FR2842463A1 - Ventilator for automobile comprises diffuser end connected to air duct and flow rate adjusting and deflecting part able to slide axially in diffuser end adjust flow and rotate to determine flow direction - Google Patents

Abstract

The ventilator comprises a diffuser end (5), which is connected to the outlet of an air duct (3), and a flow rate adjusting and deflecting part (7). The adjusting part is mounted on the end so as to be able to slide axially relative to the air outlet so that its axial position determines the flow rate adjustment. It can also rotate so as to determine the air flow direction. An independent claim is included for a vehicle fitted with a ventilator.

Description

The present invention relates to an aerator for a motor vehicle, provided

  to be connected to an air duct, comprising a nozzle forming a diffuser, adapted to be fixed to an air outlet end of said duct, and a member for regulating flow and deflection, said member being mounted on the nozzle so as to be able to slide axially with respect to the air outlet, so that the axial position of said member determines the adjustment of the flow rate, and so as to be able to rotate, so that the position

  angular of said organ determines the direction of the air flow.

  In the state of the art, such aerators are known, in which the movement of a shutter makes it possible to carry out both the adjustment of the flow rate and the adjustment of the orientation of the air flow. An aerator of this

  type is described for example in application FR 2 784 624.

  Such aerators have a relatively simple structure and an extremely reduced number of parts, compared to conventional structures in which a first series of pivoting flaps adjust the flow rate, while another series of rotary flaps placed for example downstream, realize the orientation

of the air flow.

  On the other hand, the aerator described in document FR 2 784 624 does not make it possible to maintain a constant air flow when adjusting the orientation of the air flow. In other words, once the air flow is adjusted, changing the orientation of the flow is likely to

change the flow.

  In addition, the simplicity of the structure described in FR 2 784 624 is not optimal since the shutter, which can only take two stable positions (open or closed), is articulated on a part itself sliding by

  compared to the outlet of the ventilation duct.

  The object of the invention is to solve the above drawbacks, and to propose an aerator for a motor vehicle with a still simplified structure, making it possible to adjust the orientation of the air flow without influencing the adjustment of the flow rate, and Conversely. To this end, the axis of rotation of said flow adjustment and deflection member is coincident with its axis.

sliding.

  According to other characteristics of the invention taken alone or in any technically conceivable combination: - the nozzle comprises a circular bore which defines the air outlet, while the flow and deflection adjustment member comprises a sleeve generally cylindrical hollow, the peripheral wall of which cooperates with the edge of the bore to allow said member to slide and rotate relative to the endpiece; - The sleeve is externally ringed, each ring defining with the edge of the bore an axial stop position of said member in the nozzle; - The end piece comprises a diffusion disc placed centrally in the bore, the diameter of the disc being less than that of the bore, and the member has, arranged opposite the disc at one end of the sleeve, an opening circular diameter substantially equal to that of the disc, so that, in an axial retracted position of said member relative to the nozzle, the diffusion disc closes said opening - the diffusion disc is fixed to the edge of the bore by at least one strap of suitable shape so as not to interfere with the sleeve over the entire axial stroke of said sleeve; said member comprises at least one deflection fin disposed opposite said opening; - Said fin is fixed relative to said opening and defines an inclined surface relative to the axis of the opening; - Said fin is pivotable relative to the opening about an axis orthogonal to the common axis of sliding and rotation of the sleeve; - Said member comprises at least two such fins substantially parallel and pivoting about the same axis; the nozzle is formed of a part, in particular of a molded plastic part; and - the flow and deflection adjustment member is formed from a part, in particular from a molded plastic part. The invention also relates to a motor vehicle

  equipped with an aerator as described above.

  In such a vehicle, preferably, the end piece is formed in one piece with the dashboard, in particular of a

  molded plastic part.

  Particular embodiments of the invention will now be described in detail, with reference to the accompanying drawings, in which: - Figure 1 is a perspective view of an aerator according to a first embodiment of the invention, l 'flow control and deflection member being shown separate from the nozzle and the ventilation duct; Figure 2 is a sectional view, in an axial plane, of the aerator shown in Figure 1, the flow adjustment and deflection member being in the closed position; - Figure 3 is a similar view, in an open position of the flow adjustment and deflection member; and - Figure 4 is a perspective view of a flow adjustment and deflection member, alone, along a

  second embodiment of the invention.

  In Figure 1, there is shown in perspective an aerator according to a first embodiment of the invention. The aerator shown makes it possible to conduct and diffuse a flow of air towards the passenger compartment of a motor vehicle, the injection of air into the passenger compartment being

  performed at part 1 of the dashboard.

  The aerator fits on an air duct 3, of which only one end portion of the air outlet has been shown. It comprises a nozzle 5, generally made of rigid plastic material, adapted on the air outlet end of the duct, and a member 7 for adjusting the flow rate and

  orientation of the air flow (or deflection).

  In the example shown, and advantageously, the end piece 5 is made in one piece with the dashboard

1, molded plastic.

  The end piece 5 has a circular bore 9 defined by an edge 11, said bore corresponding to the air outlet of the duct 3. The circular edge il of the bore 9 defines an air outlet with an axis ZZ, this axis materializing the average direction of an air flow flowing through

bore 9.

  The end piece 5 further comprises a diffusion disc 13 formed integrally with the rest of the end piece 5, this disc being of diameter smaller than that of the bore 9 and extending coaxially with respect to the latter. The disc 13 is connected to the edge 11 by straps 15 formed by strips of U-section, the curve of which is turned towards

inside the duct 3.

  In the example shown, four straps 15 are distributed regularly over the periphery of the disc 13, and are directed radially towards the edge 11. Thus, the passage for the air supplied by the conduit 3 is defined by four sectors of delimited rings by the edge 11, the disc 13, and the shoulder straps 15. In the example shown, the disc 13 extends substantially in the plane of the bore 9. The regulating member 7 of the aerator consists essentially of '' an externally ringed cylindrical sleeve 21, open at a first end intended to fit into the bore 9, and a closure part

  23 formed at the opposite end of the sleeve.

  The ringed sleeve 21 is slightly deformable so as to be able to fit on the edge it and be moved along the axis Z-Z, between different axial positions. The outer peripheral rings of the sleeve 21 define between them notches in the axial position of the member

adjustment 7.

  As will be seen in Figures 2 and 3, the straps 15 are formed so that they do not interfere with the sleeve 21 over its entire axial displacement stroke, that is to say between the first and the last sleeve notch. In the first embodiment shown in Figures 1 to 3, the shutter portion 23 comprises a crown 25 which projects radially on the one hand towards the outside of the sleeve 21, and on the other hand towards the inside of by delimiting an opening 27 of the same dimension as the diffusion disc 13. In addition, the closure part 23 comprises a first 29 and a second 31 deflection fins, each being placed in the passage

  of air defined by the opening 27 and the axis Z-Z.

  The first fin 29 is of generally annular shape, of external dimension corresponding substantially to that of the opening 27. It is connected by a part of its edge to the internal edge of the crown 25, by means of a strip of material. 33 forming a hinge, said hinge 33 making it possible to articulate the first fin 29 on the crown 25 around an axis YY orthogonal to the axis ZZ. The first fin 29 is inclined, in its undistorted rest position, relative to the axis

Z-Z and in the plane of the opening 27.

  The second fin 31 has the general shape of a disc disposed substantially coaxially with the first fin 29. Its diameter corresponds substantially to the internal diameter of the ring defining the first fin 29. The second fin 31 is connected to the hinge 33 by a secondary hinge 35, this hinge having come integrally with the hinge 33 and being elastically deformable, so that the second fin 31 can

  pivot around the Y-Y axis relative to the crown 25.

  In their rest position, the first fin 29 and the second fin 31 are inclined relative to the axis Z-Z and the plane of the opening 27, so as to extend

  substantially parallel to each other (see Figure 2).

  The two fins 29, 31 have a layered arrangement according to

  the axis Z-Z in the direction opposite to the conduit 3.

  In Figure 2, there is shown the adjusting member 7 in its position of maximum insertion of the nozzle 5. The hinge 33 then abuts on the surface of the diffusion disc 13, which completely closes the opening 29, so that no air flow can pass through the regulating member. The aerator is then in the closed position and the air flow is zero. It can also be seen, in the light of this Figure, that the geometry of the straps 15 allows the

sleeve stroke 21.

  In the configuration shown in Figure 3, the adjusting member 7 is in its maximum open position, the sleeve 21 being in the stop position defined by its free end notch. The maximum air flow then flows in the directions represented by F1 and F2, respectively on the one hand between the crown 25 and the first fin 29, and on the other hand between the first

  fin 29 and the second fin 31.

  It is therefore understood that the modification of the air flow rate, between the fully closed position shown in Figure 2 and the maximum open position shown in Figure 3, is obtained by axial displacement (insertion or extraction) of the member adjustment 7 with respect to the nozzle 5. The number of intermediate positions, and therefore of different air flows which can be adjusted, depends

  obviously the number of notches on the ringed sleeve 21.

  It is also understood that the orientation of the air flow F1, F2 can be modified by simple rotation of the adjusting member 7 around the axis ZZ, the rotation being made possible because the shoulder straps 15 are released from the size defined by the sleeve 21, over its entire axial travel. It goes without saying that the inclination of the air flows F1, F2 can be modified by pressing on the fins 29, 31, that is to say by deformation of the hinges 33, 35. In the example shown, this deformation is temporary, since it only lasts for the time during which

  the user presses on the fins 29, 31.

  As can be seen, the functions for adjusting the flow rate and for orienting the air flows around the ZZ axis are independent of each other, the orientation being adjustable without modifying a previously set flow rate. , and vice versa. In the example shown, the adjusting member 7 is made in one piece, by molding of plastic materials, which allows large series of

  parts at an extremely low production cost.

  On the other hand, in certain cases, it might be desirable to replace the hinges 33, 35 integrally formed with the rest of the part 7, by other types of articulations, which can for example provide several stable positions of inclination. The second embodiment shown in FIG. 4 differs essentially from that shown in FIGS. 1 to 3 in that the adjusting member 107 has, in its closing part 23, a series of fixed deflection fins 130, here three in number. These three fins 130, placed in the opening 27 and inclined relative to the plane of this opening 27, are parallel to the

to each other.

Claims (13)

  1. Aerator for a motor vehicle, designed to be connected to an air duct (3), comprising a nozzle (5) forming a diffuser, adapted to be fixed to an air outlet end of said duct (3), and a member (7; 107) for regulating flow and deflection, said member (7; 107) being mounted on the end piece (5) so as to be able to slide axially relative to the air outlet, so that the position axial of said member (7; 107) determines the adjustment of the flow, and so as to be able to rotate, so that the angular position of said member (7; 107) determines the direction of the air flow (F1, F2), characterized in that the axis of rotation (ZZ) of said member (7; 107) for regulating flow and deflection coincides with its axis of sliding.   2. Aerator according to claim 1, characterized in that the end piece (15) comprises a circular bore (9) which defines the air outlet, while the member (7; 107) for regulating flow and deflection comprises a hollow sleeve (21) of generally cylindrical shape, the peripheral wall of which cooperates with the edge of the bore (9) to allow said member to slide and rotate   (7; 107) relative to the end piece (5).   3. Aerator according to claim 2, characterized in that the sleeve (21) is externally ringed, each ring defining with the edge (11) of the bore (9) an axial stop position of said member (7; 107) in the nozzle (5). 4. Aerator according to claim 2 or 3, characterized in that the end piece (5) comprises a diffusion disc (13) disposed centrally in the bore (9), the diameter of the disc (11) being less than that of the bore (9), and the member (7; 107) has, arranged opposite the disc (13) at one end of the sleeve (21), a circular opening (27) of diameter substantially equal to that of disc (13), so that, in a retracted axial position of said member (7; 107) relative to the end piece (5), the diffusion disc (13) closes said opening (27). 5. Aerator according to claim 4, characterized in that the diffusion disc (13) is fixed to the edge (11) of the bore (9) by at least one strap (15) of a shape adapted to not interfere with the sleeve (21) on   the entire axial stroke of said sleeve.   6. Aerator according to claim 4 or 5, characterized in that said member (7; 107) comprises at least one deflection fin (29, 31; 130) arranged in look of said opening (27).   7. Aerator according to claim 6, characterized in that said fin (130) is fixed relative to said opening (27) and defines an inclined surface relative to the axis (Z-Z) of the opening (27).   8. Aerator according to claim 6, characterized in that said fin (29, 31) is pivotable relative to the opening (27) about an axis (YY) orthogonal to the common axis (ZZ) of sliding and rotation of the sleeve (21).   9. Aerator according to claim 8, characterized in that said member (7) comprises at least two such fins (29, 31) substantially parallel and pivoting around the same axis (Y-Y).   10. Aerator according to any one of   Claims 1 to 9, characterized in that the end piece (5) is   formed of a part, in particular of a molded plastic part. 11. Aerator according to any one of   Claims 1 to 10, characterized in that the member (7;   107) of flow and deflection adjustment is formed by a   part, in particular a molded plastic part.   12. Motor vehicle equipped with an aerator according to   any one of claims 1 to 11.   13. Motor vehicle according to claim 12, comprising a dashboard, characterized in that the end piece (5) is formed in one piece with said dashboard.   edge, in particular of a molded plastic part.