FR3120296A1 - Household vacuum cleaner equipped with a sound attenuation cavity - Google Patents

Abstract

The household vacuum cleaner (2) comprises a casing (3); a vacuum motor (16) configured to generate airflow; an air exhaust circuit (18) comprising at least one air exhaust opening (19) provided on the casing (3) and through which the air flow generated by the suction motor (16 ) is exhausted to the outside of the household vacuum cleaner (2), and an air exhaust duct (21) fluidly connecting an air discharge opening (17) of the suction device (12) to the at least one air exhaust opening (19). The air exhaust circuit (18) includes an acoustic attenuation cavity (22) and an acoustic absorption element (24) separating the acoustic attenuation cavity (22) and the air exhaust duct (21), the acoustic absorption element (24) and the acoustic attenuation cavity (22) being configured such that a part of the acoustic waves, coming from the suction device (12) and propagating in the air exhaust duct (21), passes through the acoustic absorption element (24) and enters the acoustic attenuation cavity (22). Figure 2

Description

Household vacuum cleaner equipped with a sound attenuation cavity

The present invention relates to the field of domestic vacuum cleaners for sucking up dust and waste present on a surface to be cleaned, which may for example be tiles, parquet, laminate, carpet or a rug.

State of the art

A domestic vacuum cleaner, and more particularly a sled vacuum cleaner, comprises in a known manner:

- a box comprising a waste collection compartment and an engine compartment separated by a dividing wall provided with a communication orifice,

- a suction nozzle arranged on the housing and through which air carrying waste can be sucked into the housing,

- a suction device housed in the engine compartment of the housing, the suction device comprising an air inlet opening fluidly connected to the suction nozzle, a motor casing defining an internal housing, a motor suction which is arranged in the internal housing and which is configured to generate an air flow through the suction nozzle and the air inlet opening, and an air discharge opening, And

- an air exhaust circuit comprising at least one air exhaust opening provided on the housing and through which the air flow generated by the suction motor is exhausted to the outside of the vacuum cleaner domestic, and an air exhaust duct which fluidically connects the air outlet opening of the suction device to the at least one air exhaust opening.

When such a domestic vacuum cleaner is in operation, the suction device generates acoustic waves which propagate in particular in the air evacuation circuit and which induce noise and vibrations liable to disturb the user.

The present invention aims to remedy all or part of these drawbacks.

The technical problem underlying the invention consists in particular in providing a domestic vacuum cleaner which is of simple and economical structure, while substantially limiting the noise and vibrations generated by the domestic vacuum cleaner.

To this end, the present invention relates to a domestic vacuum cleaner comprising:

- a housing,

- a suction nozzle arranged on the housing and through which air carrying waste can be sucked into the housing,

- a suction device housed in an engine compartment of the housing, the suction device comprising an air inlet opening fluidically connected to the suction nozzle, a motor casing defining an internal housing, a motor suction which is arranged in the internal housing and which is configured to generate an air flow through the suction nozzle and the air inlet opening, and an air discharge opening,

- an air exhaust circuit comprising at least one air exhaust opening provided on the housing and through which the air flow generated by the suction motor is exhausted to the outside of the vacuum cleaner domestic, and an air exhaust duct which fluidically connects the air outlet opening of the suction device to the at least one air exhaust opening.

The air evacuation circuit comprises an acoustic attenuation cavity opening into the air evacuation duct, and an acoustic absorption element which is made of porous material and which is configured to separate the acoustic attenuation cavity and the air exhaust duct, the sound absorption element and the sound attenuation cavity being configured such that, when the household vacuum cleaner is in operation, at least a part of the sound waves, coming from the suction device and propagating in the air exhaust duct, passes through the sound absorption element and enters the sound attenuation cavity.

By porous material, reference is made in the present invention to a material porous to air.

Such a configuration of the air evacuation circuit, and more particularly of the path of the acoustic waves within the air evacuation circuit, makes it possible to substantially reduce the energy of the acoustic waves generated by the suction device, and therefore to significantly reduce the noise generated by the domestic vacuum cleaner, and this in a passive manner and without harming the aeraulic performance of the domestic vacuum cleaner.

The household vacuum cleaner may additionally have one or more of the following features, taken alone or in combination.

According to one embodiment of the invention, the acoustic absorption element and the acoustic attenuation cavity are configured such that the acoustic waves having penetrated into the acoustic attenuation cavity are reflected on at least one internal wall of the acoustic attenuation cavity and such that at least a part of the acoustic waves reflected on the at least one internal wall of the acoustic attenuation cavity again passes through the acoustic absorption element and penetrates again in the air exhaust duct. Such reflection of the acoustic waves within the acoustic attenuation cavity results in a breakup of part of the acoustic waves and a decrease in the amplitude of some of the acoustic waves. In addition, the fact that at least a part of the acoustic waves reflected on the at least one internal wall of the acoustic attenuation cavity again passes through the acoustic absorption element and reenters the exhaust duct of air makes it possible to accentuate the reduction in the spectral amplitude of the acoustic waves. In particular, the air evacuation circuit of the domestic vacuum cleaner according to the present invention makes it possible to attenuate the amplitude of the acoustic waves over a wide frequency band.

According to one embodiment of the invention, the sound absorption element is made of porous materials with cavities, preferably with open cavities.

According to one embodiment of the invention, the sound absorption element is acoustically porous, and is advantageously made of an acoustically porous material.

According to one embodiment of the invention, the sound absorption element is an acoustic foam.

According to one embodiment of the invention, the sound absorption element is positioned in the air exhaust duct. The sound absorption element may extend over part of the width of the exhaust air duct section or over the entire width of the exhaust air duct section. Advantageously, the sound absorption element extends over only part of the width of the section of the air exhaust duct and preferably over approximately half the width of the section of the air exhaust duct. air.

According to one embodiment of the invention, the sound attenuation cavity comprises a passage opening opening into the air exhaust duct, the sound absorption element covering the passage opening. Advantageously, the passage opening is closed by the sound absorption element.

According to one embodiment of the invention, the housing comprises a waste collection compartment located upstream of the suction device, the waste collection compartment and the engine compartment being separated by a partition wall provided with an orifice Communication.

According to one embodiment of the invention, the household vacuum cleaner further comprises a waste collection device disposed in the waste collection compartment and configured to retain waste transported by the air flow.

According to one embodiment of the invention, the waste collection device is a waste collection bag or a waste separation and collection device, for example of the cyclonic type.

According to one embodiment of the invention, the acoustic absorption element comprises a first surface oriented towards the acoustic attenuation cavity and a second surface which is opposite to the first surface, the air evacuation duct comprising an air stream delimited in part by the second surface of the sound absorption element and in which at least part of the air flow is intended to circulate.

According to one embodiment of the invention, the air stream extends substantially parallel to the second surface of the sound absorption element.

According to one embodiment of the invention, the first and second surfaces of the sound absorption element are substantially parallel.

According to one embodiment of the invention, the sound absorption element is parallelepipedal.

According to one embodiment of the invention, the sound absorption element extends substantially vertically when the domestic vacuum cleaner rests, for example by its wheels, on a horizontal surface.

According to one embodiment of the invention, the suction motor has a motor axis which intersects with the sound absorption element. Advantageously, the motor axis is secant with the acoustic attenuation cavity.

According to one embodiment of the invention, the motor axis extends substantially horizontally when the domestic vacuum cleaner rests, for example by its wheels, on a horizontal surface.

According to one embodiment of the invention, the air evacuation circuit further comprises a filtration element arranged in the air evacuation duct upstream, and for example directly upstream, of the at least an air exhaust opening, and configured to filter the airflow flowing through the air exhaust duct.

According to one embodiment of the invention, the air evacuation circuit further comprises a flow guide element which partly delimits the air evacuation duct and which is arranged downstream of the flow guide element. sound absorption, the flow guiding element being configured to guide the flow of air towards the at least one air exhaust opening.

According to one embodiment of the invention, the flow guiding element comprises a flow guiding surface which is curved and concave.

According to one embodiment of the invention, the flow guide element comprises a plurality of flow guide fins which are arranged in the air exhaust duct and which extend substantially parallel to each other. to others. Advantageously, each flow guiding fin extends from the flow guiding surface.

According to one embodiment of the invention, the air evacuation circuit comprises an additional acoustic absorption element, which is for example porous, against which the flow guide element bears.

According to one embodiment of the invention, each flow guide fin has a longitudinal edge bearing against the additional sound absorption element.

According to one embodiment of the invention, the filtration element is arranged between the flow guide element and the at least one air discharge opening.

According to one embodiment of the invention, the at least one air discharge opening opens into an upper outer surface of the housing.

According to one embodiment of the invention, the air discharge opening is provided in a lower part of the engine casing.

According to one embodiment of the invention, the suction tip is arranged in a front part of the housing.

According to one embodiment of the invention, the acoustic attenuation cavity is arranged in the casing, and for example in a rear part of the casing.

According to one embodiment of the invention, the sound absorption element is located at the rear of the suction device, and for example at the rear of the suction motor.

According to one embodiment of the invention, the at least one air exhaust opening is located above the suction device, and for example above the suction motor.

According to one embodiment of the invention, the domestic vacuum cleaner comprises a holding device configured to hold the sound absorption element in position in the air exhaust duct.

According to one embodiment of the invention, the passage opening of the acoustic attenuation cavity is oriented towards the suction motor. Such a configuration of the acoustic attenuation cavity makes it possible to further reduce the noise generated by the household vacuum cleaner.

According to one embodiment of the invention, the acoustic attenuation cavity has a central axis which is substantially parallel to the motor axis. Such a configuration of the acoustic attenuation cavity makes it possible to further reduce the noise generated by the household vacuum cleaner.

According to one embodiment of the invention, the acoustic attenuation element extends partially inside the acoustic attenuation cavity. In this case, the part of the acoustic attenuation element extending partially inside the acoustic attenuation cavity does not extend to the bottom of the acoustic attenuation cavity and remains at a distance from the bottom of the acoustic attenuation cavity to preserve an empty volume in the acoustic attenuation cavity.

According to one embodiment of the invention, the domestic vacuum cleaner is a sled vacuum cleaner.

Brief description of figures

The present invention will be better understood with the aid of the following description with reference to the appended drawings, representing, by way of non-limiting examples, two embodiments of this vacuum cleaner.

There is a longitudinal sectional view of a household vacuum cleaner according to the present invention.

There is a longitudinal sectional view of the domestic vacuum cleaner of the showing the path of an air flow within the domestic vacuum cleaner and the path of acoustic waves within the domestic vacuum cleaner.

detailed description

Figures 1 and 2 show a household vacuum cleaner 2, such as a sled vacuum cleaner, comprising in particular a housing 3, also a vacuum cleaner body, comprising in known manner a waste collection compartment 4 and an engine compartment 5 which is located in downstream of the waste collection compartment 4. The waste collection compartment 4 and the engine compartment 5 are separated by a partition 6 provided with a communication orifice 7. The waste collection compartment 4 is intended to receive a waste collection device (not shown in the figures), such as a waste collection bag or a waste separation and collection device, for example of the cyclonic type, making it possible to retain waste sucked into the housing 3.

The domestic vacuum cleaner 2 further comprises a suction nozzle 8 disposed in a front part of the housing 3 and through which air carrying waste is intended to be sucked into the housing 3.

The housing 3 is advantageously equipped with wheels 11 to ensure the displacement of the domestic vacuum cleaner 2.

The domestic vacuum cleaner 2 may also comprise a flexible hose (not shown in the figures) connected, preferably in a removable manner, to the suction nozzle 8, and a suction accessory (not shown in the figures) such as , for example, a rigid telescopic tube comprising a first end fluidically connected to the flexible pipe and a second end fluidically connected to a suction head (not shown in the figures).

The domestic vacuum cleaner 2 further comprises a suction device 12 housed in the engine compartment 5. The suction device 12 comprises a motor casing 13 delimiting an internal housing 14. According to the embodiment represented in the figures, the engine casing 13 comprises a front fairing 13.1 and a rear fairing 13.2 assembled to one another, for example by screwing or snap-fastening.

The suction device 12 further comprises an air inlet opening 15 fluidly connected to the suction nozzle 8 and a suction motor 16, also called a fan motor, which is arranged in the internal housing 14 of the motor housing 13 and which is configured to generate a flow of air through the suction nozzle 8 and the air inlet opening 15. In known manner, the suction motor 16 comprises a fan and an electric motor configured to rotate the fan.

According to the embodiment shown in the figures, the suction motor 16 has a motor axis A which extends substantially horizontally when the domestic vacuum cleaner 2 rests, by its wheels 11, on a horizontal surface.

The suction device 12 also comprises an air discharge opening 17 through which the air flow is intended to leave the suction device 12. The air discharge opening 17 can for example be provided in a lower part of the motor housing 13.

The domestic vacuum cleaner 2 also comprises an air evacuation circuit 18 comprising an air evacuation opening 19 opening out into an upper external surface of the casing 3 and through which the flow of air generated by the motor of suction 16 is discharged to the outside of the domestic vacuum cleaner 2.

The air evacuation circuit 18 further comprises an air evacuation duct 21 which fluidically connects the air discharge opening 17 of the suction device 12 to the air evacuation opening 19 .

The air evacuation circuit 18 also comprises an acoustic attenuation cavity 22, also called internal cavity, which comprises a passage opening 23 opening into the air evacuation duct 21. Advantageously, the opening passage 23 is oriented towards the suction motor 16. The acoustic attenuation cavity 22 further comprises a bottom wall 22.1 which is opposite the passage opening 23 and a side wall 22.2 extending from the bottom wall 22.1.

Advantageously, the acoustic attenuation cavity 22 is arranged in a rear part of the casing 3, and the motor shaft A intersects with the acoustic attenuation cavity 22. According to the embodiment represented in the figures, the acoustic attenuation cavity 22 has a central axis B which is substantially parallel to the motor axis A.

The air exhaust circuit 18 further comprises a sound absorption element 24 positioned in the air exhaust duct 21 and configured to separate the acoustic attenuation cavity 22 and the air exhaust duct 21. The acoustic absorption element 24 is more particularly configured to cover and close the passage opening 23.

The acoustic absorption element 24 is made of porous material, such as a porous material with open cavities, and more particularly of acoustically porous material. The sound absorption element 24 is for example an acoustic foam. Advantageously, the sound absorption element 24 has a thickness of between 5 and 40 mm. Advantageously, the sound absorption element 24 extends over only part of the width of the section of the air exhaust duct 21.

According to the embodiment shown in the figures, the sound absorption element 24 is parallelepipedic and comprises a first surface 24.1 which is oriented towards the sound attenuation cavity 22 and a second surface 24.2 which is opposite to the first surface 24.1 and which is oriented towards the suction device 12. The first and second surfaces 24.1, 24.2 of the acoustic absorption element 24 are substantially parallel.

According to the embodiment shown in the figures, the sound absorption element 24 extends substantially vertically when the domestic vacuum cleaner 2 rests, via its wheels 11, on a horizontal surface, and the sound absorption element 24 is located at the rear of the suction motor 16, and is more particularly disposed between the motor housing 13 and the acoustic attenuation cavity 22. Advantageously, the motor axis A intersects with the element of sound absorption 24.

The domestic vacuum cleaner 2 comprises a holding device 25 configured to hold the acoustic absorption element 24 in position in the air exhaust duct 21. The holding device 25 may for example comprise a plurality of holding lugs spaced from each other so as to allow the flow of the air flow through the air exhaust duct 21.

According to the embodiment shown in the figures, the air exhaust duct 21 comprises an air stream 26 delimited in part by the second surface 24.2 of the sound absorption element 24 and in which is intended to circulate the airflow. Advantageously, the air stream 26 extends substantially parallel to the second surface 24.2 of the sound absorption element 24, and is also partly delimited by the motor casing 13.

The air exhaust circuit 18 further comprises a filtration element 27 which is arranged in the air exhaust duct 21 upstream, and for example directly upstream, of the air exhaust opening 19, and which is configured to filter the flow of air flowing through the air exhaust duct 21.

The air exhaust circuit 18 further comprises a flow guide element 28 which partly delimits the air exhaust duct 21 and which is arranged downstream of the sound absorption element 24. flow guide element 28 is configured to guide the flow of air towards the filter element 27. Advantageously, the filter element 27 is disposed between the flow guide element 28 and the opening of the exhaust air 19.

According to the embodiment shown in the figures, the flow guide member 28 has a flow guide surface 28.1 which is curved and concave, and a plurality of flow guide fins 28.2 which extend from the flow guide surface 28.1 and which are arranged in the air exhaust duct 21. Advantageously, the flow guide fins 28.2 extend substantially parallel to each other.

According to the embodiment shown in the figures, the air exhaust circuit 18 comprises an additional acoustic absorption element 29 which is arranged in the air exhaust duct 21 and against which the lower longitudinal edges bear. flow guide vanes 28.2. Advantageously, the additional acoustic absorption element 29 is porous, and is for example an acoustic foam.

The operation of the household vacuum cleaner 2 will now be described. When the suction motor 16 is electrically powered, it establishes a depression in particular in the waste collection device so that a flow of air, comprising waste, is sucked in by the suction nozzle 8.

The air flow then flows successively through the communication port 7 and the air inlet opening 15 of the suction device 12.

Then, the air flow flows through the air discharge opening 17 and along the air exhaust duct 21, and in particular in the air stream 26 and through the element of flow guide 28 and the filter element 27, before escaping in the direction of the air outlet opening 19.

During operation of the household vacuum cleaner 2, the suction motor 16 generates acoustic waves which propagate in the air exhaust duct 21. The acoustic absorption element 24 and the acoustic attenuation cavity 22 are configured so that:

- at least a part of the acoustic waves, which propagate in the air exhaust duct 21, crosses the acoustic absorption element 24 and enters the acoustic attenuation cavity 22,

- the acoustic waves having entered the acoustic attenuation cavity 22 are reflected on at least one internal wall of the acoustic attenuation cavity 22, and

- at least a part of the acoustic waves reflected on at least one internal wall of the acoustic attenuation cavity 22 passes through the acoustic absorption element 24 again and enters the air exhaust duct 21 again.

Such a configuration of the air evacuation circuit 18, and more particularly of the path of the acoustic waves within the air evacuation circuit 18, makes it possible to substantially reduce the energy of the acoustic waves generated by the suction device 12, and therefore to significantly reduce the noise generated by the domestic vacuum cleaner 2, and this in a passive manner and without harming the aeraulic performance of the domestic vacuum cleaner 2.

In addition, the reflection of the acoustic waves within the acoustic attenuation cavity 22 causes a reduction in the amplitude of some of the acoustic waves, and the fact that at least a part of the acoustic waves reflected in the attenuation cavity sound 22 again passes through the sound absorption element 24 and again penetrates the air exhaust duct 21 makes it possible to accentuate the reduction in the spectral amplitude of the sound waves.

Of course, the present invention is in no way limited to the embodiment described and illustrated which has been given by way of example only. Modifications remain possible, in particular from the point of view of the constitution of the various elements or by substitution of technical equivalents, without departing from the scope of protection of the invention.

In the embodiment shown in the figures, the acoustic attenuation element 24 is arranged completely outside the acoustic attenuation cavity 22. While remaining within the scope of protection of the invention, the element acoustic attenuation 24 could, in an alternative embodiment, extend partially inside the acoustic attenuation cavity 22. In this case, the part of the acoustic attenuation element extending partially to the interior of the acoustic attenuation cavity 22. the interior of the acoustic attenuation cavity does not extend to the bottom of the acoustic attenuation cavity and remains at a distance from the bottom of the acoustic attenuation cavity to preserve between the bottom of the acoustic attenuation cavity and the acoustic attenuation element an empty volume.

Claims (10)

Household vacuum cleaner (2) comprising:
- a box (3),
- a suction nozzle (8) arranged on the housing (3) and through which air carrying waste can be sucked into the housing (3),
- a suction device (12) housed in an engine compartment (5) of the housing (3), the suction device (12) comprising an air inlet opening (15) fluidically connected to the nozzle of suction (8), a motor housing (13) delimiting an internal housing (14), a suction motor (16) which is disposed in the internal housing (14) and which is configured to generate an air flow through the suction nozzle (8) and the air inlet opening (15), and an air discharge opening (17),
- an air exhaust circuit (18) comprising at least one air exhaust opening (19) provided on the casing (3) and through which the air flow generated by the suction motor ( 16) is discharged to the exterior of the domestic vacuum cleaner (2), and an air discharge duct (21) which fluidically connects the air discharge opening (17) of the suction device (12 ) to at least one air exhaust opening (19),
characterized in that the air evacuation circuit (18) comprises an acoustic attenuation cavity (22) opening into the air evacuation duct (21), and an acoustic absorption element (24) which is made of porous material and which is configured to separate the acoustic attenuation cavity (22) and the air exhaust duct (21), the acoustic absorption element (24) and the acoustic attenuation cavity ( 22) being configured such that, when the domestic vacuum cleaner (2) is in operation, at least part of the acoustic waves, coming from the suction device (12) and propagating in the air exhaust duct (21), passes through the sound absorption element (24) and enters the sound attenuation cavity (22). A domestic vacuum cleaner (2) according to claim 1, wherein the sound absorbing element (24) and the sound attenuating cavity (22) are configured such that the sound waves having entered the sound attenuating cavity (22) are reflected on at least one internal wall of the acoustic attenuation cavity (22) and in such a way that at least a part of the acoustic waves reflected on the at least one internal wall of the acoustic attenuation cavity (22) passes through the sound absorption element (24) again and enters the air exhaust duct (21) again. A household vacuum cleaner (2) according to claim 1 or 2, wherein the sound absorbing element (24) is acoustic foam. Domestic vacuum cleaner (2) according to any one of claims 1 to 3, in which the acoustic absorption element (24) is positioned in the air exhaust duct (21). Domestic vacuum cleaner (2) according to any one of Claims 1 to 4, in which the acoustic attenuation cavity (22) comprises a passage opening (23) opening into the air exhaust duct (21), the sound absorption element (24) covering the passage opening (23). Domestic vacuum cleaner (2) according to any one of claims 1 to 5, in which the acoustic attenuation cavity (22) is disposed in the housing (3). Domestic vacuum cleaner (2) according to any one of claims 1 to 6, in which the sound-absorbing element is located at the rear of the suction device (12). Domestic vacuum cleaner (2) according to any one of claims 1 to 7, in which the acoustic absorption element (24) comprises a first surface (24.1) facing the acoustic attenuation cavity (22) and a second surface (24.2) which is opposite to the first surface (24.1), the air evacuation circuit (18) comprising an air stream (26) delimited in part by the second surface (24.2) of the element of sound absorption (24) and in which the air flow is intended to circulate. Domestic vacuum cleaner (2) according to Claim 8, in which the air stream (26) extends substantially parallel to the second surface (24.2) of the acoustic absorption element (24). Domestic vacuum cleaner (2) according to any one of claims 1 to 9, in which the suction motor (16) has a motor axis (A) which intersects the sound-absorbing element (24).