EP1900437A1 - Dispensing mechanism for a liquid product, dispenser comprising such a dispensing mechanism and use of such a dispensing mechanism - Google Patents

Abstract

The nozzle (28) has an outlet port (30) extending through a frontal wall (29) and delimited by a lateral surface (35) e.g. cylindrical shaped lateral surface, rotating around a rotational axis (A) perpendicular to the wall. A unique delivery pipe (36) delivers a fluid product such as aerosol, toward the port. The pipe is extended in a plane perpendicular to the axis between upstream and downstream ends. The pipe tangentially extends with respect to the surface of the port, and the downstream end of the pipe directly emerges in the surface of the port.

Description

The invention relates to a dispensing member for fluid product, a dispenser comprising such a dispensing member and to a use of such a dispensing member.

• une paroi frontale,
• un orifice de sortie s'étendant au travers de ladite paroi frontale, ledit orifice de sortie étant délimité par une surface latérale de révolution autour d'un axe de révolution sensiblement perpendiculaire à la paroi frontale,
• au moins un conduit d'amenée du produit fluide vers l'orifice de sortie, ledit conduit d'amenée étant délimité par la paroi frontale et la surface de butée, et s'étendant dans un plan perpendiculaire à l'axe de révolution, entre une extrémité amont adaptée pour être alimentée en produit fluide par un canal d'alimentation et une extrémité aval.

In particular, the invention relates to a fluid product dispensing member comprising a pad and a spray nozzle, said stud having an abutment surface and said spray nozzle comprising:

• a front wall,
• an outlet orifice extending through said front wall, said outlet orifice being delimited by a lateral surface of revolution about an axis of revolution substantially perpendicular to the front wall,
• at least one supply duct for the fluid product to the outlet orifice, said supply duct being delimited by the front wall and the abutment surface, and extending in a plane perpendicular to the axis of revolution, between an upstream end adapted to be fed with fluid product by a feed channel and a downstream end.

This type of dispensing member generally comprises a vortex chamber from which extends the outlet orifice. The vortex chamber is defined in particular by a lateral surface which extends parallel to the axis of revolution and which has a dimension, measured perpendicular to the axis of revolution, greater than that of the outlet orifice.

The supply duct extends tangentially to the vortex chamber and the downstream end of the supply duct opens into the lateral surface of the vortex chamber.

The fluid product is driven under pressure into the vortex chamber in which it is driven in a rotational movement before exiting the dispensing member through the outlet orifice in the form of an aerosol composed of individual droplets and exhibiting a conical shape with a determined spray angle.

However, such a dispensing member poses problems for spraying a viscous fluid product, that is to say a fluid having a viscosity greater than 0.001 Pa.s.

Indeed, the swirl chamber increases the friction surfaces against which the fluid, in particular viscous, can adhere, which causes pressure drops for the fluid and a decrease in the pressure with which the fluid is entrained.

The fluid product exits the dispensing member in the form of an aerosol comprising droplets of various sizes, which may be large, and whose spray angle is reduced, for example up to 10 °, or in the form of of a jet.

The invention aims to solve the problems mentioned above.

In addition, the document FR-2,767,798 discloses a dispensing member of the aforementioned type wherein the stud is movable relative to the spray nozzle between an advanced position and a retracted position. In the retracted position, the outlet port is in fluid communication with the supply channel by first supply conduits extending substantially tangentially to the side surface of the outlet port and the second offset supply lines. compared to the first conduits feeding in the direction of the axis of revolution and extending between the first supply ducts perpendicular to the axis of revolution. The downstream end of said first and second feed ducts opens directly into the lateral surface of the outlet orifice, but said second supply ducts do not extend tangentially to the lateral surface of the outlet orifice. In the advanced position, the front wall is in contact with the abutment surface, so that the first and second supply ducts are reduced to nothing, the fluid therein is expelled and the communication between the duct power supply and the outlet port is broken.

The invention proposes a dispensing member of the aforementioned type in which the supply duct extends substantially tangentially with respect to the lateral surface of the outlet orifice, opens directly into the lateral surface of the outlet orifice, and the front wall is in contact with the abutment surface along a surface substantially perpendicular to the axis of revolution away from the supply duct, while simultaneously delimiting the supply duct putting in fluid communication the outlet orifice with the feed channel.

Thus, in accordance with the invention, the outlet orifice is in fluid communication with the supply channel only through the supply duct (s) extending substantially tangentially with respect to the lateral surface of the outlet. the outlet orifice and opening directly into the lateral surface of the outlet orifice.

The direction of the supply duct generates a swirling movement of the fluid in the outlet orifice and the absence of a swirl chamber makes it possible to limit the friction surfaces and the pressure drops for the fluid product and to maintain the pressure causing the fluid product. At the outlet of the dispensing member, the fluid product can be divided into fine droplets and form an aerosol having the desired spray angle.

• l'orifice de sortie comprend une extrémité amont et une extrémité aval, l'extrémité aval du conduit d'amenée débouchant au voisinage de l'extrémité amont de l'orifice de sortie ;
• la surface latérale de l'orifice de sortie est de section circulaire ;
• la surface latérale de l'orifice de sortie est de section elliptique,
• la surface latérale de l'orifice de sortie est cylindrique ;
• la surface latérale de l'orifice de sortie est tronconique ;
• la buse de pulvérisation comprend un unique conduit d'amenée ;
• le conduit d'amenée est délimité par une surface de fond, un bord latéral externe et un bord latéral interne, les bords latéraux étant sensiblement perpendiculaires à la surface de fond et convergeant l'un vers l'autre depuis l'extrémité amont vers l'extrémité aval ;
• la paroi frontale comprend intérieurement un bossage venant en contact avec la surface de butée et une chambre périphérique entourant le bossage, l'orifice de sortie traversant le bossage, le bossage comprenant une gorge délimitant le conduit d'amenée de sorte que l'extrémité amont dudit conduit d'amenée débouche dans la chambre périphérique ;
• la buse de pulvérisation comprend en outre une paroi latérale d'association qui s'étend au voisinage de la périphérie de la paroi frontale, sensiblement perpendiculairement à ladite paroi frontale ;
• l'organe de distribution comprend un corps qui comprend un logement présentant la surface de butée, ledit canal d'alimentation étant adapté pour alimenter le logement en produit fluide, la buse de pulvérisation étant disposée dans le logement, la paroi frontale délimitant le logement vers l'extérieur.

In particular embodiments, the dispensing member may optionally present one or more of the following provisions:

• the outlet orifice comprises an upstream end and a downstream end, the downstream end of the feed duct opening adjacent to the upstream end of the outlet orifice;
• the lateral surface of the outlet orifice is of circular section;
• the lateral surface of the outlet orifice is of elliptical section,
• the lateral surface of the outlet orifice is cylindrical;
• the lateral surface of the outlet orifice is frustoconical;
• the spray nozzle comprises a single supply duct;
• the supply duct is delimited by a bottom surface, an external lateral edge and an internal lateral edge, the lateral edges being substantially perpendicular to the bottom surface and converging towards one another from the upstream end to the outside. downstream end;
• the front wall internally comprises a boss coming into contact with the abutment surface and a peripheral chamber surrounding the boss, the outlet orifice passing through the boss, the boss comprising a groove delimiting the supply duct so that the upstream end said supply duct opens into the peripheral chamber;
• the spray nozzle further comprises a side wall of association which extends in the vicinity of the periphery of the front wall, substantially perpendicular to said front wall;
• the dispenser member comprises a body which comprises a housing having the abutment surface, said supply channel being adapted to feed the housing with fluid product, the spray nozzle being disposed in the housing, the front wall delimiting the housing towards outside.

• un réservoir présentant une ouverture et à l'intérieur duquel un produit fluide est disposé,
• un dispositif de distribution monté dans l'ouverture et comprenant un gicleur déplaçable en translation, en communication fluidique avec le réservoir et adapté pour délivrer le produit fluide sous pression,
• un organe de distribution tel que défini ci-dessus, monté sur le gicleur pour déplacer ledit gicleur, le canal d'alimentation étant en communication fluidique avec le gicleur.

Furthermore, the invention proposes a dispenser comprising:

• a reservoir having an opening and within which a fluid product is disposed,
• a dispensing device mounted in the opening and comprising a nozzle displaceable in translation, in fluid communication with the reservoir and adapted to deliver the fluid under pressure,
• a dispensing member as defined above, mounted on the nozzle to move said nozzle, the supply channel being in fluid communication with the nozzle.

The fluid product disposed inside the reservoir may have a viscosity less than or equal to 10 Pa.s.

In addition, the invention also relates to a use of the dispensing member as defined above for spraying a fluid that has a viscosity less than or equal to 10 Pa.s.

• la figure 1 est une vue partielle en coupe longitudinale d'un distributeur de produit fluide comprenant un organe de distribution intégrant une buse de pulvérisation,
• la figure 2 est une vue agrandie en perspective partiellement tronquée représentant un premier mode de réalisation de la buse de pulvérisation de la figure 1 selon une face amont,
• la figure 3 est une vue en perspective partiellement tronquée représentant une variante de la buse de pulvérisation de la figure 2 selon la face amont,
• la figure 4 est une vue agrandie en perspective représentant un deuxième mode de réalisation de la buse de pulvérisation de la figure 1 selon la face amont,
• la figure 5 est une vue en perspective partiellement tronquée de la buse de pulvérisation de la figure 4 selon la face amont,
• la figure 6 est une vue partielle en coupe longitudinale de la buse de pulvérisation de la figure 4,
• la figure 7 est une vue partielle en coupe longitudinale d'une première variante de la buse de pulvérisation de la figure 4,
• la figure 8 est une vue en perspective partiellement tronquée de la buse de pulvérisation de la figure 7 selon la face amont,
• la figure 9 est une vue partielle en coupe longitudinale d'une deuxième variante de la buse de pulvérisation de la figure 4,
• la figure 10 est une vue en perspective partiellement tronquée de la buse de pulvérisation de la figure 9 selon la face amont,
• la figure 11 est une vue en perspective partiellement tronquée d'une troisième variante de la buse de pulvérisation de la figure 4 selon la face amont.

Other objects and advantages of the invention will appear on reading the description which follows, made with reference to the appended drawings in which:

• FIG. 1 is a partial view in longitudinal section of a fluid dispenser comprising a dispenser member incorporating a nozzle of FIG. spray,
• FIG. 2 is an enlarged perspective view partially truncated showing a first embodiment of the spray nozzle of FIG. 1 along an upstream face,
• FIG. 3 is a partially truncated perspective view showing a variant of the spray nozzle of FIG. 2 according to the upstream face,
• FIG. 4 is an enlarged perspective view showing a second embodiment of the spray nozzle of FIG. 1 according to the upstream face,
• FIG. 5 is a partially truncated perspective view of the spray nozzle of FIG. 4 along the upstream face,
• FIG. 6 is a partial view in longitudinal section of the spray nozzle of FIG. 4,
• FIG. 7 is a partial view in longitudinal section of a first variant of the spray nozzle of FIG. 4,
• FIG. 8 is a partially truncated perspective view of the spray nozzle of FIG. 7 along the upstream face,
• FIG. 9 is a partial view in longitudinal section of a second variant of the spray nozzle of FIG. 4,
• FIG. 10 is a partially truncated perspective view of the spray nozzle of FIG. 9 along the upstream face;
• Figure 11 is a partially truncated perspective view of a third variant of the spray nozzle of Figure 4 according to the upstream face.

In the figures, the same references designate identical or similar elements.

FIG. 1 represents a dispenser 1 allowing the spraying of a fluid product, that is to say the dispensing the fluid product in the form of an aerosol 2 composed of individual droplets and of generally conical shape having a determined spray angle α.

The dispenser 1 comprises a reservoir 3 inside which the fluid product is disposed. The reservoir 3 may comprise a bottom and a generally cylindrical wall which extends around an axis 4 perpendicular to the bottom. The reservoir 3 has an opening 5 provided opposite the bottom and delimited, for example, by a tubular neck 6 which extends substantially coaxially with the axis 4 of the reservoir 3.

A dispensing device 7 mounted in the opening 5 of the reservoir 3 is adapted to withdraw the fluid inside the reservoir 3 and deliver it under pressure to the outside.

In the remainder of the description the terms "low" or "lower" and "high" or "higher" will be understood relative to the orientation of the tank 3 resting on the bottom. The terms "upstream" and "downstream" will be understood with respect to the flow direction of the fluid product from the reservoir to the outside.

The dispensing device 7 may comprise a tubular body 8 which extends along an axis 9 and a nozzle 10 mounted in the open upper end of the body 8. The nozzle 10 is partially movable inside the body 8 in translation along the axis 9. The lower end also open body 8 is in fluid communication with the reservoir 3, for example by means of a tubular wall attachment 11 receiving a plunger tube 12 by fitting.

In particular examples, the dispensing device 7 may be manually operable. The dispensing device 7 may be a valve mounted on the reservoir 3, which is then pressurized, and wherein the nozzle 10 comprises at least one closable orifice that can be placed in fluid communication with the inside of the body 8. Alternatively, the dispensing device 7 may be a pump comprising a chamber compression member defined by an intake valve near the lower end of the body 8, an exhaust valve and a piston integral with the base of the nozzle 10 and movable in a sealed manner inside the body 8.

The dispensing device 7 is fixed coaxially on the neck 6 of the reservoir 3. The lower free end of the plunger tube 12 resting near the bottom of the reservoir 3 so as to put into fluid communication with the reservoir 3, the nozzle 10 of which the upper end protrudes relative to the opening 5 of the reservoir 3. The nozzle 10 can thus deliver the fluid under a pressure, for example greater than 2 bar.

In other embodiments not shown, it could be provided that the reservoir 3 has a lower opening 5 and that the dispensing device 7 operates in an inverted manner, that is to say with the nozzle 10 which extends towards the bottom. In this case, the plunger tube 12 is replaced by a suitable sampling device.

In the embodiment shown, a fixing member fixes the dispensing device 7 to the reservoir 3. For example, in FIG. 1, the fastener is a metal hoop 13 which is crimped, on the one hand, on a flange integral with the body 8 of the dispensing device, and, secondly, on a flange 14 of the neck 6. It can be provided to interpose a seal 15 between the upper surface of the neck 6 and a radial surface 16 of However, the attachment of the dispensing device 7 to the reservoir is not limited to this production.

To actuate the dispensing device 7 by moving the nozzle 10 inside the body 8, a dispensing member, for example in the form of a push button 17, can be mounted on the upper end of the nozzle 10.

The push button 17 comprises a generally cylindrical body which extends along an axis 18. The body has an upper actuating wall 19 which extends substantially radially with respect to the axis 18 of the push button 17 and from the edge of which a lateral skirt 20 extends along the axis 18 of the pushbutton 17.

In the vicinity of the actuating wall 19, the body of the pushbutton 17 may comprise a cylindrical housing 21 along an axis 22 generally perpendicular to the axis 18 of the pushbutton 17, formed in the lateral skirt 20, open towards the outside and having an abutment surface. In particular, inside the housing 21, a cylindrical stud 23 may extend coaxially with the axis 22 of the housing 21 so as to form inside the cylindrical housing 21 a substantially annular space 24. The stud 23 presents a downstream end surface 27 forming the abutment surface which extends generally perpendicular to the axis 22 of the housing 21.

The push button 17 further comprises a supply channel in fluid communication with the nozzle 10. The supply channel may comprise, for example, an axial sleeve 25 which extends from the actuating wall 19 inside. the skirt 20 along the axis 18 of the body, and a radial passage 26 generally perpendicular to the axis 18 of the body and whose upstream and downstream ends respectively open in the axial sleeve 25 and in the annular space 24 of the housing 21 .

The lower end of the axial sleeve 25 may be fixed, for example by fitting, on the end upper nozzle 10. An annular projection may be provided on the inner wall of the axial sleeve 25 to improve the attachment and / or sealing of the push button 17 on the nozzle 10.

The supply channel makes it possible to supply the housing 21 with fluid under pressure delivered by the nozzle 10.

In other embodiments, provision can however be made for the axis 22 of the housing 21 and the feed channel to be parallel, whether or not merged, with the axis 18 of the dispenser member to enable dispensing axial fluid product. In addition, the dispensing member may form a nozzle mounted on a dispensing device 7 or directly on the reservoir 3.

To allow the output of the pressurized fluid in the form of an aerosol 2 composed of individual small droplets, a spray nozzle 28 is disposed in the housing 21.

In particular, the spray nozzle 28 comprises a front wall 29 which has an upstream face 33 and a downstream face 34.

The spray nozzle 28 also comprises an outlet orifice 30 which extends through the end wall 29 between an upstream end and a downstream end formed on the downstream face of the end wall 29 and through which the spray nozzle 28 opens. to the outside of the dispenser 1.

The outlet orifice 30 is delimited by a lateral surface 35 of revolution about an axis of revolution A substantially perpendicular to the front wall 29.

The lateral surface 35 of the outlet orifice 30 thus has a section generated by rotation of a generator around the axis of revolution A, along a closed control curve. The lateral surface 35 can however present a succession of such adjacent sections, analogous or different, in which succession for two adjacent sections respectively upstream and downstream, the output section of the upstream section is the inlet section of the downstream section. Each section may be straight, the generatrix being substantially rectilinear, or curved, the generator having a continuous curvature.

To bring the pressurized fluid product from the annular space 24 of the housing 21 to the outlet port 30, the spray nozzle 28 comprises at least one supply duct 36 which extends in a plane perpendicular to the axis of revolution A between an upstream end in fluid communication with the radial passage 26 through the annular space 24 and a downstream end. Each supply duct 36 extends tangentially with respect to the lateral surface 35 of the outlet orifice 30 and the downstream end of each supply duct 36 opens directly into the lateral surface 35 of the outlet orifice 30. .

Each supply duct 36 may be delimited by bottom surface 38 and internal lateral edges 39 and outer 40 substantially perpendicular to the bottom surface 38. It can be provided that the lateral edges 39, 40 converge towards each other from the upstream end to the downstream end of the feed duct 36. The side edges 39, 40 may, for example, converge towards each other with a convergence angle of between 10 ° and 30 °, in particular 20 °.

In particular, the outer lateral edge 40 may be substantially rectilinear and tangentially connected to the lateral surface 35 of the outlet orifice 30. And the also substantially rectilinear inner lateral edge 39 may be connected to the lateral surface 35 of the orifice output 30 being inclined by relative to a direction parallel to the outer lateral edge 40.

In a first embodiment shown in Figures 1 and 2, the upstream face 33 has a generally flat front surface. The upstream end of the outlet orifice 30 may be formed in the front surface of the front wall 29. The lateral surface 35 of the outlet orifice 30 may be cylindrical, the section of the lateral surface 35 being a generator right. parallel to the axis of revolution A. In addition, the closed guide curve of said straight section may be a circle so that the lateral surface 35 of the outlet orifice 30 may have a cross section relative to the axis of revolution To whom is circular of constant diameter.

Furthermore, in FIG. 2, the spraying nozzle 28 comprises a plurality of equal-feed supply ducts 36 whose downstream ends open out in the vicinity of the upstream end of the outlet orifice 30. In particular, the supply ducts 36 may be formed by grooves formed directly on the front wall 29 from the front surface.

In a variant shown in FIG. 3, to limit the contact surfaces of the fluid product with the spray nozzle 28 and thus the pressure drops for the fluid product, it is expected that the spray nozzle 28 may comprise only one duct supply 36.

In a second embodiment shown in Figures 4 to 11, the front wall 29 may comprise internally a boss 37, for example integral with the front wall 29, projecting from the front surface. The front wall 29 may also comprise a peripheral chamber 32 surrounding the boss 37 so as to be delimited by the front surface and the boss 37.

The outlet port 30 can pass through the boss 37 so as to extend between the downstream face 34 of the front wall 29 and the upstream end provided at a distance from the front surface. The boss 37 then has an inner surface which belongs to the lateral surface 35 of the outlet orifice 30.

The boss 37 may comprise a single groove defining the single feed conduit 36. The bottom surface 38 of the feed conduit 36 may be substantially coplanar with the front surface of the end wall 29. In this way, the end downstream of the supply duct 36 opens in the vicinity of the upstream end of the outlet port 30 and the upstream end of the supply duct 36 opens into the peripheral chamber 32.

In a variant, the boss 37 may comprise a plurality of grooves each delimiting a supply duct 36.

The spray nozzle 28 described above, without a swirl chamber, limits the contact surfaces of the fluid with the spray nozzle 28 and reduces the size and bulk of the spray nozzle 28.

• la distance entre les extrémités amont et aval du conduit d'amenée 36 peut être comprise entre 0,15 mm et 0,7 mm,
• l'orifice de sortie 30 peut présenter un diamètre compris entre 300 µm et 800 µm et une longueur, mesurée selon l'axe de révolution A, comprise entre 0,45 mm et 1,10 mm
• l'extrémité aval du conduit d'amenée 36 peut présenter une hauteur, mesurée selon l'axe de révolution A, comprise entre 0,25 mm et 0,60 mm et une largeur, mesurée perpendiculairement à l'axe de révolution A et dans sa partie la plus étroite, comprise entre 0,10 mm et 0,20 mm.

According to particular arrangements, it can be provided, by way of example, that the spray nozzle 28 has the following dimensions, without being limited thereto:

• the distance between the upstream and downstream ends of the feed duct 36 may be between 0.15 mm and 0.7 mm,
• the outlet orifice 30 may have a diameter of between 300 μm and 800 μm and a length, measured along the axis of revolution A, of between 0.45 mm and 1.10 mm.
• the downstream end of the feed duct 36 may have a height, measured along the axis of revolution A, of between 0.25 mm and 0.60 mm and a width, measured perpendicularly to the axis of revolution A and in its narrowest part, between 0.10 mm and 0.20 mm.

Alternatively, it is anticipated that the side surface 35 of the outlet port 30 may be convergent from the upstream end to the downstream end. The lateral surface 35 of the outlet orifice 30 then has a cross section relative to the axis of revolution which decreases from the upstream end to the downstream end, which notably makes it possible to reduce the size of the aerosol droplets. 2.

In particular, in FIGS. 7 and 8, the lateral surface 35 of the outlet orifice 30 may be frustoconical, the section of the lateral surface 35 being straight of generatrix inclined with respect to the axis of revolution, and convergent, the generatrix approaching the axis of revolution A from the upstream end to the downstream end.

According to another variant, the lateral surface 35 of the outlet orifice 30 may be divergent from the upstream end to the downstream end. The outlet orifice 30 then has a cross section relative to the axis of revolution A which increases from the upstream end to the downstream end, which makes it possible in particular to reduce the spray angle α of the aerosol 2.

In particular, in FIGS. 9 and 10, the lateral surface 35 of the outlet orifice 30 may be frustoconical and divergent, with the generator moving away from the axis of revolution A from the upstream end to the downstream end.

In addition, to allow the formation of an aerosol 2 in the form of a cone having circular sections along its entire length and a homogeneous distribution of the droplets in each of said sections, it can be provided that the closed control curve of the section or sections of the lateral surface 35 of the outlet orifice An ellipse so that the lateral surface 35 has an elliptical section.

Indeed, the single supply duct performs an asymmetrical supply of the fluid product in the outlet orifice 30, which can cause a dynamic imbalance of the fluid product driven by a rotational movement in the outlet orifice 30. Such imbalance may result in an inhomogeneous distribution of the pressure and the velocity of the fluid in the outlet orifice 30 which results in the formation of an aerosol 2 of non-circular and non-homogeneous section. The arrangement according to which the lateral surface 35 of the outlet orifice 30 has an elliptical section, as shown in FIG. 11, makes it possible to compensate for the asymmetrical feed and to avoid the appearance of the dynamic imbalance of the fluid product. In particular, the supply conduit 36 may extend tangentially to the lateral surface 35 in the vicinity of the major axis of the ellipse.

This provision can, however, be used to create or accentuate the dynamic imbalance and produce an aerosol 2 of elliptical section adapted to the dispensing of fluid product such as foundations or other makeup product. As a variant, the supply duct may extend tangentially to the lateral surface in the vicinity of the minor axis of the ellipse.

The spray nozzle 28 may constitute an insert which is fitted into the housing 21. The front wall 29 may then comprise an associated lateral wall 31 which extends in the vicinity of the periphery of the front wall 29 substantially perpendicular to the front wall 29.

The associated wall 31 of the spray nozzle 28 is fitted inside the cylindrical housing 21 parallel to the axis 22 of the housing 21, the front wall 29 coming opposite the abutment surface. 27. One or more beads may be provided between the outer periphery of the association wall 31 and the housing 21 to improve the attachment and / or sealing of the spray nozzle 28 in the housing 21.

The front wall 29 of the spray nozzle 28 can then delimit the housing 21 outwards and come into contact with the abutment surface 27 so that the abutment surface 27 closes the supply duct 36 opposite the bottom surface 38.

In particular, in the first embodiment, the front surface of the end wall 29 can come into contact with the abutment surface 27. And in the second embodiment, the boss 37 can come into contact with the abutment surface 27 In this second embodiment, the peripheral chamber 32 extends, in the spray nozzle 28, the annular space 24 of the housing 21.

The space of the housing of the dispensing member with which the upstream end of the supply duct 36 is in fluid communication is not limited to the embodiment described above. In particular, this space can be obtained by a different embodiment and / or arrangement of the components of the distribution member or other elements.

For example, in a variant, provision may be made for the spraying nozzle 28 to be integral with the body of the dispensing member 17, the abutment surface 27 being attached, for example by the insertion of an attached stud into the housing 21. This avoids the risk of expulsion of the spray nozzle 28 when spraying the fluid.

Thus, when a user presses on the upper actuating wall 19 of the pushbutton 17, the nozzle 10 moved downwards delivers the fluid under pressure to the axial sleeve 25 and the radial passageway. 26 of the feed channel into the annular space 24 of the housing 21.

The upstream end of the supply duct 36 is fed with fluid under pressure, which fluid product is then brought tangentially into the outlet orifice 30 via said supply duct 36. The fluid product may be driven in a movement rotating in the outlet orifice 30 and out of the distributor 1 in the form of the aerosol 2 composed of individual small droplets and of generally conical shape with the desired spray angle α, for example less than or equal to 80 °.

The spray nozzle 28 as described above can be used for spraying any type of fluid, for example a viscous fluid product having a viscosity greater than 0.001 Pa.s. It is furthermore provided that the spraying nozzle 28 may be used to spray a fluid which has a viscosity of less than or equal to 10 Pa.s.

The fluid product disposed within the tank 3 may therefore have a viscosity in the range provided above.

The use of the spray nozzle 28 according to the embodiments described above allows, in fact the elimination of spaces in which the fluid product can stagnate, to obtain the desired aerosol 2 from the beginning to the end of actuation of the dispenser and throughout the life of the dispenser 1.

Claims (14)

A fluid dispenser member (17) comprising a stud (23) and a spray nozzle (28), said stud (23) having an abutment surface (27) and said spray nozzle (28) comprising: a front wall (29), an outlet orifice (30) extending through said front wall (29), said outlet orifice (30) being delimited by a lateral surface (35) of revolution about an axis of revolution (A) substantially perpendicular to the front wall (29), at least one supply duct (36) for the fluid product to the outlet orifice (30), said supply duct (36) being delimited by the end wall (29) and the abutment surface (27), and extending in a plane perpendicular to the axis of revolution (A), between an upstream end adapted to be supplied with fluid by a feed channel and a downstream end opening directly into the lateral surface (35) of the outlet orifice (30), substantially tangential to the lateral surface (35) of the outlet orifice (30), said dispensing member being characterized in that the front wall (29) is in contact with the abutment surface (27) along a surface substantially perpendicular to the axis of revolution (A) away from the supply duct ( 36) while defining the supply duct (36) in fluid communication with the outlet port (30) with the supply channel. Dispensing member (17) according to claim 1, wherein the outlet orifice (30) comprises an upstream end and a downstream end, the downstream end of the feed duct (36) opening in the vicinity of the upstream end of the outlet orifice (30). Dispensing member (17) according to claim 1 or 2, wherein the side surface (35) of the outlet (30) is of circular section. Dispensing member (17) according to claim 1 or 2, wherein the lateral surface (35) of the outlet orifice (30) is of elliptical section. Dispensing member (17) according to any one of claims 1 to 4, wherein the side surface (35) of the outlet (30) is cylindrical. Dispensing member (17) according to any one of claims 1 to 4, wherein the lateral surface (35) of the outlet orifice (30) is frustoconical. Dispensing member (17) according to any one of claims 1 to 6, comprising a single supply duct (36). Dispensing member (17) according to any one of claims 1 to 7, wherein the supply duct (36) is delimited by a bottom surface (38), an outer lateral edge (40) and an internal lateral edge (39), the lateral edges (39, 40) being substantially perpendicular to the bottom surface (38) and converging towards each other from the upstream end to the downstream end. Dispensing member (17) according to any one of claims 1 to 8, wherein the front wall (29) internally comprises a boss (37) engaging the abutment surface (27) and a peripheral chamber (32) surrounding the boss (37), the outlet (30) passing through the boss (37), the boss (37) comprising a groove defining the supply duct (36) so that the upstream end of said duct brought (36) opens into the peripheral chamber (32). Dispensing member (17) according to any one of claims 1 to 9, wherein the spray nozzle (28) further comprises a side wall (31) of association which extends in the vicinity of the periphery of the wall front (29), substantially perpendicular to said front wall (29). Dispensing member (17) according to any one of claims 1 to 10, comprising a body which comprises a housing (21) having the abutment surface (27), said supply channel being adapted to supply the housing (21) fluid product, the spray nozzle (28) being disposed in the housing (21), the front wall (29) defining the housing (21) to the outside. Dispenser (1) comprising: a reservoir (3) having an opening (5) and inside which a fluid product is arranged, - a dispensing device (7) mounted in the opening (5) and comprising a nozzle (10) displaceable in translation, in fluid communication with the reservoir (3) and adapted to deliver the fluid under pressure, - A dispensing member (17) according to any one of claims 1 to 11, mounted on the nozzle (10) for moving said nozzle (10), the supply channel being in fluid communication with the nozzle (10). Dispenser according to claim 12, wherein the fluid product disposed inside the reservoir (3) has a viscosity less than or equal to 10 Pa.s. Use of a dispensing member (17) according to any one of claims 1 to 11 for spraying a fluid which has a viscosity less than or equal to 10 Pa.s.

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