The present invention concerns a device for attenuating suction noises and radiated noises, comprising a gas delivery conduit connected to an internal combustion engine.
It is known that internal combustion engines have a low-frequency acoustic component ranging from 30 Hz to 1 kHz. This acoustic component is generated by the periodic opening and closure of the valves, as well as by the resonances of the different cavities of the engine (combustion chambers, conduits . . . ). The low-frequency acoustic component propagates and is radiated at the entrance of the air supply circuit of the engine. By propagating inside the air supply conduits of the engine, the low-frequency acoustic component excites the resonance of the conduits, which generates considerable acoustic emissions.
Furthermore, in the case of turbocharged engines, there is a high-frequency acoustic component ranging from 1 kHz to 15 kHz. This acoustic component is generated by the turbocharger and may also propagate and radiate through the air supply conduits.
Conventionally, suction noise means the acoustic component which propagates in the air supply conduits, and radiated noise means the acoustic component radiated by the air supply conduits.
Currently, in order to attenuate the noises coming from the air intake conduits, it is known to use a silencer. A silencer usually has a central tube in which air coming from the turbocharger circulates, and whose wall is perforated with several orifices which put the inside of the tube in communication with a peripheral chamber, delimited by a bell which surrounds the central tube. When it is stimulated by sound waves, the small volume of air contained in each orifice substantially acts as a little mass, which would be suspended to a spring constituted by the more considerable volume of air contained in the peripheral chamber. Thus, an attenuation of the noise in a spectral band located in the vicinity of the characteristic frequency of this «mass-spring» system is achieved.
However, the silencer cannot cover the entire frequency range. Indeed, the silencer has not a sufficient attenuation level in the low-frequencies range.
Another solution consists in using a resonator. The resonator comprises a central tube having a closed bypass at a right angle. This type of resonator is very selective and operates only over a very thin frequency band.
Consequently, an object of the present invention is to propose a device for attenuating suction noises and radiated noises, allowing covering a wide range of frequencies, still without requiring a significant volume.
According to a general definition, the invention concerns a device for attenuating suction noises and radiated noises, which comprises a gas delivery conduit intended to be connected to a combustion engine. The conduit has a peripheral wall over at least one portion of which is disposed at least one air-porous element, sound attenuating means which comprise at least one tube disposed in the delivery conduit. At least one peripheral chamber is delimited inside the conduit between the tube and the peripheral wall of the conduit. The tube comprises at least one portion having an orifice which enables the inside of the tube to communicate with the peripheral chamber.
The synergy of the porous element arranged on the peripheral wall with the tube having at least one orifice enables the device according to the invention to attenuate the suction noises and the radiated noises, over a wider frequency range. In addition, the combination of the porous element disposed on the peripheral wall with the tube having at least one orifice allows the device according to the invention to be barely voluminous. Indeed, the porous element allows attenuating the sound waves over certain frequencies, which allows avoiding a long succession of orifices on the tube to cover a wide frequency range.
Thus, the invention proposes a device for attenuating suction noises and radiated noises, allowing covering a wide range of frequencies, still without requiring a significant volume.
Furthermore, in comparison with the air supply conduits of the prior art, the device according to the invention advantageously allows reducing the ingestion of hot air by the engine.
The conduit may have at least one substantially transverse inner partition wall positioned around the tube and allowing delimiting at least two compartments of the peripheral chamber.
In one embodiment, at least one portion of the tube surrounded by one of the compartments may have a plurality of orifices so that said tube portion and the corresponding compartment form an absorption silencer.
In another embodiment, at least one portion of the tube surrounded by one of the compartments may have an orifice so that said tube portion and the corresponding compartment form a resonator.
In another embodiment, at least one portion of the tube surrounded by any of the compartments may have two diametrically opposed orifices so that said tube portion and the corresponding compartment form an expansion chamber of the gas circulating in the tube.
According to a particular arrangement, the device may have at least three successive portions forming absorption silencers, at least one portion forming an expansion chamber and at least one portion forming a resonator.
Thus, the device according to the invention advantageously allows combining the effects of the absorption silencers, of the resonator and of the air-porous element.
The air-porous element may have at least one strip made of air-porous material.
According to one embodiment, the device may comprise at least two diametrically opposed air-porous elements on the peripheral wall of the conduit.
Other features and advantages of the present invention will emerge from the following description, with reference to the appended drawings which represent an embodiment of the invention:
Referring to
According to the embodiment herein described, the conduit 2 is made from two shells molded by injection and then assembled by their edges according to a welding process.
As observed in
According to the example herein described, the air-porous element may be an acrylic impregnated fibrous material.
Referring to
The space between the outside of the tube 3 and the peripheral wall 23 defines a chamber 5. Transverse inner partition walls 24 divide the chamber 5 into several compartments 51.
Moreover, it should be noted that different portions of the tube 3, each surrounded by a different compartment 51, have several orifices 30 with different geometries.
According to the embodiment shown in
According to the embodiment herein described, another portion of the tube 3 surrounded by a compartment 51 may have two diametrically opposed orifices 30b so as to form an expansion chamber of the gases circulating in the tube 3.
Moreover, it should be noted that another portion of the tube 3 surrounded by a compartment 51 may have a bypass at a right angle comprising an orifice 30c, to form a resonator 35.
During usage, the advantageous combination of the three silencers 31, of the expansion chamber 34, of the resonator 35 and of the air-porous element 4, allows the device 1 to attenuate the suction noises and the radiated noises over a wide frequency range.
Indeed, as shown in the graph represented in
In comparison with the graph represented in
In contrast, as it can be noted in the graph represented in
In addition, as shown in
Thus, the invention proposes a device 1 for attenuating suction noises and radiated noises allowing covering a wide range of frequencies, still without requiring a significant volume.
Of course, the invention is not limited to sole embodiments represented hereinabove, but it encompasses on the contrary all the embodiments.
Number | Date | Country | Kind |
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15/54916 | May 2015 | FR | national |
This application is a National Stage of PCT Application No. PCT/FR2016/051256 filed on May 27, 2016, which claims priority to French Patent Application No. 15/54916 filed on May 29, 2015, the contents each of which are incorporated herein by reference thereto.
Filing Document | Filing Date | Country | Kind |
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PCT/FR2016/051256 | 5/27/2016 | WO | 00 |