WO2018046869A1

WO2018046869A1 - Fluid product dispenser

Info

Publication number: WO2018046869A1
Application number: PCT/FR2017/052394
Authority: WO
Inventors: Arnaud Dartevelle
Original assignee: Aptar France Sas
Priority date: 2016-09-08
Filing date: 2017-09-08
Publication date: 2018-03-15
Also published as: FR3055561B1; FR3055561A1

Abstract

The invention relates to a dispenser for a fluid product, comprising at least one dispensing aperture (O1) and at least two fluid product reservoirs (R1, R2) which are fluidically connected to said dispensing aperture (O1), the fluid product reservoirs (R1, R2) each defining a useful volume (Vu) and comprising a displaceable wall (P1, P2) for varying said useful volume (Vu), characterised in that each displaceable wall (P1, P2) is made to move by means of a respective electric stepper motor (11, 12) which provides for a predefined displacement of the displaceable wall (P1, P2) each time current is supplied, such that the fluid product stored in the fluid product reservoir (R1, R2) becomes pressurised and can be pumped through the dispensing aperture (O1).

Description

Fluid dispenser

The present invention relates to a fluid dispenser comprising at least one dispensing orifice and at least one fluid reservoir in fluid communication with the dispensing orifice. The tank defines a useful volume and includes a movable wall to vary the useful volume of the tank. This movable wall is urged in displacement by an electric motor in the direction of a reduction in the useful volume of the reservoir so as to pressurize the fluid stored in the reservoir to discharge it through the dispensing orifice. The preferred fields of application of the present invention are those of cosmetics, perfumery or pharmacy, without excluding other areas, such as those of beverages and food.

Fluid dispensers having an electric motor have already been available for some time to generate a fluid dispensing at a dispensing orifice. Conventionally, the electric motors are energized by means of an actuating button and thus function as long as the actuating button is depressed. In other words, the operation of the electric motor depends directly on the depression time of the actuating button. The advantage lies in the fact that the user can obtain a continuous and regular distribution throughout the power supply period of the electric motor. However, there is a major disadvantage residing in the fact that it is difficult to accurately measure the amount of fluid dispensed, since it depends directly on the duration of depression of the actuating button.

The invention aims to overcome the aforementioned drawback of the conventional electric motor of the prior art by defining a fluid dispenser whose electric motor ensures a precise and reproducible dosage of the amount of fluid dispensed. The other object of the present invention is the easy and inexpensive implementation of the electric motor of the invention. An advantageous application of this The invention resides in dual distributors for simultaneously dispensing two different fluid products. Thanks to the present invention, a precise dosage for each fluid product is possible.

To do this, the present invention provides a fluid dispenser comprising at least one dispensing orifice and at least two fluid fluid reservoirs in fluid communication with the dispensing orifice, the fluid fluid reservoirs each defining a useful volume and each comprising a movable wall for varying the useful volume, characterized in that each movable wall is urged in displacement by a respective stepper electric motor generating a predefined displacement of the movable wall at each power supply, so as to bring under press the fluid product stored in the fluid reservoir to discharge it through the dispensing orifice. Thus, the proportion of fluid products can be fixed with high reproducible precision.

Advantageously, the pitch of each motor is adjustable, preferably by adjustment means. Preferably, the adjustment means are associated with a control electronics which determines the number of steps of each motor.

According to an advantageous embodiment, each step motor is connected to the movable wall by a worm system which transforms a rotary displacement of the stepping motor into a translational movement of the movable wall. By definition, a worm system comprises a threaded rod or pin which is rotated on itself and which is engaged with another threaded element which is locked in rotation, so that it is forced to move translatively. as the spindle or threaded rod is rotated.

According to another interesting aspect of the present invention, the stepper motors are part of a module which is removably connected to the fluid containers. Thus, the dispenser can be defined as consisting of two subsets, a subset formed by the reservoirs and another subset formed by the module. Advantageously, the worm system is part of the module or tanks of fluid product. Indeed, according to the design of the dispenser, it is sometimes more interesting to associate the worm to the module, and in another case, it is more advisable to associate with the tanks.

More specifically, the module may comprise, in addition to stepper motors, a battery, a control electronics and an actuation button, and optionally a gearbox.

According to a practical embodiment, the movable wall is a piston, advantageously non-circular, which slides in a sealed manner in a sliding shaft. The piston may for example be oblong, oval or elliptical, so that it is certainly locked in rotation inside the sliding shaft. In this way, part of the worm system can be secured to the piston and thus lock in rotation. Alternatively, the worm system may include a threaded spindle which is threadedly engaged with and through the piston. In other words, the piston can be considered as an integral part of the auger system.

According to another advantageous characteristic of the invention, the dispensing orifice may be formed by the module or the fluid reservoir. Indeed, according to the dispenser design, it may be desirable to associate the dispensing orifice module, and in other cases, it is more advisable to associate the reservoir.

According to an advantageous implementation, the two fluid fluid tanks are connected, advantageously removably, to a module integrating the stepper motors. According to a particular embodiment, the distributor comprises two worm gear systems having two threaded spindles of different pitch driven by a common stepper motor. In a variant, the module integrates two stepping motors respectively driving two identical worm gear systems, advantageously via a gearbox.

According to a practical embodiment, the fluid reservoir incorporates a worm system having a threaded spindle and comprises, at an upper face, a projecting drive end which is centrally axially arranged and a neck output fluid that is disposed eccentrically adjacent to the protruding drive end, the stepper motor being part of a module which is removably connected to the fluid containers, the module comprising a tip housing for receiving the tip of protruding drive and a connecting sleeve for the fluid outlet neck.

The spirit of the invention resides in the implementation of a stepping motor which makes it possible to move the mobile wall of the tank in a precise and reproducible manner. The use of a worm system, a non-circular piston are advantageous secondary features. The arrangement of the stepper motor in a separable module of the tank is another advantageous feature of the invention. We can thus replace the empty tanks by keeping the module, which integrates the most expensive components. The reservoir is then in the form of a cartridge. The implementation of such a stepper motor in a duo distributor is particularly advantageous because it allows to dose with very high precision the amounts of fluid to be dispensed. The duo dispenser may include a plurality of stepper motors, which are advantageously adjustable to adjust the doses of fluid product. When there is only one motor in a duo distributor, one can play on the screw of the auger system to differentiate the doses of fluid dispensed. One can also play on the diameter of the pistons.

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

In the figures:

FIG. 1 is a vertical cross-sectional view through a fluid dispenser which does not form part of the present invention,

FIG. 2 is a horizontal cross-sectional view along section line A-A of FIG. 1,

FIG. 3 is a vertical cross-sectional view through a duet distributor according to the invention, FIG. 4 is a vertical cross-sectional view along a plane perpendicular to that of FIG. 3 of the distributor module,

FIG. 5 is a horizontal cross-sectional view through the module of FIG. 4,

FIG. 6 is a vertical cross-sectional view of a duo dispenser which does not form part of the invention,

FIG. 7 is a horizontal cross-sectional view through the module of the distributor of FIG. 6, and

FIG. 8 is a vertical cross-sectional view through a module of the dispenser of FIG. 6.

Reference is first made to FIGS. 1 and 2 to describe the first embodiment. This dispenser comprises a reservoir R internally defining a cylindrical sliding shaft F, which is advantageously of non-circular shape. In this case, the sliding shaft F has an oblong, elongate, oval or ellipsoidal shape, as can be seen in FIG. 2. At its upper end, the reservoir R forms a dispensing nozzle S which ends with a O. Although not shown, an end cap may be provided at the dispensing nozzle S or at the dispensing orifice O. The reservoir R also comprises a piston P which is engaged to sliding sliding inside the sliding shaft F. The piston P comprises one or two sealing lip (s) L which extend around a bottom G. Thus, the reservoir R defines between its piston P, its sliding drum F, its dispensing nozzle S and up to the dispensing orifice O a useful volume Vu, which is of variable volume, since the piston P is movable inside the drum F. Until then , the distributor is globally under the shape of a cylindrical tube of oval section forming a dispensing nozzle and receiving internally a sliding piston P.

This distributor also comprises a module M which is detachably engaged inside the tank R, below the piston P. The module M can be engaged in the tank R by its open end opposite to the dispensing orifice O. The module M can be held by any means inside the reservoir R. This module M comprises an electric stepping motor 1 which is powered by one or more batteries (s). ) 2 controlled by a control electronics 3 and actuated (s) by means of an actuating button 4, which advantageously forms the bottom of the distributor. The stepper motor 1 is engaged with a tube T which is threaded internally. As a result, the tube T is rotated integrally with the stepping motor 1. The tube T internally receives a threaded spindle which is threadedly engaged with the threaded inside of the tube T. At its upper end, the threaded spindle B forms a disc D which is engaged with the bottom G of the piston P. Advantageously, the shape of the disk D corresponding to that of the bottom G, so that the disk D is housed without play inside the lip L, as can be seen in Figure 2. In this way, the pin B is blocked in rotation, since integral with the piston P which is prevented from rotating inside the barrel F, due to the non-circular shape of the piston P and the barrel F. It is then easily understood that a rotation of the tube T driven by the engine step 1 has the effect of moving the pin B inside the tube T, thus urging the piston P to move in the barrel F. It is thus possible to move the piston P stepwise in the direction of a decrease of the useful volume As seen from the tank, which has the effect of pushing back product uide under pressure through the outlet nozzle S and finally the dispensing orifice O. Thus, with each push on the actuating button 4, the stepper motor 1 is supplied with current and generates a predefined angular displacement and specific. The threaded tube T which is integral with the stepper motor 1 thus moves in the same way on a predefined and precise angular stroke. The threaded spindle B thus moves in translation in a predefined and precise manner and moves the piston P in a predefined and precise manner. This ensures that the dose of fluid dispensed through the dispensing orifice O is accurate and always the same. If the user wants more dispensed fluid product, it is sufficient to repeatedly press the actuating button 4. The final dose distributed will always be a multiple of the unit dose obtained by pressing the actuation button 4.

In this embodiment, the dispenser is in the form of a pipette and will preferably be used with the dispensing orifice O pointing downwards and the actuating button 4 facing upwards.

The user grasps the dispenser in the hollow of the palm of his hand so as to actuate the actuating button 4 with his thumb. The module M here integrates the worm screw system V. Alternatively, it is also possible to connect the worm system V to the piston P, so that it would then be an integral part of the tank. The module M is thus limited to the stepping motor 1, the battery 2, the control electronics 3 and the actuating button 4, and possibly a gearbox.

Reference will now be made to FIGS. 3, 4 and 5 to describe one embodiment of the invention. The distributor of these figures is a duo distributor implementing two fluid containers R1 and R2 disposed in a shell Q. The duo distributor also comprises a module M1 which is removably mounted on the two tanks R1 and R2 and / or on the shell Q. The two tanks R1, R2 may be substantially identical or different, especially as regards their useful volume. Each reservoir comprises a sliding piston P1, P2 which slides in a respective drum F1, F2. Each tank also contains a threaded spindle B1, B2 which can rotate freely on itself. Each pin B1, B2 comprises a drive end B1 1, B21 which protrudes out of the tank at its upper end. Each piston P1, P2 comprises a threaded collar C1, C2 which is threaded about its respective pin B1, B2. Since the barrels F1, F2 have a non-circular cross section, as shown in Figure 5, the pistons P1, P2 are locked in rotation inside the barrels F1, F2. As a result, a rotation of the pins B1, B2 causes a translational movement of the pistons P1, P2 inside the drums F1, F2. In other words, the combination of a threaded spindle B1, B2 and a threaded collar C1, C2 constitutes a worm system V2. On the other hand, each tank R1, R2 forms an outlet neck R1 1, R21 which projects from level of the upper end of the tank. It may be noted that the driving tips B1 1, B21 are arranged centrally and / or axially, while the output collars R1 1, R21 are arranged off-axis next to the drive ends B1 1, B21, by being arranged relatively close to each other, as can be seen in Figure 5.

The module M1 comprises two stepping motors 1 1, 12 each forming an end housing 1 1 1, 121 adapted to receive the drive ends B1 1, B21 of the two pins B1 and B2. In this way, the pins B1, B2 can be driven independently by the two stepping motors 1 1 and 12. The pins B1, B2 can be perfectly identical, but their rotation pitch will be imposed by the characteristics of the motors not These two step motors 1 1 and 12 are powered by at least one battery 21 and controlled by a control electronics 31. The module M1 also comprises an actuating button 41 on which the user can press to supply the two stepping motors 1 1 and 12. The actuating button 41 may for example be arranged at the level of the upper face of the module M1. The control electronics 31 makes it possible to accurately determine the number of steps performed by each of the motors 1 1 and 12. The actuation button 41 can be used to adjust or precisely adjust the number of steps. Alternatively, a separate adjusting member of the actuating button 41 may be provided to adjust the number of steps of each motor. In general, the module M1 comprises means for setting the number of steps that the control electronics 31 will impose on each motor.

The module M1 also comprises an output channel S1 which forms, upstream, a connecting sleeve S2 for the two output collars R1 1 and R21 and downstream the dispensing orifice 01. The outlet channel S1 may extend off-axis or eccentrically with the dispensing orifice 01 which opens laterally.

This duo distributor thus has a conventional configuration with a lateral dispensing orifice 01 and an upper actuating button 41. The shell Q may have a circular shape and contain the two reservoirs R1, R2 of non-circular section, such as ellipsoidal, oblong, ovoid. The mounting of the module M1 on the shell Q is simple, since it suffices to engage the drive ends B1 1, B21 in the end housing 1 1 1, 121 and simultaneously engage the output collars R1 1, R21 in the connection sleeve S2. By pressing the actuating button 41, the threaded pins B1, B2 are rotated on themselves with identical or different angular pitches, which causes the same or different translational movement of the two pistons P1 and P2.

Again, thanks to the implementation of the two stepper motors 1 1 and 12, it is possible to accurately dose the quantities of fluid dispensed with each pressing of the actuating button 41. The transmission between the stepper motors and the pistons is done directly and easily via the threaded pins which are threaded with the pistons, which are also traversed by the pins. In this embodiment, the worm systems V1, V2 are integrated in the tank.

Reference will now be made to FIGS. 6 and 7 to describe another embodiment. The distributor is again a duo distributor implementing two tanks R3 and R4 each comprising a piston P3, P4 threaded with threaded pins B3, B4. For this, the pistons P3, P4 comprise threaded collars C3, C4 which are engaged in threaded engagement around the threaded pins B3, B4. In this embodiment, it is interesting to note that the threads of the threaded pins B3 and B4 are different. Each pin B3, B4 comprises a drive end B31, B41 which protrudes out of the tank at its upper end. The tanks R3, R4 each comprise an outlet neck R31, R41 which extends next to the drive end.

The distributor also comprises an M3 module which here integrates a single stepping motor 13 which is connected to the drive end B31, B41 via a gearbox 53. This gearbox 53, simply allows to split the output of the stepping motor 13 so as to come identically in drive connection with the drive tips B31 and B41. The engine is not not 13 is powered by one or more battery (s) and controlled by the control electronics 33. The module M3 also comprises an actuating button 43 which is located at its upper face.

On the other hand, the module M3 comprises an output channel S3 which is connected upstream to the two output collars R31 and R41 and which defines downstream a distribution port 03. It may be noted that the output 03 is axial.

This third embodiment is thus distinguished by the fact that it implements only one stepping motor which simultaneously and identically drives two threaded spindles B3, B4 which have different threads, so that the two pistons P3, P4 will move translectively in a differentiated manner. The axial outlet of the dispensing orifice 03 is also a feature of this third embodiment.

Reference will now be made to FIG. 8 to describe a fourth embodiment for an M5 module. This module M5 is distinguished by its architecture which comprises two stages namely a lower stage M51 which defines an output channel S5, a connecting sleeve S6 and a distribution orifice 05. This lower stage M51 is traversed from one side by two passes for both drive ends B31, B41.

The module M5 also comprises an upper stage M52 which contains one or more stepping motor (s) 15 in engagement with an end housing 151 via a gear unit 65. The module M5 also comprises one or more batteries ( s) 25, a control electronics 35, and an actuating button 45.

This stepped architecture makes it possible to substantially separate the routing of fluid products and the driving of the threaded spindles. This saves space on the upper stage M52 which is not congested by the output channel S5.

Without departing from the scope of the invention, it is possible to envisage distributors comprising more than two tanks with which stepper motors are associated. In addition, it may be provided that the motor or motors make a small rotation in the opposite direction after each distribution of fluid to move the movable wall back to generate a "re-aspiration" or "sniffing" effect, to empty at least partially the outlet channel to prevent the fluid from being in contact with the external environment. This measure guarantees a better preservation of the fluid product.

Whatever the embodiment, these distributors implement one or more motor (s) step by step that can move transluctively a movable wall of a tank, in this case a piston. Instead of a sliding piston, it could also provide a piston for deforming a flexible bag. The worm system, whether or not incorporating the piston, is an extremely simple embodiment for transmitting the predefined angular displacement of the stepping motor to the movable wall. The duo distributors with two stepper motors allow precise and reproducible dosing. In addition, the adjustment of each dose by adjusting the number of steps of each motor makes it possible to vary the proportion of fluid products distributed with great precision.

Claims

claims

1. - Fluid product dispenser comprising at least one dispensing orifice (01) and at least two fluid fluid reservoirs (R1, R2) in fluid communication with the dispensing orifice (01), the fluid reservoir (R1, R2) each defining a useful volume (Vu) and each comprising a movable wall (P1, P2) for varying the usable volume (Vu), characterized in that each movable wall (P1, P2) is urged on displacement by an engine respective electric step (1 1, 12) generating a predefined displacement of the movable wall (P1, P2) at each power supply, so as to pressurize the fluid product stored in the fluid reservoir (R1,

R2) to drive it through the dispensing orifice (01).

2. - Dispenser according to claim 1, wherein the pitch of each motor (1 1, 12) is adjustable, preferably by adjusting means.

3. - Dispenser according to claim 2, wherein the adjusting means are associated with a control electronics (31) which determines the number of steps of each motor (1 1, 12).

4. - A dispenser according to any one of the preceding claims, wherein each stepper motor (1 1, 12) is connected to the movable wall (P1, P2) by a worm system (V1, V2) which transforms a rotary displacement of the stepping motor (1 1, 12) into a translational movement of the movable wall (P1, P2).

5. - Dispenser according to any one of the preceding claims, wherein the stepper motors (1 1, 12) are part of a module (M1) which is removably connected to the fluid containers (R1, R2). ).

6. - Dispenser according to claim 5, wherein the module (M1) comprises, in addition to stepper motors (1 1, 12), a battery (21), a control electronics (31) and a button. actuation (41).

7. - A dispenser according to any one of the preceding claims, wherein the movable wall is a piston (P1, P2), preferably non-circular, which slides in a sealed manner in a sliding shaft (F1, F2).

8. - A dispenser according to claim 7, when dependent on claim 2, wherein the worm system (V1, V2) comprises a threaded spindle (B1, B2) which is threaded with and through the piston (P1, P2).

9. - A dispenser according to any one of the preceding claims, wherein the two fluid reservoirs (R1, R2) are connected, preferably removably, to a module (M1) integrating the stepper motors (1 1, 12).

10. - Dispenser according to claim 9, wherein the module (M1) incorporates two stepper motors (1 1, 12) driving respectively two identical worm systems (V1, V2).

1 1. - Dispenser according to any one of the preceding claims, wherein each fluid reservoir (R1, R2) incorporates a worm system (V1, V2) having a threaded spindle (B1, B2) and comprises, at the level of an upper face, a projecting end-piece (B1 1, B21) which is centrally arranged and a fluid-product outlet neck (R1 1, R21) which is eccentrically disposed adjacent to the end portion thereof; protruding drive (B1 1, B21), the stepper motor (11, 12) forming part of a module (M1) which is removably connected to the fluid containers (R1, R2), the module (M1) comprising a tip housing ( 111, 121) for receiving the projecting drive end (B11, B21) and a connecting sleeve (S2) for the fluid product outlet neck (R11, R21).