NL2024920B1 - Building element and method for its manufacture - Google Patents

Abstract

The invention relates to a building element (1), in particular for roof, wall and floor constructions, wherein said building element (1) comprises at least one formwork (2), consisting of at least two ribs (3-4) and a first plate (6), wherein the building element (1) comprises at least a first layer of insulating material (7) arranged in the formwork (2), said first layer of insulating material (7) making contact with the first plate (1) over at least part of its surface. 6), characterized in that the formwork (2) further comprises a second plate (8) opposite to the first plate (6), said second plate (8) being acoustically open, said first layer of insulating material (7) being cured are connected at least against the aforementioned first plate and/or the ribs (3-4) of the formwork (2) by means of a connecting element (18). The invention further relates to a method for manufacturing such a building element (1).

Description

P126372EN00 Title: Building element and method for manufacturing the same The present invention relates to a building element, as well as to a method for manufacturing a building element according to the invention.

In particular, the invention relates to a building element for roof, wall and floor constructions, wherein the building element is thermally insulating and self-supporting. A self-supporting element is an element that can be placed with a limited or without an underlying, supporting structure.

Such a building element is for instance known from EP 0 978 601. The building element comprises a base plate, a foam with thermally insulating properties and one or more ribs placed in the foam concerned. The building element is thermally insulating, but has sub-optimal acoustic insulation and sub-optimal resistance to fire.

For example, EP 2 110 487 describes a building element consisting of a base plate, ribs and two insulating materials. One insulation material is provided against the base plate and is a mineral wool. The other insulating material is a hard foam and forms the side of the building element that faces the roof and the outside air. The rigid foam guarantees thermal insulation and structural strength of the building element. The mineral wool provides acoustic insulation and resistance to fire of the building element. However, the acoustic insulation and the resistance to fire of the building element are sub-optimal.

It is known that the acoustics of a room can be improved by providing a sound-absorbing or acoustically insulating finish in the room in question. Such a finish is known, for example, from GB 664 729 and from EP 2 095 029, in which the acoustic insulation is obtained via a so-called Helmholtz resonator, in which the sound waves are extinguished with the air as a medium via, on the one hand, collisions with the walls of the openings. in the finish and on the other hand by the air in the space behind the finish which functions as a spring connected to a mass, the mass being the air in the openings in the finish. The problem with the finish of GB 664 729 and EP 2 095 029 is sub-optimal to almost no thermal insulation and sub-optimal resistance to fire.

The object of the invention is in the first place an alternative building element, in which, according to various preferred embodiments, a solution can be obtained for the limitations of the building elements from the prior art. In particular, the invention contemplates an alternative building element which has a combination of properties which are further improved compared to the building elements from the prior art. According to preferred embodiments, the building element according to the invention has an improved acoustic insulation in combination with a good thermal insulation and an increased resistance to fire.

To this end, according to its first independent aspect, the white invention relates to a building element, in particular for roof, wall and floor constructions, wherein said building element comprises at least one formwork, consisting of at least two ribs and a first plate, the building element having at least a first layer insulating material arranged in the formwork, said first layer of insulating material contacting the first plate at least over part of its surface, characterized in that the formwork further comprises a second plate opposite the first plate, said second plate being acoustically open wherein said first layer of insulating material is cured at least against said first board. Preferably, the ribs of the formwork are connected by means of a connecting element. The building element according to the first aspect combines a good thermal insulation with an improved acoustic insulation and a good resistance to fire compared to the building elements according to the prior art. The inventors have found that the element of the invention further provides improved acoustic insulation over prior art building elements. It appears to be important here that the first insulating layer is hardened in the formwork, more especially hardened at least against the above-mentioned first plate and/or that the ribs are mutually connected by means of a connecting element, additionally to the above-mentioned plates.

The aforementioned second plate is acoustically open. An acoustically open plate is a plate in which the sound waves can move through the plate via the air as a medium. Preferably, the acoustically open second plate comprises one or more openings through which the sound waves can move via the air as a medium. The aforementioned opening may be, for example, a perforation, a grid opening or a channel, such as an open-walled cell. The opening may furthermore be an opening resulting from the structural construction of the relevant plate, for example a plate built up from battens or chips, wherein the relevant battens or chips are provided such that there are gaps between the battens or chips through which the sound waves can travel. move. The advantage of the use of an acoustically open second plate in the relevant construction element is that the principle of the Helmholtz resonator will occur in the construction element according to the invention, whereby the sound waves are extinguished with the air as medium via, on the one hand, collisions with the internal surfaces of the acoustically open plate and on the other hand by the air in the space behind the acoustically open plate, the space functioning as a spring connected to a mass, the mass being the air in the openings in the finish, thus providing for a range of frequencies an efficient damping can be obtained. The relevant frequency range is determined, among other things, by the volume of the space behind the acoustic plate. The principle of the Helmholtz resonator thus provides a first improvement in the acoustic insulation of the building element according to the invention compared to the building elements according to the prior art.

Preferably, the first layer of insulating material is a rigid foam, the first layer of insulating material further making contact with one or both of the aforementioned ribs. According to the invention, contact between the first layer of insulating material and the first plate and the rib or ribs of the formwork is preferably obtained by curing the relevant insulating material in the formwork after applying the relevant insulating material in the formwork in liquid form.

In the light of the invention, making contact means that the contacting components are preferably located at a distance equal to or smaller than 1 mm from each other, for example at a distance equal to or smaller than 0.5 mm, such as equal to or less than

0.2mm. The distance between the two components that make contact can be equal to 0 mm. The distance between both components making contact can be greater than 0 mm and equal to or less than 1 mm, for example a distance between 0.10 mm and 0.30 mm, such as between 0.12 mm and 0.20 mm, preferably between 0.14 mm and 0.17 mm. A distance greater than 0 mm and equal to or less than 1 mm allows the space between the two contacting components to comprise air and/or a further material. A further material may be a film, a foil, a seal, a plate, a foam or a fiber based product, for example a fire-resistant seal, a water-repellent foil, or a gas-tight film.

According to the invention, the ribs of the formwork can be connected by means of an additional connecting element. The respective connecting element may be one or more of, but not limited to, a slat, a rod, a plate, a grid, a beam.

The respective connecting element can be built up from a wood-like material, a plastic, a composite, a metal, as well as from other materials. The inventors have found that the use of such connecting elements has a similar effect to the curing of the first insulating material against the aforementioned first board, and that these measures can be applied individually or in combination to obtain a good acoustic insulation.

Preferably, said connecting element may be located in the first layer of insulating material. The connecting element can be located in the space between the first layer of insulating material and the aforementioned second plate of the building element. When the connecting element is located in the space between the first layer of insulating material and the aforementioned second plate, the connecting element can contact the first layer of insulating material over at least part of its surface. When the connecting element is provided in the formwork prior to the application of the first layer of insulating material in liquid form, the connecting element preferably comprises one or more openings which allow the insulating material, when installed in the formwork in liquid form, to flow past the respective connecting element. and thus can contact the first slab of the formwork and preferably the ribs of the formwork.

As mentioned above, the ribs of the formwork can be connected by means of two or more connecting elements. The respective connecting elements can be located in the same plane parallel to the side of the first plate that faces the first layer of insulating material and/or in several planes parallel to each other and on the side of the first plate that faces the first layer of insulating material. .

Preferably, said first layer of insulating material is a hard foam. The rigid foam can be chosen from a polyurethane (PUR), a polyisocyanurate (PIR), an extruded polystyrene (XPS), an expanded polystyrene (EPS) or a phenolic foam (phenol). Preferably, the first layer of insulating material is a polyisocyanurate (PIR). A PIR as the first layer of insulating material provides the building element with good thermal insulation and good resistance to fire compared to the building elements according to the prior art. In the event of a fire, a PIR rigid foam will slowly char and thus protect the formwork for a longer period of time against exposure to the fire and in particular to the flames, which on the one hand slows down the propagation of the fire to adjacent rooms or buildings and on the other hand the strength of the structure of the building element is preserved for longer. A PIR hard foam also has minimal smoke development. Minimal smoke development and longer retention of the structure's strength contribute to an improvement in safety in the event of fire compared to the construction elements according to the state of the art. Improved safety in the event of a fire increases the time for evacuation of the room or building. As an alternative embodiment, the first layer of insulating material may be a wool product. The wool product can be, for example, mineral wool, glass wool, wood wool or polyester wool.

According to a preferred embodiment of the building element according to the first aspect of the invention, the relevant building element comprises at least a second layer of insulating material arranged in the formwork. The relevant second layer of insulating material is preferably located in the space between the first layer of insulating material and the second plate of the building element. The second layer of insulating material can make contact with the first layer of insulating material and/or with one or more ribs of the formwork, and/or with the second plate. The advantage of providing a second layer of insulating material in the building element is the further improvement of the acoustic insulation, the thermal insulation and/or the resistance to fire of the building element according to the invention compared to the building elements according to the prior art. The combination of a wool product as a second layer of insulation material between the first layer of insulation material and the acoustically open second plate strengthens the Helmholtz resonator obtained with the acoustically open second plate by realizing a damping of the sound waves over a wider range of frequencies than for a building element without the aforementioned wool product. The relevant wool product thus further improves the acoustic insulation of the building element. The wool product further comprises thermally insulating properties and thus contributes to a further improvement of the thermal insulation of the building element. The wool product will slowly char in the event of a fire and thus shield the first layer of insulation material and the formwork for longer from exposure to the fire and in particular to the flames, further increasing the fire resistance of the building element relative to the building elements according to the state of the art.

When a connecting element is present in the formwork in the space between the first layer of insulating material and the second plate, the relevant second layer of insulating material can be located between the first layer of insulating material and the relevant connecting element and/or between the connecting element and the second plate, wherein the second layer of insulating material can make contact with the respective connecting element over at least part of its surface.

Preferably, no further hard foam is present between the second layer of insulating material and the second plate. Preferably, no further insulating materials are present between the second layer of insulating material and the second plate. Preferably there is only air present between the second layer of insulating material and the second plate.

According to a second, independent aspect, the invention relates to a building element, in particular for roof, wall and floor constructions, wherein said building element comprises at least one formwork,

consisting of at least two ribs, a first plate, a second plate opposite the first plate, at least a first layer of insulating material and a second layer of insulating material arranged in the formwork, the first insulating material and the second insulating material being different, characterized in that the second plate is acoustically open, that the first layer of insulating material contacts the first plate at least over part of its surface, and/or that said first layer of insulating material is a rigid foam. The building element according to the second aspect has an excellent thermal insulation, combined with an improved acoustic insulation and an increased resistance to fire, compared to the building elements according to the prior art. The building element according to the second aspect has a further improved acoustic insulation and further increased resistance to fire compared to the building element according to the first aspect of the art.

The first layer of insulating material may contact the first plate and one or both of the aforementioned ribs of the formwork. The inventors have found that contact of the first layer of insulating material with the first plate and one or both ribs of the formwork improves the acoustic insulation of the building element according to the second aspect over the acoustic insulation of the building elements according to the prior art. of the technique.

The second layer of insulating material may contact the second plate over at least part of its surface. The second layer of insulating material may contact the second sheet and one or both of the aforementioned ribs of the formwork.

The first layer of insulating material may further contact the second layer of insulating material over at least part of its surface. Preferably, no further insulating materials are present between the first layer of insulating material and the second layer of insulating material, for instance only air.

The respective second plate of the building element according to the second aspect is acoustically open. By acoustically open is meant the same as described above for the acoustically open second plate according to the first aspect.

By making contact is meant the same as described above as meaning for making contact.

The relevant first layer of insulating material of the building element according to the second aspect is preferably a hard foam, wherein the hard foam is selected from a polyurethane (PUR), a polyisocyanurate (PIR), an extruded polystyrene (XPS), an expanded polystyrene (EPS) or a phenolic foam (phenol). Preferably, the relevant first layer of insulating material is a polyisocyanurate (PIR). A PIR as the first layer of insulating material of the building element according to the invention provides the building element with a good thermal insulation and an increased resistance to fire compared to the building elements according to the prior art, in a manner as described above for the first aspect of the construction. invention.

Although rigid foams are preferred for the intended first layer of insulating material, it is not precluded within the scope of the present invention that a flexible foam would be used.

The relevant second layer of insulating material of the building element according to the second aspect preferably comprises at least one wool product, for instance mineral wool, glass wool, wood wool, flax wool, animal wool or polyester wool. Preferably, said wool product comprises at least mineral wool, for example rock wool. The second layer of insulating material can comprise at least one further material, such as a cellulose-based material, feathers and/or down of, for example, a duck or a goose, and/or be a fiber material. Alternatively, the second layer of insulating material may be free of wool product and comprise at least one cellulose-based material, feathers and/or down from, for example, a duck or goose, and/or a fiber material.

A wool product, in particular mineral wool, can contribute to the acoustic insulation, thermal insulation and fire resistance of the building element.

The combination of a wool product as a second layer of insulation material between the first layer of insulation material and the acoustically open second plate can improve the acoustic insulation of the building element according to the second aspect compared to the building elements according to the prior art and the building element according to the first aspect of the invention.

A wool product as a second layer of insulation material can amplify the Helmholtz resonator obtained with the acoustically open second plate by realizing a damping of the sound waves over a wider range of frequencies than for a building element without the aforementioned wool product, and can thus further contribute to the acoustic insulation of the building element.

The wool product further comprises thermally insulating properties and thus contributes to a further improvement of the thermal insulation of the building element.

The wool product will slowly char in the event of a fire and thus shield the first layer of insulation material and the formwork for longer from exposure to the fire and in particular the flames, whereby the fire resistance of the building element can be further increased.

The ratio of the thickness of the first layer of insulating material to the thickness of the second layer of insulating material is preferably within the range of 1 to 5, such as within the range of 1.1 to 3.5, for example within the range of 1.25 to 2.75, such as within the range from 1.4 to 2.6. A ratio of the thickness of the first layer of insulating material to the thickness of the second layer of insulating material within the range of 1 to 5 results in a greatly increased resistance to fire in combination with an improved acoustic insulation of the building element. A ratio of the relevant thicknesses smaller than 1 is of course not excluded.

Preferably, the ribs of the formwork are attached to the first plate at the location of the side of the first plate facing the first layer of insulation material. The first plate may extend over two or more ribs. Preferably, the ribs of the formwork are attached to the second plate at the location of the side of the second plate facing the first layer of insulating material. The second plate may extend over two or more ribs. Alternatively, a first, resp. second plate placed and fixed between two adjacent ribs of the formwork. The ribs can be attached to the respective first, resp. second plate are attached via known fasteners, for example with nails, screws, screws, staples, an adhesive such as glue, or a hot melt.

Preferably, said first plate forms the outside of the building element and said second plate forms the inside of the building element. The outside of the building element is the surface of the building element which in installed condition is oriented to the outside, the outside being the open air. In case the building element is used as a roof element, a buten finish can be installed on the outside of the building element, for example a roof covering such as roof tiles. The inside of the building element is the surface of the building element which, in installed condition, faces the inside, the inside being the internal space within the building, e.g. a room. The inside of the building element in installed condition is visible to the end user.

The second board may be a wood-like material, for example wood chipboard, plywood board, OSB, MDF or HDF. The second board may be a gypsum-like material, for example gypsum board, gypsum fiber, calcium silicate, or cementitious materials. The second board may be a pressed wool board, for example a pressed wood wool board, such as a magnesite bonded or a cement bonded wood wool board, or a pressed rock wool board. The second board may be a combination of a wood-like material and/or a gypsum-like material and/or a pressed wool board. The second plate is acoustically open in that one or more openings are present in the plate, for instance by providing perforations in the plate.

Preferably, the second plate comprises one or more perforations.

For example, the cross-sectional shape of the perforation can be, but not limited to, round, oval, square, triangular, star-shaped, diamond-shaped, lobed or polygonal, or can be a line. When the second plate comprises two or more perforations, they may have an equal or different cross-section. A different cross-section may be a cross-section of a different size, e.g. diameter, and/or a different shape. The shape and/or cross-sectional size of the perforation may be constant across the thickness of the second sheet or may vary across the thickness of the second sheet.

The degree of perforation of the second sheet may be from 5% to 50%, for example from 6% to 40%, such as from 10% to 30%. Preferably, the degree of perforation is from 15% to 20%. It is clear to a person skilled in the art that the degree of perforation is a measure of the open area of a surface or plate. A higher degree of perforation means that for a given area of the surface or plate, there is more open area, determined by the perforations, present in the surface or plate. A degree of perforation lower than 5% provides a sound attenuation via the Helmholtz resonator effect as described above, which is negligibly small 1s, so that a building element with sub-optimal acoustic insulation is obtained. A degree of perforation greater than 50% makes the second plate structurally unstable, as a result of which the building element will exhibit a weaker structural strength. A degree of perforation of 15% to 20% makes it possible, in combination with the aforementioned second layer of insulating material, to obtain a good Helmholtz resonator effect and thus to obtain a building element with excellent acoustic insulating properties.

The diameter of the perforations, for example in the case of round perforations, may be 2 mm to 35 mm, for example 3 mm to 20 mm. Preferably, the diameter of the perforations is 6 mm to 16 mm. A diameter of 6 mm to 16 mm allows, in combination with a second layer of insulation material, to obtain a good Helmholtz resonator effect and thus a building element with excellent acoustic insulating properties. It is of course not excluded that microperforations would be used, namely with a diameter smaller than 2 millimeters, or smaller than 1 millimeter, for example with a diameter of approximately 500 micrometers.

The second plate can contribute to the fire resistance of the building element by retarding the propagation of the fire and in particular the flames up to the ribs of the formwork so that in the event of a fire the building element retains its structural strength for a longer period of time. The second plate can contribute to the fire resistance of the building element because the second plate is made of a material which has fire-resistant properties, such as for instance a plaster-like material. The second plate can contribute to the fire resistance of the building element in that the second plate, which may or may not be manufactured from a material having fire-resistant properties, is treated with a fire-resistant product. Treatment with a fire-resistant product may include the application of a fire-resistant topcoat or coating.

An alternative embodiment of the second plate that contributes to the fire resistance of the building element is a second plate made of a material that has a limited resistance to fire, wherein a fire-resistant component is provided between the second plate and one or more ribs of the formwork. A fire-resistant component can, for example, be a foil, film, seal, strip, layer or plate. A fire-resistant component can be, but is not limited to, an acrylate, silicone, polyurethane (PUR) or calcium silicate-based component.

The combination of a plate made of a material that has fire-resistant properties with a fire-resistant component is also an option.

Alternatively or in combination with the fire-resistant second sheet described above, the first sheet and/or the ribs, in a similar manner as described above for the second sheet, may contribute to the fire resistance of the building element.

The building element according to the first and/or the second aspect of the invention may furthermore be provided with a finish on the side of the second plate which is visible in the installed state of the building element. Preferably, the finish is acoustically open, wherein acoustically open has the same meaning as described above for the second plate of the building element.

According to a first embodiment, the finish of the relevant side of the second plate can comprise a decor on the second plate. The decor can be any decor, such as a wood or stone decor. The decor can be obtained through, for example, printing, painting, coloring or staining. Preferably, the decor is obtained through printing, for instance through printing of ink such as digital printing by means of an inkjet printer. Preferably, the decor is a printed decor that is applied directly or directly to the relevant second plate. This is referred to as a “direct print”. It cannot be ruled out that the directly printed decor is applied to a primer or base coat present on the second panel. The direct printed decor is preferably a direct digitally printed decor and thus applied by means of a digital printer, such as an inkjet printer, single-pass or multi-pass.

According to a further embodiment, the finish may comprise an additional layer which is applied to the relevant side of the second plate, the additional layer being acoustically open. The additional layer may comprise one or more perforations. When both the additional layer and the second plate comprise one or more perforations, the perforations can coincide in size, cross-section and pattern so that the acoustic insulation of the building element obtained via the Helmholtz resonator effect of the acoustically open second plate, as described above, is preserved. stays. Alternatively, the perforations of the additional layer and the acoustically open second plate cannot coincide in size, cross-section and pattern, whereby the Helmholtz resonator effect of the building element can be improved so that an improved acoustic insulation can be obtained.

The additional layer can be attached to the second plate by means of known techniques, such as, for example, gluing, via a hot melt or pressing.

The additional layer may be a wood layer, for example a wood veneer. The wood layer can be provided with a decor. The additional layer may further be a textile component such as a fabric, knit, or nonwoven, for example a felt product. The textile component may be provided with a decor. The additional layer may further be a paper sheet on which a decor is provided. The paper sheet may be impregnated with a resin. The resin is, for example, a melamine resin. The additional layer may further be a plastic film or film. The plastic sheet or film may comprise a thermoplastic plastic. The thermoplastic plastic may comprise vinyl, such as, for example, polyvinyl chloride or PVC. The plastic foil or film can be provided with a decor.

Preferably, the decor on the above-mentioned additional layer is a printed decor, for instance a digitally printed decor and thus applied by means of a digital printer, such as an inkjet printer, single-pass or multi-pass.

The aforementioned additional layer, in particular an additional layer with a decor, may comprise a wear layer on top of the decor, especially in the case of use of the building element as a floor element. The wear layer may comprise hard or wear-resistant particles, such as corundum particles. The wear layer may comprise a plastic foil or film. The plastic sheet or film may comprise a thermoplastic plastic. The thermoplastic plastic may comprise vinyl, such as, for example, polyvinyl chloride or PVC. The wear layer may comprise a lacquer layer. The lacquer layer may comprise urethane-based lacquer or a UV-based lacquer.

According to a particular embodiment of the building element according to the first and/or second aspect of the invention, the building element comprises, in particular for roof, wall and floor constructions, at least one formwork consisting of at least two ribs, a first and a second plate, and a first layer and a second layer of insulating material arranged in the formwork, the first and second insulating material being different, characterized in that the second plate is acoustically open, in that the first layer of insulating material contacts at least part of its surface make with the first board and preferably with the aforesaid ribs that the first layer of insulating material is a rigid foam, that the second layer of insulating material is a wool product, and that the second layer of insulating material makes contact with the second board over at least part of its surface . Optionally, the building element comprises a finish on the side of the second plate which is visible in the installed condition of the building element, such as a directly printed decor or an additional layer, optionally provided with a decor.

The building element according to the special embodiment has an improved acoustic insulation, obtained on the one hand by the contact of the hard foam with the first plate and the ribs, and on the other by the

Helmholtz resonator effect obtained with the acoustically open second plate and further optimized by the wool product in the space behind the acoustically open second plate.

The building element according to the particular embodiment has an excellent thermal insulation obtained by the hard foam, in particular a PIR or PUR hard foam, further improved by the wool product.

The building element according to the particular embodiment has an increased resistance to fire, obtained by the combination of the wool product and the hard foam, in particular in a thickness ratio of hard foam to wool product in the range of 1 to 5. The hard foam and the wool product slowly char and set thus expose the formwork less quickly to the fire, and in particular to the flames, so that on the one hand the fire reaches other rooms more slowly and on the other hand the structural strength of the building element is retained longer in the event of a fire, and a safer situation is obtained for example evacuation.

According to a third aspect, the invention comprises a method for manufacturing a building element according to the first and/or second aspect of the invention, the method comprising at least the following steps: - providing a formwork; - providing a first layer of insulating material in the formwork, characterized in that the first layer of insulating material is provided in liquid form and hardens in the formwork.

When the first layer of insulating material in the formwork hardens, the relevant insulating material can at least make contact with the first plate and preferably further with one or more ribs of the formwork. Preferably, the insulating material makes contact with the first plate and the ribs, while curing in the formwork allows to improve the contact so that an excellent bond is obtained. Said excellent adhesion contributes to the reinforcement of the formwork and to the further optimization of the acoustic insulation of the building element, because a stiffer formwork is obtained and the propagation of sound waves through the first slab of the building element is reduced.

The building element may comprise a connecting element for reinforcing the formwork. According to a first embodiment, the connecting element can be provided in the formwork before the step of providing a first layer of insulating material, the connecting element comprising one or more openings that allow the first insulating material to be provided in liquid form in the formwork, passing it along the connecting element. can flow and thus contact the first slab of the formwork and preferably the ribs of the formwork. According to a second embodiment, the connecting element can be provided in the formwork after the first layer of insulating material has fully cured. According to a further embodiment, the connecting element can be provided in the formwork during the curing step, for example when the first layer of insulating material has cured at least 50% and less than 100%. In this case, a bond can arise between the first layer of insulating material and the relevant connecting element.

When the building element comprises a second layer of insulating material, for instance according to a preferred embodiment of the building element according to the first aspect or according to a building element according to the second aspect, the relevant second layer of insulating material can be applied in the formwork after the step of curing the first aspect. layer of insulation material in the formwork. The relevant second layer of insulating material can be arranged in the formwork during the step of hardening the first layer of insulating material, for instance when the first layer of insulating material has cured at least 50% and less than 100%. The relevant second layer of insulating material can be attached to the second plate, for instance via gluing, before simultaneously providing the second plate with the second layer of insulating material on and in the formwork during or after the step of curing the first layer of insulating material.

In order to better demonstrate the features of the invention, some preferred embodiments are described below, by way of example without any limiting character, with reference to the accompanying drawings, in which: figure 1 shows a perspective building element according to the invention; figure 2 shows on a larger scale the cross-section according to the section II-I indicated in figure 1; figures 3 and 4 show the cross-section of variants of the building element of figure 1 on the same scale as figure 2; figure 5 shows an aspect of figure 4 on a larger scale than figure 4; figures 6 to 18 show the cross-section of variants of the building element of figure 1 on the same scale as figure 2; figure 19 represents the surface F19 indicated in figure 1 on a larger scale; figures 20 and 21 show on equal scale a variant of the surface F19 indicated in figure 1 . Figure 1 shows a perspective view of a building element 1 according to the first aspect of the invention. The building element 1 comprises a formwork 2 which, in this case, comprises three ribs 3-4-5 and a first plate 6. The building element 1 further comprises a first layer of insulating material 7 arranged in the formwork 2. The formwork 2 further comprises a second plate 8 opposite the first plate 6, wherein the relevant second plate 8 is acoustically open. In this case, the second plate is provided with a plurality of perforations 9 with a cross-section having a round shape and wherein, in this case, the diameter of the perforations 9 is the same for all perforations 9. Figure 2 shows the cross-section of the building element 1 of figure 1. The first layer of insulating material 7 makes contact with the first plate 6 and with the ribs 3-4-5 of the formwork 2. The ribs 3-4-5 are attached to the side of the first plate 6 that faces 1s towards the first layer of insulating material 7. The three ribs 3-4-5- are all attached to the same first plate 6. The building element 1 is provided with a projecting part 10 at the location of one side of the first plate 6 of the formwork 2 and of a recess 11 at the other side of the first plate 6 of the formwork 2, the one side and the other side of the first plate 6 being parallel and perpendicular to the side of the first plate 6 facing 1s towards the first layer of insulation material 7. T At the location of the aforementioned protruding part 10 of the formwork 2, the first plate 6 extends beyond the one extreme rib 3 of the formwork 2. At the location of the aforementioned recess 11 of the formwork 2, the first plate 6 does not extend beyond the other extreme rib 5 of the formwork 2, but the first plate 6 extends to a distance from the respective extreme rib 5 of the formwork 2. The aforesaid projecting part 10 and the aforesaid recess

11 can be realized by shifting the first plate 6 in the plane parallel to the side of the first plate 6 facing the first layer of insulating material 7, the displacement of the first plate 6 taking place relative to the position of the second plate 8 and/or the ribs 3-4-5 of the formwork 2. The projecting part 10 of a first building element 1 fits into the recess 11 of another, similar building element 1, which realizes a connection between the two building elements 1.

In this case, the first layer of insulating material 7 is a hard foam, for instance a PIR hard foam or a PUR hard foam.

The first insulating material 7 is preferably applied in liquid form in the formwork 2, after which it hardens.

During curing, the free surface of the insulating material 7 deforms at the location of the ribs 3-4-5 contacted as a result of the curing reaction.

This achieves an improved adhesion of the rigid foam to the ribs 3-4-5 over a greater surface area than if the surface of the rigid foam after curing were parallel to the surface of the first plate 6 over its entire surface. rigid foam with the first plate 6 and the ribs 3-4-5 contributes, as explained above, to further optimization of the acoustic insulation.

The ribs 3-4-5 are attached to the second plate 8 at the location of the side of the second plate 8 that faces the first layer of insulating material 7. The second plate 8 is in this case finished with a decor 12 that can be directly print with an inkjet printer on the second plate 8.

Between the first layer of insulating material 7 and the second plate 8 there is a space 13 free of insulating material.

In combination with the acoustically open plate 8, this space 13 makes it possible to obtain a Helmholtz resonator effect, so that a further optimization of the acoustic insulation of the building element 2 can be obtained.

Figure 3 shows the cross-section of a variant of the building element 1 of figure 1. The building element 1 comprises a formwork 2, which in this case comprises three ribs 3-4-5, two first plates 6 and a second plate 8.

The first plates 6 and the second plate 8 are fixed between each two adjacent ribs 3-4-5 of the formwork 2. The building element 1 is provided with a protruding part 14 at the location of the one extreme rib 3 of the formwork 2 and with a recess 15 at the location of the other extreme rib 5 of the formwork 2. The projecting part 14 of a first building element 1 fits into the recess 15 of another, similar building element 1, which realizes a connection between the two building elements 1.

Figure 4 shows the cross-section of a variant of the building element 1 of figure 1, wherein the first layer of insulating material 7 almost completely fills the formwork 2 .

The acoustically open second plate 8 has perforations 9 with a round cross-section, the diameter of the cross-section of the perforations of which varies over the thickness of the relevant second plate. The first layer of insulating material 7 is a hard foam. Between the first layer of insulating material 7 and the second plate 8 there is a space 13 free of insulating material, the volume of the space 13 free of insulating material being the smallest possible volume 1s so that this space 13 in combination with the acoustically open plate 8 can provide a further optimization of the acoustic insulation via the Helmholtz resonator principle, whereby the smallest possible volume is determined, among other things, by the range of frequencies to be damped, the number, dimensions and shape of the perforations 9 and the thickness of the acoustically open plate 8.

Figure 5 shows an enlargement of the perforations 9 of the acoustically open second plate 8 of the building element of figure 4. The cross-section has a round shape over the thickness of the second plate, the diameter of the perforations 9 at the location of the side of the second plate 8 facing the first layer of insulating material 7 is greater than the diameter at the side of the second sheet 8 opposite to the side of the second sheet 8 facing the first layer of insulating material 7.

Figure 6 shows the cross-section of a variant of the building element 1 of figure 1, and shows an example of the particular embodiment of both the first and the second aspect of the invention. The formwork 2 in this case comprises a first plate 6, three ribs 3-4-5 and an acoustically open second plate 8. The acoustically open plate 8 1s provided with perforations 9 with a round shape and a diameter which in this case is constant. for all perforations 9 and over the thickness of the second plate 8. The ribs 3-4-5 are in this case attached to the first 6, resp. second 8 plate at the location of the side of the first 6, resp. second 8 plate. A first layer of insulating material 7 is a hard foam, for instance a PUR or a PIR hard foam, which is cured in the formwork 2 and thus makes contact with the first plate 6 and the ribs 3-4-5. The hard foam thus provides a reinforcement of the formwork 2 and an improvement of the acoustic insulation because the flexibility of the first plate 6 is reduced and a stiffer formwork 2 is obtained. The rigid foam contributes to an improvement of the thermal insulation of the building element 1 and shows an increased resistance to fire because it slowly chars in the event of a fire and the formwork 2 is less exposed to the fire and in particular to the flames. The second layer of insulating material 16 is a mineral wool. The mineral wool makes contact with the rigid foam, with the ribs 3-4-5 of the formwork 2 and with the acoustically open second plate 8. The mineral wool in combination with the perforated second plate 8 further optimizes the acoustic insulation of the construction element 2 The mineral wool further optimizes the fire resistance of the building element 1 because it slowly chars in the event of fire and in particular flames, and the formwork 2 is less exposed to the fire. The second plate 8 is further provided with a decor 12 which is arranged directly on the plate 8.

Figure 7 shows the cross-section of a variant of the building element 1 with cross-section as in figure 6, in which there is minimal to no contact between the two layers of insulating material 7, 16 and there is furthermore air 13 between both layers of insulating material 7, 16. The second Insulation material 16 is a wool product, for example mineral wool, and is attached to the ribs 3-4-5 of the formwork 2 and/or to the second plate 8 via, for example, gluing (not visible).

Figure 8 shows the cross-section of a variant of the building element 1 with cross-section as in Figure 6, in which there is no contact between the second layer of insulating material 16 and the acoustically open second plate 8. In this case, the second layer of insulating material 16 is a wool product containing is attached to the first layer of insulating material 7, which is a rigid foam. The attachment can be realized by providing the wool product in the formwork 2 when the hard foam has not yet fully cured. The attachment can alternatively be realized by gluing the wool product to the hard foam. This is not shown here.

Figure 9 shows the cross-section of a variant of the building element 1 with cross-section as in figure 6, wherein the second plate 8 comprises an additional layer 17 as a finish. In this case, the additional layer 17 is an acoustically open textile product, for example a felt layer. The felt layer can further optimize the acoustic insulation of the building element 1 because the felt layer itself has a certain acoustic insulation and thus contributes to the acoustic insulation of the building element 1.

Figure 10 shows the cross-section of a variant of the building element 1 of Figure 1, wherein a connecting element 18 is provided in the formwork 2. The first layer of insulating material 6 is located around the connecting element 18. In this case, the connecting element 18 consists of a different material than the material from which the formwork 2 is made. This may have the advantage that the connecting element 18 can be minimized in terms of dimensions so that the insulating properties of the first layer of insulating material 7 and of the building element 1 are minimally influenced by the presence of the connecting element 18.

Figure 11 shows the cross-section of a variant of the building element 1 with cross-section as in figure 10. A connecting element 18 is provided in the formwork 2 during the step of curing the first layer of insulating material 7, whereby a bond between the insulating material 7 and the connecting element 18 is realized. In this case, the connecting element 18 consists of the same material as the material from which the formwork 2 is made.

Figure 12 shows the cross-section of a variant of the building element 1 with cross-section as in figure 11, wherein a connecting element 18 is provided in the formwork 2 after the step of curing the first layer 1 of insulating material 7. In this case there is little to no contact between the first insulating material 7 and the connecting element 18. In this case, the connecting element 18 consists of a different material than the material from which the formwork 2 is made.

Figures 13 and 14 show the cross-section of a variant of the building element 1 with cross-section as in figures 11 and 12, respectively, wherein a second layer of insulating material 16, in this case a wool product such as mineral wool, is further provided in the formwork 2 between the connecting element 18 and the acoustically open second plate 8. The wool product makes contact with the connecting element 18, the ribs of the formwork 3-4-5 and the second plate 8. The use of a second insulating material 16, in particular a wool product such as mineral wool , contributes to the acoustic and thermal insulation of the building element 1, as explained in figure 6. Figure 15 shows the cross-section of a variant of the building element 1 with cross-section as in figure 13, with the difference that the second layer of insulating material 16 has no contact makes contact with the connecting element 18 and makes contact with the ribs 3-4-5 and the second plate 8 and is attached to one or more ribs 3-4-5 and/or the tw eede plate 8, for example by means of gluing (not visible). The connecting element 18 is made in the same material as the connecting element 18 of figure 13, but is thinner.

The additional air layer 13 can realize a further improvement of the thermal insulation of the building element 1.

Figure 16 shows the cross-section of a variant of the building element 1 with cross-section as in Figure 14, with the difference that the second layer of insulating material 16 does not contact the connecting element 18 and makes contact with the ribs 3-4-5 and the second plate 8 and is attached to one or more ribs 3-4-5 and/or the second plate 8, for example by means of gluing (not visible). The additional air layer 13 can realize a further improvement of the thermal insulation of the building element 1.

Figure 17 shows the cross-section of a variant of the construction element 1 with cross-section as in figure 13, with the difference that the second layer of insulating material 16, in this case a wool product, is arranged in the formwork 2 and makes contact with the connecting element 18 and the ribs 3-4-5, and does not make contact with the second plate 8. The wool product is attached to the connecting element 18 and/or one or more ribs 3-4-5, for example via gluing (not visible). The connecting element 18 is made in the same material as the connecting element 18 of figure 13, but is slightly thinner.

Figure 18 shows the cross-section of a variant of the construction element 1 with cross-section as in figure 14, with the difference that the second layer of insulation material 16, in this case a wool product, is arranged in the formwork 2 and makes contact with the connecting element 18 and the ribs 3-4-5, and does not make contact with the second plate 8. The wool product is attached to the connecting element 18 and/or one or more ribs 3-4-5, for example via gluing (not visible).

Figure 19 shows a schematic representation of a part of the acoustically open second plate 8 of figure 1 again. The plate 8 is provided with several perforations 9. The cross-sectional shape of the perforations 9 in this case is round and the size, in this case the diameter, of the cross-section of the perforations is in this case the same for all perforations

9. The perforations 9 are provided in a so-called square pattern.

Figure 20 schematically shows an alternative embodiment of the acoustically open second plate 8, wherein the perforations 9 in this case have a round shape and an equal diameter and are provided in a so-called diamond pattern.

Figure 21 schematically shows an alternative embodiment of the acoustically open second plate 8, wherein the plate is provided with a plurality of perforations 9 which have an elongate shape, for instance a line shape. The cross-section of the perforations 9 varies in size and shape.

The present invention is by no means limited to the embodiments described above, but such building elements and methods of manufacturing them can be realized according to different variants without departing from the scope of the present invention.

Claims (29)

CONCLUSIONS Building element (1), in particular for roof, wall and floor constructions, wherein said building element (1) comprises at least one formwork (2), consisting of at least two ribs (3-4) and a first plate (6 ), wherein the building element (1) comprises at least a first layer of insulating material (7) arranged in the formwork (2), said first layer of insulating material (7) making contact with the first plate (6) at least over part of its surface characterized in that the formwork (2) further comprises a second plate (8) opposite to the first plate (6), said second plate (8) being acoustically open, said first layer of insulating material (7) being cured at least against the aforementioned first record. Building element according to claim 1, characterized in that the measures taken for the reinforcement of the formwork (2) consist at least in that said first layer of insulating material (7) is a hard foam, the first layer of insulating material (7) further making contact with one or both of the aforementioned ribs (3-4). Building element according to one of the preceding claims 1 - 2, characterized in that the ribs (3-4) of the formwork are free from mutual connections by means of a connecting element (18). Building element according to one of the preceding claims 1 - 2, characterized in that the ribs (3-4) of the formwork are connected by means of a connecting element (18). Building element according to one of the preceding claims, characterized in that said first layer of insulating material (7) is a hard foam. 6. Building element according to claim 5, characterized in that the rigid foam is selected from a polyurethane, a polyisocyanurate, an extruded polystyrene, an expanded polystyrene or a phenolic foam. Building element according to one of the preceding claims, characterized in that the building element (1) comprises at least a second layer of insulating material (16) arranged in the formwork (2). Building element according to claim 7, characterized in that no further hard foam is present, and preferably no further insulating materials are present, preferably only air, between the said second layer of insulating material (16) and the said second plate (8). 9. Building element, in particular for roof, wall and floor constructions, wherein said building element (1) comprises at least one formwork (2), consisting of at least two ribs (3-4), a first plate (6), a second plate (8) opposite the first plate (6), at least a first layer of insulating material (7) and a second layer of insulating material (16) arranged in the formwork, the first insulating material (7) and the second insulating material (16) being different characterized in that the second plate (8) is acoustically open, that the first layer of insulating material (7) contacts the first plate (6) at least over part of its surface, and/or that said first layer of insulating material ( 7) is a rigid foam. 10. Building element according to claim 9, characterized in that the second layer of insulating material (7) makes contact with the second plate (8) over at least part of its surface. Building element according to one of Claims 9 to 10, characterized in that no further insulating materials are present between the first layer of insulating material (7) and the second layer of insulating material (16). Building element according to one of claims 9 to 11, characterized in that the first layer of insulating material (7) is a hard foam, the hard foam being selected from a polyurethane, a polyisocyanurate, an extruded polystyrene, an expanded polystyrene or a phenolic foam. 13. Building element according to one of claims 7 to 12, characterized in that the said second layer of insulating material (16) comprises at least one wool product. Building element according to claim 13, characterized in that said wool product comprises at least mineral wool. Building element according to one of Claims 7 to 14, characterized in that the ratio of the thickness of the first layer of insulating material (7) to the thickness of the second layer of insulating material (16) is within the range 1 to 5. A building element according to any one of the preceding claims, characterized in that the said ribs (3-4) are attached to the first plate (6) at the side of the first plate (6 directed towards the first layer of insulating material (7)). ). A building element according to any one of the preceding claims, characterized in that the aforementioned ribs (3-4) are attached to the second plate (8) at the side of the second plate (8 directed towards the first layer of insulating material (7)). ). A building element according to any one of the preceding claims, characterized in that said first plate (6) forms the outside of the building element (1) and that said second plate (8) forms the inside of the building element (1). Construction element according to one of the preceding claims 1 - 18, characterized in that the second plate (8) is a wood-like material. Building element according to one of the preceding claims 1 - 18, characterized in that the second plate (8) is a plaster-like material. A building element according to any one of the preceding claims, characterized in that the second plate (8) is a pressed wool plate. Building element according to one of the preceding claims, characterized in that the second plate (8) comprises one or more perforations (9). Building element according to claim 22, characterized in that the degree of perforation is from 6% to 40%. Building element according to one of Claims 22 to 23, characterized in that the diameter of the perforations (9) is 2 mm to 35 mm. A building element according to any one of the preceding claims, characterized in that the building element (1) is provided with a finish on the side of the second plate (8) opposite to the side of the insulation facing the first layer of insulating material (7). second plate (8). 26. Building element according to claim 25, characterized in that the finish comprises a decor (9) on the second plate (8). 27. Building element according to claim 25, characterized in that the finish comprises an additional layer (17) which is applied on the said side opposite to the side of the second plate (8) facing the first layer of insulating material (7), wherein said side additional layer (17) is acoustically open. A method for manufacturing a building element according to any one of claims 1 to 27, wherein the method comprises at least the following steps: - providing a formwork (2); - providing a first layer of insulating material (7) in the formwork (2), characterized in that the first layer of insulating material (7) is provided in liquid form and hardens in the formwork (2). Method according to claim 28, characterized in that when the first layer of insulating material (7) in the formwork (2) hardens, said first layer of insulating material (7) makes contact at least with the first plate (6), and preferably further with one or more ribs (3-4-5) of the formwork (2).