The present invention relates to the technical field of packaging, and more especially to the packaging and dispensing of a product that is either liquid, semi-fluid or in suspension and designed to be preserved under sterile conditions, without the addition of preservatives, and dispensed in portions or doses, notably in drop form.
The invention relates more particularly to a device for packaging and dispensing a product comprising a container designed to contain the product that is to be dispensed, with the aid of a nozzle that has no air inlet and with which the container is fitted, the nozzle optionally being an integral part of said container or being mounted in a sealed manner on an open neck of said container.
There are in the prior art packaging devices of conventional structure that can be used to preserve and dispense a product in the form of doses or drops or in any other form, while maintaining its sterility for the entire duration of its use.
These devices are used particularly in pharmaceutical, cosmetic and food applications, and in some cases more particularly in opthalmological applications.
For example, the prior art includes such devices disclosed in patents FR 2 770 495, FR 2 638 428 and FR 2 661 401 in which a container is fitted with a dispensing nozzle that includes a bacteriological filter membrane which sterilizes the product when it is expelled from the container.
In these devices, the container comprises a flexible portion which, when squeezed by hand, forces the product through the bacteriological membrane, through the nozzle and out of said container.
It should be observed that, when a portion of product is expelled from the container, a partial vacuum is created inside the container and must be compensated for, either by admitting more air equivalent to the volume of product expelled, or by a corresponding reduction in the internal volume of the container, which can be done by causing a corresponding deformation of the container.
Present-day membranes do not allow product (liquid, semi-fluid or in suspension) to flow in one direction, i.e. from the interior of the container to the exterior, and air to flow in the opposite direction, i.e. from the exterior to the interior of the container, the reason being that the internal and external faces of the membrane are “wetted” by the passage of the product and the external face resists the entrance of new air.
In this type of device it is therefore necessary to provide a container whose internal volume is variable and reduces as the product contained inside it is dispensed.
This requirement results in unattractive-looking containers that are difficult to manipulate when not protected by a protective outer jacket, or difficult and expensive to manufacture if such a protective outer jacket is provided.
Another problem with these devices is that there is no way of dispensing highly viscous products as these require excessive pressure to force them through the sterilizing membranes, the pores of which are of extremely small diameter. Nor can they be used to dispense products in suspension where the particles axe stopped by the membrane.
Another kind of device that can be used to achieve a similar result is disclosed in FR 2 772 007. This comprises a rigid container designed to contain the product to be packaged, a hand pump of the type with no air inlet mounted on the container, said pump being intended to dispense the product in single doses, and a sterilizing filter placed in an air renewal passage formed in the base of the container.
The main problem with this kind of device is that the bottle is rigid and that a dispensing pump has to be used to dispense the product. Such a pump discloses in patent FR 2 772 007 contains numerous elements, including a dose-defining chamber and two valves for isolating said chamber and dispensing precise doses of product. This construction is very expensive and considerably increases the cost price of the device, and the cost of such a pump can be practically equivalent to that of the bottle itself. The cost of such a device makes it unsuitable for its use in certain applications such as, for example, opthamology, in which the products are sold cheaply and do not need precise dosing because the products are dispensed in drop form. A pump capable of dispensing drops requires very precise construction, which increases its cost by a corresponding amount.
Another problem with such a device is that the pump used has a push rod incorporating its own nozzle through which the product is dispensed. It is inherent in the construction of the pump that the push rod is movable and the product is dispensed when the push rod is released and returns to its initial position under the action of a return spring. This mobility of the push rod, and therefore of the nozzle through which the product is dispensed, makes this device unsuitable, and possibly even dangerous, for dispensing eye drops.
Another problem with a device comprising a pump is that it is impossible to sterilize it by heating it because the pump contains plastic components, some of which are inherently unable to tolerate the high temperatures indispensable for sterilizing the complete device before it is put to use.
Another difficulty with this kind of device is that the pump usually contains metal parts, such as the spring or the valves where these consist of steel balls, and these are incompatible with certain fragile or aggressive products or products that may produce an electrolytic effect.
One object of the invention is to make it possible to use simple containers that do not deform permanently under the effect of the partial vacuum created when some of the product is expelled.
Another object of the invention is to make it possible to use a filter for new air entering the container without having to use a pump to dispense the product.
More generally, it is an object of the invention to overcome the problems of similar devices of the prior art and to provide such a device that is better suited than other known devices to the diverse requirements of the field.
To achieve these objects, the invention provides a device for packaging and dispensing a product, said product generally being liquid, semi-fluid or in suspension, comprising a container designed to contain the product to be packaged and dispensed with the aid of an accessory, and an air renewal and filtration assembly for air entering the container after a portion or dose of product has been dispensed, the device being characterized in that the dispensing accessory is a nozzle with which the container is provided, the assembly composed of the container and nozzle having at least one flexible portion which, when pressure is applied to it, is capable of expelling product, and a first valve with which the nozzle is provided to allow the product to pass out from the container when pressure is applied to said flexible portion of the assembled container and nozzle without allowing external air to enter said container when said flexible portion is released, and said air renewal and filtration assembly is provided with a second valve allowing external air to enter said container when said flexible portion of the assembled container and nozzle is released while ensuring that none of the product and little or none of the air contained in the container can escape when pressure is applied to said flexible portion.
The device thus makes it possible to dispense portions or doses of product by simple pressure on at least a flexible portion of the container/nozzle assembly, and to compensate for the partial vacuum thus created in the container by admitting air, preferably sterile, through the renewal and filtration assembly.
The container advantageously consists of two portions moulded separately and joined together hermetically, one of which parts may include the nozzle or may be the nozzle itself, to which the first valve and optionally the air renewal and filtration device are connected, while the other portion may include a rigid portion for housing the air renewal and filtration device if the latter is not located in the nozzle.
In a first embodiment, the nozzle is an integral part of the container, for example is part of the same molding as the container, which comprises at least one flexible portion, and a rigid portion, forming the base of the container, can be fitted and joined hermetically to an essentially rigid portion of the container.
In a second embodiment the container comprises an essentially rigid portion to which the nozzle which comprises at least one flexible portion is added and fixed, and said essentially rigid portion may be an extension of the rigid base of the container.
In both variants, said air renewal and filtration assembly may be situated in the nozzle, or in the rigid base connected to a substantially rigid portion of the container, and this assembly comprises a filter that may be overmoulded, ultrasound-welded, or assembled by any other means. It allows external air through by simple suction into the container in order to compensate for the partial vacuum created by the dispensing of some of the product.
If the air renewal and filtration assembly is located in the nozzle, the container does not necessarily have a rigid portion, and the flexible portion may be a portion of the nozzle or a portion of the container body.
Depending on the nature of the product contained in the container, the filter selected will be either hydrophobic or hydrophilic, but always such as to prevent the escape of the product from the interior of the container to the exterior. If the internal face of the filter which is in contact with the product has been wetted, this face is rendered partially or even entirely impervious to air, which likewise cannot escape from the interior of the container to the exterior, or can do so only with great difficulty.
Careful selection of the type of filter thus makes it possible to produce, using the latter, in an advantageously simple manner, a valve that lets external air into the container, but which, when pressure is applied to the flexible portion of the container or nozzle, prevents all liquid and most of the air from escaping to the exterior.
In a variant, the device includes an additional valve which is connected to said air renewal and filtration assembly, is arranged between the filter and the internal volume of the container, and is designed to prevent the escape of the product and air contained in the container through an air inlet passage of said assembly and to prevent any contact between the product and the filter. Such a valve will be used where it is not possible, because of the nature of this product, to find a filter quality compatible with its valve function allowing air to pass from the exterior to the interior of the container, but preventing the passage of product and air in the opposite direction, from the interior to the exterior of the container, after having been wetted by the product. This valve can also be used in all cases where the nature of the filter would be incompatible with the product contained in the container.
This valve may also not be situated in the immediate vicinity of the air renewal assembly but anywhere inside the container, provided that it performs its main function of preventing the passage of air or liquid from the interior to the exterior of the container when pressure is applied to the flexible portion.
Advantageously, this valve is elastically deformable and cooperates with a seat situated on the base, or on the nozzle, or on a component situated in the nozzle. An elastic valve of this kind is effective in preventing any product or air escaping from the container through the air inlet passage, yet letting external air in by bending elastically towards the interior of the container due to the action of external air being sucked in following the expulsion of a portion of product through the dispensing nozzle.
This dispensing nozzle, which can be moulded either with the container body or separately, comprises a valve which may either be of the same construction as the elastic valve situated in the air renewal and filtration assembly, or of a different construction, or be formed by the nozzle itself, provided that it is always able to perform the same function, namely to allow product to be expelled by a pressure increase occurring when pressure is applied to the deformable flexible portion, and to prevent any air being drawn in by suction when said flexible portion is released.
In a variant, when the nozzle is made of an elastic material, the nozzle itself has extremities in the form of lips that can open and close on a central seat to form a valve. In this case the first valve, connected to the nozzle, is formed by at least a portion of the nozzle itself.
In another variant the second valve, connected to the air renewal and filtration assembly, may be formed by at least one filter belonging to said assembly.
In yet another variant, and where the air renewal and filtration assembly is situated in the nozzle and includes an additional valve, this second valve connected to this assembly for the admission of air and the first valve connected to the nozzle for the expulsion of product may form a single component.
In this way it is possible to make, in a simple manner, a product-dispensing assembly that is advantageously sterile, made up of a deformable chamber bounded by the container itself and/or its nozzle, and two valves, one allowing only expulsion of the product through the nozzle when the container and/or its nozzle is or are compressed and the other allowing only the admission of external air through a passage containing a filter when pressure is no longer applied to the container and/or its nozzle.
In certain uses, for which a relative quantity of the product must be dispensed, it may be useful to limit the deformation of at least one flexible portion of the container and/or nozzle, in order to make the dispensing of a portion reproducible. For this purpose, the nozzle and/or the container itself includes at least one component located on the inside or outside of and adjacent to said flexible portion, the deformation of which will be limited by said component, or alternatively said flexible portion is produced in such a way, e.g. concertina-fashion, that it deforms, in more or less the same way every time.
If the air filtration and renewal assembly is situated in the rigid container base, and the deformable flexible portion is situated in the nozzle and its deformation is limited, it may be advantageous to locate the additional valve in the nozzle between the deformable flexible portion and the rigid container base.
In this way, when pressure is applied to the flexible portion of the nozzle and its deformation is limited, the pressure acting on the liquid contained in the nozzle will not be transmitted to the air contained in the container.
In certain conditions of use where the wetting of the internal face of the filter by the product makes it difficult for new air to pass from the exterior into the interior of the container, and/or, more generally, if the elasticity of the flexible portion which tends to return it to its initial position after a portion of product has been expelled, is unable on its own to create a sufficient vacuum for this new air to enter the container, it may be useful to create an extra suction by adding, on the inside or outside of the flexible portion of the container and/oz nozzle, at least one elastically deformable component to act as a return spring and apply pressure to at least one flexible portion.
In preferred embodiments, the flexible portion is provided with an actuating portion that is resiliently movable between an engagement position and a rest position, the actuating portion being axially shifted with respect to the free end of the nozzle. A dose-defining chamber extends between a stationary wall portion and a displaceable wall portion that is part of the flexible portion. A rigid stopper element is provided to form a part of the stationary wall portion. The dose-defining chamber is isolated from the air contained in the container by a specific valve. The dose-defining chamber has a determined volume in the rest position of the actuating portion. The engagement position is obtained by engaging the actuating portion of the nozzle against the stationary wall portion, so as to empty the chamber and expel a dose exactly corresponding to the determined volume of the chamber.
Preferably, the flexible portion comprises a biasing annular end adjacent to the displaceable wall portion and configured to generate a bias which strives to move the displaceable wall portion apart relative to the stationary wall portion. In one variant, the biasing annular end is hingeably connected to the stationary wall portion and extends inclined inwardly therefrom in the rest position of the actuating portion. In the engagement position of the actuating portion, the biasing annular end extends along and in contact with the stationary wall portion. In another variant, the biasing annular end is hingeably connected to an outer wall portion of the nozzle, distinct from the stationary wall portion.
A rigid outer layer may be used to reinforce the actuating portion, the biasing annular end being only connected to the inner layer of the actuating portion. The outer contact surface to be pushed thus may be a rigid surface. As a result, the product in the chamber may be efficiently compressed and expelled, in a same manner after repeated use of the actuating portion of the nozzle.
Lastly, the container can be filled through the opposite end from the nozzle before the application of a rigid base moulded separately from the rest of the container, and joined hermetically to a substantially rigid portion of the container.
Other features and advantages of the invention will be found in the description given below, with reference to the appended drawings, which show, by way of non-restrictive examples, various embodiments and implementations of the subject of the invention.
In these drawings:
a and 5b are views, similar to
a is an enlarged view of the device in partial axial half-cross section showing the air renewal and filtration assembly situated in the nozzle;
b is a view similar to
c is a view similar to
a and 14b are respective schematic axial sectional views of a device completely similar to the device of
a and 15b are views similar to
a and 17b are respective schematic axial sectional views of a device according to the invention, showing a container made of two rigid parts fitted together hermetically and showing radial movement of an actuating portion configured as a radial protrusion in the nozzle;
a and 18b are respective cross section views of the device shown in
a and 19b are respective schematic axial sectional views of a device completely similar to the device of
a and 20b are respective schematic axial sectional views of a device provided with an actuating portion connected to rigid stationary portion of the nozzle, showing radial movement of the actuating portion.
In the various figures, identical reference numbers denote similar elements of the various examples of embodiments illustrated and described.
In a form shown in
The elastic valve has an annular flange 19 trapped between a central annular axial portion 20 of the nozzle 3 and radial annular extension 21 of the seat 5; and a deformable part-cylindrical part-conical portion 4 which rests on the central seat 5 in the rest position. This valve is installed in such a way that at rest it is in compression on the seat 5, so blocking the passage 10, when it is not stressed.
The nozzle portion 3 may have an external thread 12 so that a protective cap 13 can be screwed on.
The filter 8 is attached hermetically to the rigid base 6, by overmoulding, ultrasound welding or any other means so that the air entering the container 1 through the passage 9 has to pass through this filter 8. The internal face 14 of the filter 8 in constant contact with the product contained in the internal volume of the body 11 of the container 1 is wetted by this product, which makes it effectively impossible for air to pass from the interior to the exterior of the container. The nature of the filter 8, which is selected to suit the liquid or semi-fluid product or product in suspension that is to be dispensed, ensures that no product can pass from the interior to the exterior of the container. Thus, if the product to be packaged and dispensed is aqueous, a hydrophobic-type filter will be selected, and if the product is nonaqueous a hydrophilic-type filter will be selected.
In this example, the container with its portions 2, 7 and the nozzle 3 is produced as a single moulding from a synthetic material, as are each of the elements forming the base 6, the cap 13 and the seat 5-21.
This elastic valve 15, which is in the shape of a flat or slightly dished annular disk, is held by a roundel 16, moulded separately and attached to the rigid base 6, or moulded integrally with this base 6, and the valve 15 acts on a seat that is advantageously but not necessarily conical 17 and forms part of the base 6. The fitting of this valve 15 between the roundel 16 and the seat 17 is such that the elastic valve 15 is normally permanently pressed against the seat 17. It allows the opening and closing of an inlet passage 18 formed in the roundel 16 or in the base 6 which the air follows after passing first through the first passage 9 and then through the filter 8.
The device as shown in
Hand pressure by a user in the direction of arrow A (
In this way a portion, dose or drop of the product is dispensed.
This dispensing of the product ceases when the user removes the pressure on the flexible portion 2 of the container 1.
At this point, the pressure on the interior of the container 1 having been removed, the valve 4 returns elastically to the rest position where it is in contact with the central part of the seat 5 and thus closes the outlet channel 10.
With the total relaxation of pressure on the flexible portion 2 of the container 1, the natural elasticity of this flexible part tends to cause it to return to its initial position in the direction of arrow B (
This pressure drop tends to keep the valve 4 closed, which is thus in firm leaktight contact with the seat 5 preventing outside air from getting in through the passage 10 and tends to raise the elastic portion of the valve 15 which lifts off the seat 17 allowing external air to enter the container through the channel 9 in the direction of arrow D, then through the filter 8 and finally through the passage 18 as shown by arrow D′.
This entry of external air stops once the internal pressure of the container 1 and the external pressure have equalized.
At this point the natural elasticity of the valve 15 causes it to return to its initial position where it is in contact with the seat 17. The whole of the device is now in equilibrium, and the product is isolated from the external atmosphere and protected from contamination.
The volume of product that has been dispensed has been replaced by an equivalent volume of filtered air.
The filter 8 may preferably have sterilizing qualities and, if the whole of the device has either been filled in sterile conditions or undergone final sterilization after being filled, the product can be kept sterile for the entire period of its use.
The manner of operation of the device shown in
The manner of operation of the device shown in
Another embodiment of the valve 4 situated in the nozzle 3 is illustrated in
a shows a construction of the nozzle 3 such that it forms its own valve by closing on itself, dispensing with the presence of a valve seat which is here no longer necessary. At the free end 24a, the ends in the form of lips of the flexible nozzle 3 spread apart when increased pressure is applied to the container 1, and thus allow the product to pass out through the passage 10. They then close on themselves when the pressure returns to normal and obstruct the passage 10 so that air cannot get into the container.
b shows another form of construction of the nozzle, similar to that shown in
This construction relating to the ends of the nozzle 3 in the form of lips may also be applied to the valve 4 shown in
a shows a variant in which the air renewal and filtration device is located in the nozzle 3. As in
b is a variant of
In
a can also include a dip tube 29 attached to a vertical or axial extension 28 of the valve seat 5. This dip tube 29, if fitted, allows the product to come as far as the outlet passage 10 and enables the whole device to be used the right way up. This construction can be applied to all the other variants described above, which can therefore be used in either position, that is to say the right way up, with the nozzle 3 at the top (see
c shows a combination of the means of
It should however be observed that the deformation of the flexible portion as shown in either
It should be observed that the residual volume of air 33 increases each time a portion of product 11 is expelled, and that the pressure increase caused by the displacement of a predetermined volume of product 11 declines as the device is used. This means that the expulsion of product 11 from the container is not effected by a constant force and dosage precision can consequently be impaired.
To overcome this problem it may be advantageous to site the additional valve 15 not in the immediate vicinity of the air renewal assembly but in the nozzle as shown in
If it is necessary to prevent all contact between the product held in the container and the filter or if the environment outside the device such as a pressure decrease or a temperature rise could lead to liquid escaping from the container through the filter, it may be helpful to provide a third valve 15′, as shown in
Referring to
It is understood that, when the user pushes the actuating portion 35, the flowable product (liquid or low viscosity product or similar substance) present in the dose-defining chamber 34 is compressed. The displaceable inner surface 25a of the nozzle 3, initially in contact with the product in the rest position of the actuating portion 35, is moved to exactly fit with the seat 5. Because of such movement toward the bottom (upward movement when considering the
It should be observed that if the device comprises a separate base 6 containing the air renewal and filtration assembly, as shown in
If the air filtration and renewal device is located in the nozzle 3 and the latter has a flexible portion 25, the container 1 may either be moulded in synthetic material or produced from a material such as glass or metal.
Other embodiments of the container 1, of the base 6, of the nozzle 3, of the respective valves or of the component acting as a spring are possible without departing from the context of the invention. For example, it is possible to make a nozzle capable of dispensing precisely quantified drops, or a spray nozzle or any other dispensing nozzle designed for any application at all, provided this nozzle is accompanied by a valve which will allow only expulsion of the product.
Referring to
In a device such as shown in
The chamber 34 shown in
To obtain the flexibility at the outer side of the chamber 34, a flexible hinge 3b or similar resilient connecting portion is provided, which extends adjacent and preferably around an outer perimeter of the actuating portion 35. Preferably, at least one of the actuating portion 35 and the stationary portion 3 have a greater thickness than such resilient connecting portion. The actuating portion 35, which is relatively thick and non-deformable, is articulated on one or more resilient and relatively thin connecting portions.
In the embodiments of
It is also understood that the internal shape of the thick actuating portion 35 perfectly fits the geometry of the opposite side of the dose-defining chamber 34 when the actuating portion 35 is pushed and configured in the engagement position.
More generally, it is understood that the relatively thick actuating portion 35 can be pushed to fully compress the product in the chamber 34 and then returns to its initial rest position under the effect of one or more thin and elastic portions when it is released.
In the embodiments of
Referring to
The thin resilient connection 36 may surround the flexible portion 25 of the nozzle 3. The actuating portion 35, optionally provided with an outer layer 40 of more rigid material, may be pushed axially (according to the direction of arrow F) as in the devices of
Compression of the product is obtained, so that a flexible portion 24 of the valve 4 is deformed between the side faces 38, 38′ and the product passes out at the free end 24a, along the end part 5a of the rod 50. As indicated by arrow C, the compressed product is expelled through passageway 10 that is also compressed when the engagement position is obtained.
As apparent in
Referring to
It should be noted that during its axial movement (see arrows F and F′ in
Now referring to
The chamber 34 may be as narrow as in the device of
The two thin elastic parts 36, 36′ are provided at outer end of the respective side faces 38, 38′ that cannot be deformed. Such faces 38, 38′ thus guide efficiently the actuating portion 35 to obtain the engagement position, after pushing it toward the central axis as shown by arrow A. Advantageously, the chamber 34 is entirely emptied once the inner surface 25 covers the abutment surface 37 that is here only defined by the rod 50 of the rigid stopper element S.
The outer contact face of the actuating portion 35 may substantially extend in continuation of the side wall of the nozzle 3 in the engagement position, as shown in
The one way valve 15 prevents any return of product to the container when the actuating portion 35 is pushed and the product compressed. The inlet passage 18′ is open when the inner surface 25a of the flexible portion 25 is displaced away from the abutment surface 37 for a return of the chamber 34 to its original shape. After the chamber 34 is filled and the rest position of the actuating portion 35 is obtained, the valve 15 remains in a closed state.
Referring to
the abutment surface 37 at the rod 50;
the two side faces 38, 38′; and
the inner surface 25a and adjacent flexible hinges defines by the thin parts 36, 36′.
It can be seen that the inner surface 25a has a concave shape that perfectly fits with the convex shape of the abutment surface 37 (same geometry to obtain full removal of product).
More generally, it is understood that the flexible portion 25 has an outer perimeter that fits with outer perimeter of the does defining chamber 34. For instance, the actuating portion 35 has a circular shape when the chamber 34 is circular and the slight difference with respect to the diameter is suppressed by deformation of the at least one resilient connecting portion (36, 36′) defined around the actuating portion 35. Of course, the geometry of the inner surface 25a and the abutment surface 37 are complementary in such case.
a-19b show a product-dispensing assembly functionally and structurally similar to the preceding embodiment, but a second layer, here an outer layer 40, is used in the actuating portion 35 to increase the global rigidity in this central part of the flexible portion 25. The outer layer 40 is made from a different material that does not deform during the pushing action. Such increase in thickness thus locally decreases the flexibility. Accordingly, the actuating portion 35 can be considered as rigid because, practically, only the thin connecting portion at 36, 36′ will deform when the user pushes the actuating portion 35. Here, the outer contact surface is entirely defined by the outer layer 40.
a-20b show a variant, in which the second layer is connected to the stationary portion 3a of the nozzle 3 by an auxiliary hinge 42 (corresponding to a flexible thin part) and is configured to pull the first layer of the actuating portion 35 outwards when the actuating portion 35 is released. Here, the stationary portion 3a is made of a material that is more rigid the plastic material used to define the flexible portions of the nozzle 3. The second layer here defines the outer layer 40 of the actuating portion 35. The stationary part 3a may comprise a first rigid piece 41 made of the rigid material (preferably plastic material) and a non-annular portion 47 that extends along the rod 50 and to which the flexible portion 35 is laterally attached. The portions 35 and 47 may be made of the same plastic material.
The nozzle 3 here comprises an operating part 3c fixed, for instance by overmolding operation, to the first rigid piece 41. The chamber 34 is defined in an interior volume of the operating part 3c. The operating part 3 and the first rigid piece 41 extend annularly around the central axis of the nozzle 3. The first rigid piece 41 defines a connecting interface directly attached to the container 1. The first rigid piece 21 cannot be compressed. The operating part 3c comprises the flexible portions of the nozzle 3 and extends axially, between the attachment area to the first rigid piece 41 and the free end of the nozzle 3.
The auxiliary hinge 42 is here defined in the first rigid piece 41 and the outer layer 40 is part of the first rigid piece 41. It is understood that the inner layer of the actuating portion 35 is secured to the outer layer 40 and follows movement of the outer layer 40.
As shown in
As the bonding at the auxiliary hinge 42 is typically stronger, it acts as a return spring, causing a pulling action of the outer layer 40 to drive the inner layer away from the abutment surface 37. The return to the original rest position is thus efficiently obtained. With such configuration, the determined volume remains constant after repeated use because of the pulling action of the outer layer 40 on the first layer (outward movement) when the actuating portion 35 is released.
More generally, the resilience and the spring-like effect at the junction between the flexible portion 25 and the stationary portion 3a is advantageous for contacting a rigid abutment surface 37 at least as large as the outer contact surface of the actuating portion 35. Moreover, the size of the dose-defining chamber 34 remains the same. The dose-defining chamber 34 thus always defines a same determined volume in the rest position of the actuating portion 35.
Use of an inner surface 25a that perfectly fits with the geometry of the abutment surface 37 is advantageous to fully expel the product contained in the dose-defining chamber 34. The product-dispensing assembly allows delivery of precise doses. When pushed to the engagement position as shown in
The device can be compact and is well adapted to supply same precise doses of liquid or low viscosity product. The device is suitable particularly in pharmaceutical, cosmetic and ophthalmological applications.
Number | Date | Country | Kind |
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04 08031 | Jul 2004 | FR | national |
This patent application is a continuation-in-part of U.S. application Ser. No. 11/572,378, filed on Jan. 19, 2007, which is a U.S. National Stage Application of PCT/FR05/001735, filed on Jul. 6, 2005, which claims priority to FR 04 08031, filed on Jul. 20, 2004, entitled “Product Packaging and Dispensing Device Comprising a Sterile Filter Bottle Which is Equipped With a Nozzle”.
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Number | Date | Country | |
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Parent | 11572378 | US | |
Child | 14185139 | US |