FR3097887A1 - Acoustic and vibratory improvement building module - Google Patents

Abstract

The invention relates to a construction module for the absorption of mechanical and sound vibrations comprising at least one flyweight connected to each other, or to said module or to the structure, by at least one single or one compressible multi-link having a module. of Young Y1, each of said weights also being connected to two opposite walls of said modulus by elastically deformable links having a Young's modulus Y2, with Y2 / Y1 greater than 1,000, the resonance frequencies of each of the respective pairs of weights / associated deformable links corresponding approximately and preferably to the natural frequencies of a wall of a structure.

Description

Building module with acoustic and vibration improvement

Field of invention

The present invention relates to the field of masonry and more to the field of wall structures forming floors or walls, or even interior partitions, made up of alveolar or solid masonry elements, for example bricks, some elements of which have a structure suitable for improving the phonic properties.

It is known to improve the phonic qualities by porous or fibrous materials or absorbent acoustic panels attached to the wall, but also by the insertion of so-called Helmholtz resonators.

Archaeological sources report an "acoustic vase" in the form of one or more vases that the builders inserted into the masonry in order to give the space under consideration a certain sound rendering, a desired acoustic quality, for example in the walls or in the vaults of medieval churches.

State of the art

Known in the state of the art is the German patent application DE102008042478. The method consists in transmitting vibrations acting on an object to be protected to a cubic vibrating mass which is held by inertia between tension springs or pressure springs. The static dead weight of the vibrating mass is partially absorbed by the magnetic forces which act between the elements of a horizontally acting vibration damper, the vibrating mass being entirely of steel. The vibrating mass is formed as a disc-shaped body. Viscoelastic dampers are connected to the vibrating mass, so one of the dampers is attached to the springs. A variant has a horizontally acting vibration damper formed as a spring mass system.

Patent application WO9402755 describes a device for damping the periodic movements of a body or a mass, in particular oscillations, and comprising a housing fixed to this body or this mass and which contains a damping element movable by relative to the housing and subjected to the action of an elastic force, device in which the section of the damping element is comparable to the internal section of the housing, in such a way that a fluid filling the internal space of the housing can flow only with significant resistance along the damping element or through the latter in the orifices which it comprises, and in which the mode of oscillation of the damping element with respect to the casing, mode resulting from the restoring force of the spring elements (5), at least one in number, inserted between at least one front face of the damping element and at least one inner wall of a front face of the casing; the system can only be approximately described by means of a nonlinear equation of motion.

Patent FR3027082 describes a non-linear dynamic absorber comprising a blade with two end parts and an intermediate part with a non-linear spring function, a mass fixed to the intermediate part with a non-linear spring function of the blade, as well a fixing means making it possible to fix the two end parts of the blade to a solid support. The intermediate part with a non-linear spring function can oscillate around its equilibrium position or its equilibrium positions. This patent also describes a building element containing such an absorber and the use of such an absorber or building element to reduce the acoustic transparency of a wall.

Disadvantages of the prior art

These solutions of the prior art are difficult to integrate in the form of autonomous modular elements. The solutions of the prior art constitute modules involving designing the building in a way allowing the walls to be built around these modules, and do not allow them to be integrated as a replacement for an ordinary building element.

Solution provided by the invention

In order to remedy these drawbacks, the present invention relates, in its most general sense, to a construction module for absorbing mechanical and sound vibrations comprising at least one flyweight connected to one another, or to said module or to the structure, by at least one compressible single or multi-link having a Young's modulus Y ₁ , each of said flyweights also being connected to one of the opposite walls of said module by at least one elastically deformable link having a Young's modulus Y ₂ , with Y2/Y1 greater than 1,000, the resonance frequency of each of the associated flyweight/deformable link pairs corresponding to at least one natural frequency of a wall of a structure.

Preferably, said building module for absorbing mechanical and sound vibrations comprises at least two flyweights interconnected by at least one single or one compressible multi-link having a Young's modulus Y ₁ .

Preferably, said Young's modulus Y ₁ is less than 200 MPa,

Advantageously, said Young's modulus Y ₂ is greater than 1,000 MPa,

According to an advantageous embodiment, each weight has a mass corresponding to one tenth of the surface mass of the wall, and more generally equal to at least one thirtieth of the dynamic modal mass of the considered modes of the wall.

According to a first variant, is produced by adding two half-blocks each containing a flyweight.

According to a second variant, the module is produced by adding two half-blocks each containing at least one flyweight.

According to a third variant, the module is made from a half-block containing at least one flyweight.

Detailed description of a non-limiting example of the invention

• [Fig.1] La figure 1 représente une vue de face d’une paroi comprenant un module selon l’invention
• [Fig.2] La figure 2 représente une vue éclatée d’un demi-bloc selon l’invention
• [Fig.3] La figure 3 représente une vue en perspective d’un demi-bloc
• [Fig.4] La figure 4 représente une vue en perspective d’un module assemblé
• [Fig.5]
• [Fig.6]
• [Fig.7] Les figures 5 à 7 représentent trois variantes de réalisation, les masses affichées étant purement indicatives et données à titre d’exemple selon un cas particulier de paroi.

The present invention will be better understood on reading the detailed description of a non-limiting example of the invention which follows, with reference to the appended drawings where:

• [Fig.1] Figure 1 shows a front view of a wall comprising a module according to the invention
• [Fig.2] Figure 2 shows an exploded view of a half-block according to the invention
• [Fig.3] Figure 3 shows a perspective view of a half-block
• [Fig.4] Figure 4 shows a perspective view of an assembled module
• [Fig.5]
• [Fig.6]
• [Fig.7] Figures 5 to 7 represent three embodiments, the masses displayed being purely indicative and given by way of example according to a particular case of wall.

General principle of the invention

The solution according to the present invention consists in introducing a masonry accessory (1), replacing or in juxtaposition of one or more masonry elements constituting a homogeneous wall (2) vertical or horizontal, with the aim of improving its acoustic reduction. . By homogeneous wall, we mean a structure made up of identical masonry elements, such as a wall or a partition or a floor with interjoists (see. Fig.1).

Depending on the judicious sizing of its components, relating to the nature of the homogeneous wall to be treated and the choice of materials for its components, the accessory, placed close to the center of a wall, close to the place of a maximum dynamic modal deformation of a wall, will optimize the improvement of its acoustic attenuation.

Structure of a module according to the invention

The structure of a module according to the invention is shown with reference to Figures 2 to 4.

A module of which FIG. 4 represents a perspective view consists of two half-blocks (50, 60) illustrated in FIG. 3, assembled and glued.

Figure 2 shows an exploded view of a half-block (50).

• une coque (10) présentant un fond (11) et deux cotés (12, 13) s’étendant longitudinalement
• une masselotte (30) présentant une gorge longitudinale pour le positionnement d’une lame-ressort (20)
• une plaque en mousse compressible amortissante (40) éventuellement collée sur la masselotte (30) et sur la/les mousses (45/, 46), ou sur la/les masselottes (35/, 36) du demi-bloc adjacent (60), ou sur le module (50) ou sur la structure (2).

It is made up of:

• a shell (10) having a bottom (11) and two sides (12, 13) extending longitudinally
• a flyweight (30) having a longitudinal groove for positioning a leaf spring (20)
• a damping compressible foam plate (40) optionally glued to the counterweight (30) and to the foam(s) (45/, 46), or to the counterweight(s) (35/, 36) of the adjacent half-block (60) , or on the module (50) or on the structure (2).

The half-block illustrated in FIG. 3 constitutes a multimodal resonator. The head-to-tail assembly of at least two half-blocks forms a multimodal multi-resonator.

The damping compressible foam (40) is a polymer foam or a rubber or a mineral wool which gives it a Young's modulus of less than 200 MPa. The foam is subdividable into several elements to be placed on the weights (30, 35, 36) and does not necessarily cover the entire surface of the connected weights. Depending on the height of each component (Mo-Ma-Re) (spring flyweight foam) along the Oy axis, the damping foam or foams (40, 45) are more or less crushed, at the time of the head- spade of the half-blocks. The nominal thickness of one of the foams is at least 1 mm.

The vibrating mass (30) must be greater than 1% of the dynamic modal mass of the wall. In certain cases, this mass corresponds to the ratio of the surface mass (expressed in Kg/m²) of the heavy wall to be treated, to the apparent surface of this wall (expressed in m²). In some cases, the flyweight (30) has a mass (expressed in Kg) corresponding to one tenth of the surface mass Ms of the wall (expressed in Kg/m²); ex. of an alveolar brick wall with coating Ms = 125 Kg/m². The greater the vibrating mass (30), the better the effectiveness of the masonry acoustic accessory at low frequency.

The spring (20) is a leaf with a simple or complex geometry which can naturally be deformed, such that the modal displacements of the resonator are directed almost transversely to the wall (2), or almost perpendicular to the walls (12, 13). The dimensions, the geometric shape and the choice of material of this blade contribute to the effectiveness of the acoustic accessory in the desired frequency range. Depending on the height of each component in the vertical direction, perpendicular to the bottom (11)), the springs (20) of the resonators can be more or less stressed (in compression along the vertical axis, at the time of head-to-tail assembly of the half-blocks (50, 60) with one or two interlayer foam layers (40, 45) optionally glued to the two weights (30, 35). not necessarily glued together.

The shell (10) may be comparable in nature to the structural material of the wall. After assembly (by gluing), the shells of the half-blocks (50, 60) incorporating the multimodal resonators (30, 35) have the same overall height along the axis Oy of the masonry elements of the treated wall.

Alternative realization

For higher frequency processing, additional accessories can be dimensioned by “lineically” subdividing along the longitudinal axis by discontinuity of the vibrating masses (30) and springs (20), or by changing the nature and dimensions of the masses. vibrators (30) and/or springs (20) and/or foams or mineral wools (50).

• une masselotte inférieure (30) de 12 kg et une masselotte supérieure (35) de 12 kg (figure 4)
• une masselotte inférieure de 12 kg et deux masselottes supérieures, l’une (35) de 7 kg et l’autre (36) de 5 kg(figure 5)
• une masselotte inférieure de 12 kg et deux masselottes supérieures (35, 36) de 6 kg.

Figures 5 to 7 represent examples of implementation with respectively:

• a lower weight (30) of 12 kg and an upper weight (35) of 12 kg (figure 4)
• a lower weight of 12 kg and two upper weights, one (35) of 7 kg and the other (36) of 5 kg (figure 5)
• a lower weight of 12 kg and two upper weights (35, 36) of 6 kg.

The weights displayed are given by way of example according to a particular case of wall.

The effectiveness of an accessory is optimal by keeping it at least 0.5 m away from any structural junction or any chaining contiguous to this wall.

Claims (8)

- Construction module for the absorption of mechanical and sound vibrations comprising at least one flyweight (30, 35, 36) connected to one another, or to said module (50) or to the structure (2), by at least one simple or a compressible multi-link (40, 45) having a Young's modulus Y ₁ , each of said flyweights (30, 35, 36) also being connected to two opposite walls of said module by elastically deformable links (20, 25) having a Young's modulus Y ₂ , with Y2/Y1 greater than 1,000, the resonance frequencies of each of the respective pairs of weights (30, 35, 36)/associated deformable links (20, 25, 26) and (40, 45, 46) corresponding approximately and preferentially to the natural frequencies of a wall (2) of a structure. - Building module for the absorption of mechanical and sound vibrations according to claim 1 characterized in that said Young's modulus Y ₁ is less than 200 MPa, - Building module for the absorption of mechanical and sound vibrations according to claim 1 characterized in that said Young's modulus Y ₂ is greater than 1,000 MPa, - Building module for the absorption of mechanical and sound vibrations according to claim 1 characterized in that each flyweight (30, 35, 36) has a mass corresponding to at least one thirtieth of the dynamic modal mass of a natural mode considered of the wall (2) (expressed in Kg), or corresponding in certain cases, to at least one tenth of the value of the surface mass of the wall (2) (expressed in Kg/m²), - Building module for the absorption of mechanical and sound vibrations according to claim 1 characterized in that it is made of a half-block containing at least one flyweight (30) or (35), - Building module for the absorption of mechanical and sound vibrations according to claim 1 characterized in that it is produced by adding two half-blocks, each containing at least one flyweight (30) or (35, 36), - Building module for the absorption of mechanical and sound vibrations according to claim 1 characterized in that it is made by adding two half-blocks containing for one a flyweight (30) and for the other two flyweights ( 35, 36) of identical masses, - Building module for the absorption of mechanical and sound vibrations according to claim 1 characterized in that it is made by adding two half-blocks containing for one a flyweight (30) and for the other two flyweights ( 35, 36) of different masses.