NL9301807A - Construction element suitable for forming a linear construction to which cladding can be attached - Google Patents

Abstract

Described is a construction element 1 suitable for forming a linear construction to which cladding can be attached. Said construction element 1 substantially comprises a vibration-absorbing layer 4 which comprises a strip 2, 3 on two sides opposite one another. The vibration-absorbing layer 4 comprises one or more layers of a resilient material. It is also possible for the vibration-absorbing layer 4 to comprise mechanical means. Also described are a method for fabricating the abovementioned construction element, and a sound- insulating linear construction comprising the construction element. <IMAGE>

Description

Short designation: Building element, suitable for forming a control construction against which a plating can be attached.

The present invention relates to a building element suitable for forming a control construction against which a sheeting can be attached, at least comprising a vibration-absorbing layer which comprises a frame on one side.

Such a building element is known from a brochure from Nevima concerning the so-called IVI rule. This rule consists of a vibration-absorbing layer of acoustic felt, against which a frame in the form of a chipboard rule is attached.

Using this rule, for example, a construction can be formed against an existing wall, ceiling or floor, against which a plating may be attached. The plating will then be acoustically decoupled from the existing building construction.

However, the aforementioned IVI rule has a number of drawbacks. Firstly, the thickness of the felt layer used is limited, so that the decoupling distance can only be varied by the thickness of the chipboard and not, as desirable, by the thickness of the vibration-absorbing layer. In addition, the IVI rule has great flexibility which is difficult to limit and which will be present in the final product, which is undesirable in many cases. Furthermore, the IVI rule requires a nailed reinforcement tape to strengthen the adhesive bond between the felt and the chipboard strip, which indicates that the strength of this joint is inadequate, so that the application possibilities of the rule are limited. Finally, the IVI rules must be confirmed by means of nails, impact plugs or the like, which only work together with the felt. Holes in felt can tear easily, however, with all the negative consequences that entails.

The present invention aims to avoid the above-mentioned drawbacks and is to this end characterized in that the vibration-absorbing layer on the opposite side also comprises a frame.

By providing a vibration-absorbing layer surrounded on both sides by a frame, a rule is provided that exhibits less undesirable flexibility, but at the same time can produce very good acoustic decoupling. In addition, the connection between the vibration-absorbing layer and the frames is very strong, so that the construction element is not limited in its application possibilities.

In particular, the vibration-absorbing layer comprises one or more layers of a resilient material.

The use of several layers of a resilient material allows for a variation of the acoustic value.

The resilient material expediently consists of plastic foam, cork, felt, rubber, metal wool, pressed mineral fiber or a casting emulsion.

The thickness of these material layers can vary, so that the decoupling distance can be increased or decreased depending on the thickness of the vibration-absorbing layer. According to the present invention, use is preferably made of soft foam from pressed polyurethane flakes.

In an attractive embodiment, the vibration-absorbing layer comprises mechanical means.

Mechanical means attached between the moldings impart great mechanical strength to the building element so that even very heavy cladding can be attached to the control structures formed by the building elements, which is of particular importance in ceiling insulation.

Advantageously, the mechanical means are selected from one or more coil springs, leaf springs, pendulum rods or spring dampers.

These mechanical means all have a degree of flexibility which can be limited or widened according to the desired application of the building element.

Preferably, the material of the frames is selected from a woody material, a stone-like material, plastic, metal or pressed fiberboard.

The choice of the material of the frames depends on the application of the construction element; if the building element is to be fastened to a wooden surface, preference will probably be given to frames of woody material or pressed fiberboard, while in other cases, for example, frames of stony material are desired.

The frames are advantageously each made of a different material.

This embodiment can be advantageous when one of the frames of the building element has to add a stronger structural strength to the building element.

Preferably at least one of the frames is provided with fasteners.

The fasteners may, for example, consist of a through-hole in one of the frames and in the vibration-absorbing layer and a smaller opening in the other frame, so that a screw can be inserted through them, which screw can be screwed to the inside of the latter frame turn into. All this will be explained in more detail with reference to the drawing.

At least one of the outer sides of the building element is advantageously provided with a flexible material layer.

This flexible material layer allows a good connection of the construction element to rough surfaces. The flexible material layer will also contribute to the acoustic decoupling of the existing building structure.

The present invention also provides a method for manufacturing the building element according to the invention, wherein the vibration-absorbing layer comprises a resilient material. This method is characterized in that a frame material plate is attached to both main surfaces of a vibration-absorbing material layer, after which the shaped construction is subjected to a cutting operation or not to obtain building elements of the desired dimensions.

This method makes it easy to manufacture the building element. In addition, a very strong connection between the vibration-absorbing layer and the frames is ensured since the plates are factory-fitted to each other and then formed into building elements of the desired dimensions by means of a cutting operation.

In particular, the attachment takes place by means of an adhesive connection, a melt connection, a casting connection or a mechanical connection.

With the glue and melt connection, as well as the mechanical connection, the existing strips and the vibration-absorbing material layer can be placed on or against each other and fixed, while with the cast connection the frames are set at a certain distance from each other, after which the vibration-absorbing layer in the form of a casting emulsion is poured or sprayed between and, optionally, around the frames. However, it is also possible to provide a building element with a vibration-absorbing layer in the form of mechanical means between and even around the frames with a resilient casting emulsion.

The present invention also provides a method for manufacturing the above-described building element, wherein the vibration-absorbing layer comprises mechanical means. This method is characterized in that mechanical means are fixed between two plates made of frame material, after which the shaped construction is subjected to a cutting operation or not to obtain building elements of the desired dimensions.

Generally, the moldings here will be sized prior to the attachment of the mechanical means after which the mechanical means is attached.

The invention also provides a method for forming a particularly sound-insulating construction, wherein rails are fixed against an existing building structure, after which a plating is applied on or against said rails. This method is characterized in that one or more building elements according to the invention are used as rules.

Finally, the present invention provides a sound-insulating structure comprising at least one clad control structure. This construction is characterized in that said control construction comprises one or more building elements according to the invention.

The present invention will be explained in more detail below with reference to the drawing, in which: figure 1 shows a building element according to the invention; figure 2 shows a building element in another embodiment; figure 3 shows the application of the building element of figure 1 in a sound-insulating construction; and figure 4 shows a way in which the building element according to the invention can be attached to an existing building structure.

Figure 1 shows a building element 1 according to the invention, consisting of a strip 2 and a strip 3 with a vibration-absorbing layer 4 in between. The dimensions of the individual parts of the building element and therefore also of the building element itself may vary depending on the respective application . Lists 2 and 3 can consist of the same or different materials and are selected depending on their application. For example, for the application of the building element for forming constructions against walls, ceilings and walls, frames of pressed wood fiber board (MDF) are widely used. However, if the frame has to add a greater structural strength to the building element, a stronger material can also be used, such as, for example, metal.

The vibration-absorbing layer 4 can comprise one or more layers of the same or different materials. These materials are chosen depending on their application. For example, building elements used to form structures against floors will comprise a less resilient material than building elements used to form wall structures. A residual product material which has a wide range of applications is the soft foam of pressed polyurethane flakes, which is preferred according to the invention.

Instead of a vibration-absorbing layer 4 of a resilient material, mechanical means can also be used. The advantage of these mechanical means is that they considerably increase the mechanical strength of the building element and can even support very heavy cladding. The frame 2 in figure 1 is provided with a fastening in the form of an enlarged opening 5, which in frame 2 and layer 4 has the same diameter, but in frame 3 a smaller diameter. All this in such a way that the construction element can be fixed, for example, by means of screws or impact plugs that only cooperate with the frame 3.

Figure 2 shows the building element according to the invention in another embodiment. In this embodiment, not only is a vibration-absorbing layer between the frames, but the frames are also surrounded on the outside by a layer of the same vibration-absorbing material. This embodiment is obtained in case the building element is formed by casting (injection molding, extruding). However, it is also possible to provide the building element according to Figure 1 with a flexible material layer on one or more of the outer sides.

A mounting element 10 with protruding flanges in which there are holes is located on the building element in figure 2.

Figure 3 shows the application of the building element 1 according to Figure 1 in a sound-insulating construction. In this construction, the building elements according to the present invention, also called rules, are attached to an existing building structure. The blocks are usually placed at a center-to-center distance of 0.2-0.8 m. Subsequently, sound-insulating material, such as, for example, mineral wool, is placed between the blocks and a plating 7 is mechanically attached to the formed structure. In this sound-insulating construction, the plating 7 is acoustically decoupled from the existing building structure 9 and the sound insulation is optimal.

Figure 4 shows a way in which the building element 1 can be attached to an existing building structure 9. An enlarged opening 5 is provided in the frame 2 and in the vibration-absorbing layer 4. These prefabricated openings are usually located in the building element with a center-to-center distance of 0.2-0.6 m. When fastening the building element to an existing building structure, for example, a screw 8 can be inserted through the enlarged hole 5 of the building element 1 and, optionally after drilling a hole through the frame 3 and the wall, ceiling or floor construction behind it, are screwed through the existing construction 9 to the inside of the frame 3. In the case of a solid stony wall, the fixing takes place, for example, using impact plugs with cross-head screws. For example, for a wall of wood-like sheeting it is sufficient to use a wood screw that is inserted directly through the prefabricated opening and screwed on. Although the pre-arranged opening 5 in the frame 1 and the vibration-absorbing layer 3 offer the possibility of a simple and strong attachment of the building element 1 against an existing building structure 9, other fastening means to the building element are also conceivable. The building element can for instance be provided with other openings, strips or other appendages for fixing the building element against the existing structure. Another possibility is that a clamp is attached to the existing building structure in which the building element can be clamped. The clamp can clamp the entire building element or it can engage in the vibration-absorbing layer of the building element. Another possibility is that the building element is shaped in such a way that attachment can take place in another way, such as for instance by widening the strip 3 so that the screws are screwed through the protruding ends of the frame 3.

Claims (14)

Building element, suitable for forming a control construction against which a sheeting can be attached, at least comprising a vibration-absorbing layer which has a frame on one side, characterized in that the vibration-absorbing layer (4) also has a layer on the opposite side. list includes. Building element according to claim 1, characterized in that the vibration-absorbing layer (4) comprises one or more layers of a resilient material. Building element according to claim 2, characterized in that the resilient material consists of plastic foam, cork, felt, rubber, metal wool, pressed mineral fiber or a casting emulsion. Building element according to claim 1 or 2, characterized in that the vibration-absorbing layer (4) comprises mechanical means. Building element according to claim 4, characterized in that the mechanical means are selected from one or more spiral springs, leaf springs, pendulum rods or spring dampers. Building element according to one or more of the preceding claims, characterized in that the material of the strips (2,3) is selected from a wood-like material, a stone-like material, plastic, metal or pressed fiberboard. Building element according to claim 6, characterized in that the strips (2,3) are each made of a different material. Building element according to one or more of the preceding claims, characterized in that at least one of the frames is provided with fasteners. Building element according to one or more of the preceding claims, characterized in that at least one of the outer sides of the building element is provided with a flexible material layer. A method for manufacturing a building element according to any one of claims 1-3 and 6-9, characterized in that a plate of frame material is attached to both main surfaces of a vibration-absorbing material layer, after which the shaped construction may or may not be cut is subjected to obtain building elements of the desired dimensions. Method according to claim 10, characterized in that the attachment takes place by means of an adhesive connection, a melt connection, a casting connection or a mechanical connection. Method for manufacturing a building element according to any one of claims 1-2 and 4-9, characterized in that mechanical means are fixed between two plates of frame material, after which the shaped construction is subjected to a cutting operation or not to building elements with the desired dimensions. Method for forming a particularly sound-insulating construction, wherein rules are fixed against an existing building structure, after which a plating is applied on or against said rules, characterized in that as rules one or more building elements (1) according to one or more of claims 1-8. Sound-insulating construction comprising at least one clad control construction, characterized in that said control construction comprises one or more building elements (1) according to one or more of claims 1-8.