Embodiments of the present invention relate to the production of devices for metering liquid or pasty fluids, such as, in particular, cosmetic, food or cleaning fluids, such fluids being generally contained in a flexible flask and being delivered in calibrated measured amounts each time a user presses this flask.
More precisely, embodiments of the invention relate to a metering device for transferring, from an upstream space towards a downstream space, a predetermined volume of liquid or pasty fluid in response to a rise in pressure of this fluid in the upstream space, this device including at least a hollow body and a valve, the hollow body delimiting at least partially a chamber equipped with an inlet and an outlet, the valve being movable with respect to the hollow body between a rest position, towards which this valve is biased by a return force, and an end position, which is spaced from the rest position and towards which this valve is selectively biased by the fluid flowing from the upstream space towards the downstream space, the upstream space extending at least outside the chamber at the inlet side thereof, and the downstream space extending at least outside the device and the chamber at the outlet side thereof.
Such a device is for example known from patent document EP 0,995,976 entitled “Metering end cap and container equipped with a metering end cap according to the invention”. The device described in this document has a large number of molded or blown parts, the manufacturing and assembly tolerances of which are very low. Moreover, the design of this device requires guiding the valve, called “metering piston”, both on its internal diameter and on its external diameter, which causes the generation of high friction forces.
U.S. Pat. No. 4,582,230, entitled “Metering Device”, also describes a fluid metering device, this metering device implementing a lock of which volume corresponds to the unitary metered amount. The outlet aperture of the metering device is selectively shut-off by a piston connected by a cylindrical rod to a ball controlling the opening of the lock, on the upstream space side delimited by a bottle. When the bottle is held in a vertical position, the piston closes the pourer of the metering device. When the bottle is being overturned, the piston keeps on maintaining the pourer closed, while the liquid enters in the lock. Once the bottle is in the vertical position, the ball closes the inlet of the lock, whereas the piston is descended, opening the pourer and releasing the liquid contained in the lock.
In addition to the fact that this solution also requires implementing a large number of parts, the result sought can only be obtained by slowly reversing the bottle, so that the tank fills in before the ball comes to close the liquid inlet in the tank, and before the piston releases the liquid contained in the tank. In addition, such a device is not adapted to the metering of viscous fluids.
In this context, an embodiment of the present invention is a metering device free from at least one of the aforementioned defects. To this end, embodiments of the invention include a valve that isolates the upstream space and the downstream space from each other in its end position and only in this position, and a chamber outlet that communicates with upstream space for any position of the valve other than its end position.
With this arrangement, the fluid traversing the hollow body under the effect of a pressure increase at the chamber inlet causes the valve to move from its rest position to its end position, and the volume of fluid delivered from when the valve leaves its rest position and when this valve reaches its end position is equal to the volume of fluid whose flow is necessary to operate this displacement of the valve.
In a possible embodiment, the valve includes at least a diaphragm movable in translation with respect to the hollow body, and the return force at least partially includes an elastic return force.
In this case, embodiments of the invention include at least an elastic tab attaching the valve to the hollow body, that the hollow body, the valve, and each elastic tab be integrally made from an elastic material, and that the return force be exerted by each elastic tab.
In another possible embodiment, the valve includes at least an articulated shutter, rotationally movable with respect to the hollow body, the return force at least partially comprising an elastic return force.
Embodiments of the invention can also include a sealing seat which surrounds a fluid passage disposed between the upstream space and the downstream space, and on which the valve rests in its end position.
The manufacturing of an embodiment of the invention can be facilitated by providing the embodiment of the invention with a plug inserted in the hollow body, this plug having bored therein a flow-through opening forming the chamber outlet.
In a more advanced embodiment of the invention, it is possible to provide the metering device such that it further includes a piston and a spring, that the piston be slidingly assembled in the hollow body and bears said valve, and that the spring be preloaded in compression and disposed between the plug and the piston.
If the viscosity of the fluid to be delivered is relatively low, it can be judicious to provide the chamber outlet such that it is bored in an elastically deformable wall and that it has a flow cross-section reversibly increasing under the effect of the fluid pressure.
In other possible embodiments of the invention, the density of the valve is lower than one so the valve can float in the fluid, the return force biasing this valve towards its rest position thus being at least partially composed of a buoyancy exerted on this valve which, in operation, soaks in the fluid to be delivered.
Embodiments of the invention may constitute a complete operational unit, in which case, it further includes a container provided with a neck, this container intended to contain the fluid and delimiting a variable volume upstream space, the rise in fluid pressure being obtained by reducing the upstream space volume, for example, by deforming the container in the case where it is flexible, and the hollow body being sealingly disposed in this container neck.
Other features and advantages of the invention will become more apparent from the following description thereof, given only for illustrative and in no way restrictive purposes, with reference to several embodiments illustrated in the accompanying drawings, in which:
a is an axial cross-sectional view representing an embodiment of the invention in which the valve is formed by a floater biased towards its rest position by a spring;
b is a top view of a valve which may be used in the particular embodiment constituting an alternative of
a is an axial cross-sectional view representing an embodiment of the invention in which the chamber outlet is formed by a cruciform flow-through opening;
b is a front view of the outlet of the cruciform chamber illustrated in
a is an axial cross-sectional view representing an embodiment of the invention in which the valve is formed by a diaphragm illustrated in its rest position;
b is an elevation side view of the embodiment of the invention illustrated in
c is another axial cross-sectional view of the embodiment of the invention illustrated in
d is an elevation top view of the embodiment of the invention illustrated in
a is an axial cross-sectional view representing an embodiment of the invention in which the valve is formed by a single shutter illustrated in dotted lines in its rest position and in solid lines in an intermediate position;
b is an axial cross-sectional view of the embodiment of the invention illustrated in
a is an axial cross-sectional view representing an embodiment of the invention in which the valve is formed by a diaphragm illustrated in its rest position, and in which the chamber is closed by the diaphragm associated with a piston and has a variable volume, this chamber being represented with its maximum volume;
b is an axial cross-sectional view of the embodiment of the invention illustrated in
c is an axial cross-sectional view of the embodiment of the invention illustrated in
d is an axial cross-sectional view of the embodiment of the invention illustrated in
e is an axial cross-sectional view of the embodiment of the invention illustrated in
f is a top view of the embodiment of the invention illustrated in
a is an axial cross-sectional view representing an embodiment of the invention in which the valve is formed by a double shutter illustrated in its end position, and in which the chamber is closed by this double shutter associated with a piston, this chamber having a variable volume and being represented with its minimal volume;
b is an axial cross-section of the embodiment of the invention illustrated to the
c is a side view of the piston and valve of the embodiment of the invention illustrated in
d is a top view of the piston and of the valve of the embodiment of the invention illustrated in
a is an axial cross-sectional view representing an embodiment of the invention in which the valve is formed by a single shutter illustrated in its rest position, and in which the chamber is closed by this shutter associated with a piston, this chamber having a variable volume and being represented with its maximum volume;
b is a top view of the piston and the valve of the embodiment of the invention illustrated in
c is an axial cross-sectional view of the embodiment of the invention illustrated in
d is a top view of the piston and the valve of the embodiment of the invention illustrated in
As previously stated, an embodiment of the invention relates to a metering device for transferring, from an upstream space E1 towards a downstream space E2, a predetermined volume of liquid or pasty fluid in response to a rise of fluid pressure in the upstream space E1.
As shown in particular on
An embodiment of the invention further includes a container 8 (represented only partially on the figures) for containing a fluid to be dispensed, and provided with a neck 80 which is the unique outlet for the fluid.
The internal volume delimited by this container, which constitutes at least the upstream space E1, has a variable capacity.
To this end, the container may for example include a flexible and elastically deformable wall, so that a pressure exerted on this wall by a user causes a transient reduction of the volume of the upstream space E1 and a concomitant rise in the pressure of the fluid contained in the container.
Alternatively, the container may be only formed with rigid walls, while including a piston which may be actuated by the user to cause a transient reduction of the upstream space E1 volume and a concomitant rise in the pressure of the fluid contained in this container.
The hollow body 1 is sealingly disposed in the neck 80 of this container 8. In particular, the hollow body 1 can be forcibly inserted into neck 80 until a stopper 9 of the hollow body presses against this neck.
The hollow body 1, of which shape is substantially cylindrical, at least partially delimits a chamber 100 provided with an inlet 5 and an outlet 6.
Valve 2 is movable with respect to hollow body 1 between a rest position illustrated, for example, on
Valve 2 is biased towards its rest position by a return force, and biased towards its end position, during application of a differential pressure between the chamber inlet 5 and the chamber outlet 6, the fluid flowing from the upstream space E1 towards the downstream space E2, upstream space E1 extending at least outside chamber 100 at its inlet 5 side, and the downstream space E2 extending at least outside the metering device and from chamber 100 at its outlet 6 side.
In its typical rest position, the container or flask 8 is positioned vertically so that its neck 80 is turned downwards, the fluid to be dispensed thus spontaneously tends to flow by gravity from the upstream space E1 towards downstream space E2, and from the inlet 5 of chamber 100 towards the outlet 6 of this chamber.
According to an embodiment of the invention, valve 2 isolates the upstream space E1 and the downstream space E2 from each other in its end position, and only in this position.
In addition, the outlet 6 of chamber 100 communicates with upstream space E1 for any position of valve 2 other that its end position. As shown in particular in
Moreover, as shown in
b illustrate embodiments of the invention in which valve 2 has an average density lower than that of the fluid to be dispensed, and typically a density lower than one.
In this case, valve 2, when it soaks in the fluid to be dispensed, behaves like a floater, so that the return force which biases this valve towards its rest position is at least partially composed the buoyancy exerted thereon.
As an extension of this description of the embodiments of
Moreover, the container or flask 8 will be regarded to as being oriented such that its neck 80 is aimed downwards.
In the first detailed embodiment illustrated in
This hollow body 1 is forcibly inserted in neck 80 of container 8 containing the fluid to be metered until a stopper 9 of this body 1 comes into contact with this neck.
In addition, plug 3 is forcibly inserted in the lower part of the hollow body 1 until a stopper 7 of this plug 3 comes into contact with this body 1.
The inlet 5 of chamber 100 has the shape of an opening provided in the hollow body 1, and the outlet 6 of chamber 100 has the shape of an opening provided in plug 3.
The size and/or shape of the outlet of the fluid chamber 6 may thus be modified at will by substituting the plug 3 inserted in neck 80 by another plug 3 having a flow-through opening 6 of a different size and/or shape.
Two grooves 4, for example U-shaped and disposed at 90° from each other, are provided in the upper part of the hollow body 1 so as to avoid floater 2 from sealingly shutting-off the inlet opening 5 of chamber 100, which is located in the upper part of the hollow body 1.
The edge of the recessed part of plug 3 forms a sealing seat 30 making it possible for floater 2, when it comes to rest on this seat 30 in its end position under the effect of a fluid pressure rise in upstream space E1, to isolate this upstream space E1 from downstream space E2, and to stop the fluid flow through the calibrated opening 6 of chamber 100 outlet.
The annular gap between the hollow body 1 and floater 2 is sized so as to allow a flow by gravity of the fluid under floater 2. Thus, as soon as the fluid pressure in the upstream space E1 is released, allowing the fluid to flow again under floater 2, this floater is subjected, as its density is lower than that of the fluid, to a buoyancy which sends floater 2 back in contact with the upper part of the hollow body 1, i.e. in its rest position illustrated in
To generate, within the fluid to be dispensed, the differential pressure necessary to displace floater 2, the flow cross-section of opening 6 of the outlet of chamber 100 should be provided such that it is higher than the flow cross-section provided by the annular gap between the floater 2 and the hollow body 1.
When a pressure is exerted on the flexible container 8 to expel the fluid contained in the upstream space E1, floater 2 is biased by the fluid moving to the bottom of the hollow body 1, while the majority of the fluid contained in chamber 100 between floater 2 and plug 3 traverses the outlet opening 6 of the chamber. Then, floater 2 comes to abut against the plug on the sealing seat 30 which it seals, prohibiting expelling more fluid. The subsequent release of pressure on container 8 and thus in upstream space E1 creates a depression which, by a light rising of the floater, causes air to enter into chamber 100.
The flexible container 8 can thus return to its rest position, and the fluid, which flows by gravity in the hollow body 1, makes floater 2 to ascend at the upper position towards its rest position, under the effect of buoyancy.
In another embodiment of the invention, illustrated in
In an embodiment, the elastic force exerted by spring 10 on floater 2 is sized to only compensate the weight of floater 2, spring 10 being only used to support the ascent of floater 2 when the fluid flows at the bottom of hollow body 1. This arrangement, which makes it possible to easily overcome viscous frictions, is more particularly adapted if the viscosity of the fluid to be dispensed is high.
b illustrates an alternative of the embodiment of
When container 8 is in the rest position, with the neck 80 oriented downwards, the fluid contained in this container 8 flows by gravity until it fills chamber 100 delimited by the hollow body 1, so that the floater is brought back to its rest position, by the effect of buoyancy, abutting against tab 11.
A pressure exerted on container 8 causes the fluid contained therein to flow towards neck 80. The moving fluid exerts a pressure on the floater 2, which moves downwards while expelling, through the outlet opening 6, the fluid contained in chamber 100. Once floater 2 is resting against seat 30 surrounding the outlet opening 6, this opening is sealed and the flow of fluid out of chamber 100 and towards downstream space E2 is stopped. The relief of the pressure on the surface of container 8 produces a depression which causes air to enter inside hollow body 1, bringing back the container to its rest state. Owing to the annular gap between floater 2 and the interior wall of the cylindrical hollow body 1, the fluid flows again in chamber 100 by gravity and passes under floater 2, so that the buoyancy exerted on this floater 2 gradually brings it back to its rest position, in abutment against the semi-rigid tab 11.
In an embodiment, the semi-rigid material constituting tab 11 is selected flexible enough to be able to undergo the necessary deformation to forcibly insert floater 2 in hollow body 1 without breaking, but sufficiently rigid so as not to undergo, under the effect of the buoyancy exerted on floater 2, a deformation which would cause the floater to escape from the hollow body when in its rest position in which it is pressed on this tab. The embodiment of
a and 5b illustrate an alternative embodiment particularly applicable to the embodiment of
According to this alternative embodiment, the outlet of chamber 6 is bored in an elastically deformable wall and has a flow cross-sectional area reversibly increasing under the effect of the fluid pressure.
In this regard, the bottom 12 of hollow body, where the flow-through opening 6 forming the outlet of chamber 100 is provided, is made from an elastically deformable material exhibiting a cruciform cut-out, and valve 2 exhibits a cylindrical shape.
When the pressure exerted on the flexible container 8 causes floater 2 to descend towards its end lower position to abut on seat 30, the thrust exerted by the fluid moving at the same time than floater 2 exerts on bottom 12 a pressure which deforms each part of the cruciform cut-out, so that the surface of outlet 6 of chamber 100 reversibly increases as an increasing function of this pressure.
Once abutting on the lower part in its end position, floater 2 seals outlet 6 and prevents any flow of fluid. Without external pressure, the only force generated by the height of fluid in the container cannot overcome the elasticity of the flexible blades formed at the corners of the cruciform outlet 6 of chamber 100, the fluid being thus retained in the metering device.
a to 10d illustrate other possible embodiments of the invention, in which the density of valve 2 is not specified a priori and in any case not necessarily lower than that of the fluid, this valve being biased towards its rest position by a return force of an exclusively elastic nature.
In the embodiment depicted in
In this embodiment, the hollow body 1, the valve 2 and each elastic tab 21 are preferably integrally formed from an elastic material.
The sealing seat 30, on which valve 2 rests in its end position, is formed on the upper part of the hollow body 1 and surrounds a fluid passage disposed between upstream space E1 and downstream space E2 and forming the inlet 5 of chamber 100.
At rest, valve 2 occupies the position illustrated in
When the fluid in the upstream space E1 is subjected to a pressure which pushes it towards outlet 6, the kinetic energy imparted to the fluid exerts on valve 2 a trailing force which biases it towards its end position illustrated in
Fx=ρ·S·V
2·Cx/2,
Where ρ represents the fluid density;
where S represents the master-torque of valve 2;
where V is the fluid speed; and
where Cx represent the trailing coefficient, related to the shape of the valve.
As in the preceding embodiments, the fluid which traverses the hollow body 1 under the effect of a pressure increase at the inlet 5 of chamber 100 moves valve 2 from its rest position (
The embodiment depicted in
The embodiment depicted in
On the other hand, the embodiment depicted in
The piston 14 is slidingly mounted in hollow body 1 and valve 2 is carried by the piston 14 by means of two elastic tabs 21 in the same way than it was carried by hollow body 1 in the embodiment depicted in
Piston 14 has a substantially annular form (
Spring 15 is preloaded in compression and disposed between plug 3 and piston 14, so that it tends to give to chamber 100 a maximum volume.
A stopper 140 is formed on the internal periphery of hollow body 1 to limit the travel of piston 14 upwards by defining a maximum upper position of this piston within hollow body 1.
The operation of the metering device according to an embodiment is illustrated in a sequential and chronological way in
a illustrates an embodiment of the invention in its stable rest configuration, in which outlet 6 of chamber 100 communicates with inlet 5 of this same chamber.
The pressure rise in container 8 causes the displacement of valve 2 towards its end position illustrated in
Insofar as the pressure of the fluid is thus exerted on the entire surface of the piston 14 closed by valve 2, this piston moves downwards while reducing the volume of chamber 100, causing the discharge, through outlet 6, of the fluid contained in this chamber, and compressing spring 15 correlatively, this movement being stopped when the piston 14 comes to rest against plug 3 (
Following the relief of the fluid pressure in container 8, the elastic return force exerted by tabs 21 brings valve 2 back to its rest position (
As spring 15 biases piston 14 upwards, as well as to the fluid which flows in chamber 100, chamber 100 resumes its initial maximum volume (
Thus, the embodiment of
a to 9d on one hand, and
Moreover, in these two cases, the chamber is partially delimited by a plug 3 inserted in the hollow body 1, and the latter including an internal peripheral stopper 140 making it possible to limit the ascending travel of the piston 14.
In the embodiment depicted in
In an embodiment, piston 14, each one of shutters 22 forming valve 2, and each one of the elastic hinge forming tabs 21 are integrally made from an elastic material.
The embodiment depicted in
In the embodiment depicted in
Meanwhile, the embodiment depicted in
In an embodiment, the piston 14, the shutter 23 forming the valve 2, and the elastic hinge-forming tab 21 are integrally made from an elastic material.
As in the embodiment depicted in
Number | Date | Country | Kind |
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0806164 | Nov 2008 | FR | national |
This application is a division of application Ser. No. 13/127,972 filed Jul. 27, 2011, which is a National Phase entry of PCT Application No. PCT/FR2009/001277, filed Nov. 4, 2009, which claims priority from French Application No. 0806164, filed Nov. 5, 2008, each of which is hereby fully incorporated herein by reference.
Number | Date | Country | |
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Parent | 13127972 | Jul 2011 | US |
Child | 14189605 | US |