WO2010058120A1

WO2010058120A1 - Acoustic reflector

Info

Publication number: WO2010058120A1
Application number: PCT/FR2009/052199
Authority: WO
Inventors: Alain Tisseyre
Original assignee: Alain Tisseyre
Priority date: 2008-11-20
Filing date: 2009-11-17
Publication date: 2010-05-27
Also published as: FR2938687B1; MA32908B1; EP2347406A1; FR2938687A1; CN102216981A; CN102216981B

Abstract

The invention relates to an acoustic reflector (4), characterized in that it has a structure comprising a plurality of longitudinal members (6) separated from one another and connected via a plurality of crossmembers (5), which are spaced apart, said structure having at least one first zone with a first spacing between the crossmembers and at least one second zone with a second spacing between the crossmembers, the second spacing being different from the first spacing.

Description

Acoustic reflector

The invention relates to an acoustic reflector.

Acoustic reflectors are particularly used in theaters, such as concert halls, opera or theater, or in rehearsal rooms or recording studios. The wave produced inside a room is reflected on the different walls, formed in particular by the floor, the walls and the ceiling.

Sounds, regardless of the medium in which they are propagated, undergo reflections on the walls or panels that surround them. The characteristics of these reflections depend on many parameters: the shape and the modenature, the material of the reflecting walls, the thickness of these walls, the material located at the rear of the reflecting walls, the sound level of the source. reflections in the space defined by the room constitute the spatio-temporal characteristics of the acoustic field. Spatial characteristics are defined by the distribution of acoustic energy in space and temporal characteristics are defined by the distribution of acoustic energy over time.

A sound source emits so-called source waves, reflected a first time on a wall. The waves thus reflected form the primary reflections. These reflected waves will themselves be reflected on other walls, one or more times. The subsequently reflected waves thus form the secondary reflections.

Each type of reflection brings different information to the listener. The human ear primarily uses the time between the original sound and the primary reflections to determine the size of the surrounding area, while the secondary reflections indicate the type and complexity of the environment in which the listener is. as well as its distance to the transmitting source.

Direct waves and multiple reflections form the acoustic field. The spatio-temporal characteristics of this one determine the way in which the listener perceives the sounds emitted in the room.

In addition, the walls subjected to the impact of a wave can vibrate and thus emit parasitic waves during the reflection of the wave. In this case, each vibrating wall constitutes an additional acoustic source superimposed on the source waves and the reflected waves. The phenomenon of vibration can cause audible noise and thus annoy including musicians. This phenomenon must be avoided.

The phenomenon of vibration is all the more common as light plate coatings, generally less expensive, are often used. Moreover, the mounting of these light plates at a distance from the walls, form reverberant volumes that amplify a harmful effect, called "drum skin".

In order to limit this amplification, it is known to place acoustic absorbent materials, for example mineral wool, in the volume located between the plate and the wall. However, this arrangement allows only to limit the amplification born volume between the plate and the wall, but has no effect on the vibration of the plate.

The work of the room designers consists in choosing materials to limit this phenomenon.

In addition, in order to adapt the general acoustics of a room, it is necessary to be able to regulate the following phenomena: the phenomenon of reflection: the incident waves are reflected, without preferential direction. the absorption phenomenon: this assumes that a part, or almost all of the incident wave, is absorbed.

In particular, it is necessary to be able to adjust the spatio-temporal response of the soil, limiting or promoting the aforementioned phenomena. Finally, it is necessary to be able to act on the various parameters of diffusion, absorption, reflection, and reverberation, over the entire audible range of wavelengths.

In order to regulate all or part of these parameters, it is known to have, on the walls of the room, reflectors of hemispherical, semi-cylindrical, pyramidal shape, or in the form of a truncated pyramid or bar.

These reflectors make it possible to obtain a very diffuse reflection of the incident wave, without preferential direction.

Figures 1 to 3 show the waveform 1 reflected by a reflector 2 of pyramidal shape, respectively for a source or incident wave of low frequency, medium frequency and high frequency. The waveform 1 is a three-dimensional diagram representing the intensity of acoustic waves reflected by a wall or a solid as a function of their direction of reflection. Thus, in the case of the waveforms 1 shown in FIGS. 1 to 3, lobes 3 appear, the latter representing areas of high intensity of the reflected waves. It can be seen that these lobes 3 are of the same intensity and are oriented in opposite directions. In this case, the waveform does not have a privileged direction.

However, depending on the applications, it may be necessary to orient the diffusion of the reflected waves. For example, it may be necessary to direct some of the reflected waves and broadcast to an orchestra so that each musician can benefit from an acoustic feedback of his own game and the game of other musicians.

The invention aims to remedy all or part of these disadvantages by proposing a diffuser to ensure an oriented diffusion of acoustic waves.

For this purpose, the invention relates to an acoustic reflector, characterized in that it comprises a structure comprising a plurality of spacers spaced relative to each other, connected by a plurality of cross members spaced relative to each other, the sleepers being distributed so that the structure has at least a first area having a high density of sleepers and at least a second area having a low density of sleepers.

This type of diffuser makes it possible to ensure diffusion of the acoustic waves, while conferring on the reflected and diffused waves a particular preferred orientation. Indeed, the reflected wave will tend to be directed towards the area of lower density of sleepers.

In addition, such a diffuser does not create parasitic vibrations.

Preferably, the spacing between two adjacent ties of the first zone increases progressively, as said sleepers of the first zone are close to the second zone, the distance between two sleepers of the second zone gradually decreasing, as and as said sleepers of the second zone are close to the first zone, so as to ensure a progressive and continuous distribution of the sleepers along the structure. According to a feature of the invention, the structure has, on the side of a volume to which the sound must be reflected, a general shape concave, convex or wavy.

This shape makes it possible to accentuate the orientation of the reflected and diffused waves. it is then possible to create reflectors whose waveform can be predefined, by playing on certain parameters, such as the dimensions of the crosspieces, their spacing, or the overall flat or curved reflector shape. Advantageously, the concave, convex or corrugated zone has a radius of curvature of between 1 meter and 10 meters.

According to an alternative embodiment of the invention, the structure has a generally planar shape.

According to one embodiment of the invention, at least part of the structure is covered, on the opposite side to the volume to which the sound is to be reflected, at least one acoustic reflection plate.

Advantageously, the acoustic reflection plate is made of wood or plaster.

This type of material makes it possible to amplify the phenomenon of reflection and to increase the reverberation.

Advantageously, the acoustic reflection plate is made of fiberglass cloth.

This type of material makes it possible to absorb part of the incident wave, and thus to limit the effect of reverberation due to the multiplicity of echoes reflected by walls and objects. It is recalled that when the reverberation of the sound is too great inside the volume, speech intelligibility and sound reproduction are difficult to control.

Preferably, the rails and / or sleepers are made of wood. According to a characteristic of the invention, the longitudinal members and / or the crosspieces have a height of between 22 and 40 mm and a thickness of between 10 and 100 mm.

The height is defined as the distance along the axis normal to the structure and the width as the distance along the tangent plane of the structure. Anyway, the invention will be better understood with the aid of the description which follows with reference to the attached schematic drawing showing, by way of example, several embodiments of this acoustic reflector.

Figure 1 to 3 are views showing the waveform of a pyramidal-shaped acoustic reflector, respectively for incident waves at low, medium and high frequencies.

Figure 4 is seen in perspective and from below, an acoustic reflector of generally wavy shape;

Figure 5 and a side view of the reflector of Figure 4; Figure 6 is a top view of the reflector of Figure 4;

Figure 7 is a perspective view from below of a reflector of Figure 4, in which the shape of the reflected and scattered wave is shown;

Figure 5 is a view of a rehearsal room equipped with a reflector of Figure 4;

9 to 12 are views respectively corresponding to FIGS. 4 to 7, of a reflector of FIG. 4 equipped with reflection and / or absorption plates.

FIGS. 13 to 16 and 17 to 20 are views respectively corresponding to FIGS. 4 to 7 and 9 to 12, of a generally concave reflector;

21 to 24 and 25 to 28 are views respectively corresponding to Figures 4 to 7 and 9 to 12, a reflector of generally convex shape; Figure 29 and 30 are views respectively corresponding to Figures 6 and 7, a reflector of generally planar shape.

An embodiment of a reflector 4 is shown in FIGS. 4 to 8. This reflector 1 comprises a structure of generally wavy shape, comprising a plurality of wooden crosspieces 5 spaced apart from one another, refitted by a plurality of longitudinal members. 6 wooden apart from each other. The corrugated shape defines a vertex 7 and a recess 8, said structure further having an upper surface 9, intended to be turned towards a ceiling 10 and a lower surface 11, intended to be turned towards the interior of a theater or repetition. The spacing of the crosspieces 5 varies according to their position. More particularly, the sleepers 5 are distributed so that the structure has one or more areas having a high density of sleepers and at least one or more areas having a low density of sleepers. In the example shown in FIG. 4, the zones of high density are situated at the level of the vertex 7 and the hollow 8, the low density zones being located at the ends 14 of the structure and in a median zone 15 of the -this.

The spacing between two adjacent crosspieces of each high density zone increases progressively as said cross members of the high density zone are close to the low density zone (s).

In addition, the spacing between two crosspieces 5 of each low density zone gradually decreases, as said cross members 5 of the low density zone are close to the high density zone or zones.

The arrangement of the crosspieces 5 is made in a progressive and continuous distribution thereof along the structure.

More particularly, the zones of high density are slightly off-center of the axis A of the vertex 7 and of the axis B of the recess 8, this decentration favoring the orientation of the wave reflected in a preferential direction, as is better described. below.

The spacing between the crosspieces 5 is between 10 and 100 mm, in areas of small spacing and is between 100 and 500 mm, in areas of high spacing.

The radius of curvature of the structure 4 is between 1 m and 10 m. In addition, the cross members 5 and / or the longitudinal members 6 have a height of between 22 and 40 mm and a thickness of between 10 and 100 mm. The height is defined as the distance along the axis normal to the structure 4, and the width as the distance along the tangent plane of the structure 4.

It is noted that the reflected waves 1 are scattered in all directions, but that the waves thus diffused are oriented preferentially along the axis or the plane P (FIG. 7). More particularly, we note that the shape of the wave 1 tends to move towards the zone of greater spacing, that is to say of lower density, sleepers 5.

It is then possible to direct a portion of the waves to an orchestra or to a preferred area of the room. According to one embodiment shown in FIGS. 9 to 12, the upper surface 9 can be equipped with reflection or diffusion plates 12, covering all or part of cells 13 delimited by the crosspieces 5 and the longitudinal members 6.

The acoustic reflection plates are made of wood, plaster or fiberglass cloth, especially in a material marketed under the trademark "Acoustis 50".

The number and position of these plates make it possible to adjust the reverberation phenomenon according to the needs. As shown in FIG. 12, the orientation of the waveform 1 is not substantially modified.

Another embodiment is shown in Figures 13 to 16. In this embodiment, the reflector 4 has a generally concave shape, facing downwards. Elements similar to those described above have been designated by the same references. The areas of lower density of the crosspieces 5 are located at the ends 14 of the structure, the zone of higher density of the crosspieces 5 being located at the hollow 8 formed by the concavity. More particularly, the zone of higher density is slightly off-center with respect to the axis B of the hollow 8. In the same manner as above, the structure may be equipped with reflection or acoustic absorption plates 12, as shown Figures 17 to 20.

In addition, as previously, the reflected and scattered waves 1 are oriented preferentially towards the zone of more low density of the crosspieces 5.

Figures 21 to 24 and 25 to 28 show similar embodiments to those respectively described in Figures 13 to 16 and 19 to 20, the structure however having a convex shape, facing downwards.

In this embodiment, the zone of higher density of the crosspieces 5 is centered on the axis A of the vertex 7 of the structure, formed by the convexity. In this case, the reflected and scattered waves 1 are oriented preferentially in two directions P ₁ , P2, directed on either side of the symmetry plane of the structure. As before, this orientation is directed towards the low density lateral zones, that is to say of greater spacing of the crosspieces 5.

Figures 29 and 30 show an embodiment similar to that described in Figures 4 to 7, the structure however having a planar shape. As can be seen in these figures, the crosspieces 5 may have larger dimensions than the longitudinal members 6. The reflected and diffused waves 1 are substantially directed in a zone normal to the zone of greater spacing of the cross members, delimited on both sides. other by areas of smaller gauge.

It goes without saying that the invention is not limited to the embodiments of this acoustic reflector, described above as examples, but it encompasses all variants.

Claims

1REVENDICATIONS

1. acoustic reflector (4), characterized in that it comprises a structure comprising a plurality of spacers (6) spaced relative to each other, connected by a plurality of cross members (5) spaced relative to each other, the cross members being distributed so that the structure has at least a first zone having a high density of sleepers and at least a second zone having a low density of sleepers.

2. acoustic reflector (4) according to claim 1, characterized in that the spacing between two adjacent crosspieces (5) of the first zone increases gradually, as said sleepers (5) of the first zone are close the second zone, the spacing between two crosspieces (5) of the second zone progressively decreasing, as said sleepers (5) of the second zone are close to the first zone, so as to ensure a gradual distribution and continues sleepers (5) along the structure.

3. Reflector acoustic (4) according to claim 1 or 2, characterized in that the structure has, on the side of a volume to which the sound must be reflected, a general shape concave, convex or wavy.

4. Reflector acoustic (4) according to claim 3, characterized in that the concave zone, convex or corrugated has a radius of curvature of between 1 meter and 10 meters.

5. Acoustic reflector (4) according to claim 1 or 2, characterized in that the structure has a generally planar shape.

6. Reflector acoustic (4) according to one of claims 1 to 5, characterized in that at least part of the structure is covered on the side (9) opposite the volume to which the sound must be reflected, d ' at least one acoustic reflection plate (12). read

7. Acoustic reflector (4) according to claim 6, characterized in that the acoustic reflection plate (12) is made of wood, plaster or fiberglass cloth.

8. Reflector acoustic (4) according to claim 6, characterized in that the acoustic reflection plate (12) is made of fiberglass cloth.

9. Reflector acoustic (4) according to one of claims 1 to 8, characterized in that the longitudinal members (6) and / or crosspieces (5) are made of wood.

10. Acoustic reflector (4) according to one of claims 1 to 9, characterized in that the longitudinal members (6) and / or the crosspieces (5) have a height of between 22 and 40 mm and a thickness of between 10 and