 shows a second example of wall construction. In this second example element of type p(3) (p(3-1) and p(3-2)) and that of type p(5i) (p(5'i) and p(5”1)) is each time formed by two pieces where the two pieces of type p(3) have the same predetermined height, while the two pieces which form type p(5i) can have different heights. So in this example the element of type p(5i) is composed of two pieces p(5'i) and p(5”i) of which one p(5'i) is placed between the two pieces of type p (3) and the other p(5”i) on the second piece of the type element p(3). It is also possible to superimpose the two pieces of construction elements of type p(5'i) and p(5”1) on top of each other. Of course other sequences of fitting the parts of the construction elements p(3-1) and p(3-2), p(5'i) and p(5”i) are also possible, as in the example shown in Figure 5.

It will be noted in Figures 1 and 2 that for the exterior wall 1 above the openings for a door 5 or a window 6 we do not use an element p(5”i) in order to allow the door and the window can extend to below the element p(4). On the other hand, when it comes to an interior wall 2, use is made of a piece p(5”i) which overhangs the entire width of the door.

The layer of binder or other pasty and sticky substance applied to slab 3 is preferably 1cm. It is also possible to apply between two vertical sides of two juxtaposed elements a vertical joint which is for example formed by polyurethane foam. The p(1) type construction element serves as the basis for the construction of the wall and makes it possible to compensate for the variation in level of the slab. The construction elements are preferably made of ordinary concrete based on recycled aggregates having a mass/volume ratio of 2,200 kg/m°. However, the element p(2) can also be made of insulating concrete having a mass/volume ratio of less than 700kg/m3. Finally, a hybrid solution combining different densities, such as low and insulating, or strong and load-bearing) is also possible. This p(2) type insulating construction element is used to form a thermal break with the slab on which the building is constructed. Other construction materials, such as terracotta, or a sand-lime material, can also be used to manufacture the construction elements.

The construction element of type p(1) preferably has a height of maximum h(1)= 5cm and a length of 120cm. The p(2) type construction element preferably has a height of h(2) = 40cm and a length of 120cm. The construction element of type p(3) preferably has a height of h(3) = 160cm and a length equal to the length of the wall. This construction element is preferably made of honeycomb type concrete. When the construction element of type p(3) is formed of two pieces p(3-1) and p(3-2), each piece preferably has a height h(3-1) = h(3-2 ) = 80cm and a length of 120cm.

The construction element of type p(4) preferably has a height h(4)= 30cm and a length which will be determined according to the length of the wall. This element forms a load-bearing beam preferably made of reinforced concrete and is used in particular to take up the loads at the right of the bays.

The construction elements of type p(5i) are used to take into account the height h(c) of the screed 4 which can vary for example between 7 and 24 cm and to take into account the height H of the wall which can for example be of 240cm, 250cm or 260cm under the ceiling and thus arrive at the right height under the beam formed by the element p(4). The p(5i) type construction elements preferably have a length between 0.80m and 1.20m. These construction elements are part of a first set of elements p(5i) of prefabricated constructions having heights h(5i) different from each other located between 1cm < h(5i) = 49cm. Optimal flexibility of the first set of elements p(5i) is obtained if the first set includes elements which each vary in height by 1cm between them, because this allows adjustment to the nearest centimeter.

When the construction element of type p(5i) is formed of two parts p(5'i) and p(5”1), the part p(5'i) will be used to take into account the height h(c ) of the screed 4 and the part p(5”i) will be used to take into account the height

H of the wall.

In the example illustrated in Figure 2 use is made of a part p(5'i) having a height h(5'i) located between 1cms h(5'i) = 24cm and a part p(5”i ) having a height h(5”i) located between 5cm <= h(5”i) = 25cm.

So for example the first game can include three elements p(5'1), p(5'2) and p(5'3) where h(5'1) =7cm, h(5'2) =15cm and h (5’3) =22cm and three elements p(5”1), p(5”2) and p(5”3) where h(5”1) =5cm, h(5”2) =15cm and h (5”3) =25cm. Alternatively the element p(5'3) can be formed by a combination of the elements p(5'1) and p(5'2) and the element p(5”3) can be formed by a combination of two elements p (5”1) and an element p(5”2).

Figure 3 illustrates an example of a wall having a predetermined height H under ceiling where H = 250 cm and constructed by the application of the first mathematical formula f1. In this example the screed has a height of h(c) = 22cm. Using the formula f1 we will choose an element p(1) of h(1) = 5cm, an element p(2) of h(2) = 40cm, an element p(3) composed of pieces p(3 -1) and p(3-2) of height equal to 80cm, an element p(4) of h(4) = 30cm, an element p(5'3) of h(5'3) = 22 cm and a element p(5”1) of h(5”1) = 15 cm. Thus the application of the first mathematical formula f1 gives: 250 = 5+40+(80+80)+30+(22+15) -22

We will therefore see that the mathematical formula f1 allows us to choose from the range the elements p(1) to p(5i) needed to build a wall with a height of 250cm and where a screed of h(c) = 22 cm is applied to the slab.

In one embodiment each type of construction element has a predetermined length |(x). In this example ((x)= 120cm. To build the wall of length L, we use a second mathematical formula f2

L = nl(x) + glx) where n is an integer and O< g <1 indicates the fraction of the length (x). To build the wall we juxtapose the n construction elements of the same type horizontally and in the case where g#0 we complete a row of construction elements by adding a fraction of length gl(x) obtained either by selection in a available range where several lengths are available, or by cutting beforehand during manufacturing.

Figure 4 shows a third embodiment of two walls constructed by application of the method according to the invention. This embodiment differs from that shown in Figures 1, 2 and 5 in that the construction elements do not all have the same length, but for each type of construction element there are elements of different lengths. lengths. Indeed, for each type k of construction element p(k) (1s k <= 5) a second set is provided comprising m construction elements p(km) of said type p(k) each having a length I(km ) predetermined. To build the wall of length L, we will apply a third mathematical formula f3 k, m

L= 2 f (I(km)) 1 where f is the number of elements of a type p(km).

So for example for construction elements of type p(km), we plan to build the walls with the following element lengths:

For elements of type p(1): (11) = 80cm; I(12) = 40cm; (13) = 20cm; 1(14) = 10cm.

For elements of type p(2): I(21) = 120cm; I(22) = 60cm; I(23) = 30cm; (24) = 15cm; I(25) = 7cm; (26) = 3cm; (27) = 2cm; (28) = 1cm.

For elements of type p(3): I(31) = 120cm; I(32)=60cm; (33) = 30cm; (34) = 15cm; (35) = 5cm; (36) = 3cm; 1(37) = 2cm; (38) = 1cm.

For p(4) type elements: preferably maximum 8m

For elements of type p(5): (51) = 120cm; I(52) = 60cm; (53) = 30cm; I(54) = 15cm; I(55) = 10cm; (56) = 5cm; (57) = 3cm; (58) = 2cm; (59) = 1cm.

It goes without saying that these are examples and of course other lengths can be provided.

Thus we will see in Figure 4 that the interior wall 2 comprises for the elements p(3m) placed on the elements p(2m) two elements of type p(3-1) of length (31), an element of type p( 3-1) of length (32), an element of type p(3-1) of length I(33), an element of type p(3-1) of length I(34), and two elements of type p (3-1) of length I(35). For the elements p(3m) placed on the elements p(5m) one element of type p(3-2) of length (31), three elements of type p(3-2) of length I(32), one element of type p(3-2) of length I(33), an element of type p(3-2) of length |(34), and two elements of type p(3-2) of length (35).

We will also see on the exterior wall 1 that we can combine the elements of type p(5i) with those of type p(3) by placing them vertically and not horizontally. This allows you to adjust the length of the wall.

To allow passage on either side of an interior wall, when installing the construction elements, interruptions 7 are left between at least two successive p(1) type elements. This makes it possible to pass heating pipes, sanitary pipes or tubes to house electrical cables from one room to another in the building.

It is also possible to arrange reservations in line with the bays to allow the passage of pipes for electrical cables. This avoids damaging the construction elements.

If the elements are provided with cells, these cells can be used for the passage of tubes or pipes.

To allow subsequent finishing of the walls, a plasterboard or wood fixing system can be provided. This can be done by reservations in the construction elements, by fixing elements or by adhesive strips. The space between the wall and the plate can also be used for technical purposes, such as for housing electrical cables.

Preferably the walls do not fit into each other, but are secured together using metal or plastic elements, fixed in the elements and embedded in the binder joint, and surrounded in the upper part by elements of type p(4) themselves docked together.

Preferably the construction elements include through holes 8 intended to introduce a gripping element for a crane.

This facilitates the handling of construction elements.

In the drawings only the walls of a ground floor are included. It goes without saying that the invention is not limited to ground floor walls and that it also applies to walls of upper floors, cellars, ventilated spaces and floors under a roof. roof. For this last type of wall we then provide construction elements which have an angled side face.

Claims (9)

1. Method for constructing a wall (1,2) of a building, in particular a residential building, which wall is constructed using prefabricated construction elements forming part of a range comprising at least five types of construction elements (p(1) to p(5)) which are different in height from each other, four of these types of construction elements having per type a predetermined height (n(1), h(2) , h(3), h(4)) and the at least a fifth type is composed of construction elements forming part of a first set (p(5i)) of prefabricated construction elements having heights (h( 51)) different from each other, characterized in that before building the wall of a predetermined height H under the ceiling and taking into account a screed having a height h(c) applied to a slab on which the wall will be built, we select from said range of construction elements those which are necessary to obtain said height H by using a first mathematical formula f1 H= h(1)+h(2)+h(3)+h(4)+ h(5i)-h(€), which wall being constructed by applying a layer of binder to the slab, on which layer of binder the selected construction elements of type p(1) and height h(1) are placed, then we place on the elements of type p(1) the selected elements of type p(2) and of height h(2) >h(1) using a layer of binder applied between the elements of type p( 1) and p(2), we then place on the elements of type p(2) a succession either in order or in disorder, of the type of construction elements, composed of the selected elements of type p(3) and selected elements of type p(5i), and each time a layer of binder is applied between two superimposed elements, and in that we finalize the construction of the wall by placing on said succession the selected elements of type p(4 ), which elements of type p(4) being elements designed to take up loads exerted in line with the openings present in the wall. 2. Construction method according to claim 1, characterized in that for the first set (p(5i)) of prefabricated construction elements, elements having heights (h(5i)) different from each other located between 1cm < h(5i) = 49cm. 3. Construction method according to claim 1 or 2, characterized in that each type of construction element has a predetermined length (x) and in that to construct the wall of a length L, use is made of a second mathematical formula f2 L = nl(x) + gl(x) where n is an integer and O< g <1 indicates the fraction of the length (x), and we place the n construction elements of a horizontally same type and in the case where g#0 we also place a construction element whose length is a fraction g of length |(x). 4. Construction method according to claim 1 or 2, characterized in that for each type of construction element a second set is provided comprising construction elements p(km) of said type p(k) (1<k = 5) having different predetermined lengths I(km), and in that to build the wall of a length L will apply a third mathematical formula f3 k, m L= 2 f(l(km)) 1 Where f is the number of elements of a type p(km). 5. Construction method according to one of claims 1 to 4, characterized in that for construction element of type p(3) use is made of at least two parts p(3-1) and p(3 -2). 6. Construction method according to one of claims 1 to 5, characterized in that for the construction element of type p(5i) use is made of at least two parts p(5'i) and p (5”i). 7. Construction method according to one of claims 1 to 6, characterized in that during their installation, interruptions are left between at least two elements of type p (1) juxtaposed to allow passage on either side of the wall. 8. Construction element intended for the application of the method according to one of claims 1 to 7, characterized in that it comprises through holes (8) intended to introduce a gripping element for a crane. 9. Building constructed using walls constructed by applying the process according to one of claims 1 to 711.