FR2910450A1 - Pump for distributing e.g. cosmetics, has base with annular supporting surface separated from support, where supporting surface lies against inner surface of lip, and linkage arranged between base and actuation tube - Google Patents

Abstract

The pump has a sealed lip (27a) with an inner surface and an outer surface that is slidingly installed on the inner surface of an annular body (1). A piston (25) and a base (30) comprise respectively comprise two sealed supports, which form an exhaust valve (33) with open and closed conditions. The base has an annular supporting surface separated from the support, where the supporting surface lies against an inner surface of the lip. A linkage is arranged between the base and an actuation tube (21).

Description

Pump for dispensing a fluid product The invention relates to a

  pump to dispense a fluid product. More particularly, the invention relates to a pump for dispensing a fluid product, comprising: a tubular body extending along a central axis between a first and a second end and comprising an inner surface which delimits a metering chamber; body comprising an inlet for the fluid in the metering chamber in the vicinity of said first end, - an inlet valve adapted to selectively close the inlet orifice, - a nozzle mounted axially movable inside the body between a remote position and a position close to the inlet orifice, said nozzle being resiliently biased towards the remote position, said nozzle comprising an axial actuating tube delimiting an outlet duct, a base adjoining the duct; actuation and arranged inside the metering chamber facing the inlet port, and at least one exhaust port of the pro a piston comprising an annular central sleeve slidably mounted on the nozzle and an annular sealing lip having an inner surface and an outer surface which is slidably mounted on the inner surface of the body, the piston and the base forming an exhaust valve which has an open state and a closed state.

  The use of such a pump requires initial priming to expel the air initially contained upstream of the exhaust valve, particularly in the metering chamber, to replace it with fluid.

  The performance of such a pump in terms of priming and, subsequently, product distribution 2910450 2 fluid are related to the sealing of the pump. Indeed, the sealing conditions the realization, in the metering chamber when the nozzle passes from the close position to the remote position, a vacuum sufficient to suck air, during priming, or the product fluid. The invention aims to improve the sealing of a pump of the aforementioned type. For this purpose, the invention proposes a pump of the aforementioned type in which the base comprises an annular bearing surface which, in the closed state of the exhaust valve, bears against the inner surface of the lip of seal. Thus, the bearing surface makes it possible to provide reinforced support for the sealing lip against the body and to improve the seal between the sealing lip and the body when the exhaust valve is closed, in particular when the nozzle moves from the close position to the remote position. This increases the performance of the pump in terms of priming and fluid dispensing. In particular embodiments, the pump may optionally present one or more of the following arrangements. The piston and the base respectively comprise two sealing surfaces that come into mutual sealing contact when the exhaust valve is in the closed state: the sealing surfaces can thus form the exhaust valve that selectively closes the valve; exhaust port, - the sealing surface of the base is distinct from the bearing surface, - the sealing lip surrounds the central sleeve, the piston comprising a radial wall connecting the sealing lip to said sleeve central, the central sleeve having a free end which comprises one of the sealing surfaces: these arrangements allow 2910450 3 to obtain a substantially radial support of the base against the sealing lip and a substantially axial sealing contact between the base and the central sleeve, the base has a concavity facing the piston, the free end of the central sleeve extending into the concavity of the base: nsi reduce dead volumes between the central sleeve and the sealing lip, - the base comprises a central portion and a frustoconical peripheral flange which extends from the central portion, the collar having a free peripheral edge having the scope of support, the central portion and the flange being located on either side of the free end of the sleeve: these arrangements make it possible to reinforce the contact between the central sleeve and the base 15 to ensure a good seal of the valve of exhaust, - the base comprises a support member on which the bearing surface is formed, - a swiveling is provided between the base and the actuating tube 20: the swiveling provides a centering and self-alignment between the base and the actuating tube and between the piston and the body so as to obtain a uniformity of contact between the base and the piston as well as a better distribution of the support of the base against the surface inside the sealing lip. 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 longitudinal sectional representation of a pump according to an embodiment of FIG. the invention, - Figures 2a, 2b, 2c and 2d are longitudinal sectional representations of steps of the actuation of the pump of Figure 1.

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

In the figures, there is shown a pump for dispensing a fluid, liquid or viscous product, for example the field of perfumery, pharmacy, cosmetics or other. The pump comprises: - a tubular body 1 extending along a central axis A between a first 3 and a second 4 ends, defining internally a metering chamber 2 of determined volume and having an inlet 6 for the fluid in the metering chamber 2 to the vicinity of the first end 3, a compression member slidably mounted along the central axis A inside the body 1 so as to be able to vary the volume of the metering chamber 2. pump is intended to be disposed by the first end 3 of the body 1 in an opening of a tank, not shown, and fixed in a known manner, for example by fitting and / or by means of a fastener, to the reservoir so that it can take a dose of fluid contained in the reservoir.

In the remainder of the description, the terms upper or upper and lower or lower will be understood with respect to locations located respectively close to the second end 4 of the body 1 and near the first end 3 of the body 25. elsewhere, the terms axial or longitudinal and radial or transverse refer to planes respectively parallel and perpendicular to the central axis A. The body 1 comprises an annular side wall 30 in which the compression member is mounted. The side wall 7 has an inner surface, an outer surface, an open upper end forming the second end 4 of the body 1, and a lower end.

In the figures, the inner surface of the side wall 7 of the body 1 may have a substantially circular section. The upper end 4 may have an annular flange 5 protruding outwardly and whose inner surface has a diameter. The inner surface of the side wall 7 of the body 1 may also have a first portion adjacent to the flange 5 with a first diameter substantially smaller than the diameter of the flange 5 and a second portion adjacent to the first portion opposite the flange 5 with a second diameter substantially smaller than the first diameter. A vent hole through hole 8 may be provided in the side wall 7 so as to allow an air passage between the outside and the inside of the tank to compensate for the dose of fluid taken by the pump. In the particular embodiment shown, it is provided that the body 1 may also have an annular bottom wall 9 which extends from the lower end of the side wall 7 and whose free end forms the first end 3 of the body 1, i.e. the lower end.

The bottom wall 9 internally comprises the inlet port 6 and an inlet valve, for example a ball valve comprising a ball 10, a seat 11 and stop members 12, adapted to allow the selective sealing of the inlet port 6.

The lower wall 9 may also allow to receive by internal or external fitting a dip tube, not shown, for communicating the metering chamber with the reservoir. The bottom wall 9 may be adapted to facilitate the fitting of the dip tube, for example by making internal chamfer 13a and / or outside 13b, or to improve the holding of the dip tube. In other embodiments, provision may be made for the body 1 to have no bottom wall 9, for the lower end of the side wall 7 forming the first end 3 of the body 1, or for it to comprise an inner wall surrounded by by the side wall 7, the inlet valve 2910450 and the inlet port 6 being adapted accordingly. To close the upper end 4 of the body 1 and to allow the guide of the dispensing member in translation along the central axis A, the pump further comprises an annular expander 14 associated with the upper end 4 of the body 1. In the figures, the stent 14 may include an upper portion protruding from the upper end 4 of the body 1 and a lower portion extending within the side wall 7. The lower portion of the the stent 14 may be associated with the inner surface of the side wall 7 of the body 1 by any known means, including fitting, latching or the like. Alternatively, it can be provided that the stent 14 is associated with the outer surface of the side wall 7 of the body 1. It can be provided that the stent 14 also includes a shoulder 15 projecting radially outwardly to rest on the flange 5 of the body 1 and a radial projection 16 which extends inwardly. The compression member comprises: a nozzle 20 axially movable inside the body 1 between a remote position and a position close to the inlet port 6; a piston 25 axially slidably mounted to the The nozzle 20 may comprise an axial actuating tube 21 which delimits an outlet duct 30 for the fluid product from the metering chamber to the outside, an insert 22 assembled to the fluid tube. actuation 21 and at least one exhaust port of the fluid from the metering chamber 2 to the outlet conduit. The actuator tube 21 extends within the expander 14 and includes an open bottom end disposed within the body 1 and proximate the inlet port 6, and one end 2910450 7 upper open, located away from the inlet port 6 and protruding from the upper end 4 of the body 1. The upper end of the actuating tube 21 5 is adapted to allow the attachment of a actuating member, such as a pusher not shown, on which a user can exert pressure to move the nozzle 20 from the remote position to the close position.

In addition, it is provided that the nozzle 20 is resiliently biased toward the remote position. To do this, the actuating tube 21 has an annular rim 23 which extends outwards and which is arranged facing the radial projection 16 of the stent 14. An elastic member 15, for example a spring of 17, extends between the edge 23 of the actuating tube 21 and the radial projection 16 of the expander 14. The compression spring 17 thus disposed around the actuating tube 21 outside the chamber 20 assay 2 makes it possible to improve the compactness of the pump and to avoid the contact between the fluid product and the compression spring 17. However, it is possible, in a variant, to provide any other suitable arrangement of the compression spring 17, in particular to the outside the expander 14, or any other type of elastic member. To ensure translation guidance along the central axis A of the actuating tube 21, an annular skirt 19 may extend axially from the free end of the rim 23 of the actuating tube 21. The skirt 19 of the tube 30 In this embodiment, in the embodiment shown, the lower end of actuating tube 21 defines the exhaust port defined by one or more passages for the fluid product to the outlet conduit 2910450 8. The actuating tube 21 has, in the vicinity of the lower end, an end zone 24 of reduced transverse dimension. The end zone 24 on which the piston 25 is slidably mounted may be delimited upwards by a shoulder 18. The insert 22 comprises a base 30 which extends generally transversely with respect to the central axis A and which is arranged within the metering chamber 2 opposite the inlet port 6. The base 30 may comprise a central portion 31 and a peripheral collar 32 which extends substantially transversely to the central axis A from the central portion 31. On the other hand, in the embodiment shown in the figures, the piston 25 comprises: an annular central sleeve 26 slidably mounted on the end zone 24 of the actuating tube 21 between the shoulder 18 and the base 30, an annular sealing lip 27a having an inner surface and an outer surface which is slidably mounted on the inner surface of the body 1. The piston 25 and the base 30 form an exhaust valve 33 which has an open state and a closed state so as to selectively close, on sliding of the central sleeve 26 on the actuating tube 21, the exhaust port. For example, the piston 25 and the base 30 respectively comprise two sealing surfaces. The sealing surfaces are spaced from each other to allow fluid to flow to the outlet conduit when the exhaust valve 33 is in the open state, as shown in FIGS. 2b and 2c. . The sealing surfaces come into mutual sealing contact to prevent the passage of fluid to the outlet conduit when the exhaust valve 33 is in the closed condition, as shown in FIGS. 1, 2a and 2d. The dimension along the central axis A of the central sleeve 26 and the distance between the shoulder 18 and the base 30 are adapted 2910450 9 to obtain a sufficient opening of the exhaust valve 33. The piston 25 and the base 30 may have Sealing faces curved or inclined with respect to the central axis A. According to the figures, the base 30 may have a concavity facing the piston 25, the central sleeve 26 may have a free end which comprises one of the spans sealing surface and extends into the concavity so as to be able to come into sealing contact with the sealing surface of the base 30. Furthermore, the sealing surfaces can come into sealing contact in one or more zones and the base 30 can be adapted to perform a nip of the free end of the central sleeve 26.

For example, flange 32 may be frustoconical by flaring upwardly. The free end of the central sleeve 26 can then, with an inner zone of the sealing surface, come into sealing contact on an axial zone of the central part 31 belonging to the sealing surface 20 of the base 30 and, with an inclined outer zone of the sealing surface, coming into sealing contact on an inclined zone of the flange 32 belonging to the sealing surface of the base 30. The central part 31 and the flange 32 can thus be located on the and other of the free end of the central sleeve 26 to pinch the free end of the sleeve 26 and thus improve the seal between the base 30 and the central sleeve 26. In addition, it can be provided that the base 30 comprises an annular groove 29 formed in the concavity between the central portion 31 and the flange 32 to obtain a better flexibility of the flange 32, favoring the pinching of the free end of the sleeve 26. re the central part 31 and the flange 32.

In a priming phase, the displacement of the nozzle 20 from the remote position to the close position makes it possible, before the first use, to expel the air upstream of the exhaust valve 33 to replace it with a fluid product. . In order to ensure rapid priming of the pump and to improve fluid dispensing, the base 30 comprises an annular bearing surface which is adapted to bear against the inner surface of the sealing lip 27a, in the state closed of the exhaust valve 33, and remotely the sealing lip 27a, in the open state of the exhaust valve 33.

In the embodiment shown in the figures, the bearing surface and the sealing surface of the base 30 are distinct from one another. For example, the flange 32 may have a free peripheral edge including the bearing surface. According to the figures, the base 30 may comprise a support member 40, for example integrally formed with the free peripheral edge of the collar 32, on which the bearing surface is formed. The bearing member 40 can then bear substantially radially against the inner surface of the sealing lip 27a in the closed state of the exhaust valve 33 (FIGS. 2a and 2d) and be away from the surface. inside of the sealing lip 27a in the open state of the exhaust valve 33 (FIGS. 2b and 2c).

In this way, when the exhaust valve 33 is in the closed state, it is possible to seal the pump with the sealing surfaces and to press the sealing lip 27a onto the body 1 because radial bearing of the bearing surface against the inner surface of the sealing lip. Due to the distinction of the sealing surfaces and support of the base 30, it can be provided that the bearing surface is continuous or discontinuous. Thus, when the nozzle 20 moves from the close position to the remote position, sufficient vacuum can occur in the metering chamber 2 to suck air, during priming, or fluid during operation.

In the embodiment shown, the sealing lip 27a is formed on an annular sleeve 27 surrounding the central sleeve 26. The piston 25 comprises a radial wall connecting the sleeve 27 to the central sleeve 26.

The sealing lip 27a may then extend substantially axially from the radial wall to the first end 3 of the body 1. The sealing lip may be disposed against the second part of the side wall 7 of the body 1 so that improve the seal because of the reduction of the diameter. The support member 40 can then be arranged between the central sleeve 26 and the sealing lip 27a to occupy a dead volume of the metering chamber 2. Furthermore, it can be provided that the base 30 and the chamber 15 dosage 2 in the vicinity of the inlet port 6 have substantially complementary shapes so as to minimize the volume of the metering chamber 2 in the close position of the nozzle 20. It is also possible that the support member 40 is adapted to abut on a surface of the body 1 in the close position of the nozzle 20 to avoid applying stresses on the sealing lip 27a in the close position. The bushing 27 may also include an upper lip 27b in contact with the inner surface of the body and extending axially from the radial wall opposite the sealing lip 27a. In order to limit the wear of the piston 25 and the stresses on the upper lip 27b, it is provided that, in a position remote from the nozzle 20, the upper lip 27b is disposed against the inner surface of the first part of the lateral wall 7 of the body. 1. Furthermore, in the position remote from the nozzle 20, the vent hole 8 is disposed between the upper 27b and lower 27a lips. Alternatively not shown, it can be provided that the sealing surface of the piston 25 is formed on the sleeve 27 and / or on the radial wall. Furthermore, the bearing surface and the sealing range of the base 30 can be combined. The bearing surface then ensures the plating of the sealing lip 27a on the body and the sealing of the intake valve. To do this, the bearing surface, continuous, can be adapted to come into substantially radial sealing abutment against the inner surface of the sealing lip 27a. In the embodiment shown in the figures, to allow the mounting of the piston 25 on the nozzle 20 having, on the one hand, the edge 23 and the shoulder 18 on the actuating tube 21 and on the other hand , the base 30 on the insert 22, the actuating tube 21 and the insert 22 are two separate pieces assembled after the piston 25 has been mounted on the actuating tube 21. Furthermore, the edge 23 has come 15 of the material with the actuating tube 21. The actuating tube 21 is then mounted in the stent 14 by the upper part prior to the assembly of the compression member and the mounting of the stent 14 on the body 1 of the pump. Alternatively, it is expected that the rim 23 can be reported, the mounting of the expander 14 can then be achieved after the assembly of the compression member. In the figures, so that the relative positioning of the insert 22 and the actuating tube 21 can ensure a tight and uniform contact between the base 30 and the central sleeve 26 and a satisfactory support of the support member 40 against the sealing lip 27a, a swiveling may be provided between the insert 22 and the actuating tube 21.

For example, the insert 22 may include a rod 34 which extends from the central portion 31 of the base 30 substantially perpendicularly thereto. The rod 34 may be provided with a head 35 snapped onto a continuous or discontinuous annular flange 36 formed inside the actuating tube 21. The insert 22 may comprise longitudinal wings 37 which are equally distributed and extend from the 2910450 13 rod 34 of the insert 22 towards the inner surface of the actuating tube leaving a transverse clearance Jt. The insert 22 may also comprise equidistributed longitudinal studs 38 which extend between the fins 37 and the base 30 and which are arranged facing the lower end of the actuating tube 21 with an axial clearance Ja. The fins 37 and the pads 38 allow, on the one hand, to limit the movements of the insert 22 relative to the actuating tube 21 and, on the other hand, to provide passages for the fluid product between the insert 22 and the actuating tube 21. The combination of the clipping of the head 35, the axial play Ja and the transverse clearance Jt forms a connection 15 equivalent to a ball joint connection and makes it possible to arrange between the insert 22 and the actuating tube 21, in addition to the swiveling, an axial displacement. Alternatively, the insert 22 may comprise a hollow rod 34 which delimits a lower portion of the outlet conduit, the exhaust port being transversely provided on the hollow stem or on the actuating tube 21. In addition, the piston 25 could be slidably mounted on the insert 22. In another embodiment not shown, it can be provided that the insert 22 is an adjoining part to the actuating tube 21 so that the base 30 is fixed by It can also be provided that the base 30 is directly adjacent to the actuating tube 21, for example formed integrally with the lower end of the actuating tube 21. The actuating tube 21 may then have one or more exhaust orifices arranged transversely above the base 30. In connection with Figures 2a, 2b, 2c and 2d, various stages of the actuation of the pump by a user are described.

2910450 14 In the absence of external stress, the nozzle 20 urged by the compression spring 17 is in its remote position (Figure 2a). Due to the swiveling and the biasing of the compression spring 17, the insert 22 aligns with the actuating tube 21. The piston 25 is in abutment with its radial wall on the lower end 41 of the expander 14 and the sealing surface of the free end of the central sleeve 26 is in sealing contact with the sealing surface of the base 30 to close the exhaust valve 33, the free end of the central sleeve 26 being pinch between the central portion 31 and the flange 32 of the base 30. The bearing surface of the support member 40 is in abutment against the inner surface of the sealing lip 27a and plate 15 the outer surface of the sealing lip 27a against the body 1. In addition, the inlet valve is closed. In the embodiments shown, it is expected that the frictional force between the piston 25 and the body 1 is greater than the frictional force between the piston 25 and the nozzle 20. When the user exerts pressure P For example, as a pusher on the actuating tube 21, because of the difference between the friction forces, the actuating tube 21 slides relative to the piston 25 so as to open the valve. exhaust 33 until the central sleeve 26 abuts against the shoulder 18 of the actuating tube 21. In doing so, the support member 40 is placed at a distance from the sealing lip 27a. Then, the displacement of the actuating tube 21 causes the piston 25 to move towards the inlet port 6 (FIG. 2b). The displacement of the nozzle 20 can be continued until the nozzle 20 reaches the close position (Figure 2c). The intake valve is closed.

In the close position, according to the embodiment shown, the support member 40 rests on a transverse bottom surface of the body 1 and the frustoconical base is placed inside a frustoconical housing provided in FIG. At the lower end of the side wall 7. When the user releases the pressure P on the pusher, the compression spring 17 urges the actuating tube 21 towards the remote position (FIG. 2d). Because of the difference in frictional forces, the actuating tube 21 slides relative to the piston 25 until the sealing surface of the central sleeve 26 comes into sealing contact with the sealing surface of the base 30 and closes the exhaust valve 33. The support member 40 bears on the inner surface of the sealing lip 27a. Then, the discharge of the nozzle 20 is accompanied by the rise of the piston 25 in the body 1 and 15 therefore an increase in the volume of the metering chamber 2. A vacuum is created in the metering chamber 2, which causes the opening of the inlet valve, the ball 10 being offset relative to the seat 11, and suction of the fluid, or air in the priming phase.

In other embodiments, it would be possible to control the opening and closing of the exhaust valve by means of an elastic member such as a pre-compression spring, particularly in the presence of a fluid product of low viscosity, this spring being in high abutment on the one hand on the nozzle 20, for example against the shoulder 18, and on the other hand in low support against the piston 25, so that it is necessary that a certain pressure is reached in the metering chamber 2 so that the exhaust valve 33 opens. 30

Claims (8)

  A pump for dispensing a fluid product, comprising: - a tubular body (1) extending along a central axis (A) between a first (3) and a second (4) end and comprising an inner surface which delimits a chamber metering device (2), the body comprising an inlet (6) for the fluid in the metering chamber (2) in the vicinity of the said first end (3), - a suitable intake valve (10, 11) for selectively sealing the inlet port (6), - a nozzle (20) mounted axially movable within the body (1) between a remote position and a position close to the inlet port (6); ), said nozzle (20) being resiliently biased towards the remote position, said nozzle (20) comprising an axial actuating tube (21) delimiting an outlet duct, a base (30) adjoining the actuating tube and arranged at the inside of the metering chamber (2) opposite the inlet orifice (6), and at least s an outlet of the fluid to the outlet duct, - a piston (25) comprising an annular central sleeve (26) slidably mounted on the nozzle (20) and an annular sealing lip (27a) having a surface interior and an outer surface which is slidably mounted on the inner surface of the body (1), the piston (25) and the base (30) forming an exhaust valve (33) which has an open state and a closed state, said pump characterized in that the base (30) comprises an annular bearing surface which, in the closed state of the exhaust valve (33), bears against the inner surface of the sealing lip (27a) .   2. Pump according to claim 1, wherein the piston (25) and the base (30) respectively comprise two sealing surfaces which come into mutual sealing contact when the exhaust valve (33) is in the state closed.   The pump of claim 2, wherein the sealing surface of the base (30) is distinct from the bearing surface.   The pump of claim 3, wherein the sealing lip (27a) surrounds the central sleeve (26), the piston (25) including a radial wall connecting the sealing lip (27a) to said central sleeve (26). ), the central sleeve (26) having a free end which has one of the sealing surfaces.   The pump of claim 4, wherein the base (30) has a concavity facing the piston (25), the free end of the central sleeve (26) extending into the concavity of the base (30).   6. Pump according to claim 5, wherein the base (30) comprises a central portion (31) and a frustoconical peripheral collar (32) extending from the central portion (31), the collar having a free peripheral edge. having the bearing surface, the central portion (31) and the flange (32) being located on either side of the free end of the sleeve (26). 25   7. Pump according to any one of claims 1 to 6, wherein the base (30) comprises a support member (40) on which the bearing surface is formed.   8. Pump according to any one of claims 1 to 7, wherein a swiveling is provided between the base (30) and the actuating tube (21).