EP3615224B1 - Head for dispensing a fluid product - Google Patents

Description

The present invention relates to a fluid product dispensing head intended to be associated with a dispensing member such as a pump or a valve. The head can be in the form of a pusher and define a bearing surface on which the user can exert a pushing force to actuate the dispensing member. The dispensing head can be integrated into, or mounted on, the dispensing member. This type of fluid product dispenser head is frequently used in the fields of perfumery, cosmetics or even pharmacy.

• un manchon de raccordement destiné à être raccordé à une sortie d'un organe de distribution, tel qu'une pompe,
• un puits d'entrée dans le prolongement du manchon de raccordement,
• un logement de montage axial dans lequel s'étend une broche, définissant une paroi latérale et une paroi frontale, et
• un gicleur en forme de godet comprenant une paroi sensiblement cylindrique dont une extrémité est obturée par une paroi de pulvérisation formant un orifice de pulvérisation, le gicleur étant monté selon un axe X dans le logement de montage axial avec sa paroi cylindrique engagée autour de la broche et sa paroi de pulvérisation en butée axiale contre la paroi frontale de la broche.

A conventional dispensing head, for example of the pusher type, comprises:

• a connecting sleeve intended to be connected to an outlet of a distribution member, such as a pump,
• an inlet well in the extension of the connection sleeve,
• an axial mounting housing in which extends a pin, defining a side wall and a front wall, and
• a nozzle in the form of a cup comprising a substantially cylindrical wall, one end of which is closed by a spray wall forming a spray orifice, the nozzle being mounted along an X axis in the axial mounting housing with its cylindrical wall engaged around the spindle and its spray wall in axial abutment against the front wall of the spindle.

In the document FR2903328A1 , several embodiments of a nozzle are described comprising a spray wall pierced with several spray holes of substantially or perfectly identical diameter, of the order of 1 to 100 μm. Such a spray wall would generate a spray whose droplet size is relatively homogeneous.

The document WO2015194962 describes several embodiments of a nozzle comprising a spray wall pierced with several holes spray, as well as one or more filters arranged upstream of the spray wall.

The document FR2915470 discloses a push button and dispenser comprising a front wall for forming an aerosol composed of individual fine droplets.

A problem with this type of micro-hole nozzle, and more particularly when it is equipped with filter (s), is that it sometimes becomes clogged, so that the spraying gradually deteriorates until it becomes even impossible. Initially, it was thought that the clogging or clogging of the nozzle was due to fine particles in suspension in the fluid or coming from the manufacture, assembly or operation of the distribution member (pump). It was only after several series of tests that the cause of this clogging or clogging of the nozzle was identified: it would seem to come from the drying out or the strong increase in viscosity of the fluid product at the level of the nozzle itself. Thus, solid or pasty residues would form in the nozzle and clog the spray wall and / or the filter (s), which would lead to the deterioration, or even the stopping, of the spraying.

To solve this problem of clogging or clogging of micro-hole nozzles, and in particular when they are equipped with filter (s), the present invention proposes that the head comprises a suction chamber having a variable volume, so that the volume of the suction chamber decreases when pressure is exerted on the bearing surface and increases when the pressure is released on the bearing surface. Thus, the suction chamber generates a suction or “sniffing” which makes it possible to remove the fluid product from the spray wall and / or from the filter (s) by making the fluid product rise in the suction chamber. It suffices for this to adapt the variation in volume of the suction chamber to the volume defined by the spray wall alone or from the spray wall to the most upstream filter.

Advantageously, the spray holes have a diameter of the order of 1 to 100 μm, advantageously of the order of 5 to 30 μm, and preferably of the order of 10 to 20 μm.

According to an advantageous embodiment, the distribution head further comprises at least one filter upstream of the spray wall.

The filter may be in the form of a filter plate comprising filter holes which are more numerous than the spray holes, but having a smaller diameter than those of the spray holes. The filter can also be in the form of a filter block forming an array of open cavities. A single nozzle can include both one or more filter plate (s) and one or more filter block (s).

The variation in volume of the suction chamber is advantageously greater than the cumulative volume of the spray holes, when there is no filter. Otherwise, an intermediate space is formed between the spray wall and the filter, the variation in volume of the suction chamber then advantageously being greater than the cumulative volume of the spray holes, of the intermediate space and of the filter holes and / or the network of open cavities.

According to a practical embodiment, the suction chamber may comprise a piston or an elastically deformable wall.

• un manchon de raccordement destiné à être raccordé à une sortie d'un organe de distribution, tel qu'une pompe,
• un puits d'entrée dans le prolongement du manchon de raccordement,
• un logement de montage axial,
• un conduit d'alimentation reliant le puits d'entrée au logement de montage axial,
• un gicleur engagé dans le logement de montage axial, la paroi de pulvérisation étant solidaire du gicleur,

dans laquelle la chambre d'aspiration est formée entre le manchon de raccordement et le puits d'entrée ou entre le puits d'entrée et le conduit d'alimentation.The dispensing head may be in the form of a pusher, comprising:

• a connecting sleeve intended to be connected to an outlet of a distribution member, such as a pump,
• an inlet well in the extension of the connection sleeve,
• an axial mounting housing,
• a supply duct connecting the inlet well to the axial mounting housing,
• a nozzle engaged in the axial mounting housing, the spray wall being integral with the nozzle,

wherein the suction chamber is formed between the connection sleeve and the inlet well or between the inlet well and the supply conduit.

The spirit of the invention lies in the fact of emptying the multiple-hole nozzle of the fluid product which it contains after the spraying phase. The suction chamber integrated into the pusher creates a vacuum just after the spraying phase which has the effect of sucking the fluid product contained in the nozzle and storing it in the suction chamber until the next spraying phase. Thus, the nozzle is assuredly empty of any fluid product, so that there is no longer any risk of clogging or clogging by drying, formation of solid residues or increase in viscosity.

The invention will now be described more fully with reference to the accompanying drawings, giving, by way of non-limiting examples, several embodiments of the invention.

• La figure 1 est une vue en coupe transversale verticale à travers une pompe équipée d'une tête de distribution intégrant une chambre d'aspiration selon un premier mode de réalisation de l'invention,
• La figure 2a est une vue agrandie au repos de la tête de distribution de la figure 1,
• La figure 2b est une vue agrandie actionnée de la tête de distribution de la figure 2,
• La figure 3a et 3b sont des vues ; respectivement en perspective et en coupe transversale, du gicleur des figures précédentes,
• La figure 3c représente le volume de produit fluide présent dans le gicleur des figures 3a et 3b,
• Les figures 4a et 4b sont des vues respectivement similaires à celles des figures 3b et 3c pour un second mode de réalisation du gicleur selon l'invention, et
• Les figures 5, 6a et 6b sont des vues respectivement similaires à celles des figures 1, 2a et 2b pour un second mode de réalisation de la chambre d'aspiration.

In the figures:

• The figure 1 is a vertical cross-sectional view through a pump equipped with a dispensing head incorporating a suction chamber according to a first embodiment of the invention,
• The figure 2a is an enlarged view at rest of the dispensing head of the figure 1 ,
• The figure 2b is an actuated enlarged view of the dispensing head of the figure 2 ,
• The figure 3a and 3b are views; respectively in perspective and in cross section, of the nozzle of the preceding figures,
• The figure 3c represents the volume of fluid present in the nozzle of the figures 3a and 3b ,
• The figures 4a and 4b are respectively similar views to those of figures 3b and 3c for a second embodiment of the nozzle according to the invention, and
• The figures 5, 6a and 6b are respectively similar views to those of figures 1, 2a and 2b for a second embodiment of the suction chamber.

We will refer indifferently to figures 1, 2a and 2b to describe the constituent parts, as well as their mutual arrangement, of a distribution head T produced according to the invention.

The dispensing head T comprises three essential constituent parts, namely a head body 1 and a nozzle 2 and a piston 3. These parts can be produced by injection molding of plastic material. The head body 1 is preferably made in one piece: it can however be made from several parts assembled together. The same is true for the nozzle 2 which can be produced as a single-piece, single-material, by overmolding or bi-injection of several materials or even by mechanical assembly.

The head body 1 comprises a substantially cylindrical peripheral skirt 10 which is closed at its upper end by a plate 16. The head body 1 internally defines an inlet well 11 which is open at the bottom and closed at its upper end by the plate 16. The head body 1 also defines a supply duct 13 which connects the inlet well 11 to a mounting housing 12, as can be seen in the figures. figures 1 and 3 . The axial mounting housing 12 is generally cylindrical in configuration, thereby defining an inner wall which is substantially cylindrical. The supply duct 13 opens into the mounting housing 2 in a centered manner. It can also be noted that the internal wall of the mounting housing 12 has hooking profiles allowing better maintenance of the nozzle 2. The head body 1 also defines a sliding barrel 14 which extends downwards in a concentric manner. inlet well 11. This sliding barrel is internally cylindrical and has a retaining profile on its outer wall, for example in the form of a small shoulder towards the outside.

Optionally, the head body 1 can be engaged in a covering capsule 4 comprising an upper bearing surface 41 for a finger and a lateral envelope 42 forming a lateral opening 43 for the passage of the nozzle 2. In the absence of a capsule. cover 4, the bearing surface is formed by the plate 16 of the head body 1.

The nozzle 2 has a substantially conventional overall configuration in the form of a cup which is open at one end and closed at its opposite end by a spray wall D, advantageously in the form of a small plate, at the level of which are formed several holes or spray orifices DO. With reference to figures 3a and 3b , it can be seen that the nozzle 2 comprises a nozzle body 20 of substantially cylindrical overall shape which preferably has an axial symmetry of revolution. In other words, the nozzle 2 does not need to be angularly oriented before it is presented in front of the entrance to the axial mounting housing 12. The nozzle body 20 forms an external mounting wall 21 which is advantageously provided with hooking reliefs able to cooperate with the hooking profiles of the mounting housing 12. Thus, the nozzle 2 can be engaged axially without particular orientation in the axial mounting housing 12. The nozzle body 20 internally forms a chamber delimited by an internal wall 23 forming several steps of decreasing diameters. On its outer front face, the nozzle body 20 forms a planar annular land 25 defining a central opening 26.

The spray wall D is integral with the nozzle body 20, advantageously at the level of the central opening 26. The spray wall D is fixed to the nozzle body 20 by any means, such as overmolding, bi-injection, one-piece mono-material molding, snap-fitting, crimping, expansion, press-fitting, etc.

The spray wall D can be a one-piece mono-material plate, an assembly of several parts or else a multilayer product, for example a laminate. It can be made of metal, plastic, ceramic, glass or a combination thereof. More generally, any material capable of being pierced with small holes or orifices can be used. The thickness of the spray wall D, at the level where the holes DO are formed, is of the order of 1 to 100 μm. The number of holes DO is of the order of 20 to 500. The diameter of the spray wall D, at the level where the holes DO are formed, is of the order of 0.5 to 5 mm.

According to an advantageous manufacturing process, the holes DO are drilled in the spray wall D when it is already integral with the body of the sprayer. nozzle 20. Thus, the nozzle body 20 can be used as a device for manipulating the spray wall D for its drilling operation, which can for example be carried out by laser. It should be borne in mind that the spray wall D is a very small part, and therefore difficult to handle. It should be noted that the drilling of the holes DO with the spray wall D pre-assembled on the nozzle body 20 is a method which can be implemented regardless of the size of the holes DO, i.e. regardless of the size of the holes. makes that the distributor head incorporates a suction chamber.

Advantageously, the nozzle 2 also comprises two filters F1 and F2 arranged upstream of the spray wall D.

The filter F1 is mounted on a step of the internal wall 23 behind the spray wall D by defining between them a first intermediate space E1. The filter F1 is a plate substantially similar to the spray wall D with filter holes FO which are advantageously more numerous than the spray holes DO, but which advantageously have a smaller diameter than those of the spray holes DO. It can also be noted that the diameter of the filter plate F1 is greater than that of the spray wall D. Its thickness can be substantially the same as that of the spray wall D, or even slightly greater.

The filter F2 is also mounted on a step of the internal wall 23 upstream of the filter F1 by defining between them a second intermediate space E2. The filter F2 is in the form of a block of porous material, advantageously rigid, such as Porex ®, which forms a network of open cavities, the average pore size of which may be of the order of 7 to 100 microns. .

Thus, by pressing on the distributor head T, the fluid product delivered by the pump P flows through the inlet well 11, the supply duct 13, passes through the filter F2, fills the second intermediate space E2, passes through the filter F1, fills the first intermediate space E1, and finally passes through the spray wall D to the outlet from which it is sprayed into fine droplets. The figure 3c represents the volume of the fluid in the filter F1, namely VF1, the first intermediate space E1, namely VE1, and the spray wall D, namely VD.

The figure 4a shows a second embodiment for a nozzle 2 ', which can be implemented in the distributor head T instead of the nozzle 2. This nozzle 2' comprises a spray wall D 'on which the nozzle body 20' has been overmolded. The spray wall D 'also defines a series of small spray holes DO' of the order of 1 to 100 microns in diameter. The nozzle 2 ′ comprises only a single filter F2 ′ which may be substantially identical to the filter F2, that is to say formed by a part or a block of porous material, advantageously rigid, such as Porex®, which forms a network of open cavities, the average pore size of which may be of the order of 7 to 100 microns. The filter F2 ′ and the spray wall D define between them an intermediate space E1 ′. The figure 4b is similar to figure 5c and shows the volume of the fluid in the intermediate space E1 ', namely VE1', and the spray wall D ', namely VD'.

According to the invention, the distributor head T incorporates a suction chamber 30 which is formed by the cooperation of the head body 1 with the piston 3. With reference to figures 2a and 2b , it can be seen that the piston 3 is slidably mounted around the sliding barrel 14 against a spring 33, which may be an elastically deformable ring. The piston 3 is therefore biased away from the inlet well 11 while remaining integral with the sliding barrel 14 by virtue of the retaining profile of the barrel 14 which cooperates with a ring 32 of the piston 3 which is engaged around the barrel 14. On the figure 2a , the piston 3 is at rest and on the figure 2b , the piston 3 is moved as far as possible towards the inlet well 11 by compressing the spring 33. The piston also comprises a sleeve 35 which is engaged in the sliding barrel 14 by being connected at its lower end to the ring 32 and forming at its free upper end, a piston lip 34 which in leaktight sliding contact with the cylindrical inner wall of the sliding barrel 14. The sleeve 35 also defines a central passage 31. The sleeve 35 also defines a central passage 31. piston 3 and the head body 1 define between them the suction chamber 30, the volume of which varies with the sliding movement of the piston 3.

Referring again to the figure 1 , it can be seen that the sleeve 35 is connected to the free end of an actuating rod P2 of a distribution member P, such as a pump or a valve. The actuating rod P2 can be moved back and forth along the Y axis against an internal spring (not shown). Preferably, the stiffness of the spring 33 of the piston 3 is less than that of the internal spring of the distribution member P. The actuating rod P2 is hollow so as to define a delivery duct in communication with a metering chamber. the distribution member P. The central passage 31 of the piston 3 is located directly downstream of the outlet of the actuating rod P2, so that the fluid product delivered by the distribution member P passes through the suction chamber 30 to reach the entrance shaft 11.

When the distributor head T is at rest ( figure 2a ), the suction chamber 30 has a maximum volume. When a user presses on the bearing surface of the head T, the suction chamber 30 will decrease in volume until it reaches a minimum ( figure 2b ). Then, the actuating rod P2 will be pushed in so as to distribute the fluid product through the head T and its nozzle 2 where it will be sprayed. As soon as the user releases his pressure on the bearing surface of the head T, the actuating rod P2 returns to its rest position under the action of the internal spring. The piston 3 will also move to also regain its rest position ( figure 2a ). In doing so, a vacuum is created in the suction chamber, due to its increase in volume. This depression will generate a suction force at the level of the nozzle 2 which will move the fluid that it contains towards the suction chamber 30. It is thus possible to empty the spray holes DO, the filter (s) F1, F2, F2 'and the intermediate space (s) E1, E2, E1'. The variation in volume of the suction chamber 30 can be adapted to the design of the nozzle to remove a sufficient volume of fluid. In nozzle 1, it is for example possible to evacuate the spray holes DO, the first space intermediate E1 and the filter holes FO, but not the second intermediate space E2, nor the filter F2. Thus, one would evacuate only the volume represented on the figure 3c .

On the figures 5, 6a and 6b , we can see a second embodiment for the suction chamber. A flexible dome 3 'is mounted on the head body 1' in place of the plate 16 of the first embodiment. This flexible dome 3 ′ comprises an anchoring ring 32 ′ which is mounted on a fixing flange 14 ′ of the head body 1 ′. On the other hand, the covering cap 4 ′ forms a re-entrant flap 41 ′ which supports the anchoring ring 32 ′ on the head body 1 ′. Thus, the anchoring ring 32 ′ is mounted in a fixed and sealed manner on the head body 1 ′. The flexible dome 3 'also comprises an elastically deformable actuating wall 34' which forms a bearing surface for a user's finger. The suction chamber 30 'is then formed between the head body 1' and this elastically deformable actuating wall 34 '. It is supplied with fluid by the inlet well 11 'and the outlet of the chamber is formed by the supply duct 13' which is connected to the nozzle 2.

By depressing the elastically deformable actuating wall 34 ', as shown in figure 6b , the volume of the actuating rod P2 is reduced, then the actuating rod P2 of the distribution member P. is pushed in. Fluid is then pumped through the actuating rod P2: it passes through the well d 'inlet, the suction chamber 30', the supply duct 13 'and the nozzle 2, from which it leaves sprayed in fine droplets. As soon as the user releases the pressure on the actuating wall 34 ', the actuating rod P2 returns to its rest position and the actuating wall 34' also returns to its rest position. The vacuum thus created in the suction chamber 30 'is used, as in the first embodiment, to empty or evacuate the nozzle 2 of its fluid.

It is obvious that the nozzle 2 'of the figures 4a and 4b can be mounted instead of the nozzle 2 in the second embodiment of the suction chamber 30 '.

The present invention is thus based on the combination of a suction chamber with a nozzle with multiple micro-holes (20 to 500 holes of 1 to 100 microns), advantageously equipped with one or more filters.

Claims (10)

1. A fluid dispenser head (T) for mounting on a dispenser member (P), such as a pump, and including a bearing surface (16; 41; 34') for actuating the dispenser member (P), and a spray wall (D) that is perforated with a network of holes (DO) through which the fluid under pressure passes so as to be sprayed in small droplets,
   the dispenser head being characterized in that it further includes a suction chamber (30; 30') of volume that is variable such that the volume of the suction chamber (30; 30') decreases when pressure is exerted on the bearing surface (16; 41; 34') and increases when the pressure on the bearing surface (16; 41; 34') is relaxed.
2. . A dispenser head according to claim 1, wherein the spray holes (DO) present a diameter lying in the range about 1 µm to about 100 µm.
3. A dispenser head according to claim 1 or claim 2, wherein the spray holes (DO) present a diameter lying in the range about 5 µm to about 30 µm, and preferably in the range about 10 µm to about 20 µm.
4. A dispenser head according to any preceding claim, further including at least one filter (F1, F2; F2') upstream from the spray wall (D).
5. A dispenser head according to claim 4, wherein the filter is a filter plate (F1) including filter holes (FO) that are more numerous than the spray holes (DO), but presenting a diameter that is smaller than the diameter(s) of the spray holes (DO).
6. A dispenser head according to claim 4 or 5, wherein the filter is a filter block (F2; F2') forming a network of open cavities.
7. A dispenser head according to any preceding claim, wherein the variation in the volume of the suction chamber (30; 30') is greater than the combined volumes of the spray holes (DO).
8. A dispenser head according to any one of claims 4 to 6, wherein, when an intermediate space (E1; E1') is formed between the spray wall (26) and the filter (F1; F2'), the variation in the volume of the suction chamber (30; 30') is greater than the combined volumes of the spray holes (DO), of the intermediate space (E1; E1'), and of the filter holes (FO) and/or of the network of open cavities.
9. A dispenser head according to any preceding claim, wherein the suction chamber (30; 30') includes a piston (3) or a flexible dome (3').
10. A dispenser head according to any preceding claim, said dispenser head being in the form of a pusher, comprising:

    • a connection sleeve (35; 15) for connecting to an outlet of a dispenser member (P), such as a pump,

    • an inlet well (11; 11') in line with the connection sleeve (35; 15);

    • an axial assembly housing (12; 12'),

    • a feed duct (13; 13') that connects the inlet well (11; 11') to the axial assembly housing (12; 12'),

    • a nozzle (2; 2') that is engaged in the axial assembly housing (12; 12'), the spray wall (D) being secured to the nozzle (2; 2'),
    wherein the suction chamber (30; 30') is formed between the connection sleeve (35) and the inlet well (11) or between the inlet well (11') and the feed duct (13').

Images