BE1025726B1 - Construction button - Google Patents

Abstract

Composite carrier profile comprising an upper side adapted to support a window, a lower side adapted to be supported on an inner wall, wherein the composite carrier profile comprises a first indentation and a second indentation on either side of the carrier profile, respectively, so that an inner window tablet through first indentation is supportable and an outer window tablet is supported by the second indentation.

Description

Construction button

The invention relates to a building node in a building in which an opening is provided in a wall of the building for a window or door, which opening extends in an outer wall and in an inner wall of the wall.

Standards with regard to insulation and airtightness for buildings have become stricter and stricter in recent years. Many materials and techniques have been developed to improve walls, improve windows and doors, improve roofs, etc. The insulation properties and possibilities for airtight construction with these elements have increased dramatically. Each of these elements has been optimized to meet the high standards and norms. The connection between various of these elements is called construction nodes. In practice, construction nodes appear to be poorly adapted to meet the high insulation and airtightness requirements.

The invention relates in particular to the constructional node between a window or door on the one hand and a wall on the other. A first difficulty with such a construction node relates to airtightness, namely the inner walls typically have an airtight foil that is connected to the window. An additional difficulty relates to the thickness of the wall and the thickness of the window. The wall typically has an inner wall and an outer wall, which together are noticeably thicker than the thickness of the window. This means that the resistance to heat transfer in the wall extends over a considerably greater distance than in the window profile. Because of this difference in distance, a cold bridge will almost always be created in practice when the window is connected to the wall somewhere. A further additional difficulty relates to the finish, in particular the window tablets which are placed on the inside and on the outside under the window to finish the window opening in the wall. These window tablets are traditionally made from a material with good heat conductivity, for example stone or metal. In practice, these window tablets often have a negative influence on the insulation properties at the site of the construction joint.

It is the object of the invention to provide a solution for at least one of the above problems to improve the constructional node between window or door and wall.

To this end, the invention provides a composite support profile which includes an upper side adapted to support a window, a lower side adapted to be supported on an inner wall, the composite support profile including a first indentation and a second indentation on either side of the support profile, respectively, so that an inner window tablet can be supported by the first indentation and an outer window tablet can be supported by the second indentation.

BE2017 / 5858

The composite carrier profile according to the invention forms an intermediate element for the window, the wall and the two window tablets such that all these elements can be kept at a distance from each other. This distance is determined by the cross-section and dimensions of the composite support profile. Furthermore, a composite bearing profile is known for its good insulating properties, so that providing the distance between the elements has the direct consequence that the heat transfer between the elements is limited. Furthermore, the composite bearing profile provides a mounting surface for each of the elements. For example, the window can be placed on the top of the composite support profile, so that the window is thereby supported. The underside of the composite bearing profile is provided to rest on the inner wall, so that the composite bearing profile, possibly with the window, is supported by the inner wall.

Furthermore, the composite carrier profile has indentations on both sides that are provided to support the window tablets. In practice, mounting the window tablets at the right height relative to the window is often cumbersome. Namely, the window tablets must be supported at the correct height at the location of the window, taking into account the thickness of the window tablet. The indentations in the composite bearing profile offer an extremely simple solution for this. Using the composite support profile according to the invention therefore not only has an advantage with regard to the insulation of the construction node, but also considerably simplifies the placement of the various elements.

Preferably, the composite support profile has a thermal conductivity that is less than 0.5 lambda. Further preferably, the composite support profile has a cavity that is filled with insulating material. More preferably, the insulating material has a thermal conductivity of less than 0.05 lambda. The thermal conductivity of the composite bearing profile will have a major influence on the insulation properties of the construction joint. A composite bearing profile naturally has acceptable insulation properties. However, by choosing the composite support profile with a thermal conductivity as defined above, the construction node can be realized in an optimum manner. Furthermore, it appears to be simple to manufacture a composite carrier profile hollow. This cavity entails a further insulation effect. By filling the cavity with an insulating material, this insulating effect can be further improved, so that the composite bearing profile gives the building node optimum insulation characteristics.

The top side preferably has a width that is smaller than the width of the bottom side. This creates a base on the underside of the plastic support profile that is wider than the top on which the window rests. On the one hand, this simplifies assembly because it is easy to have a profile that is wider at the bottom with this wide side facing

BE2017 / 5858 to be positioned below. Furthermore, this structure brings the shape of the composite bearing profile closer to the shape of the construction node, in which the wall typically has a noticeably greater width than the window.

Preferably, the first indentation is higher than the second indentation. The first indentation is provided for mounting the inner window tablet, while the second indentation is provided for mounting the outer window tablet. The outer window tablet typically has a noticeably greater thickness than the inner window tablet, so that when the inner and outer window tablets connect equally high to the window, the first indentation will be higher than the second indentation. Furthermore, by providing a height difference between the first indent and the second indent, the resistance to heat transfer from the window tablets to each other is further increased. Namely, the distance between the first indent and the second indent becomes greater because not only a horizontal distance, but also a vertical distance is created.

Preferably, the first indentation lies in the upper half of the composite carrier profile, and the second indentation lies in the lower half of the composite carrier profile. Tests have shown that the composite support profile can be produced in a balanced manner when the opposite recesses lie in different halves of the support profile. Furthermore, the distance between each indentation and the top of the composite carrier profile will determine the optimum thickness of the window tablet. When a window tablet with a thickness that is almost equal to this distance is placed, the top of the window tablet fits nicely with the bottom of the window. The thickness of an outer window tablet is typically noticeably greater than the thickness of an inner window tablet, so that the second indentation is formed farther from the top than the first indentation.

Preferably, each indentation is formed as a step. Alternatively to a staircase, the recess could also be made as a recess or groove. Forming the indentation as a staircase is the simplest way to realize an indentation on which a window tablet can rest. By providing a staircase, only a minimum number of corners must be provided in the cross-section of the bearing profile in order to realize the indentation. This is advantageous when manufacturing the composite support profile.

The invention further relates to a building node in a building, wherein an opening is provided in a wall of the building for a window or door, which opening extends in an inner wall and in an outer wall of the wall, the building node further comprising the composite carrier profile according to the invention, wherein the composite carrier profile is placed on the inner wall, and wherein the composite carrier profile carries the window or door, and wherein

BE2017 / 5858 a first window tablet is at least partially supported by the first indentation, and wherein a second window tablet is at least partially supported by the second indentation.

In the construction node according to the invention, the composite support profile forms an intermediate piece between the window and wall and also between the inner window tablet and the outer window tablet. Because the composite bearing profile is placed between the window and the wall, heat transfer between the wall and the window is greatly reduced. Furthermore, since the composite carrier profile is placed between the inner window tablet and the outer window tablet, the heat transfer between these window tablets will also be appreciably reduced. As a result, the composite bearing profile dissolves the so-called thermal bridge that typically occurs when a window or door is connected.

The constructional node according to the invention is simple to realize because the composite carrier profile is provided with indentations of the window tablet, on which the window tablet can partially rest. This considerably simplifies the placement of the window tablet, namely on the side of the window the window tablet will be placed on the indentation of the composite support profile, and slid up to or near the composite support profile and / or the window, with which the window tablet is always correct is positioned. The person skilled in the art will understand that the position of the indentation and the thickness of the window tablet are correspondingly chosen to achieve this effect. In a traditional situation, a support will have to be provided manually at the location of the window on which the window tablet can rest. This support must typically be created by the person skilled in the art, which is cumbersome, requires craftsmanship and is therefore on the one hand error prone and on the other hand expensive. The indentations of the composite carrier profile already provide this support for the window tablets, so that the window tablet can be placed directly and correctly.

Preferably, the top side of the composite support profile has a width that is smaller than the thickness of the window or door and the window or door is placed on the composite support profile to protrude over the composite support profile on both sides, in the width direction. A window or door typically has an outer shell and an inner shell that are thermally insulated from each other. This thermal insulation is typically located in a central zone of the window profile between the outer shell and the inner shell. Providing the composite support profile under the window and having the window cross in the transverse direction has two consequences. The first consequence is that the composite support profile typically extends over the central zone of the window, which insulates the outer shell from the inner shell. The composite support profile also has good insulating properties, so that the resistance to heat transfer from the window is extended to the composite support profile when the window is thus placed on the composite support profile. A second consequence is that when the window tablets are placed,

BE2017 / 5858 the composite bearing profile is completely hidden from view because it does not protrude transversely. The window tablets can then be placed just below the window profile, which is aesthetically beautiful. The outer window tablet will be positioned below the outer edge of the window, against or near the outer shell of the window. The inner window tablet will be positioned below or near the inner edge, against or near the inner shell of the window. A heat transfer from the outer window tablet to the outer shell of the window is not detrimental to the insulation properties of the building node. Also, a heat transfer from the inner window tablet to the inner shell of the window is not detrimental to the insulation properties of the building node. Because the composite support profile is located between the window tablets, and the distance between the outer shell and the inner shell of the window is practically bridged, a great resistance to heat transfer is realized between the outside and the inside of the building. This high resistance to heat transfer is not only situated in the window, but also in the connection of the window to the wall via the composite support profile.

The composite bearing profile is preferably placed on the inner wall with, in the width direction of the profile, a crossing towards the outside of the building. The overhang is preferably greater than the depth of the second indentation. The outer wall, or at least the outer shell of the outer wall, is typically insulated from the inner wall, at least the inner shell of the inner wall. The insulation effect extends over the distance between the inner wall and the outer wall, or between the outer shell of the outer wall and the inner shell of the outer wall. Tests have shown that the optimum position for placing the composite bearing profile is the outside of the inner wall. A stable positioning of the window can be realized at the location of the outside of the inner wall. It can also be guaranteed that the composite support profile extends at least partially over at least a portion of the insulating working zone of the wall. As a result, the composite support profile bridges at least a portion of the insulating zone of the wall, so that the insulating effect of the wall can be extended at least partially to the composite support profile. A cold bridge is also prevented at the location of the wall. When the overhang is greater than the depth of the second indentation, the distance between the outer window tablet and the inner wall is increased. This has the direct consequence that the resistance to heat transfer from the outer window tablet to the inner wall is also increased.

The invention further relates to a method for placing a window or door in an opening of a building, the method comprising successively:

- placing a composite bearing profile on the inner wall;

- placing the window or door on the composite support profile; and

BE2017 / 5858

- placing the window tablets on indentations of the composite carrier profile.

With a simple method a window can be placed in a correct way and window tablets can be provided. In addition, it can be guaranteed that the construction node has good insulation properties. Also, the correct placement of window tablets will not be cumbersome.

The invention will now be described in more detail with reference to an exemplary embodiment shown in the drawing.

In the drawing:

figure 1 shows a plan drawing of a cross-section of a composite support profile in a construction node according to a first embodiment of the invention;

Figure 2 shows a section of a composite bearing profile according to a further embodiment of the invention;

figure 3 shows a detail drawing of an embodiment of a construction node with composite support profile according to the invention; and figure 4 shows a further embodiment of a composite bearing profile.

In the drawing, the same reference numeral is assigned to the same or analogous element.

Figure 1 shows a composite carrier profile 1 according to a preferred embodiment of the invention. Figure 1 shows the composite support profile 1 schematically in section and in a built-in state. The composite support profile 1 is provided to improve the insulation properties at the site of a construction node. The building node in question is the building node located at the bottom of a window or door. Windows and doors are provided to close openings in walls of buildings. In the description below and in the figures, the composite support profile 1 is always shown and described in combination with a window. It will be clear to those skilled in the art that the same composite bearing profile can be applied in an analogous manner for placing a door in an opening of a building.

The composite support profile 1 is shown in section in Figure 1, and shows a bottom side 5 and a top side 4. At the location of the upright sides, the composite support profile 1 is each provided with an indentation 6, 7. That is to say viewed in section , each upright side of the composite support profile 1 has an indentation. One of the sides of the composite support profile 1 will extend to the inside of the building in the installed state. In figure 1 this is the right-hand side of the composite bearing profile 1. The indentation at this side is called the first indentation and is indicated in the figures with reference numeral 6. The first indentation 6 is provided for

BE2017 / 5858 at least partially supporting the inner window tablet 8. Opposite this side is a second side. The second side of the composite support profile 1 will lie on the outside of the building in the installed state. In Figure 1 this is the left-hand side of the composite carrier profile 1. This side also contains an indentation, which is called the second indentation and is designated by reference numeral 7. The second indentation is provided to at least partially support the outer window tablet 9.

The underside 5 of the composite bearing profile 1 is provided for placing on an inner wall 3. The upper side 4 of the composite support profile 1 is provided to support a window 2 or door. The bottom 5 and top 4 extend substantially parallel at a distance from each other. This distance is preferably larger than 5 cm, more preferably larger than 8 cm, most preferably larger than 12 cm. Each indentation 6, 7 preferably has a depth greater than 0.5 cm, preferably greater than 1 cm, more preferably greater than 1.5 cm. The depth of the indentation determines the maximum size of the surface on which the respective window tablet can rest. Tests have shown that an indentation larger than 0.5 cm, preferably larger than 1.0 cm, more preferably larger than 1.5 cm is sufficient or even optimal to support a window tablet at the location of the window 2.

The bottom 5 is preferably wider than the top 4. In Figure 1, the width of the bottom is indicated by arrow b5 and the width of the top is indicated by arrow b4. Figure 1 shows an embodiment in which the difference in width between the bottom side 5 and the top side 4 comes directly from, and is related to the depth of the recesses 6, 7. In particular, the recesses 6, 7 are formed as a step. By providing a staircase on either side towards a center of the composite support profile 1, the composite support profile 1 will have a wider underside 5 than an upper side 4.

The width b4 of the upper side 4 of the composite support profile 1 is smaller or equal to the width of the window profile. The width b4 of the upper side 4 of the composite support profile 1 is preferably at least 2 mm smaller, more preferably at least 4 mm smaller, most preferably at least 8 mm smaller than the width of the window profile. The width of the window profile is herein defined as the distance between the raised outer surface and the raised inner surface of the window. When the composite support profile 1 is placed with respect to the window 2, the composite support profile 1 is preferably substantially centered in the transverse direction with respect to the window 2. As a result, the window 2 protrudes on both sides over the top side 4 of the composite support profile 1. . This overhang makes it possible to place window tablets 8 and 9 in such a way that the composite carrier profile 1 is virtually completely hidden from view. The window tablet 8 and / or 9 can be brought just under the window, or

BE2017 / 5858 against a side of the window. As a result, a nice visual finish can easily be realized at the bottom of the window.

The underside 5 of the composite support profile 1 is preferably placed on the inner wall 3 with a overhang towards the outside. The inner wall 3 and the composite bearing profile 1 are furthermore preferably complementary shaped such that a horizontal distance is realized between the inner upright surface of the inner wall 3 and the composite bearing profile 1. This distance can be filled by a filling plate (indicated in Figure 3). with reference numeral 17) and makes it possible to easily finish the interior wall visually. Because the composite bearing profile 1 has a protrusion with respect to the inner wall 3 in the direction of the outside of the building, the composite bearing profile 1 extends at least partially over the zone of the wall in which the insulating effect of the wall takes place. As a result, the insulating effect of the wall is at least partially extended to the composite support profile 1, so that a thermal bridge is at least partially avoided. Furthermore, it appears to be advantageous to connect the window 2 to the outside of the inside wall 3. At the location of the outside of the inside wall 3, airtight foil of the wall can be optimally connected to the window.

The indentations 6 and 7 are preferably formed complementarily with the window tablets 8 and 9. More specifically, the height of the indentations 6 and 7 in the composite support profile 1 will be complementary to a thickness of the respective window tablets 8 and 9. In practice, it is desirable that the window tablets 8 and 9 connect to an underside of the window 2. For this purpose the indentations 6 and 7 are placed at a vertical distance from the upper side 4 of the composite carrier profile 1 which is substantially equal to the thickness of the respective window tablets 8, 9. This has the direct consequence that when the window tablet 8,9 with this thickness is placed on the respective indentation 6, 7, the top side of the window tablet comes to be almost at the same height as the top side 4 of the carrier profile 1. Because the window 2 rests on this top side 4, preferably with a crossing in the two transverse directions, the window 2 will connect nicely to the window tab watch 8, 9.

The composite support profile is made of a composite material that conducts heat poorly. Such a composite material is typically a fiber-reinforced plastic. For example, fibers in a resin can be processed into the composite support profile 1. The resin and the fibers can be selected in function of the desired maximum heat conduction. Due to the poor thermal conductivity of the composite material, which has been quantified above, the composite support profile 1 will act as an insulating element between the various components connected thereto. The composite support profile is preferably made hollow, for example by manufacturing the composite support profile with a substantially

BE2017 / 5858 constant wall thickness. The cavity is further preferably filled with an insulating material. As a result, the composite carrier profile 1 forms an insulating block which, in use, extends below the window and between the window tablets 8 and 9. This makes it difficult to transfer heat from the inner window tablet to the outer window tablet and vice versa. Heat transfer from the outer shell to the inner shell of the window and vice versa is also made more difficult. Heat transfer from the inner wall to, for example, the outer window tablet is also made more difficult. It will be apparent to those skilled in the art that complicating heat transfer does not mean absolute decoupling or absence of heat transfer, but that the size of the heat transfer is appreciably reduced compared to a situation where the composite support profile is not present. As a result, the composite support profile 1 creates a thermal resistance between outside and inside. The outside of the composite support profile is connected to the outer shell of the window, the outer window tablet and an intermediate or outside of the wall, whereby this side of the composite support profile typically assumes the outside temperature. The inner side of the composite bearing profile is thermally connected to the inner shell of the window, the inner window tablet and the inner wall, so that this inner side of the composite bearing profile assumes the inner temperature. Due to the high thermal resistance in the composite support profile, the composite support profile can act as an insulator in such a situation.

Figure 2 shows an alternative embodiment of a composite support profile 1. In this case, the composite support profile 1, analogous to the embodiment of Figure 1, has a substantially parallel bottom side 5 and top side 4. However, the width b5 of the bottom side 5 is also substantially equal to the width b4 from the top 4. The recesses 6, 7 are not formed as a step as in figure 1. In the embodiment from figure 2, the recesses 6 and 7 are formed as recesses from the side surface. Such recesses can be realized in various ways. The window tablets are preferably a thickness that is equal to or smaller than the height of the recesses 6, 7. In the embodiment of Figure 2, an upper segment of the composite support profile 1 will remain visible when the window is placed directly on top 4, and when the window tablets are inserted into the recess. However, in terms of mounting simplicity and insulating properties, the embodiment in Figure 2 has substantially the same advantages than the embodiment in Figure 1.

Figure 3 shows a detailed view of the construction node and illustrates how the composite carrier profile 1 can be used in a practical way to connect the window to the inner wall and to position the window tablets. Figure 3 shows the inner wall 3 and the outer wall 12. Insulation 10 is provided between the inner wall 3 and the outer wall 12 and a cavity 11 is provided. In this context, cavity 11 is formed by an air layer. It will be clear

BE2017 / 5858 are for the skilled person that the entire space between the outer wall 12 and the inner wall 3 can be formed by cavity 11 or by insulation 10 or by a combination of insulation 10 and cavity 11.

Figure 3 shows how the composite support profile 1 is filled with insulating material 19. The composite support profile 1 is placed on the inner wall 3 with an overhang to the outside thereof, by means of a glue layer 16. Gluing can for instance be pure. To this end, the composite support profile can first be positioned at the correct height and position by means of filling elements and positioning elements, after which PUR or another bonding material is sprayed between the inner wall and the underside 5 of the composite support profile 1 around the space between the composite support profile 1 and the inner wall 3.

Because the composite support profile 1 is positioned on an outside of the inner wall 3, a filler plate 17 is provided against the inside of the composite support profile 1 and under the inner window tablet 8. Optionally, the filler plate 17 is further finished with a finishing layer 18, for example plaster, to determine the visual impression of the interior wall. The inner window tablet 8 rests on the one hand on the first indentation and on the other hand on the spacer plate 17. Alternatively, the inner window tablet can be connected on both sides to the inner wall 3 and is supported on the first indentation 6. The inner window tablet is preferably provided with several cavities 14. The inner window tablet can preferably be formed from plastic, for example PVC. Alternatively, the inner window tablet can be a stone or metal window tablet. When the inner window tablet is made as a PVC profile with air chambers, it has a lambda value of approximately 0.15. The same window tablet made of wood has a lambda value of approximately 0.20. The same marble window tablet has a lambda value of approximately 2.3. Tests have shown that the combination of a window tablet with a relatively low lambda value, for example lower than 0.25, with a composite profile that has a strong insulating effect (as described above), greatly improves the insulating properties of the construction joint. The composite profile is herein preferably provided with insulating material 19 on the inside.

An outer window tablet 9 is provided at the location of an outside side. This can be a stone window tablet, for example blue stone or bluestone. Alternatively, the outer window tablet 9 can be formed from a metal, for example aluminum. When the outer window tablet is formed from a metal, for example aluminum, the outer window tablet preferably has cavities. These cavities can be filled with an insulation material. The outer window tablet 9 rests at the location of the composite support profile 1 on the second recess 7. Furthermore, the outer window tablet 9 preferably rests on the outer wall. It is possible

BE2017 / 5858 support the outer window tablet 9 directly on the second recess 7 and the outer wall 12, or support it indirectly. Figure 3 shows an embodiment in which the outer window tablet 9 is supported indirectly, via a plate 15, on the second recess 7 and on the outer wall 12. Between the outer wall and the window tablet, accessories can be provided for positioning the outer window tablet 9. .

Preferably, an auxiliary profile 13 is provided between the outer window tablet 9 and the composite carrier profile 1. The auxiliary profile 13 is formed to ensure correct drainage from the window 2 to a top side of the window tablet 9. For this purpose, the auxiliary profile is formed, viewed in section. as a spring element extending from under the window 2, the auxiliary profile 13 preferably pressing against a bottom side of the window 2, up to the window tablet 9, where the auxiliary profile 13 preferably presses on an upper side of the window tablet 9. Such an auxiliary profile 13 can be formed, viewed in section, with a long leg and a short leg that are oriented relative to each other, such as a "1". Here, the long leg extends between the composite carrier profile 1 and a rear wall of the outer window tablet 9. The short leg extends downwards from under the window 2 to the window tablet 9. Alternatively, as shown in Figure 3, the auxiliary profile is 13, at the location of the upper rear edge of the window tablet 9 bent substantially perpendicularly to an outer side, and the auxiliary profile 13 is further bent obliquely upwards from the window tablet 9 towards the window, so that a zigzag section is obtained that the same drainage of the window to the window tablet 9. It will be clear to those skilled in the art that other configurations are also possible to guarantee drainage.

Figure 4 shows a further embodiment of a composite carrier profile 1. The composite carrier profile 1 of Figure 4 has properties and characteristics that essentially correspond to the properties and characteristics described above. At the location of the underside 5, the composite support profile 1 of figure 4 is provided with a slot 20. In the figure, the slot 20 is dovetail-shaped, so that a complementary shaped profile 21 fits into the slot 20. Alternatively, a straight slot 20 can be formed in which a straight profile 21 is fixed by gluing or screwing or in some other way.

The profile 21 can further be connected to a bracket 22. This bracket can be a plate-shaped strip with openings in the strip. Such a bracket 22 can be fixedly connected to the inner wall on the one hand and fixedly connected to the profile 21 on the other hand. For example, the composite support profile 1 can be fixedly connected to the inner wall 3 via the bracket 22. According to a further alternative embodiment, not shown, the bracket 22 can be directly connected to the composite support profile 1.

BE2017 / 5858

On the basis of the above description, it will be understood by those skilled in the art that the invention can be practiced in different ways and on different principles. In addition, the invention is not limited to the embodiments described above. The embodiments described above, as well as the figures, are merely illustrative and serve only to increase the understanding of the invention. The invention will therefore not be limited to the embodiments described herein, but is defined in the claims.

Claims (12)

Conclusions A composite carrier profile comprising an upper side adapted to support a window, a lower side adapted to be supported on an inner wall, the composite carrier profile comprising a first indentation and a second indentation on either side of the carrier profile, respectively, such that an inner window tablet can be supported by the first indentation and an outer window tablet can be supported by the second indentation, the composite support profile having a cavity filled with insulating material. Composite support profile according to claim 1, wherein the composite support profile has a thermal conductivity that is smaller than 0.5 λ. Composite support profile according to claim 1 or 2, wherein the insulating material has a thermal conductivity that is smaller than 0.05 λ. Composite support profile as claimed in any of the foregoing claims, wherein the top side has a width that is smaller than the bottom side. Composite support profile according to one of the preceding claims, wherein the first indentation is higher than the second indentation. The composite support profile of claim 5, wherein the first indentation lies in the upper half of the composite support profile, and wherein the second indentation lies in the lower half of the composite support profile. A composite bearing profile according to any one of the preceding claims, wherein each indentation is formed as a step. 8. Construction node in a building, wherein an opening is provided in a wall of the building for a window or door, which opening extends in an inner wall and in an outer wall of the wall, wherein the construction node further comprises the composite bearing profile from one of the previous claims, wherein the composite carrier profile is placed on the inner wall, the composite carrier profile carries the window or door, and wherein a first window tablet is at least partially supported by the first recess, and wherein a second window tablet is supported at least partially by the second indentation. Building node as claimed in the foregoing claims, wherein the top of the composite support profile has a width that is smaller than the thickness of the window or door and wherein the window or door is placed on the composite support profile to extend on either side, in the width direction. to protrude the composite support profile. Building node as claimed in claim 8 or 9, wherein the composite bearing profile is placed on the inner wall with, in the width direction of the profile, a crossing towards the outside of the building. 14 BE2017 / 5858 11. Construction node as claimed in claim 10, wherein the overhang is greater than the depth of the second indentation. 12. Method for the location of a window or door in an opening of a building, the method comprising successively: 5 - placing a composite bearing profile on the inner wall; - placing the window or door on the composite support profile; and - placing the window tablets on indentations of the composite support profile.