NL1018944C1 - Block-shaped building element. - Google Patents

Abstract

The invention relates to a block-shaped structural element, the external shape of which is determined by a bottom, top and four sides. At least one of the sides is provided with a slot formed in a plastic material in which sheet material can be fixed. At the opposite side the top edge can be constructed sloping downwards at an angle alpha (Fig. 1).

Description

Block-shaped building element.

The present invention relates to a block-shaped building element whose outer contour is determined by a bottom side, a top side and four mutually connecting sides.

When building houses, it often happens that sheet metal, such as iron plate, aluminum plate, plastic plate or a lead bib, have to be attached to a facade. Such sheet metal is generally used to obtain a watertight connection / seal. For example when constructing a conservatory, care must be taken that rainwater cannot enter between the connection when the conservatory is connected to the facade. Also with chimneys and roofs the case arises that one wants to fix sheet metal in the facade. It is common to attach such sheet metal by inserting it into a joint and fixing it with mortar. However, the problem is that sheet metal and mortar adhere poorly to difficultly and that the connection therefore leaves something to be desired. A further problem is that it is often necessary to first grind the joint to remove a hardened mortar already present therein in order to provide space for inserting an edge of the sheet metal to be fixed therein.

According to a first aspect, the present invention has for its object to provide a block-shaped building element with which plate material can be attached to a facade in a simple, efficient manner. As already indicated above, such plate material according to the invention can be very diverse in nature, it can even concern sheet-like material, such as plastic foil.

The aforementioned object is achieved according to the invention by providing a block-shaped building element, the outer contour of which is determined by a bottom side, a top side and four mutually connecting sides, a first of the sides being provided with an opening opening on that first side. first slot extending entirely over that first side, and wherein according to an advantageous further embodiment the portion of said first slot located in the building element is bounded by a plastic material. The building element provided according to the invention is relatively universally applicable due to its essentially block-shaped shape, and the dimensions of the building element can easily be matched to the dimensions of other building elements, generally called bricks. By providing the first slot in the building element according to the invention, this building element can easily be incorporated in the facade to subsequently insert plate material into said first slot and secure it by providing another fastening means in the first slot, such as possibly a wedge , but preferably a filler material that is liquid during processing, such as an adhesive, a kit or possibly even grout. And further excellent fastening means can be a rubber or plastic strip that clamps the sheet material inserted into the slot after having also been inserted into the slot. By limiting the first slot in the building element by a plastic material, it is achieved in particular that the plate material can be secured very well and reliably with many commercially available types of glue and kit types, in particular gluing and / or filling kit types.

According to the advantageous embodiment of the invention, a second side connecting to the first side is provided with a second slot opening at said second side and extending along the whole of said second side. It is furthermore advantageous here if in this embodiment the part of the second slot located in the building element is bounded by a plastic material. In this way a building element is obtained which can be applied particularly well to corners of facades, wherein sheet material must be attached to the facade on both sides of the corner.

According to a still further embodiment of the first aspect of the invention, it is advantageous if the top side has a substantially horizontal section, when the building element has a third side opposite the first side, and when the building element at the top side the third side is sloping towards the horizontal part of the top side. It thus becomes possible that the building element at the third side with the sloping portion collects moisture, in particular water, and guides it to the top of that building element to drain it along that top. This is for example very useful with cavity walls, where the third side will be a side facing the inside of the cavity wall, in particular projecting slightly into the cavity. The moisture collected by the obliquely extending portion can optionally be discharged via the hardened mortar which will lie on the top of the building element. In order to improve the drainage of this moisture, however, it is advantageous if drainage channels are formed in the upper side of the building element according to the invention, which channels connect with one end to the obliquely sloping portions, with the other end opening onto the first side. The drainage channels can be open upwards or in other words grooves formed in the upper side of the building element. However, the drainage channels can also be closed upwards and only open at the first side 5 and at the sloping portion at the third side.

In order to facilitate fixing of the building element according to the invention by means of mortar, it is preferred according to the invention if recesses are formed in the bottom side, open towards the bottom side. These open recesses are then able to fill with mortar when being fixed in the facade. After curing of the mortar, the building element will then be retained by the mortar by means of the mortar parts engaging in the recesses. This makes it possible in particular to manufacture the building element as such from materials that are not or hardly barable, because they cannot of themselves enter into an adhesive connection with mortar. Although this can be very advantageous, it is not necessarily necessary to manufacture the entire building element from plastic. For the purpose of fixing the plate material, it is possible to suffice with a plate or block-shaped plastic part in which the first or second slot are formed.

According to a preferred embodiment the building element is formed by a hollow plastic body obtained by injection molding, in which the first and optionally second slot are formed, and the cavity is filled with a pressure-resistant, in particular pressure-resistant material. A suitable filling material for the cavity is, for example, so-called foam glass, which is known as a thermal insulation material with high compressive strength.

The advantage of a building element that, viewed in the vertical direction, is moisture and / or heat insulating, as can be achieved, for example, by manufacturing the entire building element from plastic or when a hollow plastic body is filled with a pressure-resistant and preferably heat-insulating material clear from the following:

When building houses with walls made of bricklable material, it is a known phenomenon that moisture can pull up along the walls or sink down along the walls and thus cause moisture problems inside the house. Furthermore, it is a known phenomenon that when placing an extension against an outside wall through that outside wall cold, the building can enter and heat can leave the building. This phenomenon occurs in particular with walls made of a brick or brick-like material. According to the invention, a bricklable brick-like materials is understood to mean not only baked bricklable bricks, carved natural bricklable bricks, or bricks formed from concrete-like material, but also concrete walls cast as a whole.

In a short sense, according to the invention, "a bricklable brick-like material" is understood to mean not only brick-like materials, but also other materials that can be bricked with brick mortar. Stony building materials have the property that they are porous to a greater or lesser extent and can thus lead moisture up or moisture down. For example, when the façade has become very moist due to rainfall, such stony materials can introduce the moisture into the building. This is one of the reasons why people often work with cavity walls. When built on a damp surface, walls constructed from such stony materials can allow moisture to be drawn up into the house from the ground.

By designing building elements, viewed in the vertical direction, in a heat-insulating manner, or at least interrupting or complicating the conduction of moisture or heat in the vertical direction, the aforementioned problems are overcome.

According to a second aspect subsequent to the first aspect, the invention has for its object to provide an improved bricklable building element which is particularly suitable for fixing sheet metal thereto.

According to the second aspect of the invention, this object is achieved by providing a bricklable building element, which bricklaying building element according to the second aspect of the invention comprises: an upper side of brickable stony material, and a bottom side of brickable stony material, along which a first side, parallel to said top and bottom, a strip of a plastic material is embedded in the building element, said strip extending along the whole of said side and being provided with a slot opening on said first side parallel to said top and underside extending entirely through said first side 30. The embedded strip can - viewed in the depth direction of the trench - extend very well only over a part of the building element. The advantages of this bricklable building element according to the second aspect are explained below with reference to the slot formed in the plastic intermediate layer of the building element according to the third aspect. The same applies to the following special embodiment of the bricklable building element according to the second aspect.

According to the second aspect of the invention, it is of particular advantage if that strip is the edge zone of a moisture-tight plastic intermediate layer located between the lower and upper layer.

According to a further advantageous embodiment of the second aspect, on the second side opposite the first side, a plastic covering layer is provided which is connected to the moisture-tight plastic intermediate layer. According to a still further advantageous embodiment, this covering layer is provided at the top with an edge draining towards the building element.

According to a third aspect, the present invention has for its object to provide a bricklable building element which counteracts moisture conduction and possibly heat conduction in the vertical direction.

To achieve this goal, according to the third aspect of the invention, a bricklable building element is provided, comprising: an upper layer of brickable brick-like material, a lower layer of brick-ready brick-like material, and a moisture-tight plastic intermediate layer located between the lower and upper layers. The bricklable building element thus obtained is, as it were, a sandwich-like, at least three-layer building element. By manufacturing the top and bottom layer of a bricklable brick-like material, it is ensured that the building element can be built into a wall by bricklaying. By providing a moisture-tight plastic intermediate layer between the lower and upper layer, both a cold bridge and a moisture barrier are provided. Thus cold is prevented from passing through the bricklable building element according to the invention transversely to the direction of extension of its layers. Due to the moisture-proof properties, moisture is also prevented from passing transversely to the layer direction in the one or the other direction. Such a bricklable building element can be used advantageously in various places, such as cavity walls below the roll layer, with a vertical dilatation in the facade, at floor height under an inner cavity leaf, under a sill of a facade element, with a roof trim connection, as well as in the roof trim connection. especially also above all conservatory, glass roof, sloping roof connections on the facade.

1018944 6

In an advantageous embodiment of the third aspect of the invention, the first side of the building element is provided with a slot formed in the plastic intermediate layer which extends parallel to the plastic intermediate layer along the whole of that side. Such a slot makes a very simple and reliable mounting of sheet material on the facade possible. The invention is understood by such a sheet material, for example, to be an aluminum, plastic setting or a lead bib.

Such sheet metal is usually attached to a facade by milling a slot in the facade, often in the cement joints, inserting an edge of the sheet material here and subsequently fixing it by fixing the rest of the milled slot with mortar. to fill. A disadvantage of both grout and brick mortar, in particular with metal sheet, is that these species and metal sheet adhere very poorly to each other. By now forming a slot in the plastic interlayer, it becomes possible to insert the sheet material with an edge zone into that slot formed in the plastic interlayer and then insert that edge zone into it by means of tried and tested methods, such as gluing or by means of a kit or possibly a rubber or plastic strip. to secure that slot. As the trench in the building element will already be prefabricated, it is no longer necessary to grind or mill a trench in the façade.

In order to prevent the passage of rising or settling moisture along the plastic intermediate layer, it is of additional advantage according to the invention if the building element is coated at least partially, preferably wholly, with a plastic coating layer on the third side opposite said first side. which coating layer is preferably of the same material as the moisture-tight plastic intermediate layer, wherein the plastic coating layer is connected to the moisture-tight plastic intermediate layer. When used, the covering layer is positioned on the side of the building element that is turned inwards, in particular the cavity.

In order to prevent moisture dripping downwards along the inside, in particular the inside cavity side of the building element, and ultimately to be able to lead to the outside of the building element, it is preferred according to the invention if the covering layer is the third side of the upper layer at least partially coated and when the top edge of the coating layer is slanted towards the top layer. The upper edge of the cladding layer thus absorbs dripping / dripping moisture downwards and directs the building element - which, given the stony material in the upper layer, is porous and moisture-transmitting - to the moisture-tight plastic layer along the building element along the top. outside of the building element in this case to direct the outside of the facade.

With the building element according to both the second and the third aspect of the invention, it is of particular advantage if the plastic intermediate layer is made of rubber or rubber-like material. Rubber and rubbery materials, in addition to being highly moisture-proof, also work very well as a thermal bridge. Within the scope of this invention, rubber or rubber-like material is certainly understood to mean both artificial and natural rubber or rubber-like material on the basis of both artificial and natural rubber, wherein the artificial rubber and natural rubber are both separate from each other (one or the other ) if can be used in combination.

The invention further relates to the use of a building element according to both the first and the second and the third aspect of the invention, wherein the top layer resp. essentially horizontal. According to a special embodiment, the building element according to the first and / or the second and / or third aspect is used here for obtaining a thermal bridge active in the vertical direction. According to another, further advantageous embodiment, the building element according to a first and / or second and / or third aspect of the invention is used for fixing plate material, such as an aluminum plate or a lead bib, to a wall.

The invention further relates to a wall provided with a building element according to the first and / or second and / or third aspect of the invention.

This wall will in particular be a cavity wall, wherein the building element according to the first and / or second and / or third aspect of the invention will then be placed in the outer wall.

In all aspects of the invention, pressure-resistant is understood to mean a pressure resistance of at least 0.4 N / mm 2.

The present invention is explained in more detail below with reference to a number of exemplary embodiments schematically shown in the drawings.

Herein shows: 1018944 8

Figure 1 shows a schematic, perspective view of a building element that embodies both the first, the second and the third aspect of the invention;

Figure 2 shows a schematic sectional view of an application of the building element according to the invention, embodying both the first, the second, and the third aspect thereof;

Figure 3 shows a schematic cross-sectional view of a further application of the building element according to the invention, embodying all three aspects thereof;

Figure 4 shows a schematic sectional view of a still further application of the building element according to the invention, embodying all three aspects thereof; Figure 5 shows a schematic sectional view of a still further application of the building element according to the invention, in particular illustrating the third aspect thereof;

Figure 6 shows a schematic sectional view of a still further application of the building element according to the invention, in particular illustrating the second aspect thereof;

Figure 7 shows a perspective view of a building element, in particular illustrating the first aspect of the invention; and

Figure 8 is a sectional view according to VIII-VIII of Figure 7.

Figure 1 shows a building element indicated in its entirety by 1. The building element 1 has a top side 2, a bottom side 3, a first side side 12 and a third side side opposite it 13. The terms "top side" and "bottom side" are related here to the orientation of the building element 1 intended for installation. top edge 9 to be discussed yet is absent or is effectively not required and optionally the covering layer 8 to be discussed is absent or not required, then the bottom and top can be interchanged.

The building element 1 as shown in Fig. 1 is composed of an upper layer 4 of bricklable material like brick, a lower layer 5 of brickwork material that can also be bricked, and an intermediate layer 6 of plastic, and in particular a moisture-proof plastic that is attached to it. the majority of the plastics 30 also inherently have cold / heat transport interrupting properties.

A slot 7 is formed on the first side 12 in the material of the intermediate layer 6. This slot 7 extends essentially parallel to the top 2 and 0169 44. * 9 bottom 3 over all of that side 12. As will be discussed further below, a profile, plate (whether or not set) or lead flashing 99 can be attached in slot 7.

On the opposite third side 13, a covering layer 8 formed as a whole with the intermediate layer 6 is provided. This covering layer 8 does not necessarily have to be formed as a whole with intermediate layer 6 and can also be a separate layer 8 which will then be connected to layer 6, for example by gluing. In the example shown in Figure 1, the covering layer 8 is provided on the entire third side 13. However, the covering layer 8 does not have to extend over the entire third side 13. In particular, the covering layer 8 does not have to extend over the second side of the bottom 3. The covering layer 8 will preferably extend at least over a portion of the second side of the upper layer 4. This does not have to be over the entire height of the second side of the top layer 4. Generally, it will suffice if the covering layer 8, measured from the underside of the upper layer 4, has a height of 5 to 10 mm. The upper edge 9 of the covering layer 8 runs obliquely at an angle α, draining in the direction of the upper layer 4.

In the example shown in Figure 1, the cross-section of the building element 1, viewed parallel to the plane of the drawing, is the same everywhere. However, this is not a requirement.

In connection with being able to withstand a pressure in the vertical direction, it is quite conceivable that pressure-resistant elements are present in the intermediate layer 6 which contact the upper layer 4 on the one hand and the lower layer 5 on the other hand. This will be particularly advantageous when a relatively pressure-sensitive material, i.e. compressible under the influence of a compressive force, is used for the intermediate layer 6.

The top layer 4 can be made of ordinary brick, but can also be cut from a natural stone and be formed from a concrete mixture. The same applies to the lower layer 5 which will preferably be of the same material and the same composition and preferably even of the same dimensions as the upper layer 4. The intermediate layer 6 can be made of a compression-resistant rubber-like material. The intermediate layer 6 can have a height of approximately 10 mm, while the slot 7 can have a height of approximately 5 mm. At the height of the lower and upper layer 4 can be approximately 15 mm. The thickness of the covering layer 8 can be approximately 10 mm. The width of the building element extending parallel to the plane of drawings and extending transversely to the height direction can be approximately 110 mm in total. The length of the component extending perpendicular to the surface of drawings transversely to the height direction can be approximately 200 mm. The aforementioned dimensions are only intended to be indicative and in no way limitative of the scope of the invention.

With regard to the second aspect of the invention, the part of the building element to the left of the center line 14 could be made entirely of a stone-like material.

Regarding the first aspect of the invention, the materials and layers from which the building element is constructed are of relatively minor importance. In the first aspect of the invention, the slot 7 is particularly important as a receptacle for plate material.

An example of a building element according to the first aspect of the invention is particularly shown in Figures 7 and 8. Figure 7 shows a perspective view and Figure 8 shows a cross-sectional view according to the arrows VIII-VIII in Figure 7.

The building element according to the invention is indicated in its entirety in figures 7 and 8 by 100. This block-shaped building element has an outer contour defined by a bottom side 103, a top side 102 and four mutually adjoining sides, namely 101.104.106 and 105.104. here also referred to as so-called first side, while 106 is also referred to as so-called second side and 105 as so-called third side. A so-called first slot 107 is formed in the first side 104 and a so-called second slot 108 is formed in the second side 106. A piece of plate material 99 can be accommodated in both slots in a similar manner as with the building element 1 of Figure 1.

The top 102 is essentially horizontal. However, advantageously, on the side of the third side 105, a portion 109 which runs downwards from the top of the third side 105 towards the top 102 of the component is formed. Like the oblique part 9 of building element 1 from figure 1, the sloping part 109 is advantageous to collect moisture seeping downwards along the inside of a cavity wall. To facilitate the drainage of moisture collected on the inclined portion 109, drainage channels 110 are formed in the upper side 102 of the component 100, which channels extend over the entire horizontal portion of the upper side 102 and preferably also extend through the inclined portion 109, although the latter is not necessarily necessary.

In order to be able to ensure fastening of the building element 100 by means of mortar even when the building element 100 is made of a material that does not adhere very badly to mortar, such as, for example, certain plastics and aluminum and lead, it is advantageous if the building element 100 is still is provided with recesses 111 in which mortar can be received in order to form a kind of anchoring pins with a layer of mortar adjoining it. The recesses 111 are shown in Figure 7 as being formed in the underside 103 of the component 100. However, it will be clear that the recess 111 may also be formed on other sides of the component 100, such as for example in the sides 101 and / or or 106 and / or in the top 102. Furthermore, the recesses need not have a cylindrical shape.

In figure 2 to be discussed below, a building element 100 according to figures 7 and 8 is shown schematically, in cross-section. In figures 3-6 to be discussed next, a building element according to essentially figure 1 is shown each time diagrammatically and in cross-section. it is not already clear, it is to be noted that in the embodiment according to figure 2 it is also very possible to use the building element 1 from figure 1, just as also that in the embodiments according to figures 3,4,5 and 6 also the building element 100 from 7 and 8 can be used instead of the schematically shown building element 100.

Referring in particular to Figure 8, it is formed in the component 100 by injection molding a plastic casing 101,102, 103,104,105,106 with a cavity and slots 107,108 and recesses 1111 and grooves 110 therein. The cavity is then filled with a pressure-resistant material, such as foam glass 113, which is inserted through opening 114.

Figure 2 shows an application of the building element 100 according to the invention just above the connection of a conservatory roof 20 to the outside 21 of a facade, wherein the facade is a cavity wall with an inner wall 23 and an outer wall 22. The layer 24 is an insulating layer. 25 is a ceiling or floor. Downwards according to arrow 26 along the inside of the outer wall 22 (hopping moisture is collected on the draining upper edge 109 and guided, inter alia, via the channels 110 to the upper surface 102 of the component 100 according to the invention. In the absence of channels 110 or 018944 12 in addition, this moisture can be drained to the outside via the porous joint or overlying brick, thus preventing moisture problems below the building element 100 according to the invention. Due to the moisture-tightness of the building element 100, the permeability of moisture from above to below is completely prevented. An aluminum setting plate 27 is inserted into the slot 107 and is fixed here by means of sealant, glue or possibly a rubber strip The construction element 100 in the application according to figure 2 prevents on the one hand that vertical downward transport of moisture can occur by the outer wall 22, which could lead to moisture problems under the greenhouse roof 20 and prevents biting s that cold is led via the outer wall 22 from above the greenhouse roof 20 to the wall section below the greenhouse roof 20, which would result in cold in the greenhouse.

Figure 3 shows an application of a building element 1 according to the invention which essentially differs from Figure 2 only in that a flat roof 28 is provided instead of a conservatory roof 20 and that a building element 1 is shown in place of a component 100. Therefore, corresponding reference numbers are used for corresponding components.

Figure 4 shows, in a schematic cross-sectional view, a portion of, for example, a conservatory at ground level 35. A foundation 30, a finishing floor 33, a layer of stone 34 supporting the foundation and a slidable back and forth perpendicular to the plane of the drawing are shown. sliding door 32. The building element 1 according to the invention is used here to prevent rising damp and to provide a practical fixing point for an L-shaped piece of setting 31 in cross-section. The setting 31 can be inserted here in a simple manner into the slot 7 of the building element 1 according to the invention and optionally fixed in it by means of glue, sealant etc. It is possibly conceivable in the situation from figure 4 that the setting 31 just insert it into the slot 7 and not secure it.

Figure 5 shows a situation in which the building element 1 according to the invention is only used to repel rising damp. The figure shown in Figure 5 can be, for example, the connection of a conservatory to a building. Herein 40 is the part of an outer façade lying below ground level, 41 the crawl space, 42 the floor of the original building, 43 the concrete floor of the conservatory and 44 the finishing floor thereof.

Figure 6 shows diagrammatically in cross-section the connection of a flat roof to an outer facade. The building element 1 is only used here as a simple and practical fastening means for a profile 45 or, if necessary, typesetting. The building element 1 is here provided as a top layer on an outer wall 46 with a cavity wall 46, 47. The flat roof is indicated by 49.

1018944

Claims (21)

A block-shaped structural element whose external contour is determined by a bottom side (3,103), a top side (2,102) and 4 mutually connecting sides (12, 13,101,104,106,105), wherein a first one of the sides (12,104) is provided with a first side opening first slot (7,107) extending along the whole of said first side, and preferably the portion of the first slot (7,107) located in the building element is bounded by a plastic material. Building component as claimed in claim 1, wherein a second side (106) connecting to the first side (104) is provided with a second slot (108) opening along said second side (106) and extending along the whole of said second side (108), and wherein preferably the portion of the second slot (108) located in the building element is bounded by a plastic material. 3. Building element as claimed in any of the foregoing claims, wherein the top side (2,102) has a substantially horizontally extending part, wherein the building element has a third side (13,105) opposite the first side, and wherein the building element at the top near the third side is inclined (a) to the horizontal part of the top side (2,102). 4. Building element as claimed in claim 3, wherein drainage channels (110) are formed in the top side (102) which connect one end to the sloping part (109) and end with the other end on the first side (104). Building component according to one of the preceding claims, wherein recesses (111) are formed in the underside (103), open towards the underside. 6. Building element (1,100) as claimed in any of the foregoing claims, comprising at least one sticky or block-shaped plastic part in which the first and / or second slot (7, 107, 108) is formed. Building component as claimed in any of the foregoing claims, wherein the entire building element is formed from plastic. 8. Building element as claimed in any of the foregoing claims formed as a hollow plastic injection molded product, wherein the cavity is preferably filled. Building element (1), preferably according to one of the preceding claims, comprising: an upper side (2) of bricklable brick-like material, and 018944 a lower side (3) of bricklable brick-like material, wherein along a first side (12) parallel to said top and bottom is a strip (6) of a plastic material embedded in the building element (1), said strip (6) extending entirely along that side and being provided with a slot (7) opening on said first side which extends parallel to that top and bottom along all of that first side (12). A bricklable building element (1) according to claim 9, wherein said strip is the edge zone of a moisture-tight plastic intermediate layer (6) located between the lower (3) and upper (2) layer. 11. Building element according to claim 10, wherein the building element on the third side (13) opposite to said first side is at least partially covered with a covering layer (8) of preferably the same material as the moisture-tight plastic intermediate layer (5), wherein the plastic covering layer (8) is connected to the moisture-tight plastic intermediate layer. The building element according to claim 11, wherein the cladding layer (8) at least partially clads the third side of the upper (2) layer and wherein the upper edge (9) of the cladding layer (8) slopes obliquely (a) towards the upper layer is carried out. A building element, preferably according to any one of the preceding claims, comprising: an upper layer (2) of bricklable material, a lower layer (3) of bricklable material, and a layer located between the lower (2) and upper (3) layers moisture-proof plastic intermediate layer (6). A building element according to claim 13, wherein a first side (12) of the building element is provided with a slot (7) formed in the plastic interlayer, which slot extends parallel to the plastic layer along the whole of that side. 15. Building element according to claim 13 or 14, wherein the building element on the third side (13) opposite to said first side (12) is at least partially covered with a plastic covering layer (8) of preferably the same material as the moisture-tight plastic intermediate layer (6), wherein the plastic covering layer is connected to the moisture-tight plastic intermediate layer (6). Λ Cl 1 ft Q A A 5 The building element according to claim 15, wherein the cladding layer (8) at least partially covers the third side (13) of the upper layer (2) and wherein the upper edge (9) of the cladding layer (8) is inclined towards the upper (2) low drainage. A building element according to any one of the preceding claims 9-16, wherein the plastic intermediate layer (6) is made of rubber or a mbber-like material. Use of a building element according to any one of the preceding claims, wherein the top layer or top side is essentially horizontal. 19. Use according to claim 18 for obtaining a thermal bridge active in the vertical direction. Use according to claim 18 or 19 for fixing plate material such as an aluminum plate or a lead bib to a wall. 21. Wall provided with building element according to one of the preceding claims. 1018944