NO752723L - - Google Patents

Description

The present invention relates to an edge dampening profile

for sound-absorbing building constructions, especially for flat-like building elements with two shells, e.g. wall elements, door and window sashes or the like, consisting of a hole profile that faces the sound-transmitting room, and a cushion arranged behind the hole profile

of sound-absorbing material.

It is known to design soundproof windows in the form of a double-shell construction. This double-shell design is achieved by installing two panes of glass that extend parallel and at a distance from each other. As far as possible, there should be no physical connection between the two shells, each equipped with a glass pane. However, this cannot be achieved in practice with building constructions. A two-shell design is therefore realized by means of frame elements which are clamped mainly only during the intermediate connection of elastic and sealing elements.

As a result of the double-shell construction, it is achieved that the sound energy that hits one route must again be emitted from this, absorbed by the other route and emitted again into the inner space. During this multi-double sound transition, part of the sound energy is destroyed.

It is also known to insert edge damping profiles between the two shells in soundproof windows. The task of these profiles is to absorb sound energy that penetrates into the space enclosed by the two shells, and in particular to capture cross-resonances. These edge damping profiles have, on the side facing the sound-transmitting room, inlet holes for the sound energy, while a cushion of sound-damping material is arranged on the back of the hole profile. In this cushion, the absorbed sound energy is largely converted into heat.

Practice shows that the sound is reflected not only on the side of the glass panes facing the space, but above all also

on the surface of the edge damping profiles. That is why it also takes place there

in the space between the panes or in the sound-transmitting space between the two seashells, a spherical propagation of the sound entails the danger that a collection of oscillating sound waves will occur in the sound-transmitting space.

The purpose of the present invention is to further develop an edge damping profile of the type described in more detail at the beginning so that a larger proportion of the sound energy is destroyed in this under otherwise equal conditions, while at the same time a reflection of the sound waves on the edge damping profile is to a large extent excluded and furthermore, an accumulation of oscillating sound waves in the sound-transmitting space is avoided.

This is achieved according to the invention by at least some of the sound passage holes in the hole profile being arranged in connection with a sound diffusion channel facing the sound transmitting room. With this device, the risk of a reflection of the sound waves on the upper side of the edge damping profile is substantially reduced or, to a large extent, completely eliminated. Furthermore, in this way the spherical propagation and thus the accumulation of sound waves in the sound-transmitting space is inhibited. Instead, a diffuse sound field is obtained in this room, which leads to a significant improvement in the destruction of the sound energy. In addition, such sound diffusion channels support the destruction of the sound energy even before it reaches the sound-absorbing material. Particularly advantageously, the purpose of the invention can be achieved by means of

steps that project into the sound-transmitting space, and which between them delimit a sound diffusion channel for several, preferably arranged in longitudinal rows, holes in the hole profile.

Practice has shown that particularly favorable effects can be achieved when the sound diffusion channels, at least over certain stretches or sections, expand in the direction of the sound input or at most have a constant cross-section. In all cases, the sound diffusion channel should have a cross-sectional narrowing, preferably close to the side facing the sound-transmitting space. This cross-sectional narrowing can advantageously lie at the level of the end surfaces of the steps facing the sound-transmitting space. In certain cases, it has also proven appropriate to arrange these narrowing points at a small distance from the end surfaces and to perform the steps between the narrowed point and the end edge with a rounded or pointed cross-section.

A profile in which the thickness of the steps first decreases evenly from the free, flat end edge and then remains constant to the root of the step has proven particularly advantageous.

The edge damping profile can be advantageously used to limit the sound-transmitting space enclosed between two plates or panes, e.g. in a window, a wall element or a door, while the steps appropriately extend in a plane arranged parallel to the plates or panes. However, the edge damping profiles according to the invention can also be arranged with particular advantage in the area of the gap between e.g. one movable wing and a wall-fixed frame, more specifically preferably adjacent to a sound-transmitting space of this gap which is limited by two gaskets arranged at a distance from each other. In this case, it is sufficient to arrange the edge dampening profile either only on the wing or only on the wall-fixed frame. Corresponding edge dampening profiles can, however, also be arranged on both parts of the building. Here, too, it has proved expedient if the steps run parallel to the gaskets.

The steps are suitably designed in one piece with the hole profile. This can be made of metal, plastic or another material that is suitable for the purpose. Nor does it play a decisive role what the part of the building to which the edge profile is attached consists of. In any case, it has proved especially appropriate to connect the edge damping profile with the associated building part via sealing profiles or other elements with high sound transmission resistance. When used in windows or similar building elements, the sound dampening profile on its outer sides can simultaneously support the sealing elements that abut against the plate-shaped building parts or the glass panes.

The invention will subsequently be described in more detail with reference to schematic drawings of several embodiment examples. Fig. 1 is a cross-section through the frame for a two-shell building element in the form of a window. Fig. 2 is a cross-section through the structural parts of a movable wing and a wall-fixed frame which adjoin each other while forming a gap. Fig. 3 shows on a larger scale a cross-section through a modified step profile. Fig. 4 is a cross-section through a preferred step profile.

The cross section in fig. 1 shows a window frame. In this, panes of glass 1 and 2 are arranged at a distance from each other and parallel to each other. The thickest pane of glass 1 faces the interior of a building, while the thinner pane 2 forms the outside of the window. The two panes 1 and 2 are sound-insulated from each other and form a construction with two shells which between them enclose a space 7 which transmits sound. The thicker, inner pane 1 is then clamped between two gaskets 3 and a glass holder strip made of wood that is not provided with a reference number, more specifically in a wooden window frame 5. The outer glass pane 2 is arranged between two gaskets 4 in an outer glass holder profile 6 This outer glass holder profile is sandwiched by a further gasket 8 which simultaneously serves as sound dampening material, connected to an edge dampening profile which surrounds the sound-transmitting space 7 in a ring-like manner and on the two sides facing the panes, carries the gaskets 3 and 8. The edge dampening profile consists of of

■ a hole profile 10 which faces the sound-transmitting room 7 and on the back forms a receiving room for a cushion 9 of sound-absorbing material. Through the holes 11 that face the sound-transmitting room 7, the sound waves can penetrate the sound-absorbing material 9 lying behind the hole profile, where the sound energy is converted into heat energy.

In the example shown, the holes 11 are arranged in rows which

lies in a plane that extends parallel to the planes of the glass panes 1 and 2. To each row of holes belongs a sound diffusion channel which in the example shown is limited by two steps 12. These steps extend parallel to each other and parallel to the planes of the glass panes 1 and 2. They protrude from the hole profile 10 and into the sound-transmitting space 7, more specifically a considerable distance which can approximately correspond to the hole diameter.

Instead of steps, however, tubular diffusion channels can be assigned to each hole or to individual holes. However, the design shown using steps has proven to be particularly advantageous both for sound attenuation and for production.

With the help of the steps, the otherwise mainly smooth surface of the hole profile 10 is converted into a surface split by the channels, whereby reflections of the sound waves on the surface of the hole profile are prevented to a large extent. At the same time, the steps ensure that in the sound-transmitting space 7 between the panes of glass, a diffuse sound field is formed where a superimposition of oscillating sound waves (Aufschaukeln der schallwellen) becomes impossible. At the same time, a larger proportion of the sound energy needs to pass through the diffuse sound field through the holes 11 and into the sound-absorbing material 9.

For the effect, it has proven to be particularly advantageous if the sound diffusion channels formed between the steps have their smallest cross-section near the end edges of the steps. This can be achieved in different ways. In fig. 3 shows an embodiment where the steps 22, which project into the sound-transmitting space from the hole profile 20 and are designed as one with the hole profile/have an approximately drop-shaped cross-section which has its greatest thickness at 24 and then decreases on both sides, as the reduction towards the free step edge at 2 3 is stronger than towards the root of the step. Thereby, sound diffusion channels are obtained which, apart from the entrance part which is limited by the area 23, continuously expand from a narrowest place 24 which is determined by the greatest thickness of the steps, towards the holes 21 in the hole profile 20.

It should be noted here that the holes should make up the largest possible proportion of the total surface of the hole profile between the steps. In any case, the holes' share of this surface should be greater than 50%bg preferably greater than 75%.

In fig. 4 shows another design example of the step profile. This step profile is the one used according to fig. 1. Here, too, the steps are made in one piece with the hole profile 10. The hole profile with the steps can be made of any suitable material. Each step has over a large part of its height bordering the root of the step, a portion 12 of constant thickness. This part is joined in the direction towards the sound-transmitting space by a part 15 which has continuously increasing thickness, and which ends in flat end surfaces 13. The flanks 14 of the steps can be smooth, but can also be made rough, fluted or stepped. If necessary, the profile in fig. 4 a rounded or pointed end part of the step as shown at 23 in fig. 3, could join the step profile in fig. 4. The embodiment in fig. 4 has, however, proven particularly advantageous in the form shown.

The edge damping profile according to the invention can also be used for other building elements that consist of two shells, e.g. in partitions with double panes of glass or in wall elements consisting of two panels lying at a distance from each other. Instead of in windows, the edge dampening profiles can also be used in the described manner in door wings and the like.

A further important application example concerns sound attenuation in the area of passage gaps as they exist, e.g. between movable wings and wall-fixed frames of doors, windows or the like. The new edge damping profile can be so arranged on one or both of the gap's limiting surfaces that the sound waves that penetrate through the gap enter the sound diffusion channels between the steps and are affected in the manner described above before they enter the pad of sound-absorbing material through holes in the hole profile. With particular advantage, the edge dampening profile in this case is arranged between two spaced apart gasket elements that seal the gap between the two structural parts. As a result of the sealing elements, a mainly closed sound-transmitting space is formed in which the edge damping profiles according to the invention are arranged. An embodiment of this is shown in fig. 2. Here it is assumed that 30 is the wing part. A gasket 31 is embedded in this. The wing is closed on the outside by a metal or plastic profile 35 which has a sealing strip. Between the structural part described and the wall-fixed frame 32 there is a through gap 38. This is sealed on the outside by a gasket strip 33 which is arranged in an external profile 34, while the other gasket 31 interacts directly with the edge dampening profile 37. This again has a hole profile 40 with a protruding step 39 and a sound-absorbing pad 36 arranged behind the hole profile. The effect is of a similar nature to that of the edge dampening profile in the window described above.

Claims (16)

1. Edge damping profile for sound-absorbing building constructions, especially for surface-like building elements with two shells, e.g. wall elements, door and window sashes or the like, consisting of a hole profile facing the sound-transmitting room, and a pad of sound-absorbing material arranged behind the hole profile, characterized in that at least some of the sound passage holes (11) in the hole profile (10) are arranged in connection with a sound diffusion channel facing the sound transmitting room (7). 2. Profile as specified in claim 1, characterized in that the sound diffusion channel is limited by steps (12, 13) which project into the sound transmitting space. 3. Profile as specified in claim 2, characterized in that the holes (11) are arranged in rows that extend in the longitudinal direction of the hole profile (10), and that the row of holes is limited on both sides of a step (12, 13) . 4. Profile as specified in claim 3, characterized in that the portion of holes makes up more than half and preferably more than 3/4 of the entire hole profile's raft between the steps. 5. Profile as stated in claim 1 or 2, characterized in that the limiting surfaces for the sound diffusion channel, resp. each sound diffusion channel, from the hole plane of the hole profile in the direction towards the sound-transmitting space, runs parallel and/or converges over most of the channel length measured in the direction of the hole axis. 6. Profile as specified in claim 5, characterized in that each sound diffusion channel has a cross-sectional narrowing near the edge facing the sound-transmitting space. 7. Profile as specified in one of claims 2-6, characterized in that each step has a cross-sectional fold (24) close to the edge (13) facing the sound-transmitting space. 8. Profile as stated in one of the claims 2-7, characterized in that the stepped edge facing the sound-transmitting space is rounded or pointed in cross-section (fig. 3). 9. Profile as specified in one of claims 2-7, characterized in that the step edge facing the sound-transmitting room is flat in cross-section. 10. Profile as specified in claim 9, characterized in that the sound diffusion channel has its smallest cross-section in the area of the free step edge (13). 11. Profile as stated in claim 9 or 10, characterized in that the thickness of the step first decreases evenly from the free step edge (13), and that the step then transitions into a step part (12) which has a constant thickness and extends to the root of the step . 12. Profile as specified in claim 8, characterized in that the thickness of the step decreases evenly from the rounded, resp. to-pointed, step edge (2 3) to the root of the step. 13. Profile as stated in one of claims 2-12, characterized in that the steps are produced in one piece with the hole profile. ' 14. Profile as specified in one of the preceding claims, characterized in that the inner surface of the sound diffusion channel is made rough, grooved or stepped. 15. Profile as stated in one of the claims 1-14, characterized in that the steps, when incorporating the profile at the perimeter of a space between two parallel, spaced apart plates or panes with limited sound transmitting space, extend parallel to the plates or panes. 16. Profile as stated in one of the claims 1-14, characterized in that the profile is arranged between two gaskets (31>33) which are at a distance from each other in the sound transmission direction and seals a gap (38) between a movable wing (30) and a wall-fixed frame (32), and at least on one of the two parts (wing or frame).