NL2012796B1 - Wall part for forming an insulated wall of a building, building provided with it and method for manufacturing thereof. - Google Patents

Abstract

The invention relates to a wall part for forming an insulated wall of a building, a building provided with it and a method for manufacturing it. The wall part comprises: - a sandwich panel comprising a first plate and a second plate and a core part fixed between the plates of a lightweight, heat-insulating material, characterized in that the wall part comprises elongated supporting beams which are connected to the sandwich panel and which are substantially parallel and are arranged at a distance from each other in a longitudinal direction of the panel.

Description

A WALL PART FOR FORMING AN ISOLATED WALL OF A BUILDING, A BUILDING EQUIPPED AND A METHOD FOR MANUFACTURING THEM

The invention relates to a wall part for forming an insulated wall of a building. Such a wall part can for instance be used in the construction of houses.

Dutch patent NL2005561 in the name of the same inventor describes a wall part for a stable wall which comprises a sandwich panel with an insulating core, such as expanded polystyrene (EPS). The use of EPS ensures good insulation, while at the same time the weight of the wall part remains relatively low.

An object of the invention is to provide an improved wall part with an increased bearing capacity.

This object is achieved with the wall part for forming an insulated wall of a building, comprising: - a sandwich panel comprising a first plate and a second plate and a core part of a lightweight, heat-insulating material fixed between the plates, with the characterized in that the wall part comprises elongated support beams connected to the sandwich panel and arranged substantially parallel and spaced apart in a longitudinal direction of the panel.

Because supporting beams are integrated in the wall part, a solid prefabricated wall part is obtained with a high insulation value. Moreover, due to the presence of the supporting beams, a wall part of relatively large dimensions can be provided. Therefore, only one wall part needs to be used to form a straight wall of a house, so that relatively few couplings between wall parts are necessary. This prevents the formation of seams between wall parts. Moreover, the supporting beams give the wall part more bearing capacity. It is therefore possible to have a storey floor partially or entirely supported by walls formed by the wall part according to the invention. This makes the wall part according to the invention particularly suitable for use in homes.

In a preferred embodiment, the supporting beams are attached to the second plate of the panel.

When the wall part is used for building a building, the first plate is preferably directed to the outside of the building, so that the second plate is directed to the inside of the building. Preferably, in any case, a part of the core part is located between the first plate and the supporting beams, so that the supporting beams cannot form a cold bridge between the second plate and the first plate.

In a preferred embodiment, a first side of the supporting beams is attached to an outside of the second plate, and a second, opposite side of the supporting beams is attached to a third plate, in which a space is provided between the second plate, third plate and the supporting beams. .

In other words, the wall part has a double sandwich structure with successively the first plate, the core part, the second plate, the support beams and the third plate. The supporting beams keep the second plate and third plate at a distance from each other, so that a space is defined between them. The space contributes to additional insulation.

The third plate is, for example, a plaster plate.

In a further preferred embodiment, pipes are provided in the space between the second plate, third plate and the supporting beams.

For example, a lockable opening is provided in the third plate, such as a door. This makes the space in the wall part accessible from the side of the third plate, for example for placing or connecting pipes.

In a further preferred embodiment, at least a part of the space between the second plate, third plate and the supporting beams is filled with a heat-insulating material, preferably rock wool.

In an alternative embodiment, the supporting beams are provided with recesses in the core part. In this embodiment the supporting beams are located between the first and second plate. This has the advantage that the wall part is of compact design.

In a further embodiment, on the side of the second plate away from the core part, additional beams are provided to which a third plate is attached. The additional beams thus keep the second plate and third plate at a distance. In this manner, a space is created between the second and third plates in a similar manner to that described above, which space can optionally be partially or fully filled with insulating material and / or space for pipes. The additional beams can also be designed as supporting beams for additional load-bearing capacity.

In a presently preferred embodiment, the heat insulating material of the core member comprises a plastic foam, preferably a polystyrene foam, and more preferably expanded polystyrene (EPS) or extruded polystyrene (XPS).

In a further preferred embodiment the first and / or second plate comprises wood. Preferably the first plate and / or second plate is an Orientated Strand Board (OSB). This is a wooden plate in which wood chips are compressed and glued. Alternatively, the first and / or second plate is, for example, a chipboard. It is emphasized that the first plate and second plate can comprise the same material, but also a different material. For example, the first plate comprises wood, while the second plate comprises a plastic.

In a preferred embodiment the first plate, second plate, core part and supporting beams are glued together.

In an embodiment with a third plate, the third plate is preferably also glued together.

For example, a press machine is used for gluing the parts of the wall plate together.

The invention further relates to a building which comprises a wall part as described above.

The same advantages and effects apply to the building as described above with regard to the wall part according to the invention.

In a preferred embodiment, the building comprises two wall parts according to the invention, in which the core part of each of the wall parts is partially exposed and the wall parts are attached to each other, the exposed parts making contact.

The core parts of the wall parts of the building are attached to each other, whereby the core parts touch each other. This prevents cold bridges from forming between the inner wall and the outer wall of the building. The core parts connected to each other form a continuous insulation. For example, the core parts are attached to each other by means of an adhesive, such as PUR or glue.

In a further preferred embodiment, the exposed part of a first of the wall parts is on a long side of the core part and the exposed part of a second of the wall parts is on a short side of the core part.

For example, this construction is used to make the wall parts form an angle. For example, a short side of a first wall portion has been exposed by not providing a side wall. For example, a part of the long side of the second wall part has been exposed by providing the second plate with a shorter length than the length of the core part, so that a part at the end of the core part is exposed at the bottom. The wall parts are placed against each other at an angle of, for example, substantially 90 degrees, the exposed core parts touching each other. For example, a first plate of the first wall part extends beyond the short side, for fixing this projecting part of the first plate to the short side of the second wall part.

In a preferred embodiment the building comprises a foundation on which a floor is provided, in which a short side of the floor is coupled to the foundation by means of a coupling means.

In conventional buildings, the floor is attached to the underlying foundation from below. According to the invention, however, there is no connection on the underside of the floor, and the floor is connected to the foundation via its end face. Because the floor is coupled from its side to the foundation, some degree of horizontal movement of the floor is possible. This makes it possible to absorb shocks, for example in the event of an earthquake.

The coupling means preferably comprises a resilient element, for example of rubber. This increases the effectiveness of the floor in absorbing shocks.

Finally, the invention relates to a method for manufacturing a wall part for a building, comprising: - forming a sandwich panel by fixing a core part of a lightweight, heat-insulating material between a first plate and a second plate, characterized by connecting elongated support beams to the sandwich panel, wherein the support beams are arranged substantially parallel and spaced apart in a longitudinal direction of the panel.

The same advantages and effects as described above with regard to the wall part and the building according to the invention apply to the method.

In a preferred embodiment, a wall part as described above is manufactured with the aid of the method.

In a further preferred embodiment, the method comprises gluing together at least the first plate, second plate, core part and the supporting beams. In an embodiment in which a third plate is provided, this is preferably also fixed by means of gluing.

Further advantages, features and details of the invention are elucidated on the basis of preferred embodiments thereof, wherein reference is made to the accompanying drawings. Figure 1 shows schematically a section of a wall part according to the invention; Figure 2 shows a section of a wall in which wall parts according to the invention are applied; Figure 3 shows a cross-section of an alternative embodiment of a wall part according to the invention; Figure 4 shows a section in front view of a building according to the invention; Figure 5 shows a vertical section of the building from Figure 4, in which the coupling of the floor with the wall parts is shown in detail; Figure 6 shows a vertical section similar to Figure 5, in which an alternative coupling between the floor and wall parts is shown; and - Figure 7 shows in vertical section a roof of the building according to Figure 4.

Wall part 2 (figure 1) comprises a sandwich panel which comprises a first plate 4, a core part 6 and a second plate 8. In the example shown, plates 4, 8 are made of wood. The plates are preferably 4, 8 OSB plates or chipboards. In the example shown, the core part 6 is an EPS core, also called styrofoam. The core part 6 is fixed between the first plate 4 and second plate 8 by means of glue.

On the side of the second plate 8 facing away from the core part 6, supporting beams 10 are fixed. The supporting beams 10 are elongated; Figure 1 shows the support beams in a cross-sectional view. Wall part 2 further comprises a third plate 12, which are kept at a distance from second plate 8 by supporting beams 10. In the example shown, plate 12 is a plaster plate.

The supporting beams create a space between the second plate 8 and third plate 12. This space is partially filled with rock wool 14. The remaining space 16 can be used for the passage of pipes.

The side of the core part can be covered by means of a side panel 18. In the example shown, the support beams 10 are positioned such that one support beam 10 forms a cover for the space between the second plate 8 and third plate 12 (right-hand side of Figure 1). Alternatively, one side panel is provided that covers the entire side of wall part 2.

For example, the first plate 4 and second plate 8 each have a thickness of 5-30 mm, preferably 10-20 mm, more preferably 12-15 mm. Although the thickness of the first plate 4 may differ from the thickness of the second plate 8, the plates 4, 8 preferably have the same thickness.

For example, the core part 6 has a thickness of 50-300 mm, preferably a thickness of 100-250 mm, more preferably a thickness of 150-200 mm.

For example, the support beams 10 have a cross section of 20-50 mm by 50-110 mm, preferably 25-45 mm by 60-100 mm, more preferably 30-40 mm by 70-90 mm. The supporting beams 10 are preferably beams according to the Scandinavian Lumber Standard (SLS). For example, the supporting beams have a dimension of 39 mm by 89 mm. For example, the supporting beams are made of pine.

For example, the distance between the support beams is about 200 mm - 1000 mm, preferably 300 - 900 mm, more preferably about 400 - 800 mm and most preferably about 500 - 700 mm.

For example, plasterboard 12 is approximately 5-20 mm thick, for example 10-15 mm thick, preferably approximately 12.5 mm thick. For example, between second plate 8 and third plate 12, 5-110 mm rock wool 14 is provided, preferably 20-100 mm, more preferably 30-90 mm and most preferably about 70 mm rock wool.

Two wall parts 2 are coupled to form a wall (Figure 2). In the embodiment shown, the first plate 4 of the wall part on the upper side of the figure extends beyond its core part 6 on the left-hand short side of the wall part 2. This projecting part can thus be coupled in a simple manner to a side panel 18 of another wall part for example by means of nails 20. No side wall is provided on the left-hand side of this wall part 2, so that core part 6 is exposed at the end. The other wall part 2 in Figure 2 has a lower plate 8 which is shorter than the length of the core part 6, so that at the end a part of the underside of the core part 6 is exposed. The exposed parts of core parts 6 are connected to each other by an adhesive 22, such as PUR or glue. By connecting the wall sections in this way, the side walls of the building form a continuous insulation of EPS without the presence of thermal bridges.

The supporting beams 10 of the two wall parts near the corner can be attached to each other, for example by means of nails 24. In an alternative embodiment, the supporting beams 10 are placed in the core part 6 (Fig. 3). For this purpose, recesses are made in the core part 6, in which the supporting beams 10 are positioned. In the example shown, the support beams 10 are attached to second plate 8. Optionally, a conduit shaft is created by placing a third plate 12 at a distance from the second plate 8 with the aid of spacers 26. The spacers are, for example, wooden beams, for example SLS beams with a size of 32 by 38 mm. The second plate is, for example, a plaster plate. For both this embodiment and for the embodiments from figures 1 and 2, it is possible to provide a wall cladding 28 against first plate 4.

A house 30 (figure 4) comprises side walls 32, floor 34, roof parts 36 and floor 37. A cavity 38 (figure 5) is provided between side wall 32 and cladding 40. The building is placed on a foundation 42. In the foundation is a anchor 44 that extends through the top of the foundation 42 through a mounting beam 46. The floor 34 is placed on the foundation, the underside of floor 34 resting on one or more support surfaces 47, which for instance comprise felt. The underside of floor 34 is formed by a watertight plate 48. In the example shown, the watertight plate is a polyester plate. However, alternatively, a plate of a different type of plastic or waterproof material can be used.

Floor 34 further comprises a core part 50 of EPS in which floor beams are incorporated (not shown). A chipboard 52 is provided on core part 50, so that the core part 50 is provided between the polyester plate 48 and chipboard 52. In the example shown, the core part has a thickness of 200 mm, the floor beams have a diameter of 71 mm by 200 mm and the chipboard 52 has a thickness of 18 mm.

A second layer of EPS 54 is provided on chipboard 52. Subsequently, a covering floor 56 was created on layer 54, for example by pouring cement. On the side of floor 34 the core part 50 is covered by a side wall 57 of, for example, wood.

For the cavity 38, a bib 58 is provided between side wall 32 and outer wall 40.

The floor 34 is attached to side wall 32 by nailing the underside of side wall 32 to the top of floor 34 with nails 60.

In an alternative construction according to the invention (Figure 6), the floor 34 is attached to foundation 42 in a different way. The anchor 54 has a part that protrudes above the foundation 42. The anchor is attached to a foundation by means of a screw or nail 64. the short side of the floor 34. Here, screw or nail 64 extends into the side wall 57 of the floor. Preferably, a resilient element 66 is provided between the floor 34 and the anchor 54 for absorbing shocks. In the example shown, element 66 is a rubber support. Supporting surface 68 can also be made of rubber.

The storey floor 37 (Figure 7) comprises a core part 70 of EPS, a lower plate 72 and an upper plate 73. Support beams are present in the EPS (not shown). Rock wool 14 is provided between EPS core part 70 and lower plate 72.

A stand 74 is provided on the floor floor for supporting roof part 36 at least in part. Floor 37 comprises a side plate 75 for covering core part 70 and rock wool 14. The roof parts 36 are fixed to floor 37 by means of a purlin 76 .

The present invention is by no means limited to the above described preferred embodiments thereof. The requested rights are determined by the following claims within the scope of which many modifications are conceivable.

Claims (23)

Wall part for forming an insulated wall of a building, comprising: - a sandwich panel comprising a first wooden plate and a second wooden plate and a core part fixed between the plates of a lightweight, heat-insulating material, which is a plastic foam wherein the wall part comprises elongated support beams connected to the sandwich panel and arranged substantially parallel and spaced apart in a longitudinal direction of the panel. Wall part according to claim 1, wherein the supporting beams are attached to the second plate of the panel. 3. Wall part as claimed in claim 2, wherein a first side of the supporting beams is attached to an outside of the second plate, and a second, opposite side of the supporting beams is attached to a third plate, wherein between the second plate, third plate and the girders a space is provided. Wall part according to claim 3, wherein pipes are provided in the space between the second plate, third plate and the supporting beams. Wall part according to claim 3 or 4, wherein at least a part of the space between the second plate, third plate and the supporting beams is filled with a heat-insulating material. Wall part according to claim 5, wherein the heat-insulating material in the space between the second plate, third plate and the supporting beams is rock wool. Wall part according to claim 1 or 2, wherein the supporting beams are provided with recesses in the core part. Wall part according to claim 7, wherein a third plate is placed at a distance from the second plate by means of spacers attached to the second plate. Wall part according to one of the preceding claims, wherein the heat-insulating material comprises a polystyrene foam, preferably expanded polystyrene (EPS) or extruded polystyrene (XPS). 10. Wall part according to one of the preceding claims, wherein the first and / or second plate is an Orientated Strand Board (OSB). 11. Wall part as claimed in any of the foregoing claims, wherein the first plate, second plate, core part and supporting beams are glued together. 12. Building comprising at least one wall part according to one of the claims 1-11. A building comprising two wall parts according to any of claims 1-11, wherein the core part of each of the wall parts is partially exposed and the wall parts are attached to each other, the exposed parts making contact, so that the core parts coupled to each other form a continuous insulation . The building of claim 13, wherein the exposed portion of a first of the wall portions is on a long side of the core portion and the exposed portion of a second of the wall portions is on a short side of the core portion. 15. Building as claimed in claim 13, 14 or 15, comprising a foundation on which a floor is provided, in which a short side of the floor is coupled to the foundation by means of a coupling means. 16. Building as claimed in claim 15, wherein the coupling means comprise a resilient element for absorbing shocks. 17. Building as claimed in any of the claims 12-16, comprising an upright carrying a roof part, the roof part comprising: - a sandwich panel comprising a first plate and a second plate and a core part of a lightweight, heat-insulating mounted between the plates material, wherein the wall part comprises elongated support beams connected to the sandwich panel and arranged substantially parallel and spaced apart in a longitudinal direction of the panel. 18. Method for manufacturing a wall part for a building, comprising: - forming a sandwich panel by fixing a core part of a lightweight, heat-insulating material between a first plate and a second plate, characterized by connecting it to the sandwich panel of elongated support beams, wherein the support beams are arranged substantially parallel and spaced apart in a longitudinal direction of the panel. A method according to claim 18, wherein the wall part is a wall part according to one of the claims 1-11. A method according to claim 19, comprising gluing together at least the first plate, second plate, core part and the supporting beams. Use of the wall part according to one of claims 1 to 11 in a building. Use according to claim 21, wherein the wall part functions as the roof part of the building. Use according to claim 21, wherein two wall parts according to claims 1-11 are used, wherein the core part of each of the wall parts is partially exposed and the wall parts are attached to each other so that the exposed parts make contact, so that the core parts coupled to each other continuous insulation.