IT202100002015A1 - OPTIMIZED SOUND-INSULATION DEVICE - Google Patents

Description

Description of the Industrial Invention entitled:

?OPTIMIZED SOUND-INSULATION DEVICE?.

DESCRIPTION

The present invention relates to an optimized acoustic insulation device, in particular an optimized acoustic insulation device whose operation is based on the Helmholtz resonance principle.

Noise pollution developed in an external and/or internal environment are stress factors that deteriorate the comfort of life.

To rediscover comfort ? It is often necessary to acoustically isolate the noise source, when is it? impossible for economic reasons to reduce the noise source up to an acceptable level, we resort to acoustic insulation. Is isolation possible? obtain by exploiting either the acoustic absorption or the reduction of the acoustic transmission.

Are known to the art a plurality? of devices called Helmholtz resonators, which are based on the Helmholtz resonance principle, and consist of a volume, containing air, connected to the environment from which the noise propagates through a narrow neck and an opening. The energy of the incident sound makes the air contained in the resonator neck vibrate and, due to the compressed volume of the chamber, it behaves like a mass connected to a spring. As with any mass-spring system, there is a resonant frequency at which maximum vibration occurs. If the frequency of the incident sound coincides with the latter, the transfer of energy will be? maximum, and therefore also absorption, due to friction losses.

Are known a plurality? of systems that fully or partially use the Helmholtz principle, to solve different technical problems, such as for example those indicated in the following patents:

- US4185715, discloses a device designed to reduce noise within a duct flow, generated by an internal combustion engine.

- CN210627893 discloses an ultra-thin low-frequency Helmholtz resonator with an S-shaped neck;

- CN210508947 describes a Helmholtz resonator consisting of a frame and a plurality of of uniformly distributed blades assuming a rectangular shape; and finally

- CN111105774 describes a Helmholtz resonator in which ? there is at least one tube.

The known Helmholtz resonators are expensive to make and effective only on narrow frequency bands, therefore perforated panels equipped with an absorption mechanism similar to the known Helmholtz resonators are often used, they are mounted at a certain distance from a rigid surface; the holes in the panel act as a series of necks insisting on the same chamber. The air contained in these openings, similarly to the Helmholtz resonator, behaves like a series of masses connected to a single spring, there will be? therefore a resonance frequency at which the absorption of the sound wave ? maximum. By their very nature, this type of device tends to work at medium and medium-high frequencies (equal to or higher than 1KHz) and as for the single resonator, ? It is possible to predict the resonance frequency of said structure by means of a known empirical formula.

In the specific case of acoustic insulation in the aeronautical field, in relation to turboprop aircraft, the natural frequencies due to the propeller blades show evident noise peaks which are perceived in a very annoying way by the occupants of the aircraft cabin. AND? known as particularly in this area ? there is a high demand for structural components which, with a very low weight, are specifically designed to absorb noise at the aircraft's own frequencies. In general, for low frequencies (below about 350 Hz) there? it is obtained in a non-efficient way by means of thin layers of viscoelastic material (usually silicone rubber).

AND? It is clear that, especially in the aeronautical field, there is not a single device with rigid partitions, which takes advantage of the Helmholtz principle, which allows you to work on multiple? frequencies simultaneously, dampening noise and simultaneously increasing the thermal resistance of the device itself without altering its volume.

Therefore, the purpose of the present invention ? solve the above prior art problems by providing an optimized sound isolation device designed to attenuate a plurality of of sound waves of a disturbing signal.

Another object of the present invention ? that of providing an acoustic insulation device capable of increasing the thermal resistance of the device.

A final aim of the present invention ? to provide an acoustic insulation system equipped with a plurality? of soundproofing devices.

The above and other objects and advantages of the present invention, as will appear from the following description, are achieved with an optimized acoustic insulation device such as the one described in claim 1.

Preferred embodiments and non-trivial variants of the present invention form the object of the dependent claims.

It is understood that all the attached claims form an integral part of the present description.

will result? it is immediately obvious that innumerable variations and modifications may be made to what has been described (for example relating to shape, dimensions, arrangements and parts with equivalent functions) without departing from the scope of protection of the invention as appears from the attached claims.

This invention will come better described by some preferred embodiments, provided by way of non-limiting example, with reference to the attached drawings, in which:

- FIG. 1 shows a side view of a preferred embodiment of the device according to the present invention;

- FIG.2 shows, with a section plane AA, a top sectional view of the device according to the present invention;

- FIG.3 shows, with a sectional plane BB, a top sectional view of the device according to the present invention;

- FIG.4 shows a three-dimensional view in lateral section of the device according to the present invention; And

- FIG. 5 shows a top view of a system equipped with the device according to the present invention.

As known, in a closed volume the reflected sound waves are added to the direct ones produced by an external source coming from an open field with an overall increase in noise, consequently, with reference to FIG. 1, an optimized sound insulation device 1, according to the present invention, ? designed to mitigate a plurality? of sound waves of a disturbance signal coming from periodic sources in particular from an open field to a closed volume by means of the Helmholtz resonance principle, for example, a disturbance signal generated by propellers for the helicopter, aeronautical, naval, or generated by an engine room of a ship, etc?, and to increase the thermal resistance of the device 1, by means of a horizontal element 3 equipped with a plurality? of holes 4. Furthermore, the device 1, according to the present invention, comprises:

- at least one cylindrical element 2, such as, for example a cylindrical container, of rigid material, preferably plastic, designed to enclose an internal volume;

- two or more vertical and rigid partitions 6, arranged along a radial direction from the central axis of the cylindrical element 2, designed to divide the internal volume of the cylindrical element 2 into two or more? 7 chambers arranged vertically;

- the? horizontal element 3 endowed with the plurality? of holes 4, arranged perpendicular to the vertical axis of the cylindrical element 2, designed to divide each of the two or more? chambers 7 in an upper section 7a and in a lower section 7b, increasing the thermal resistance offered by the device 1;

- at least one closure device, designed to facilitate hermetic closure of the cylindrical element 2, equipped with at least one closure means 5, at least one gasket 5a, mutually connected by means of a plurality of of self-threading fastening screws arranged in a housing element 9 integrated in the cylindrical element 2; - two or more studs 8 with calibrated hole of cylindrical shape designed to facilitate entry into the device 1 of the plurality of sound waves with frequency values characterizing the harmonic components of the plurality? of sound waves, contained within a range: 80Hz -600 Hz; in correspondence of each of the two or more? 7 chambers of 1 device ? arranged, on the closing device, each of the two or more? studs 8, designed to trap inside them a mass of air according to the volume of each of the two or more? rooms 7 corresponding, which attenuates one of the harmonic components of the plurality? of sound waves passing through device 1.

Advantageously, the upper section 7a and the lower section 7b obtained by means of the horizontal element 3, designed to divide each of the two or more? chambers 7 in the upper section 7a and in the lower section 7b each retain a volume of air which acts as a convective thermal resistance, in particular the volume of air in the upper section 7a represents a convective thermal resistance disposed in series with the volume d? air of the lower section 7b, consequently increasing the thermal resistance of the device 1.

With this device 1, the radial arrangement of the two or more? vertical and rigid septa 6, induces the formation of two or more? angles, the amplitude of each of the two or more? corners ? functional to the plurality? of frequencies characterizing the harmonic components of the plurality? of sound waves of the disturbing signal to be attenuated; the choice of? width of each of the two or more? corners induces the formation of each of the two or more? 7 chambers with a specific volume, making each of the two or more? rooms 7 suitable to work on one of the plurality? of frequencies characterizing the harmonic components of the plurality? of sound waves, as a function of the volumetric dimensions of each of the two or more? chambers 7. In particular to choose the width of each of the two or more? corners, we must consider that the volume of each of the two or more? rooms 7 ? directly proportional to? the amplitude of each of the two or more? angles corresponding to each of the two or more? chambers 7 and simultaneously the sum of the amplitudes of the two or more? corners ? equal to 360?.

Below is an embodiment of a device 1 designed to attenuate a disturbance signal generated by a periodic external source, such as, for example, a hydraulic pump rotating at speed? angular fixed, in particular this device 1 ? designed to act on the base frequency fB of the disturbance signal, and on the frequency of the first harmonic f1H of the Fourier series expansion of the sound pressure generated by the periodic source, and ? equipped with two vertical and rigid partitions 6, arranged radially suitable to form two angles and to identify two chambers 7, a chamber for the frequency fB and a chamber for the frequency f1H, equipped respectively with a volume VB, and V1H, furthermore each of the two rooms 7 ? equipped above with one of the two or more? studs 8, considering that each calibrated hole of each of the two or more? studs 8 have the same diameter and length, it results:

Consequentially ? possible to express the width of the angle ?B as a function of ?1H as ?B = 4* ?1H and taking into account that the sum of the angles ?B and ?1H ? equal to 360? as? ?B + ?1H = 360?, it results:

Finally, the amplitude of the angle ?1H corresponding to the chamber 7 relative to the first harmonic of frequency f1H ? equal to:

and consequently the amplitude of the angle ?B corresponding to the chamber 7 relative to the basic frequency fB ? equal to:

Advantageously each of the two or more? rooms 7 ? equipped with two vertical walls in common with an adjacent chamber 7, giving the device 1 a limited weight; also the two or more? septa 6 vertical and rigid that delimit the two or more? chambers 7, give stiffness to the device 1 in particular to the closure device, and to a flat element 12 designed to form the basis of the device 1.

In particular ? shown in FIG. 5 by way of non-limiting example, an acoustic insulation system 10 equipped with:

- two or more devices 1 arranged in parallel within an insulating medium 11, each designed to attenuate the plurality? of sound waves of the disturbing signal as a function of the frequencies characterizing the harmonic components of the plurality? of sound waves of the disturbing signal; - the insulating means 11, such as, for example, a mat of expanded melamine, or fibreglass, or mineral fibers for application in the naval field, etc?, provided with a plurality of of holes (not shown) and designed to facilitate the insertion inside of two or more? devices 1; and eventually

- a heat-sealed plastic film, designed to cover the insulating medium 11 with two or more? devices 1, preventing any leakage of the two or more? devices 1 from the insulating medium 11.

Advantageously, two or more elements are arranged inside the insulating medium. devices 1 as a function of the mass per unit? of overall area of the system 10, of the sound pressure attenuation to be obtained, and of the thermal resistance value to be achieved.

Furthermore, the system 10 ? modular, designed to be equipped with a variable number of devices 1, according to the zone and installation environment of the system 10, hosting a variable number of devices 1. For example, could the insulating medium have a non-uniform distribution of the devices 1 inside it, in particular a part of the insulating medium 11? equipped with a greater number of devices 1 and arranged in an installation area on a special aircraft or on a boat where the jamming signal ? more intense, and a part of the insulating means 11 equipped with a smaller number of devices 1 arranged in an installation zone where the disturbance signal is less intense, giving modularity? to system 10, and allowing its use and adaptation in variable installation areas.

Finally the system 10 ? otherwise designed? to simultaneously attenuate disturbing signals characterized by different frequencies and different intensities?, by means of two or more? devices 1 each designed to work at a different frequency value.

In particular, by way of non-limiting example, FIG. 5 shows an example of a system 10, equipped with five devices 1, designed to attenuate two frequency values: 120 and 240 Hz, arranged inside the insulating medium 11.

The invention has the following advantages:

- allows the attenuation of a noise coming from an open field that enters a closed volume or the isolation of airborne noise from the source, such as for example an engine room of a ship, or other similar;

- allows you to work simultaneously on the frequencies of the noise through the rigid-walled chambers built inside the device; And

- increases the thermal resistance of the device while maintaining continuity? volume inside the device itself.

AND? A preferred embodiment of the present invention has been previously illustrated and described: obviously, to those skilled in the art, numerous variants and modifications, functionally equivalent to the previous ones, which fall within the scope of protection of the invention as evidenced in the attached claims, will be immediately apparent.

Claims (6)

1. Optimized acoustic insulation device (1) characterized in that it is designed to attenuate a plurality of of sound waves of at least one disturbance signal coming from periodic sources by means of the Helmholtz resonance principle and to increase the thermal resistance of said device (1) by means of at least one horizontal element (3) equipped with a plurality? with holes (4), said device (1) being equipped with: - at least one cylindrical element (2) made of rigid material, designed to enclose an internal volume; - two or more vertical and rigid partitions (6), arranged along a radial direction from the central axis of said cylindrical element (2), designed to divide said internal volume of said cylindrical element (2) into two or more? chambers (7) arranged vertically; - said horizontal element (3) equipped with said plurality? of holes (4), arranged perpendicularly to the vertical axis of said cylindrical element (2), designed to divide each of said two or more? chambers (7) in an upper section (7a) and in a lower section (7b) increasing the thermal resistance offered by said device (1); - at least one closure device, designed to facilitate hermetic closure of said cylindrical element (2), equipped with at least one closure means (5), at least one gasket (5a), mutually connected by means of a plurality of of self-threading fixing screws, in a housing element (9) integrated in said cylindrical element (2); - two or more studs (8) with calibrated hole (8) arranged on said closure device, and designed to facilitate entry into said device (1) of said plurality of of sound waves and to trap inside each of said two or more? studs (8) a mass of air as a function of the volume of each of said two or more? chambers (7) corresponding, attenuating one of the harmonic components of said plurality? of sound waves passing through said device (1). 2. Device (1) according to the preceding claim, characterized in that each of said two or more? rooms (7) ? equipped with two vertical walls in common with said adjacent chamber (7), giving a limited weight to said device (1); also said two or more? septa (6) vertical and rigid that delimit these two or more? chambers (7), give stiffness to said device (1) to said closure device and to a flat element (12) designed to form a base of said device (1). 3. Device (1) according to claim 1, characterized in that said upper section (7a) and said lower section (7b) obtained by means of said horizontal element (3), each retain a volume of air which acts as a convective thermal resistance , said volume of air of said upper section (7a) represents a convective thermal resistance arranged in series with said volume of air of said lower section (7b) consequently increasing the thermal resistance of said device (1). 4. Device (1) according to claim 1, characterized in that said arrangement along a radial direction of said two or more? septa (6) vertical and rigid, induces the formation of two or more? angles, the width of each of these two or more? corners ? functional to the plurality? of frequencies characterizing the harmonic components of said plurality? of sound waves of said disturbance signal to be attenuated; the choice of said amplitude of each of said two or more? angles induces the formation of each of these two or more? chambers (7) with a specific volume, making each of these two or more? chambers (7) suitable to work on one of said plurality? of frequencies, as a function of the volumetric dimensions of each of the two or more? chambers (7) whereas said volume of each of said two or more? rooms (7) ? directly proportional to? amplitude of each of said two or more? angles and at the same time that the sum of the amplitudes of these two or more? corners ? equal to 360?. 5. Acoustic insulation system (10) equipped with two or more? devices (1) according to any one of the preceding claims, characterized in that it comprises: - said two or more? devices (1) arranged in parallel within an insulating medium (11), each designed to attenuate said plurality? of sound waves of said disturbance signal as a function of said plurality? of frequencies characterizing the harmonic components of said plurality? of sound waves; - said insulating means (11) equipped with a plurality? of holes (not shown) and designed to facilitate the insertion inside of said two or more? devices (1); and eventually - a heat-sealed plastic film, designed to coat said insulating medium (11) with inside said two or more? devices (1), preventing a? possible release of said two or more? devices (1) by said insulating medium (11). 6. System (10) according to the preceding claim, characterized in that said system (10) is modular, designed to be equipped with a variable number of said devices (1), according to the area and the installation environment of said system (10), allowing to host a variable number of devices (1), and allowing their use and? adaptation in variable installation areas, and also? designed to simultaneously attenuate a plurality? of disturbing signals characterized by different frequencies and different intensities?, by means of said two or more? devices (1) each designed to work at a different frequency value.