EP3626143A1 - Suction device for a home vacuum cleaner - Google Patents

Abstract

The suction device (12) comprises a motor housing (13); a suction motor (15) disposed in the motor housing (13) and configured to generate a suction flow; and an air sealing element (18) comprising a first annular sealing portion (19) configured to cooperate sealingly with the motor housing (13), and a second annular sealing portion (21) configured to cooperate tightly with the suction motor (15). The first annular sealing portion (19) is molded onto the motor housing (13) and has an annular sealing protrusion (28) which extends around a passage opening (14) and which is configured to cooperate tightly with a housing (3) of a household vacuum cleaner.

Description

Technical area

The present invention relates to the field of household vacuum cleaners for vacuuming dust and waste of small particle size present on a surface to be cleaned, which can for example be tiling, parquet, laminate, carpet or carpet.

State of the art

• un carter de moteur comprenant une ouverture de passage,
• un moteur d'aspiration disposé dans le carter de moteur et configuré pour générer un flux d'aspiration, le moteur d'aspiration comprenant une ouverture d'entrée d'air, et
• un élément d'étanchéité aéraulique comprenant une première portion d'étanchéité annulaire configurée pour coopérer de manière étanche avec le carter de moteur et pour coopérer de manière étanche avec un boîtier de l'aspirateur domestique, et une deuxième portion d'étanchéité annulaire configurée pour coopérer de manière étanche avec le moteur d'aspiration.

A household vacuum cleaner comprises, in known manner, a suction device comprising:

• a motor housing comprising a passage opening,
• a suction motor disposed in the motor housing and configured to generate a suction flow, the suction motor comprising an air inlet opening, and
• an air sealing element comprising a first annular sealing portion configured to cooperate sealingly with the motor housing and to cooperate sealingly with a housing of the domestic vacuum cleaner, and a second annular sealing portion configured to cooperate tightly with the suction motor.

When mounting the suction device in the housing of such a domestic vacuum cleaner, the air sealing element generally undergoes a shearing movement relative to the housing of the domestic vacuum cleaner. However, such a shearing movement can adversely affect the mechanical strength of the aeraulic sealing element with respect to the motor housing, and therefore adversely affect the seal between the motor housing and the suction motor and between the motor and the vacuum cleaner housing.

Summary of the invention

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

The objective of the present invention consists in particular in providing a suction device ensuring easy and reliable mounting by shearing of the air sealing element on the vacuum cleaner housing, while having optimal suction performance.

• un carter de moteur comprenant une ouverture de passage,
• un moteur d'aspiration disposé dans le carter de moteur et configuré pour générer un flux d'aspiration, le moteur d'aspiration comprenant une ouverture d'entrée d'air, et
• un élément d'étanchéité aéraulique comprenant une première portion d'étanchéité annulaire configurée pour coopérer de manière étanche avec le carter de moteur, et une deuxième portion d'étanchéité annulaire configurée pour coopérer de manière étanche avec le moteur d'aspiration,

caractérisé en ce que la première portion d'étanchéité annulaire est surmoulée sur le carter de moteur et comporte une protubérance d'étanchéité annulaire qui s'étend autour de l'ouverture de passage et qui est configurée pour coopérer de manière étanche avec un boîtier de l'aspirateur domestique, la protubérance d'étanchéité annulaire présentant, au moins localement, une partie creuse.To this end, the present invention relates to a suction device for a domestic vacuum cleaner, comprising:

• a motor housing comprising a passage opening,
• a suction motor disposed in the motor housing and configured to generate a suction flow, the suction motor comprising an air inlet opening, and
• an air-tight sealing element comprising a first annular sealing portion configured to cooperate in leaktight manner with the motor casing, and a second annular sealing portion configured to cooperate in leaktight manner with the suction motor,

characterized in that the first annular sealing portion is molded onto the motor housing and has an annular sealing protuberance which extends around the passage opening and which is configured to cooperate sealingly with a housing the domestic vacuum cleaner, the annular sealing protuberance having, at least locally, a hollow part.

Such a configuration of the annular sealing protuberance and such overmolding of the first annular sealing portion on the motor housing ensure optimum sealing between the vacuum cleaner housing and the motor housing with a minimum of overmolded material, while ensuring easy and reliable shear mounting of the air sealing element on the vacuum cleaner housing and while guaranteeing optimal flexibility of the air sealing element. In particular, the overmolding of the first annular sealing portion on the engine casing ensures optimal mechanical strength of the aeraulic sealing element on the engine casing. In addition, the hollow shape of the annular sealing protuberance increases the flexibility of the annular sealing protuberance.

Consequently, the suction device according to the present invention ensures easy and reliable mounting by shearing of the air sealing element on the housing of the vacuum cleaner, while exhibiting optimal suction performance.

The suction device can also have one or more of the following characteristics, taken alone or in combination.

According to one embodiment of the invention, the first annular sealing portion extends over the periphery of the passage opening.

According to one embodiment of the invention, the annular sealing protrusion projects away from the suction motor.

According to one embodiment of the invention, the annular sealing protuberance is flexible.

According to one embodiment of the invention, the annular sealing protuberance has a curved front profile and a rear profile having at least locally a hollow shape.

Such a hollow-shaped rear profile makes it possible to reduce the thickness of the wall forming the annular sealing protuberance, which has the advantage of increasing the flexibility of the annular sealing protuberance.

According to one embodiment of the invention, the annular sealing protuberance comprises an annular wall which is curved, the annular wall comprising a first curved annular surface which is concave and oriented towards the suction motor and a second curved annular surface which is opposite to the first curved annular surface, the second curved annular surface being convex and oriented opposite the suction motor. Such a configuration of the annular sealing protuberance makes it possible to obtain more flexibility in the direction of the axis of the suction motor in order to guarantee optimum sealing by absorbing the clearances between the motor housing and the housing of the domestic vacuum cleaner. In addition, the annular wall can be particularly fine, which makes it possible to use a material having a higher hardness to manufacture the aeraulic sealing element and therefore to ensure a better sliding of the latter during its assembly by shearing.

According to one embodiment of the invention, the second curved annular surface is oriented towards a partition wall belonging to the housing of the vacuum cleaner.

According to one embodiment of the invention, the annular sealing protuberance further comprises a plurality of connecting walls which are angularly offset from one another and which are distributed around the passage opening, each connecting wall s extending from the first curved annular surface and being fixed to the motor housing.

Such a characteristic makes it possible to ensure better maintenance of the shape of the annular sealing protuberance and in particular to prevent the annular sealing protuberance from returning to the mounting of the apparatus and having an inverted shape with respect to the form initially overmolded.

According to one embodiment of the invention, the motor housing comprises a front fairing and a rear fairing, the first annular sealing portion being molded onto the front fairing of the motor housing. Advantageously, the first annular sealing portion extends over a front face of the front fairing which is located opposite the suction motor.

According to one embodiment of the invention, the motor housing comprises a plurality of through orifices which are angularly offset from one another and which are distributed around the passage opening, the first annular sealing portion being overmolded on the motor housing at the level of the through holes so that the annular sealing protuberance covers the through holes.

Such through orifices allow the passage of the parts of the mold coming to define the hollow shape of the internal wall of the annular sealing protuberance during the overmolding of the latter on the crankcase.

According to one embodiment of the invention, each through orifice extends in an arc.

According to one embodiment of the invention, the through orifices are aligned circumferentially.

According to one embodiment of the invention, the motor casing comprises a holding part on which the first annular sealing portion is molded, the holding part comprising an annular holding ring which defines the passage opening, a main retaining portion extending around the annular retaining ring, and connecting tabs which connect the annular retaining ring to the main retaining portion, the connecting tabs being angularly spaced from one another so as to form, with the annular retaining ring and the main retaining portion, the through holes.

According to one embodiment of the invention, the connecting tabs correspond to the connecting walls of the annular sealing protuberance.

According to one embodiment of the invention, the connecting tabs extend radially.

According to one embodiment of the invention, the front fairing of the motor housing comprises the holding part.

According to one embodiment of the invention, the air sealing element is annular and flexible.

According to one embodiment of the invention, the second annular sealing portion is configured to be pressed and held in sealing manner against the suction motor when the suction motor is supplied and generates the suction flow . In other words, when the suction motor is supplied and generates the suction flow, the result of the forces applying to the second annular sealing portion is such that the second annular sealing portion is pressed and kept pressed against the suction motor. Such a configuration of the aeraulic sealing element makes it possible to ensure the holding and sealing of the latter at the suction motor without adding any additional part, and therefore to reduce the manufacturing costs of the suction device and to simplify the mounting of the latter.

According to one embodiment of the invention, the second annular sealing portion is configured to bear against the suction motor when the suction motor is stopped.

According to one embodiment of the invention, the second annular sealing portion comprises an annular sealing lip which extends around the air inlet opening from an annular sealing rib configured to cooperate with sealingly with the suction motor, the annular sealing lip having support ribs which extend under the annular sealing lip and which are configured to bear against the suction motor in order to locally raise the annular sealing lip and allow the vacuum generated by the suction flow to apply under the annular sealing lip to the edge of the annular sealing rib when the suction motor is supplied and generates the suction flow.

The support ribs are more particularly configured to locally raise the annular sealing lip when the latter is pressed towards the suction motor by the suction flow generated by the suction motor. Thus, the suction flow can be applied uniformly up to the edge of the annular sealing rib configured to cooperate sealingly with the suction motor.

The support ribs therefore make it possible to distribute the pressure forces applied to the annular sealing lip when the suction motor is supplied and generates the suction flow and therefore make it possible to improve the mechanical strength of the annular seal and thus the seal between the aeraulic sealing element and the suction motor under conditions of use of the suction device.

According to one embodiment of the invention, the air sealing element is in one piece.

According to one embodiment of the invention, the support ribs extend around the air inlet opening.

According to one embodiment of the invention, the support ribs are regularly distributed around the air inlet opening.

According to one embodiment of the invention, the support ribs extend to an internal peripheral edge of the annular sealing lip.

According to one embodiment of the invention, the support ribs extend substantially radially with respect to a central axis of the aeraulic sealing element.

According to one embodiment of the invention, the annular sealing lip comprises an annular sealing rib configured to cooperate in sealed manner with the suction motor.

According to one embodiment of the invention, the annular sealing rib is formed at an external peripheral edge of the annular sealing lip. Advantageously, the annular sealing rib extends substantially parallel to the central axis of the aeraulic sealing element.

According to one embodiment of the invention, the support ribs extend to the annular sealing rib or near the annular sealing rib.

According to one embodiment of the invention, the second annular sealing portion has an outside diameter less than an outside diameter of the first annular sealing portion.

According to one embodiment of the invention, the annular sealing lip extends transversely with respect to the central axis of the aeraulic sealing element.

According to one embodiment of the invention, the aeraulic sealing element further comprises an annular intermediate portion located between the first and second annular sealing portions, the annular intermediate portion comprising a first tubular portion extending from the first annular sealing portion and towards the suction motor, and a second tubular portion extending from of the second annular sealing portion and opposite the suction motor, the first and second tubular portions being substantially concentric and being axially offset relative to each other.

According to one embodiment of the invention, at least a part of the first tubular portion is located opposite the second tubular portion. In other words, the first and second tubular portions at least partially overlap in an axial direction.

According to one embodiment of the invention, the second tubular portion is located radially inside the first tubular portion.

According to one embodiment of the invention, the first and second annular sealing portions are offset axially with respect to each other.

According to one embodiment of the invention, the annular intermediate portion comprises at least one radial ply oriented substantially radially with respect to the central axis of the aeraulic sealing element, and at least one annular ply substantially concentric with the central axis of the air sealing element. Such a configuration of the air-tight sealing element, and in particular the presence of the at least one radial ply and the at least one annular ply, makes it possible to greatly limit the transfer of vibrations generated by the suction motor. to the vacuum cleaner housing. Indeed, the at least one radial fold makes it possible to increase the flexibility of the aeraulic sealing element in a tangential direction and therefore to significantly reduce the transfer, to the housing of the vacuum cleaner, of the vibrations generated by the electromagnetic forces. generated by the operation of the suction motor and the interactions between the rotor and the stator of the suction motor, while the at least one annular fold makes it possible to increase the flexibility of the air sealing element in one direction radial and therefore reduce substantially the transfer to the vacuum cleaner housing of the vibrations generated by the unbalance of the suction motor.

According to one embodiment of the invention, the annular intermediate portion further comprises an annular connection portion located between the first and second tubular portions and connecting the first and second tubular portions to each other so as to define the '' at least one annular fold.

According to one embodiment of the invention, the annular connection portion connects the first and second tubular portions to each other so as to define two annular folds substantially concentric with the central axis of the sealing element air flow, the two annular folds being oriented in two opposite directions. Such a configuration of the annular connection portion further increases the flexibility of the aeraulic sealing element and therefore further limits the transfer of vibrations generated by the suction motor to the housing of the domestic vacuum cleaner.

According to one embodiment of the invention, the annular intermediate portion has a generally Z-shaped longitudinal section.

According to one embodiment of the invention, the at least one radial fold is formed at least partially on the second tubular portion.

According to one embodiment of the invention, the at least one radial fold is formed at least partially on the second tubular portion and at least partially on the annular connection portion.

According to one embodiment of the invention, the at least one radial fold extends generally along a plane oriented radially with respect to the central axis of the air-tight sealing element.

According to one embodiment of the invention, the annular intermediate portion comprises a plurality of radial folds which are oriented substantially radially with respect to the central axis of the aeraulic sealing element and which are angularly offset from one another and distributed around the central axis, and for example regularly distributed around the central axis.

According to one embodiment of the invention, each radial ply has a concave surface oriented towards the outside of the aeraulic sealing element and a convex surface oriented towards the inside of the aeraulic sealing element.

According to one embodiment of the invention, the passage opening is provided on the front fairing.

According to one embodiment of the invention, the suction motor comprises a fan and an electric motor configured to drive the fan in rotation.

According to one embodiment of the invention, the suction motor further comprises a fan cover at least partially covering the fan, the air inlet opening being provided on the fan cover.

According to one embodiment of the invention, the suction device comprises a suspension system configured to support the suction motor. The suspension system may include a plurality of damping elements disposed around the periphery of the suction motor and connected to the motor housing. Advantageously, each damping element has a generally S-shaped cross section. Such a configuration of the damping elements makes it possible to use very flexible damping elements and therefore further limit the transfer of vibrations generated by the engine d suction to the vacuum cleaner housing, and thus to ensure an improved decoupling of the suction motor with respect to the vacuum cleaner housing.

According to one embodiment of the invention, the suspension system further comprises at least one compensation spring configured to compensate for the weight of the suction motor. Such a compensating spring makes it possible in particular to keep the suction motor "levitated" so that the damping elements can work in the same way and therefore ensure appropriate centering of the suction motor relative to the vacuum cleaner housing.

According to one embodiment of the invention, the aeraulic sealing element is made of elastomer.

According to one embodiment of the invention, the air sealing element is configured to guide the suction flow from the passage opening to the air inlet opening.

The present invention further relates to a household vacuum cleaner comprising a suction device according to any one of the preceding characteristics.

According to one embodiment of the invention, the domestic vacuum cleaner comprises a housing comprising a filtration compartment and a motor compartment separated by a partition wall provided with a communication orifice, the first annular sealing portion being configured to cooperate tightly with the partition wall.

According to one embodiment of the invention, the annular sealing protuberance is configured to extend around the communication orifice and to cooperate in sealed manner with the partition wall.

Advantageously, the air sealing element is configured to guide the suction flow generated by the suction motor from the communication orifice to the air inlet opening.

The present invention also relates to an aeraulic sealing element for a domestic vacuum cleaner, comprising a first annular sealing portion configured to cooperate sealingly with a motor casing, and a second annular sealing portion configured to cooperate sealingly with a suction motor, characterized in that the first annular sealing portion is overmolded on the motor housing and has an annular sealing protuberance which extends around the passage opening and which is configured to cooperate sealed with a vacuum cleaner housing

The present invention also relates to an air sealing element for a suction device, the air sealing element being configured to guide a suction flow from a passage opening provided on a motor housing to an opening air intake of a suction motor, the air sealing element being annular and flexible, the air sealing element comprising a first annular sealing portion configured to cooperate sealingly with the housing motor, and a second annular sealing portion configured to cooperate sealingly with the suction motor, characterized in that the second annular sealing portion has an annular sealing lip which extends around the opening air inlet, and support ribs which extend from the annular sealing lip and which are configured to take pressing against the suction motor, and for example against an external surface of the suction motor, and in that the annular sealing lip is configured to be pressed and kept in sealing contact against the suction motor when the suction motor is powered and generates the suction flow.

Brief description of the figures

• Figure 1 est une vue partielle en perspective d'un aspirateur domestique selon la présente invention.
• Figure 2 est une vue en coupe longitudinale d'un boîtier de l'aspirateur domestique de la figure 1.
• Figure 3 est une vue en perspective, partiellement tronquée, d'un dispositif d'aspiration appartenant à l'aspirateur domestique de la figure 1.
• Figure 4 est une vue éclatée en perspective du dispositif d'aspiration de la figure 3.
• Figure 5 est une vue en perspective arrière d'un carénage avant et d'un élément d'étanchéité aéraulique appartenant au dispositif d'aspiration de la figure 3.
• Figure 6 est une vue en coupe longitudinale du carénage avant et de l'élément d'étanchéité aéraulique de la figure 5.
• Figures 7 et 8 sont des vues en perspective avant et arrière de l'élément d'étanchéité aéraulique de la figure 5.
• Figure 9 est une vue en perspective arrière du carénage avant et d'un moteur d'aspiration appartenant au dispositif d'aspiration de la figure 3.
• Figure 10 est une vue arrière du carénage avant et du moteur d'aspiration de la figure 9.

The invention will be better understood with the aid of the description which follows with reference to the appended schematic drawings showing, by way of nonlimiting example, an embodiment of this suction device.

• Figure 1 is a partial perspective view of a household vacuum cleaner according to the present invention.
• Figure 2 is a longitudinal section view of a housing of the domestic vacuum cleaner of the figure 1 .
• Figure 3 is a perspective view, partially truncated, of a suction device belonging to the domestic vacuum cleaner of the figure 1 .
• Figure 4 is an exploded perspective view of the suction device of the figure 3 .
• Figure 5 is a rear perspective view of a front fairing and a aeraulic sealing element belonging to the suction device of the figure 3 .
• Figure 6 is a view in longitudinal section of the front fairing and of the air sealing element of the figure 5 .
• Figures 7 and 8 are front and rear perspective views of the airtight sealing member of the figure 5 .
• Figure 9 is a rear perspective view of the front fairing and of a suction motor belonging to the suction device of the figure 3 .
• Figure 10 is a rear view of the front fairing and the suction motor of the figure 9 .

The Figures 1 to 10 represent a domestic vacuum cleaner 2 comprising in particular a housing 3, also a vacuum cleaner body, in a known manner comprising a filtration compartment 4 and a motor compartment 5 separated by a partition wall 6 provided with a communication orifice 7. The compartment filtration 4 is intended to receive a filtration device (not shown in the figures), such as a filtration bag or a cyclonic separation device, making it possible to retain waste sucked into the housing 3.

The housing 3 also comprises an air inlet 8 by which air transporting waste is sucked into the housing 3, and an air outlet 9 by which the air previously removed from the waste by the filtration device is evacuated outside the housing 3. The housing 3 is advantageously fitted with wheels 11 to move the domestic vacuum cleaner 2.

The domestic vacuum cleaner 2 may also include a flexible hose (not shown in the figures) connected, preferably removably, to the air inlet 8 of the housing 3, and a suction accessory (not shown in the figures) ) such as, for example, a rigid telescopic tube which can receive, at its end opposite the flexible pipe, a removable suction head.

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

The suction device 12 further comprises a suction motor 15, also called a motor-fan, disposed in the motor housing 13 and configured to generate a suction flow. In known manner, the suction motor 15 comprises a fan and an electric motor configured to drive the fan in rotation. The suction motor 15 may further comprise a fan cover 16 at least partially covering the fan and defining an air inlet opening 17.

The suction device 12 also comprises an aeraulic sealing element 18 which is in one piece and which is configured to guide the suction flow from the passage opening 14 to the air inlet opening 17.

As shown more particularly on figures 6 to 8 , the air sealing element 18 is annular and flexible, and comprises a first annular sealing portion 19 configured to cooperate in leaktight manner with the motor housing 13, a second annular sealing portion 21 configured to cooperate in a manner sealed with the suction motor 15, and an annular intermediate portion 22 located between the first and second annular sealing portions 19, 21. Advantageously, the first and second annular sealing portions 19, 21 are axially offset l 'one over the other.

According to the embodiment shown in the figures, the first annular sealing portion 19 extends around the periphery of the passage opening 14 and is molded onto the front fairing 13.1 of the motor housing 13. Advantageously, the first annular sealing portion 19 extends over a front face of the front fairing 13.1 which is located opposite the suction motor 15.

As shown on Figures 5 and 6 , the front fairing 13.1 comprises a holding part 23 on which the first annular sealing portion 19 is overmolded. The holding part 23 advantageously comprises an annular holding ring 24 which defines the passage opening 14, a holding portion main 25 extending around the annular retaining ring 24, and connecting tabs 26 which connect the annular retaining ring 24 to the main retaining portion 25. Advantageously, the connecting tabs 26 extend radially and are spaced apart angularly from one another so as to form, with the annular retaining ring 24 and the main retaining portion 25, through orifices 27 which are angularly offset from one another and which are distributed around the passage opening 14. Advantageously, the through holes 27 extend in an arc and are circumferentially aligned.

As shown on figures 6 and 8 , the first annular sealing portion 19 comprises an annular sealing protrusion 28 extending around the passage opening 14 and projecting opposite the suction motor 15. The annular sealing protrusion 28 is configured to extend around the communication orifice 7 and to cooperate in leaktight manner with the partition wall 6. Advantageously, the annular sealing protuberance 28 covers the through orifices 27.

The annular sealing protrusion 28 includes an annular wall 29 which is thin and which is curved. The annular wall 29 has a first curved annular surface 29.1 which is concave and oriented towards the suction motor 15 and a second curved annular surface 29.2 which is convex and oriented opposite the suction motor 15, that is to say i.e. towards the partition wall 6.

The annular sealing protrusion 28 further comprises a plurality of connecting walls 31 which are angularly offset from each other and which are distributed around the passage opening 14. Each connecting wall 31 extends from the first curved annular surface 29.1 and facing a respective connecting tab 26, and is fixed by overmolding to the latter. Thus, each connecting wall 31 advantageously extends radially.

As shown on the figure 3 , the second annular sealing portion 21 extends around the air inlet opening 17 and has an outside diameter smaller than an outside diameter of the first annular sealing portion 19.

The second annular sealing portion 21 more particularly comprises an annular sealing lip 32 which extends transversely with respect to the central axis A of the air sealing element 18 and which is configured to cooperate in leaktight manner with the suction motor 15, and more particularly with the fan cover 16.

The annular sealing lip 32 is configured to bear against the suction motor 15 when the suction motor 15 is stopped, and to be pressed and held in sealing contact against the suction motor 15 when the suction motor 15 is powered and generates the suction flow. In other words, when the suction motor 15 is supplied and generates the suction flow, the result of the forces applied to the annular sealing lip 32 is such that the annular sealing lip 32 is pressed and kept in sealed contact against the suction motor 15.

According to the embodiment shown in the figures, the annular sealing lip 32 comprises an annular sealing rib 33 configured to cooperate in leaktight manner with the suction motor 15. The annular sealing rib 33 is advantageously provided at level of an external peripheral edge of the annular sealing lip 32, and extends substantially parallel to the central axis A of the air sealing element 18.

As shown on the figure 8 , the second annular sealing portion 21 further comprises support ribs 34 extending from the annular sealing lip 32 and configured to bear against the suction motor 15, and for example against a surface outside of the fan cover 16. Advantageously, the support ribs 34 extend around the air inlet opening 17 and extend radially with respect to the central axis A of the element d air sealing 18. The support ribs 34 are more particularly configured to raise the annular sealing lip 32 upstream of the annular sealing rib 33 so as to distribute the pressure forces applied to the annular sealing lip 32 in the vicinity of the annular sealing rib 33 when the suction motor 15 is supplied and generates the suction flow. According to the embodiment shown in the figures, the support ribs 34 extend on the one hand to the annular sealing rib 33 and on the other hand to an internal peripheral edge of the lip of annular seal 32.

As shown more particularly on the figure 6 , the annular intermediate portion 22 of the air sealing element 18 comprises a first tubular portion 35 extending from the first annular sealing portion 19 and in the direction of the suction motor 15, and a second tubular portion 36 extending from the second annular sealing portion 21 and opposite the suction motor 15. The first and second tubular portions 35, 36 are concentric with the central axis A of the element air tightness 18 and are offset axially with respect to each other. Advantageously, the second tubular portion 36 is located radially inside the first tubular portion 35, and the first and second tubular portions 35, 36 partially overlap in an axial direction.

The annular intermediate portion 22 further comprises an annular connection portion 37 located between the first and second tubular portions 35, 36 and connecting the first and second tubular portions 35, 36 to each other so as to define two annular folds 38, 39 concentric with the central axis A of the air sealing element 18. The two annular folds 38, 39 are advantageously oriented in two opposite directions, so that the annular intermediate portion 22 has a generally Z-shaped longitudinal section.

According to the embodiment shown in the figures, the annular intermediate portion 22 also comprises a plurality of radial folds 41 which are oriented substantially radially with respect to the central axis A of the air sealing element 18, and which s' advantageously each extend generally in a plane oriented radially with respect to the central axis A. The radial folds 41 are angularly offset from one another and are advantageously regularly distributed around the central axis A.

Each radial ply 41 advantageously comprises a concave surface 41.1 oriented towards the outside of the aeraulic sealing element 18 and a convex surface 41.2 oriented towards the inside of the aeraulic sealing element 18.

According to the embodiment shown in the figures, each radial fold 41 is advantageously formed partially on the second tubular portion 36 and partially on the annular connection portion 37.

The suction device 12 further comprises (see in particular the Figures 9 and 10 ) a suspension system 43 configured to support the suction motor 15. The suspension system 43 more particularly comprises a support piece 44 fixed to the suction motor 15, and a plurality of damping elements 45 interposed between the support piece 44 and the motor housing 13 and distributed around the suction motor 15.

The support piece 44 can for example comprise an annular support part 44.1 extending around the suction motor 15, a rear part 44.2 extending behind the suction motor 15 and connecting branches 44.3 s extending longitudinally and connecting the annular support part 44.1 to the rear part 44.2. Advantageously, the support piece 44 can thus define a housing in which the suction motor 15 is mounted.

Advantageously, each damping element 45 has a section generally S-shaped transverse, and comprises a first fixing part 45.1 fixed to the engine casing 13, for example to the rear fairing 13.2, and a second fixing part 45.2 fixed to the support piece 44. The suspension system 43 can for example comprising four damping elements 45 regularly distributed around the suction motor 15.

According to the embodiment shown in the figures, the suspension system 43 further comprises a compensation spring 46 configured to compensate for the weight of the suction motor 15. The compensation spring 46 may for example be located above the motor 15 and be formed by a tension spring. According to an alternative embodiment, the compensation spring 46 could be located below the suction motor 15 and be formed by a compression spring.

The compensation spring 46 is more particularly interposed between the support piece 44 and the motor housing 13. Thus, the compensation spring 46 advantageously comprises a first end portion 46.1 fixed to the motor housing 13, for example to the rear fairing 13.2, and a second end portion 46.2 fixed to the support piece 44.

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

Claims (15)

Suction device (12) for a domestic vacuum cleaner (2), comprising: - a motor housing (13) comprising a passage opening (14), a suction motor (15) arranged in the motor housing (13) and configured to generate a suction flow, the suction motor (15) comprising an air inlet opening (17), and - an air sealing element (18) comprising a first annular sealing portion (19) configured to cooperate in leaktight manner with the motor housing (13), and a second annular sealing portion (21) configured to cooperate tightly with the suction motor (15), characterized in that the first annular sealing portion (19) is molded onto the motor housing (13) and has an annular sealing protuberance (28) which extends around the passage opening (14) and which is configured to cooperate sealingly with a housing (3) of the domestic vacuum cleaner, said annular sealing protuberance having, at least locally, a hollow part. The suction device (12) according to claim 1, wherein the annular sealing protrusion (28) projects away from the suction motor (15). Suction device (12) according to claim 1 or 2, wherein the annular sealing protuberance (28) has a curved front profile and a rear profile having at least locally a hollow shape. The suction device (12) according to claim 3, wherein the annular sealing protrusion (28) comprises an annular wall (29) which is curved, the annular wall (29) having a first curved annular surface (29.1) which is concave and oriented towards the suction motor (15) and a second curved annular surface (29.2) which is opposite to the first curved annular surface (29.1), the second curved annular surface (29.2) being convex and oriented opposite the suction motor (15). Suction device (12) according to claim 4, wherein the annular sealing protrusion (28) further comprises a plurality of connecting walls (31) which are angularly offset from each other and which are distributed around the 'passage opening (14), each connecting wall (31) extending from the first curved annular surface (29.1) and being fixed to the motor housing (13). Suction device (12) according to any one of claims 1 to 5, in which the motor housing (13) has a plurality of through orifices (27) which are angularly offset from one another and which are distributed around of the passage opening (14), the first annular sealing portion (19) being overmolded on the motor housing (13) at the level of the through holes (27) so that the annular sealing protuberance (28 ) covers the through holes (27). Suction device (12) according to claim 6, wherein each through hole (27) extends in an arc. Suction device (12) according to claim 6 or 7, wherein the through holes (27) are aligned circumferentially. Suction device (12) according to any one of claims 6 to 8, in which the motor housing (13) has a holding part (23) on which the first annular sealing portion (19) is molded, the retaining part (23) comprising an annular retaining ring (24) which defines the passage opening (14), a main retaining portion (25) extending around the retaining ring annular retainer (24), and connecting lugs (26) which connect the annular retaining ring (24) to the main retaining portion (25), the connecting lugs (26) being angularly spaced apart from each other forming, with the annular retaining ring (24) and the main retaining portion (25), the through holes (27). Suction device (12) according to any one of claims 1 to 9, in which the second annular sealing portion (21) is configured to be pressed and held in sealing contact against the suction motor (15 ) when the suction motor (15) is powered and generates the suction flow. Suction device (12) according to any one of claims 1 to 10, in which the second annular sealing portion (21) has an outside diameter less than an outside diameter of the first annular sealing portion (19) . Suction device (12) according to any one of claims 1 to 11, in which the air sealing element (18) further comprises an annular intermediate portion (22) located between the first and second sealing portions annular (19, 21), the annular intermediate portion (22) comprising a first tubular portion (35) extending from the first annular sealing portion (19) and in the direction of the suction motor (15), and a second tubular portion (36) extending from the second annular sealing portion (21) and opposite the suction motor (15), the first and second tubular portions (35, 36) being substantially concentric and being axially offset from one another. Suction device (12) according to any one of claims 1 to 12, in which the air sealing element (18) is configured to guide the suction flow from the passage opening (14) to the air inlet opening (17). Domestic vacuum cleaner (2) comprising a suction device (12) according to any one of the preceding claims. Aeraulic sealing element (18) for a domestic vacuum cleaner, comprising a first annular sealing portion (19) configured to cooperate sealingly with a motor housing (13), and a second annular sealing portion (21) configured to cooperate sealingly with a suction motor (15), characterized in that the first annular sealing portion (19) is molded onto the motor housing (13) and has an annular sealing protuberance (28) which extends around the passage opening (14) and which is configured to cooperate in sealed manner with a housing (3) of the domestic vacuum cleaner.

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