FR3139584A1 - Glass wool panel for sound absorption, associated manufacturing process and use - Google Patents

Abstract

Glass wool panel for sound absorption, manufacturing process and associated insulation process The invention relates to a glass wool panel intended for use as an acoustic panel and having: - a density of between 40 kg/m3 and 55 kg/m3, a thickness of between 10 mm and 50 mm, and an average micronaire index between 2/5g and 5.5/5g, or- a density between 60 kg/m3 and 85 kg/m3, a thickness between 10 mm and 50 mm, and an average micronaire index between 2.4/5g and 8.5/5g, or- a density equal to 90 kg/m3, a thickness between 10 mm and 38 mm, and an average micronaire index between 3/5g and 8.5/5g, or- density equal to 100 kg/m3, a thickness between 10 mm and 30 mm, and an average micronaire index between 3.3/5g and 8.5/5g.

Description

Glass wool panel for sound absorption, associated manufacturing process and use

The present invention belongs to the general field of the manufacture of products for improving sound absorption within an interior space. It relates more particularly to a glass wool panel intended to be used as an acoustic panel. It also relates to a method for manufacturing such a panel as well as a use of the latter within an interior space.

By “acoustic panel” is meant throughout this description a panel which, due to its glass wool composition, may possibly provide thermal insulation properties, but is first and foremost configured to improve sound absorption within an interior space, such as a room in a home (example: bedroom in a house, an office in a workplace, etc.).

As a reminder, sound absorption determines the amount of sound that is absorbed within a single interior space, more particularly by all of the elements that make up the latter (walls, floors, curtains, etc.). For example, in a large empty space with hard walls and floors and no furniture, sound absorption is low and acoustic reverberation is strong. This space will therefore sound hollow and give rise to a resonance effect. Conversely, the more soft and absorbent surfaces the space contains, the better the absorption and the less resonance there will be.

To ensure good mechanical strength of an acoustic panel, and more particularly good resistance of its edges, the parameter considered to be of greater interest during the manufacture of the panel is the density of the glass wool making up the latter, it being understood that the higher this density, the better the mechanical strength.

To date, and for the reasons mentioned above, the production of glass wool panels is largely driven by the density parameter. However, this approach is disadvantageous when it comes to taking into account the sound absorption capacities of these panels.

Indeed, it has been observed that playing on the density parameter alone, by aiming to increase it, had the effect of increasing the resistivity to air flow of a panel, therefore leading to a degradation of the sound absorption performance.

The present invention aims to remedy all or part of the drawbacks of the prior art, in particular those set out above, by proposing a solution which makes it possible to provide a glass wool panel having, for a given density, better sound absorption performance than those of prior art panels of the same density.

For this purpose, and according to a first aspect, the invention relates to a glass wool panel intended to be used as an acoustic panel and having:
- a density between 40 kg/ ^m3 and 55 kg/ ^m3 , a thickness between 10 mm and 50 mm, and an average micronaire index between 2/5g and 5.5/5g, or
- a density between 60 kg/ ^m3 and 85 kg/ ^m3 , a thickness between 10 mm and 50 mm, and an average micronaire index between 2.4/5g and 8.5/5g, or
- a density equal to 90 kg/ ^m3 , a thickness between 10 mm and 40 mm, preferably between 10 mm and 38 mm, and an average micronaire index between 3/5g and 8.5/5g, or
- density equal to 100 kg/ ^m3 , a thickness between 10 mm and 30 mm, and an average micronaire index between 3.3/5g and 8.5/5g.

As is known, the micronaire index (also called "the micronaire") is representative of the fineness of the glass fibers used to form the panel. The measurement of this micronaire index more particularly takes into account their specific surface area via the measurement of the aerodynamic pressure loss when a given quantity, i.e. a sample (typically 5 grams), of fibers extracted from an unsized panel is subjected to a given pressure of a gas, such as typically air or nitrogen. Such a measurement is common in mineral fiber production units, and is carried out according to the DIN 53941 or ASTM D 1448 standard using a device called a "micronaire device".

For further details on the measurement of the micronaire index of a sample, as well as on the design and operation of said micronaire device, it is for example possible to consult document WO2003098209.

It follows from the above that the terms “average micronaire index”, in reference to an acoustic panel, refer to an average value of micronaire indices determined from several samples taken from said acoustic panel. In other words, the micronaire index measurable by taking a sample from an acoustic panel may vary significantly around this average micronaire index, depending on where the sample is taken on the panel.

As a non-limiting example, the relative variation of the micronaire index within an acoustic panel according to the invention is less than 15%. By "relative variation", reference is conventionally made to the ratio between, on the one hand, the difference between the extreme values of micronaire index within the panel, and, on the other hand, the minimum value of micronaire index within the panel. Having a relative variation of less than 15% makes it possible to guarantee good homogeneity (in terms of micronaire index) of the acoustic panel.

Generally speaking, the important information on which the present invention is based is that the more the average micronaire index increases, the more the resistivity to air flow decreases (the measurement of this resistivity being conventionally carried out according to the ISO 9053 standard).

Thus, the invention proposes, for a given density and thickness of glass wool panel, to influence upwards another parameter to improve the sound absorption, namely said average micronaire index. In this sense, the invention goes against the prejudice of the state of the art according to which it would not be possible to improve the sound absorption performance of a glass wool panel at constant density and thickness without using suitable veil(s) (the state of the art considering that the improvement of these performances necessarily implies aiming at least for a reduction in the density of the panel).

In other words, the invention is particularly advantageous in that it makes it possible to optimize the sound absorption performance for a given density and thickness of glass wool panel, so as to also guarantee good thermal insulation performance.

In practice, thanks to digital simulation tools but also thanks to manufacturing and testing campaigns, the inventors were able to determine the ranges of micronaires characterizing the glass wool panels according to the invention, so that they have excellent acoustic absorption performance (typically a resistivity to air flow substantially between 20 kPa.s/m ² and 100 kPa.s/m ² ).

Correlatively, it was found that these ranges of values make it possible to improve the acoustic absorption over the entire frequency range from 100 Hz to 4000 Hz compared to the panels of the state of the art. It was further observed that the panels according to the invention stand out particularly, to their advantage, from the panels of the state of the art in a frequency zone located around 500 Hz.

It should be noted that the upper limit considered for the panels of the invention, in terms of average micronaire index, is 8.5/5g. The inventors have in fact noted, through the various tests carried out, that the manufacture of glass wool panels having an average micronaire index exceeding this upper limit was not realistically possible with the production means known to date.

In particular embodiments, the glass wool panel may further comprise one or more of the following characteristics, taken individually or in all technically possible combinations.

In particular embodiments, the panel has a density equal to 40 kg/m3, a thickness of between 10 mm and 50 mm and an average micronaire index of between 2.1/5g and 4.4/5g.

In particular embodiments, the panel has a density equal to 50 kg/m3, a thickness of between 10 mm and 50 mm and an average micronaire index of between 2.2/5g and 5.5/5g.

In particular embodiments, the panel has a density equal to 60 kg/m3, a thickness of between 10 mm and 50 mm and an average micronaire index of between 2.4/5g and 7.1/5g.

In particular embodiments, the panel has a density equal to 70 kg/m3, a thickness of between 10 mm and 50 mm and an average micronaire index of between 2.5/5g and 7.5/5g.

In particular embodiments, the panel has a density equal to 80 kg/m3, a thickness of between 10 mm and 50 mm and an average micronaire index of between 2.7/5g and 7.5/5g.

The invention covers still other more particular examples of embodiment, as described in detail later.

According to a second aspect, the invention relates to a method of manufacturing a glass wool panel according to the invention.

Such a manufacturing process typically includes an internal centrifugation step implemented using an installation comprising:
- at least one centrifuge capable of rotating around a given axis, in particular vertical, and whose peripheral strip is pierced with a plurality of orifices to deliver filaments of a molten material,
- a high-temperature gas drawing means in the form of an annular burner which ensures the drawing of the filaments into fibers, and
- a receiving belt associated with suction means to receive the fibers.

The centrifuge(s), also called fiberizing plates, in fact make it possible to form mineral fibers or other thermoplastic materials, by an internal centrifugation process associated with drawing by a high-temperature gas stream. Internal centrifugation is applied in particular to the industrial production of glass wool intended for use in the composition of thermal and/or acoustic insulation products, for example. A stream of molten glass is introduced into each centrifuge rotating at high speed and pierced at its periphery by a very large number of orifices through which the glass is projected in the form of filaments under the effect of centrifugal force. These filaments are then subjected to the action of an annular drawing current at high temperature and speed along the wall of the centrifuge, a current which thins them and transforms them into fibers. The fibers formed are carried by this gas drawing current towards a receiving device generally consisting of a gas-permeable strip, called a receiving belt.

The implementation of the manufacturing process depends on several parameters, the values chosen for these parameters having an influence, in particular, on the density and the average micronaire index of the manufactured panel.

Examples of parameters to be adjusted to implement the manufacturing process include: viscosity of the molten glass, burner pressure, total glass output per day per centrifuge, number of holes per centrifuge, rotation speed of each centrifuge, etc.

Generally speaking, a person skilled in the art knows how to choose suitable values for the parameters of the manufacturing process, so as to obtain a glass wool panel having characteristics of density, thickness and average micronaire index included in the ranges according to the invention.

Preferably, the manufacturing process is implemented by adding a binder in the form of powder or droplets of binder solution sprayed (atomized) onto the glass fibers before collection on the receiving belt (preferably, the binder does not include thermoplastic binding fibers). The panel is then consolidated by hardening the binder.

For example, the binder content is between 2% and 30%, preferably between 3 and 15%, more preferably between 4 and 10%.

According to a third aspect, the invention relates to a use of a glass wool panel according to the invention for improving sound absorption within an interior space, said panel being fixed to a wall surface of said interior space.

In particular modes of implementing said insulation method, the wall surface is a ceiling.

Of course, nothing rules out considering other wall surfaces, such as a vertical wall or even a floor.

Description of examples of achievement

As mentioned above, more specific examples of producing glass wool panels according to the invention will now be described.

More particularly, the glass wool panels described in these examples are those for which the inventors were able to determine, in terms of average micronaire index, optimal acoustic performances at given density and thickness.

Thus, for each of these examples, when the thickness of the panel is equal to 20 mm (respectively 40 mm), the resistivity to air flow obtained is substantially equal to 60 kPa.s/m ² (respectively substantially equal to 30 kPa.s/m ² ).

Examples No. 1 and No. 1 bis of a panel with a density equal to 40 kg/m ³

According to example no. 1, a panel is considered to have a density equal to 40 kg/ ^m3 as well as a thickness equal to 20 mm and an average micronaire index equal to 2.4/5g.

According to example no. 1a, a panel is considered to have a density equal to 40 kg/ ^m3 as well as a thickness equal to 40 mm and an average micronaire index equal to 3.3/5g.

Examples No. 2 and No. 2a of a panel with a density equal to 50 kg/m ³

According to example no. 2, a panel is considered to have a density equal to 50 kg/ ^m3 as well as a thickness equal to 20 mm and an average micronaire index equal to 2.6/5g.

According to example no. 2a, a panel is considered to have a density equal to 50 kg/ ^m3 as well as a thickness equal to 40 mm and an average micronaire index equal to 4/5g.

Examples No. 3 and No. 3a of a panel with a density equal to 60 kg/m ³

According to example no. 3, a panel is considered to have a density equal to 60 kg/ ^m3 as well as a thickness equal to 20 mm and an average micronaire index equal to 3/5g.

According to example no. 3a, a panel is considered to have a density equal to 60 kg/ ^m3 as well as a thickness equal to 40 mm and an average micronaire index equal to 5/5g.

Examples No. 4 and No. 4a of a panel with a density equal to 70 kg/m ³

According to example no. 4, a panel is considered to have a density equal to 70 kg/ ^m3 as well as a thickness equal to 20 mm and an average micronaire index equal to 3.4/5g.

According to example no. 4a, a panel is considered to have a density equal to 70 kg/ ^m3 as well as a thickness equal to 40 mm and an average micronaire index equal to 6.3/5g.

Examples No. 5 and No. 5a of a panel with a density equal to 80 kg/m ³

According to example no. 5, a panel is considered to have a density equal to 80 kg/ ^m3 as well as a thickness equal to 20 mm and an average micronaire index equal to 3.9/5g.

According to example no. 5a, a panel is considered to have a density equal to 80 kg/ ^m3 as well as a thickness equal to 40 mm and an average micronaire index equal to 7.5/5g.

Examples No. 6 and No. 6a of a panel with a density equal to 90 kg/m ³

According to example no. 6, a panel is considered to have a density equal to 90 kg/ ^m3 as well as a thickness equal to 20 mm and an average micronaire index equal to 4.5/5g.

According to example no. 6a, a panel is considered to have a density equal to 90 kg/ ^m3 as well as a thickness equal to 40 mm and an average micronaire index equal to 7.5/5g.

Example no. 7 of a panel with a density equal to 100 kg/m ³

According to example no. 7, a panel is considered to have a density equal to 100 kg/ ^m3 as well as a thickness equal to 20 mm and an average micronaire index equal to 5.2/5g.

Claims (15)

Glass wool panel intended to be used as an acoustic panel and featuring:
- a density between 40 kg/ ^m3 and 55 kg/ ^m3 , a thickness between 10 mm and 50 mm, and an average micronaire index between 2/5g and 5.5/5g, or
- a density between 60 kg/ ^m3 and 85 kg/ ^m3 , a thickness between 10 mm and 50 mm, and an average micronaire index between 2.4/5g and 8.5/5g, or
- a density equal to 90 kg/ ^m3 , a thickness between 10 mm and 40 mm, preferably between 10 mm and 38 mm, and an average micronaire index between 3/5g and 8.5/5g, or
- density equal to 100 kg/ ^m3 , a thickness between 10 mm and 30 mm, and an average micronaire index between 3.3/5g and 8.5/5g.
Panel according to claim 1, said panel having a density equal to 40 kg/m ³ , a thickness between 10 mm and 50 mm as well as an average micronaire index between 2.1/5g and 4.4/5g. Panel according to claim 2, said panel having:
- a thickness equal to 20 mm and an average micronaire index equal to 2.4/5g, or
- a thickness equal to 40 mm and an average micronaire index equal to 3.3/5g. Panel according to claim 1, said panel having a density equal to 50 kg/m ³ , a thickness between 10 mm and 50 mm as well as an average micronaire index between 2.2/5g and 5.5/5g. Panel according to claim 4, said panel having:
- a thickness equal to 20 mm and an average micronaire index equal to 2.6/5g, or
- a thickness equal to 40 mm and an average micronaire index equal to 4/5g. Panel according to claim 1, said panel having a density equal to 60 kg/m ³ , a thickness between 10 mm and 50 mm as well as an average micronaire index between 2.4/5g and 7.1/5g. Panel according to claim 6, said panel having:
- a thickness equal to 20 mm and an average micronaire index equal to 3/5g, or
- a thickness equal to 40 mm and an average micronaire index equal to 5/5g. Panel according to claim 1, said panel having a density equal to 70 kg/m ³ , a thickness between 10 mm and 50 mm as well as an average micronaire index between 2.5/5g and 7.5/5g. Panel according to claim 8, said panel having:
- a thickness equal to 20 mm and an average micronaire index equal to 3.4/5g, or
- a thickness equal to 40 mm and an average micronaire index equal to 6.3/5g. Panel according to claim 1, said panel having a density equal to 80 kg/m ³ , a thickness between 10 mm and 50 mm as well as an average micronaire index between 2.7/5g and 7.5/5g. Panel according to claim 10, said panel having:
- a thickness equal to 20 mm and an average micronaire index equal to 3.9/5g, or
- a thickness equal to 40 mm and an average micronaire index equal to 7.5/5g. Panel according to claim 1, said panel having a density equal to 90 kg/m ³ as well as:
- a thickness equal to 20 mm and an average micronaire index equal to 4.5/5g, or
- a thickness equal to 40 mm and an average micronaire index equal to 7.5/5g. Panel according to claim 1, said panel having a density equal to 100 kg/m ³ , a thickness equal to 20 mm and an average micronaire index equal to 5.2/5g. A panel according to any one of claims 1 to 13, wherein the relative variation in the micronaire index is less than 15%. Use of a glass wool panel according to any one of claims 1 to 14 for improving sound absorption within an interior space, said panel being fixed to a wall surface of said interior space, said wall surface being for example a ceiling.