BE1023853B1 - BUILDING ELEMENTS AND ROOF CONSTRUCTION - Google Patents

Abstract

Building element, more especially for roof, wall or floor constructions, wherein this building element (1) is at least composed of a base plate (2) and two ribs (3) arranged thereon between which there is insulating material (4), the aforementioned two ribs ( 3) have an average height H1 and a thickness D and the aforementioned insulating material (4) comprises at least rigid foam (11), characterized in that the height H4 of the rigid foam (11) is greater than the aforementioned thickness D of the ribs (3) and the top surface (22) of said hard foam (11) is at least 0.2 H1 below the top (23) of the ribs (3). The invention furthermore relates to a roof construction (14) which comprises such building elements (1).

Description

Building elements and roof construction.

This invention relates to building elements, more particularly for roof, wall or floor constructions, as well as to a roof construction that uses such building elements.

The building elements or building panels known from the state of the art mainly exist in two types. On the one hand there is the so-called open-scaled or open building element, in which a base plate is applied on only one flat side of the building element or building panel and the other side, namely the open side, is mainly formed by the insulation material itself and, on the other hand, the closed or sandwich component with an upper plate arranged on the second flat side, so that insulation material is present in the space between the base plate and the upper plate. In the case of sandwich elements, the top and bottom plates are relatively thin. Such building elements can be used as a roof element, as a wall element or as a floor element. For examples of open-scaled roof elements and closed or sandwich roof elements, reference is made to EP 0 978 601, EP 2 110 487 and EP 1 162 050, EP 2 273 024, respectively.

The use of building elements as an insulating, possibly self-supporting, roof element is already known per se. For this purpose, reference is made by way of example to EP 0 450 731 or EP 1 253 257. Such roof elements can be mounted with their base plate on a simply constructed roof hood, for example a roof hood with only purlins. After the installation of such roof elements, they are usually still fitted with tile battens which in turn support the roof tiles or other roof covering. In such a construction, the roof element fulfills the function of a traditional insulated roof. It is also possible that the aforementioned base plate forms the inner lining of the relevant roof construction or that the base plate is provided with such inner lining. Such roof elements are customarily prefabricated for a home.

A current challenge in the construction sector is the ever-increasing demands placed on buildings in terms of thermal and / or acoustic insulation. Polyurethane (PUR) or polyisocyanurate (PIR) are effective thermal insulation materials, but due to their rigidity and low mass, they lead to noise reduction problems. Roof or building elements form a rigid construction, certainly in those cases where rigid foam is used as insulation, so that ambient noise can easily propagate to the inside of the building. Mineral wool is a known alternative insulation material that exhibits better sound insulation, but, however, produces a much more limited thermal insulation than, for example, expanded polystyrene (EPS), polyurethane (PUR) and polyisocyanurate (PIR). A well-known solution for sound insulation problems with scaled-up building elements is therefore the complete replacement of the hard foam insulation with mineral wool or other soft insulation materials.

It is known from EP 2 110 487 to build building elements with a first layer and a second layer of insulating material, the insulating material of the second layer being different from that of the first layer. This ensures that specific properties of both insulation materials can be combined in one element. For example, an insulation material with favorable acoustic properties can be combined with an insulation material with favorable mechanical properties. The noise reduction obtained is limited.

EP 2 273 024 discloses a building element of the closed type wherein the top plate is acoustically decoupled from the base plate. This technique cannot be applied to open-scaled building elements.

NL 2010692 describes renovation elements that can be aligned with existing building elements. The composite element can form a sandwich element with two different insulation materials, for example polyurethane (PUR) and rock wool. The ribs of the elements arranged on top of each other can be acoustically disconnected from each other by means of disconnection strips. NL'692 does not offer a solution for improving the sound damping of prefabricated open-scaled building elements.

In view of improved sound insulation, EP 0 450 731 describes, in its second possible embodiment, a sandwich element in which two thin sheet materials enclose foamed insulating material, and an insulating wool is applied to the top sheet. The foamed insulation material in the thin sandwich element ensures the cohesion of the roof element. EP 0 450 731 does not offer a solution for open-scaled building elements. Moreover, such an element greatly reduces the thermal insulating value for only a limited improvement in sound insulation. Such a solution is therefore insufficient nowadays.

With a view to obtaining improved sound attenuation in thermally insulating building elements, the present invention according to a first independent aspect relates to a building element, more especially for roof, wall or floor constructions, wherein this building element is at least composed of a base plate and two on it ribs arranged between which insulating material is present, wherein said two ribs have an average height H1 and an average thickness D and said insulating material comprises at least rigid foam, characterized in that the height H4 of the rigid foam is greater than the aforementioned thickness D of the ribs and the upper surface of the aforementioned rigid foam is at least 0.2 Hl below the upper side of the ribs.

Because the rigid foam takes up a considerable height H4, namely more than the thickness D of the ribs, it contributes significantly to the rigidity of the structural element and, according to the inventors, a considerable sound damping can still be achieved. The aforementioned rigid foam is preferably arranged on the base plate. A vapor-tight layer can optionally be provided between the base plate and the rigid foam. Because the upper surface of the rigid foam is still at a considerable distance of at least 0.2 Hl below the upper side of the ribs, a cavity is created between the covering to be applied later, for example roof covering, and the rigid foam material. Roof covering is preferably provided on the element by means of an acoustically interrupted suspension.

In contrast to the prevailing view that hard foam should be avoided as much as possible when good acoustic insulation is to be achieved, the present inventors have realized that sufficient hard foam, and in particular when applied directly to the base plate, can just contribute to a improved sound insulation.

Preferably, the aforementioned rigid foam is cured against the aforementioned ribs, fully glued thereto, or, in another way, firmly connected to the aforementioned ribs.

Preferably, the aforementioned rigid foam extends from the base plate to a height of at least 0.3 Hl, or, in other words, to a height of between 0.3 and 0.8 Hl. In this way good thermal insulation is combined with good sound insulation. The thickness of the rigid foam insulation material is preferably at least 2 times the thickness D of the ribs, or even at least 4 times the thickness D.

Preferably, the aforementioned rigid foam extends from the base plate to a height H4 of at least 0.5 times the height of the ribs H1, or even 0.7 times the height H1.

Preferably, the aforementioned insulating material further comprises soft or flexible insulating material which is located above the hard foam. The soft insulation material provides additional sound absorption in the aforementioned cavity between the upper surface of the rigid foam and the roof covering. Moreover, a direct incident of the sound on the hard foam material is avoided.

Preferably, the aforementioned soft insulation material extends at least to a height corresponding to 0.9 times the height H1 of the ribs, and this preferably from the upper surface of the rigid foam. Even better, the upper surface of the soft insulating material corresponds to the height H1 of the ribs, or substantially to the height H1 of the ribs. The soft insulation material is preferably provided directly on the upper surface of the rigid foam, i.e. without intermediate insulation materials or sheet materials.

A watertight and / or vapor-permeable film is preferably provided on the top or open side of the building element, for example a so-called under-roof film. Such a foil is preferably composed of one or more layers of polypropylene and / or polyethylene. This foil is preferably applied continuously over the installed components.

Preferably, the aforementioned rigid foam is selected from the range of polyurethane (PU), polyisocyanurate (PIR), Resol and expanded polystyrene (EPS) or extruded polystyrene (XPS).

The construction element of the invention preferably relates to a so-called open-scaled element, wherein the rigidity of the construction is mainly or exclusively supplied by the base plate, the aforementioned ribs and the rigid foam. The element preferably has only one plate material, namely a plate material on the underside of the element, on which then, preferably, the ribs are directly attached. The structural section of said ribs is preferably made in one piece and, in other words, does not consist of a plurality of smaller ribs or slats attached to each other. In those cases where the ribs are composed of a plurality of superimposed parts, the upper surface of the aforementioned rigid foam is preferably at least 0.2 times the height H3 below the top of the lower one-part portion of the ribs in question, where H3 is the height is from this one-part section. According to a special possibility, the ribs in question consist of so-called LVL (laminated veneer lumber). It is clear to a person skilled in the art that the structural section of such ribs must also be seen as one-piece, since the lamination of the veneers is such that they behave as a one-piece rib.

The aforementioned ribs preferably have a height H1 between 150 and 250 millimeters. The height H1 of the ribs proposed here leads to improved sound insulation in the low frequency range, for example in the range of 200 Hz and lower. The height of the ribs plays a significant role in the flexural stiffness of the ribs and the element as a whole. By increasing the height of the ribs, the resonance frequency thereof can be reduced considerably, so that a good sound insulation can be achieved for the total element even in the low fire frequency range.

The ribs preferably have a thickness D of 20 millimeters or more, for example 28 millimeters.

According to a second independent aspect, the present invention also relates to a roof construction comprising one or more building elements with the features of the first aspect, wherein a roof covering is attached to the building elements, characterized in that the distance between the underside of the roof covering and the upper surface of the aforementioned rigid foam is more than 7 centimeters, for example between 7 and 15 centimeters and / or that this distance is at least 0.3 times the height H1 of the ribs. As aforementioned, the aforementioned roof covering is preferably acoustically interrupted on the roof elements. Preferably, the aforementioned distance is for the most part filled with soft insulation material. It is clear that, mutatis mutandis, the building elements can also be used for a floor covering or a wall covering, whereby this is applied instead of a roof covering, a floor or ceiling or an internal or external wall covering and the aforementioned distances are achieved between the underside thereof and the upper surface of the rigid foam.

According to a third independent aspect, the present disclosure describes, for the same purpose, another building element, more especially for roof, wall or floor constructions, said building element being composed at least of a base plate on which two or more ribs are arranged with an intermediate insulation material comprising said ribs and wherein this building element is of the open type, characterized in that said ribs comprise an acoustic interruption.

For the same purpose, according to a fourth independent aspect, the present disclosure describes a building element, more especially for roof, wall or floor constructions, wherein this building element is composed at least of a base plate on which two or more ribs are arranged with an intermediate between said ribs insulation material, and wherein this building element is preferably of the open type, characterized in that the aforementioned building element further comprises transverse slats which are attached to the aforementioned ribs via an acoustic interruption. Such a technique can also be applied to building elements of the closed type.

Both in the third and in the fourth aspect, it is achieved that the further cladding of the building element, such as pans or the like, is automatically - that is to say, without additional special measures - acoustically disconnected from the base plate, without providing special gauges of the roof covering must be taken. This allows significant noise reduction.

In the following, preferred embodiments are discussed that may be applicable to all aspects of the invention and / or disclosure.

Preferably, said insulating material comprises at least one hard foam layer, such as polyisocyanurate (PIR) or polyurethane (PUR). Alternatively, hard foam based on resol, EPS or XPS can be used. It is mainly with such elements that the present invention can bring about significant sound attenuation. The rigid foam layer is preferably located against the base plate, with no appreciable intermediate insulating material. A vapor-tight layer can optionally be provided between the base plate and the rigid foam. Preferably, the aforementioned acoustic interruption, from the third and / or fourth aspect, is above the aforementioned hard foam layer, in other words the acoustic interruption is further away from the base plate than the upper side of the hard foam insulation layer. In this way, the rigid construction of base plate and hard foam is acoustically decoupled from the outside of the building element and any covering.

Preferably, said insulating material comprises at least one layer of a flexible insulating material, such as a layer of rock wool, glass wool, wood wool or the like. Such an insulating material is preferably arranged above a layer of rigid foam insulating material, but, in the case of the fourth aspect, for example, can also be the only insulating material of the building element. A flexible insulation material has relatively good sound-damping properties. The aforementioned acoustic interruption, of the third and / or fourth aspect, is preferably at the level of the flexible insulating material.

Preferably, said ribs have such a height that they protrude above the insulating material. In this way, lines or slats can easily be attached to the protruding ribs. Moreover, an air chamber is formed between the insulating material and the optional covering of the building element. Such an air chamber is advantageous for sound absorption. This is because sound reflections can occur in this air chamber or cavity that have a quenching effect on the sound waves. When the top insulation material is a flexible insulation material such as glass wool or rock wool, the sound is absorbed to the maximum. However, it is not excluded that they would exhibit the same height as the insulating material or even exhibit a smaller height than the insulating material. In the latter case, the protruding insulating material is preferably formed by a flexible insulating material, such as rock wool or glass wool. In this way it can be depressed to some extent for applying lines or slats, such as tile slats, to the ribs.

Preferably, the aforementioned acoustic interruption of the third and / or fourth aspect is at least formed by collapsible pads and / or decoupling strips. Such strips are known per se. These may be, for example, strips or cushions made of open-cell or closed-cell foam rubber, polyethylene foam or polyvinyl chloride foam. According to a variant, it is also possible to use a gel or a liquid which is, for example, in a closed, deformable container.

Preferably, a plurality of said compressible cushions and / or uncoupling strips are provided along the length of said ribs, said compressible cushions being separated from each other by an air gap or by a flexible, unloaded insulating material. According to another variant, resilient profiles, for example of plastic or metal, can be used as an acoustic interruption.

A watertight and / or vapor-permeable film is preferably arranged on the open side of the building element, for example a so-called under-roof film. Such a foil is preferably composed of one or more layers of polypropylene and / or polyethylene. This foil is preferably applied continuously over the installed components.

The building elements of the invention are particularly suitable for use in a roof construction. It is clear that the invention also relates to a roof construction which comprises one or more building elements with the characteristics of the first or second aspect or the preferred embodiments thereof.

The building elements according to all aspects of the invention are preferably self-supporting. By this is meant that such building elements can form a self-supporting structure, or in other words in such a structure are able to bear their own weight without significant distortion. This property can lead to very simple constructions.

Preferably at least the base plate and / or, in case a top plate is used in the element of the fourth aspect, the top plate consists essentially of a wood-based material such as a multiplex plate, OSB plate (Oriented Strand Board), a wood chipboard, a wood fiber board such as MDF or HDF (Medium Density Fiberboard or High Density Fiberboard). Other sheet materials are also possible, such as flax chipboard, gypsum board, cement fiber board, gypsum fiber board or silicate board. The material used for the base plate and / or the top plate can have the property that it is water-resistant and / or fire-retardant, as can be the case with wood chip plate. The base plate of the building element and, if available, the top plate, preferably have a thickness of at least 6 millimeters, and more preferably of at least 10 millimeters and most preferably at least 12 millimeters.

According to a preferred embodiment, the building element of the invention furthermore has the feature that the base plate on the side facing inwards is finished with decorative material, for example with a laminate layer, scraps or the like. By applying such a building element, the finishing on the inside of the building can be simplified.

Said ribs are preferably wooden ribs or ribs made of a material other than the insulating material.

The aforementioned ribs are preferably designed as squares with a thickness D of 20 millimeters or more, for example 28 millimeters, and a height H1 of 150 millimeters or more, for example 170 millimeters.

Possibly, the aforementioned ribs without intermediate insulating material are mounted on the aforementioned base plate. The ribs in question can, for example, be attached by means of nail, screw and / or glue connections and / or via any other fixing means. The direct attachment of the aforementioned ribs to the base plate, namely without intermediate insulating material, ensures that the ribs can absorb the applied forces in a good manner and possibly transfer them to the underlying structure when the component is bent. By a suitable choice of the height H1 of the ribs, the transmission of sound to the base plate can nevertheless be limited. Moreover, according to this preferred embodiment, a simple construction of the building element can be achieved. As is apparent from the foregoing, the ribs in question, according to the invention, are preferably both directly connected to the base plate and laterally connected to the insulating material, for example by an adhesive connection, or because the insulating material, for example in the case of rigid foam, is cured between the corresponding ribs.

Preferably, the aforementioned flexible or soft insulating material is selected from the list consisting of cellulose-based insulating material, insulating material based on wood fibers, mineral wool, glass wool, rock wool. Plastic-based flexible foams such as PU foam or melamine foam can also be used as a flexible insulation material. Furthermore, plastic wool, such as polyester wool, is also possible. In the case of rock wool or mineral wool, a significant fire-retardant effect is achieved. Cellulose-based insulation materials are known for their good acoustic insulation value, moreover they also show an acceptable to very good thermal insulation value. The cellulose-based insulation material can be applied to the building element either dry, as a self-contained layer or as a viscous liquid substance, after which it is cured or dried out. Insulation materials based on wood fiber also exhibit good acoustic insulation values in combination with an acceptable to very good thermal insulation value. The wood fibers can herein be connected to each other, for example, with the aid of a polyolefin. It is also possible that this insulation material is provided with fire-retardant additives, such as one or more inorganic nitrogen-containing mineral acids. For example, the wood Flex insulation boards marketed by HOMATHERM® are also suitable for use in the components of the present invention.

The rigid foam is preferably selected from the list consisting of polyurethane, polyisocyanurate, expanded polystyrene, extruded polystyrene and phenol insulating material.

Still according to the invention, for the flexible or soft insulating material, it is also possible to work with other insulating materials such as wood wool, flax wool, sheep wool, plumes, such as for example duck plumes or flaked foam. Flaked foam can, for example, contain foam flakes connected with polyurethane, these foam flakes being obtained, for example, as waste in the production of mattresses or seats.

According to a preferred embodiment, the building element of the present invention has a thermal resistance value (Rc) of more than 5.5 m2K / W, and preferably more than 6.45 m2K / W and most preferably more than 7.2 m2K / W. Such insulating values can be achieved with a layer of insulation material based on polyurethane or polyisocyanurate, this layer of insulation material per se having a thickness of 65 millimeters, 75 millimeters and 95 millimeters or more, respectively.

The building element of the present invention is preferably elongated, said ribs preferably extending in the longitudinal direction of the building element. Preferably, two or more such ribs are used. The insulating material is preferably located at least for a part thereof between the aforementioned two or more ribs. Such ribs preferably consist of wooden beams or squares, preferably with a rectangular cross-section. Naturally, it is not excluded that a material other than wood is used, and / or that a different cross-section is opted for for these ribs, such as for a cross-section similar to the cross-section of an I-profile. Preferably, a lateral distance of at least 30 centimeters is kept between the ribs and more preferably of at least 40 centimeters. It is not excluded that the ribs would have a mutual distance of 80 centimeters or more.

It is clear that where there is a base plate, it is preferably this plate that is directed inwards in the roof construction. However, it is clear to the person skilled in the art that similar effects can be achieved if this base plate were directed outwards. It is therefore not excluded that the building elements described in the context of the invention can be used upside down in a construction, for example in a roof construction.

For the same purpose, according to a fifth independent aspect, the present disclosure describes another roof construction, wherein this roof construction comprises one or more self-supporting building elements that are at least composed of a base plate, ribs and insulating material made of rigid foam, the aforementioned roof construction comprising a roof covering, characterized in that the aforementioned roof cladding is attached to the aforementioned self-supporting building elements via an acoustic interruption. Preferably, there is a space between the rigid foam and the roof covering that contains a sound-absorbing material, preferably a flexible or soft insulating material. The current independent aspect provides for the construction of a roof construction on the basis of known self-supporting building elements, either of the open type or of the closed type, whereby a similar effect is achieved as on the basis of the building elements of the other aspects. The acoustically interrupted attachment of the roof covering leads to a reduced propagation of sound waves to the building element. The placement of a sound-absorbing material between the roof covering and the rigid foam insulation material leads to a further noise reduction.

It is clear that for the insulating materials, ribs and base plates of the fifth aspect the ones mentioned in connection with the components of the remaining aspects can be used. The aforementioned acoustic interruption is preferably achieved in that the roof covering is mounted on slats or ribs which are attached to the building element via an acoustic interruption.

Furthermore, it is clear that a roof construction with the characteristics of the fifth aspect can be obtained on the basis of the building elements of the other aspects of the invention and / or disclosure.

With the insight to better demonstrate the features of the invention, a few preferred embodiments are described below as an example without any limiting character, with reference to the accompanying drawings, in which: figure 1 represents a building element with the features of the first in perspective; aspect of the invention; figure 2 represents a view in the direction F2 indicated in figure 1; figures 3 and 4 in a view similar to that of figure 1 represent building elements with inter alia the features of the fourth aspect of the disclosure; figure 5 represents a roof construction with the features of the invention in perspective; figures 6 and 7 show examples of building elements according to the invention in a view similar to that of figure 1; figure 8 represents a building element with the features of the first aspect of the invention in a view similar to that of figure 1.

Figure 1 shows a building element 1, more particularly a roof element or roof panel, with the features of, among others, the third aspect of the present invention.

The roof element of figure 1 comprises a base plate 2 with ribs 3, wherein insulation material 4 is present between these ribs 3. In the case shown, two compartments 5 are formed on the base plate 2 on the basis of the ribs 3, both of which are provided with the aforementioned insulating material 4. It is clear that it is also possible to work with a single compartment 5, or with three or more compartments 5 which contain insulating material 4. It is also clear that the insulating material 4 of the different compartments 5 is preferably similarly constructed.

The building element 1 of figure 1 relates to an open-ended roof element. The flat side 6 of the roof element, which is opposite the aforementioned base plate 2, is here open and this open side 6 is mainly formed by the aforementioned insulating material 4. By "open" is meant that on the relevant side 6, above the insulation material 4, no structural parts of the roof element. It is of course possible that the insulating material 4 on the open side 6 is covered by a membrane, foil, print or the like. Such a covering layer is preferably water-retaining and / or vapor-opening, but is not shown here.

It is noted that the roof element of Fig. 1 is shown in short and that the length L of a roof element can in practice be several times its width B. The length L can be provided to measure to the roof construction and is preferably between 2 and 8 meters, while the width B of the element 1 depends on the number of compartments 5 that the roof element has, the width B1 of one compartment 5 preferably is between 35 and 60 centimeters, with a width B1 of approximately 40 centimeters being a good value. The height H of a roof element depends on the height H1 of the aforementioned ribs 3 and can herein preferably be chosen between 7 and 35 centimeters. The associated total height H 2 of the insulating material 4 is preferably smaller than the height H 1 of the aforementioned ribs 3 and can herein preferably be chosen between 6 and 33 centimeters in accordance with the height H 1 of the ribs 3.

The aforementioned base plate 2 can be selected from the range of wood chipboard, gypsum board, gypsum fiber board, plywood board, OSB board (Oriented Strand Board) and silicate board. Such a base plate 2 can be provided on its outwardly facing side 7, that is to the inside of the roof construction, with finishing layers, such as with one or more lacquer layers, laminate layers, or with scrapes attached thereto. The base plate 2 may also have fire-retardant and / or water-resistant properties. It is known per se to the person skilled in the art how such properties can be obtained with the base plate materials mentioned here. It is generally assumed that such a base plate, and in particular chipboard, has no or practically no heat-insulating properties, but it is not excluded that it is possible to work with base plates which can offer a significant heat insulation.

The aforementioned ribs 3 or squares preferably consist of wood such as pine or pine and preferably cover the entire length of the roof element. Preferably, each rib consists of one piece in the longitudinal direction and preferably has a thickness of 20 to 45 millimeters. Instead of being made in one piece, one or more of the aforementioned ribs can also be assembled in their spring direction from several parts, for example by attaching shorter ribs to each other. Such confirmation can be carried out with a so-called finger joint. For an example of such a technique, reference is made to the aforementioned EP 1 162 050. It is noted that the base plate can also consist of sections welded together.

The special feature of the roof element 1 shown is that, in accordance with the third aspect of the invention, it comprises ribs which exhibit an acoustic interruption 8. As shown in Figure 2, in this case, the acoustic interruption 8 is formed by compressible cushions 9 arranged along the length L of the ribs 3, each time separated by, for example, an air gap 10.

The roof element 1 comprises a layer of insulating material from rigid foam 11 and a layer of flexible insulating material 12, for example mineral wool. The aforementioned acoustic interruption 8 is located above the aforementioned layer of rigid foam 11, in particular more towards the open side 6 of the roof element 1 than the layer of rigid foam 11. More specifically, the acoustic interruption is, in this case, at the level of the flexible insulating material 12. The rigid foam layer is hereby formed from an insulating foam, which in the present case is applied in liquid form to the building element 1 and is cured there. It may, for example, be polyurethane foam or polyisocyanurate foam which, as is known per se, can be formed on the basis of the reaction of two components. The layer of flexible insulating material 12 is located directly above the hard foam layer 11.

The roof element in figures 1 and 2 also forms an example with, inter alia, the features of the first aspect of the invention mentioned in the introduction. To this end, the ribs 3 have an average height H1 and a thickness D. The insulating material 12 comprises at least hard foam 11. The height H4 of the hard foam 11 is greater than the thickness D of the ribs 3 and the upper surface of the hard foam 11 is at least at a distance A of 0.2 H1 below the top of the ribs 3. In this case, the top surface of the rigid foam 11 is also at least at a distance A1 of 0.2 H3 from the top of the portion 3A of the ribs 3, H3 being the height of the lower one-part portion 3A of the ribs 3. The rigid foam 11 is mounted on the base plate 2, in particular against it and cured against the ribs 3. A soft or flexible insulating material 12 is provided on top of the hard foam 11. The soft insulating material 12 extends at least to a height H2 corresponding to 0.9 Hl.

Figure 3 shows a roof element with the features of the fourth aspect of the invention. It concerns, in this case, an open-ended roof element. The roof element 1 is provided with transverse slats 13. These slats 13 are attached to the ribs 3 via an acoustic interruption 8. The layer of flexible insulating material 12, which is located above the hard foam 11, extends between the slats 13. In other words, the slats 13 are sunk into the flexible insulating material 12. The acoustic interruption 8 is located above the hard foam 11, at the height of the flexible insulating material 12. Optionally, this layer of flexible insulating material 12, and possibly also the slats 13, can extend over a plurality of building elements installed side by side. In this way an installation can be achieved with a limited risk of the occurrence of thermal bridges in the connection of the components installed next to each other.

Figure 4 shows a variant of a roof element with the features of, inter alia, the fourth aspect, in which the transverse slats 13 are not recessed, but instead extend above the flexible insulating material 12. The acoustic interruption 8 is in this case above the whole of the insulating material 4. These slats 13 can be designed as tile slats with a continuously compressible cushion 9 on the underside thereof. These slats 13 can optionally extend over a number of building elements installed side by side.

It is clear that the attachment of the two parts 3A-3B of the ribs 3 of figures 1 and 2 or of the slats 13 to the ribs 3 of figures 3 and 4 can be done by means of screws or nails through the aforementioned compressible pillows 9.

It is clear that the embodiment of figure 4 also forms an example of the first aspect of the invention, in which case, moreover, a disconnected roof covering can then be obtained automatically, namely without special additional measures having to be taken for that purpose.

It is further noted that, for example the element of figure 4, can also be applied upside down, whereby a disconnected inner lining is then automatically achieved, which also causes significant sound insulation.

Figure 5 shows a roof construction 14 with among other things the features of the fifth aspect of the invention. In this case the roof elements 1 from figure 1 are used. A relatively simple roof canopy 15, as shown, can be assumed, wherein a limited number of purlins 16 is used, on which the roof elements 1 are then fixed on the basis of mechanical fastening means such as nails and / or hooks. Any seams between the roof elements can then be finished even further, for example by filling them with an insulating material, such as polyurethane foam. Preferably, such insulation material only extends to a height below the aforementioned acoustic interruption 8.

As shown, the further roof covering or roof covering 17 can then be applied to these roof elements 1. For example, as shown here, roof tiles 18 can be installed after tile slats 19 have first been provided. It is clear that if the roof element of figure 4 were to be applied, the slats 13 mentioned there could form the tile slats 19.

The roof construction 14 of figure 5 has the feature of the fifth aspect mentioned in the introduction, namely the feature that the roof covering 17 is attached to the roof elements 1 via an acoustic interruption 8. Between the rigid foam 11 and the roof covering 17 there is a space 20 which contains the flexible insulating material 12.

Figure 6 shows another roof element 1 with the characteristics of the third aspect, wherein the roof element 1 has only one compartment 5. In this case it concerns a compartment with a width B1 of 80 centimeters or more. In order to give the roof element 1 a good rigidity, in particular against torsional deformation, a plate material 21, for example similar to the base plate 2, is applied above the hard foam 11. This plate material 21 extends between the ribs 3. The acoustic interruption 8 is located above this plate material 21.

Figure 7 shows a variant in which the sheet material 21 extends into the ribs 3, or between the parts 3A-3B of the ribs 3, in particular below the acoustic interruption 8 in these ribs 3.

It is clear that any of the building elements shown in the figures can be used to form a roof construction 14 in accordance with the fifth aspect of the invention.

According to a variant of the embodiment shown in Fig. 7, which is not shown, it is possible that the parts 3B have previously been designed as slats which are offset with respect to the parts 3A and, in other words, are not vertically above the rib parts 3A. With such building elements, a roof construction 14 can also be obtained with the characteristics of the invention

It is noted that the open side 6 of the roof elements of the invention, and in particular of the embodiments shown in the figures, can be finished with a membrane, foil or a coating, which must not necessarily have significant heat-insulating properties. . The application of such cover layers is not illustrated here.

Figure 8 shows another embodiment of a roof element 1 with, inter alia, the features of the first aspect of the invention, wherein in this case the ribs 3 are free from acoustic interruption and extend in one piece from the base plate 2 up to the top or open side 6 of the roof element 1. In such a case, the height H1 of the ribs 3 is equal to the height H3 of the lower one-part portion of these ribs 3. The upper surface 22 of the rigid foam 11 is at a distance A from the upper side 23 of the ribs 3, this distance A being at least 0.2 times the height H1 of the ribs 3. The rigid foam 11 extends from the base plate 2 up to a height H4 greater than 0.3 times the height of H1 of the ribs 3. In this case even up to a height H4 greater than 0.5 times the height H1 of the ribs 3. The height H4 is also many times more than the thickness D of the ribs 3, in this case at least 3 or 4 times the thickness D of the ribs 3. The rigid foam 11 is cured in the compartments 5, against the base plate 2 and the ribs 3. The soft or flexible insulating material 12, together with the rigid foam 11, extends to a height H2 corresponding to more than 0.9 times the height of the ribs H1.

It is clear that, in a roof construction composed of one or more elements 1 of the example of Figure 8, the distance between the underside of the roof covering and the upper surface 22 of the rigid foam 11 is at least 0.3 times the height H1 of the ribs 3.

It goes without saying that the base plate 2 on its side remote from the rigid foam can be provided with further plate materials or other, possibly decorative, finishes, such as plasterboard.

The present invention is by no means limited to the embodiments described above, but such building elements and roof constructions can be realized according to different variants without departing from the scope of the present invention. For example, it is possible to use, instead of the invention, the flat building elements shown in the figures, to use so-called arched building elements. These are characterized in that the aforementioned base plate and / or top plate are curved according to an arc with a radius of, for example, 2 to 10 meters, and this preferably around an axis parallel to the longitudinal direction of the building element. These building elements are suitable, for example, as an acoustic roof element in a roof construction that has a certain curvature. Such roof elements preferably extend with their longitudinal direction in the width of the roof construction.

The elements of the invention can for instance also be used as a wall construction, or floor construction with an acoustically decoupled finish, or as a house separating wall, wherein then, preferably, two of such elements are turned towards each other for forming the separation. In other words, the elements of the invention can therefore also be combined in pairs or more to form such separations and lead to an extremely low-noise wall.

Claims (12)

Conclusions. 1, - Building element, more especially for roof, wall or floor constructions, wherein this building element (1) is at least composed of a base plate (2) and two ribs (3) arranged thereon between which there is insulating material (4), the aforementioned two ribs (3) have an average height H1 and a thickness D and the above-mentioned insulating material (4) comprises at least hard foam (11), characterized in that the height H4 of the hard foam (11) is greater than the aforementioned thickness D of the ribs (3) and the top surface (22) of the aforementioned rigid foam (11) is at least 0.2 Hl below the top (23) of the ribs (3). Building component according to claim 1, characterized in that the aforementioned rigid foam (11) is arranged on the base plate (2). Building component according to claim 1 or 2, characterized in that the aforementioned rigid foam (11) is cured against the aforementioned ribs (3), or is glued to the surface completely. Building component according to one of the preceding claims, characterized in that the aforementioned rigid foam (11) extends from the base plate (2) to a height H4 of at least 0.3 Hl. Building component according to one of the preceding claims, characterized in that the aforementioned insulating material (4) further comprises soft insulating material (12) which is arranged above the rigid foam (11). Building component according to claim 5, characterized in that the aforementioned soft insulation material (12) extends at least to a height corresponding to 0.9 Hl. Building component according to one of the preceding claims, characterized in that the above-mentioned rigid foam is selected from the range of polyurethane (PU), polyisocyanurate (PIR) and expanded polystyrene (EPS). Building component according to one of the preceding claims, characterized in that it is a so-called open-scaled element. Building element according to one of the preceding claims, characterized in that a roofing foil is arranged on the upper side (6) of the element (1). Building component according to one of the preceding claims, characterized in that the height H1 of the aforementioned ribs (3) is between 150 and 250 millimeters. A construction, preferably roof construction, wherein this construction (14) comprises one or more building elements with the features of the preceding claims, wherein a covering, preferably a roof covering (17) is attached to the building elements (1), characterized by that the distance between the underside of the covering (17) and the upper surface (22) of the aforementioned rigid foam (11) is more than 7 centimeters, for example between 7 and 15 centimeters and / or that this distance is at least 0.3 Hl. Construction according to claim 11, characterized in that the aforementioned distance is for the most part filled with soft insulation material (12).