RU2813674C1 - Dosing device and assembly product for packaging and dosed release of product - Google Patents

Abstract

FIELD: dosing device.

SUBSTANCE: invention is related to a dosing device for dosed release of a fluid product. The device includes an outlet end, a connection end and an outlet valve located between the connection end and the outlet end and formed by an elastic element and a rigid element. The outlet valve is configured to switch between an open position, in which an outlet channel is formed between the elastic member and the rigid element, allowing the product to flow towards the outlet end, and a closed position, in which the outlet channel is closed. The outlet valve includes a first valve portion and a second valve portion. The second valve portion is located closer to the outlet end than the first valve portion. The outlet valve is configured such that a greater pressing force is applied to the rigid member by the elastic member in the first valve portion than in the second valve portion when the outlet valve is in the closed position.

EFFECT: ensuring the possibility of preventing the penetration of bacteria from the outlet hole into the outlet channel.

21 cl, 10 dwg

Description

Field of technology to which the invention relates

The invention relates to a dosing device for dispensing a flowable product in liquid, semi-liquid or suspension form, in particular to such a device which needs to be kept in a clean and sterile state. The invention also relates to a prefabricated product containing such a dosing device.

State of the art

A variety of devices are known for packaging and dispensing a fluid product. Such devices can be used in the pharmaceutical, cosmetics and food industries, in particular in the field of ophthalmology. For example, WO 2015/124844 A1 discloses a device for packaging and dispensing a generally fluid product. The described device is equipped with a check valve designed to allow the product to be released when pressure is applied to the pressure portion of the device. When the pressure is released, the check valve returns to its original position, thereby preventing outside air from entering the exhaust duct.

This device has been found to be useful in that it prevents the penetration of bacteria from the outlet into the outlet channel. However, there has also been a growing demand for sterile dispensing devices.

It is an object of the present invention to provide a dispensing device that is free from bacteria or other substances that could contaminate the contents of the dispensing device.

Disclosure of the Invention

The object of the present invention is achieved by means of a dosing device, which is defined in paragraph 1 of the appended claims and the corresponding dependent claims.

More precisely, a dispensing device for dispensing a fluid product is disclosed, comprising:

- an outlet end configured to release said product through it,

- a connecting end for attachment to a container containing said product, and

- an outlet valve located between the connecting end and the outlet end, and formed by the elastic element and the rigid element, wherein the outlet valve is switchable between an open position in which an outlet channel is formed between the elastic element and the rigid element, allowing the product to flow in the direction of the outlet end, and a closed position in which the outlet channel is closed,

and

the outlet valve comprises a first valve portion and a second valve portion, wherein the second valve portion is located closer to the outlet end than the first valve portion, wherein the outlet valve is configured such that a greater pressing force is applied to the rigid element by the elastic element in the first valve portion, than in the second valve section when the outlet valve is in the closed position.

The elastic element in the first valve portion may have greater rigidity than in the second valve portion.

The elastic element and the rigid element are configured to create a greater tension in the first valve section than in the second valve section.

The elastic element in the first portion of the valve may comprise a reinforcing element.

The elastic element in the first valve portion may have a greater thickness than in the second valve portion.

The elastic element may have an at least partially conical shape, tapering towards the outlet end.

The elastic element in the first valve portion may be made of a material that is stiffer than the material from which the elastic element in the second valve portion is made.

The elastic element may include a surface facing the rigid element that is rougher at the first valve portion than at the second valve portion.

The rigid member may include a surface facing the elastic member that is rougher at the first valve portion than at the second valve portion.

The elastic element in the outlet valve may include one or more grooves formed on a surface facing the rigid element.

The elastic element in the outlet valve may include more than one groove on the surface facing the rigid element, and the depth of an individual groove may be greater than the depth of an adjacent groove located closer to the outlet end.

The rigid element in the outlet valve may include one or more projections on a surface facing the elastic element.

The rigid element in the outlet valve may include more than one protrusion, and an individual protrusion may extend further than an adjacent protrusion located closer to the outlet end.

The dispensing device may further comprise a dispensing chamber located between the outlet valve and the connecting end, and configured to store a metered amount of product, wherein the dispensing chamber may be formed between the rigid element and the elastic element, which is spaced outward from the rigid element.

The metering chamber may at least partially have a shape that tapers towards the outlet valve.

The elastic element defining the metering chamber may comprise an internal conical portion tapering towards the outlet valve.

The rigid member defining the metering chamber may comprise an outer conical portion tapering towards the outlet valve.

The outlet channel and the outlet end may be connected by a guide channel extending substantially at right angles to the outlet channel.

The guide channel may be formed by at least one groove or at least one hole provided on or in the rigid element.

The elastic element may be positioned coaxially around the rigid element, the elastic element may include an axial projection extending beyond the rigid element and a radial projection extending radially inward from the axial projection to define an outlet opening at the outlet end.

In addition, an assembly product for packaging and dosed release of a fluid product is disclosed, containing:

- a container configured to store the product, and

- a dosing device as described in any of the preceding paragraphs.

Brief description of drawings

Embodiments of the present invention will now be described in more detail with reference to the accompanying drawings, in which:

fig. 1 is a longitudinal section showing an assembly containing a dispensing device,

fig. 2 is a longitudinal section showing the assembly of FIG. 1 when the metering chamber is compressed to release a portion of fluid product;

Fig. 3 is an enlarged view of part of the assembly of Fig. 1 around the outlet end,

fig. 4 shows exhaust ports formed on the exhaust valve seat,

fig. 5 shows a part of the valve equipped with reinforcing elements,

fig. 6 is a longitudinal section illustrating another embodiment of an assembly containing a metering device,

fig. 7 is an enlarged view of part of the assembly of FIG. 6 around the outlet end of the dispensing device,

fig. 8 is an enlarged view of part of another embodiment of the assembly around the outlet end of the dispensing device,

fig. 9 is a schematic sectional view of an exhaust valve flap equipped with annular grooves, and

fig. 10 schematically shows an exhaust valve seat equipped with projections.

Carrying out the invention

In fig. 1 illustrates by way of example an assembly 100 for packaging and dispensing a product to which the present invention is applicable. The assembly 100 can be used to package and dispense a flowable product. The flowable product may be in liquid form, semi-liquid form or suspension form.

The assembly 100 may include a container 110 and a dispensing device 10. The container 110 defines a fluid product storage chamber 112. Container 110 may be made of any suitable material for storing the fluid product in a clean and sterile condition. For example, container 110 may be made of glass or plastic. Plastics used to make the container 110 may include, but are not limited to, low-density polyethylene, high-density polyethylene, polypropylene, polyethylene terephthalate, polybutylene terephthalate, cyclic olefin polymer, or cyclic olefin copolymer. Container 110 may have an opening 114 defined for fluid communication with product storage chamber 112.

The dispensing device 10 includes a connection end 12, an outlet end 14, and an outlet valve 16 located between the connection end 12 and the outlet end 14.

The dispensing device 10 can be attached directly or via an intermediate piece to the container 110 by the connecting end 12 in a known manner, which includes, among others, precision fitting, screwing and gluing. A sealing member of a known type may be provided between the connecting end 12 and the container 110 to prevent leakage of the liquid product and contamination of the liquid product contained in the product storage chamber 112.

The dosing device 10 may include a portion loading valve 18. The batch loading valve 18 may be supported by the connecting end 12, and may be configured as a normally closed check valve. The opening 114 of the container 110 is closed by a portion of the connecting end 12 of the dispenser 10 and a portion loading valve 18. The portion loading valve 18 is configured to transfer the fluid product from the container 110 to the dispensing device 10, but not in the opposite direction. Therefore, the fluid contained in the product storage chamber 112 can flow into the dosing device 10 through the portion loading valve 18 when the latter is open, but the reverse movement of the fluid is prohibited, i.e. movement from the dispensing device 10 into the product storage chamber 112.

The dispensing device 10 may also include an air valve 20 and a filter element 22. The air valve 20 and the filter element 22 may also be supported by a connecting end 12 of the dispensing device 10. The connecting end 12 may be provided with an air passage (not shown) for connection with each other. chamber 112 and the atmosphere outside the assembly 100 through the filter element 22 and the air valve 20. The air valve 20 is a normally closed valve that opens when the pressure inside the chamber 112 decreases. Due to the filter element 22, when the air valve 20 is open, clean and fresh air may be introduced into the product storage chamber 112 to compensate for the pressure drop in the chamber 112 as a portion of the fluid product is released.

The metering device 10 may also include a metering chamber 24. The metering chamber 24 is formed by a thrust portion 26 and a deformable portion 28. The thrust portion 26 is made of a rigid material and extends between the connecting end 12 and the outlet valve 16. The rigid material used for the thrust portion 26 is can serve, among other possibilities, high-density polyethylene or polypropylene. The deformable part 28 is made of flexible material. The flexible material for the deformable portion 28 may be a thermoplastic elastomer or silicone. The deformable portion 28 may extend over and be radially spaced from the thrust portion 26 to form an annular space between the outer surface of the thrust portion 26 and the inner surface of the deformable portion 28. The metering chamber 24 may determine a set volume corresponding to a portion of the flowable product.

The metering chamber 24 may have a shape that tapers toward the outlet end 14. Alternatively, the metering chamber 24 may have a shape that tapers over its entire length in the axial direction. The tapered shape of the metering chamber 24 may be formed by an inner conical portion that is formed on the deformable portion 28 and tapers toward the outlet valve 16, and/or an outer conical portion that is formed on the thrust portion 26 and tapers toward the outlet valve 16. Outer conical portion the abutment portion 26 may face at least partially toward the inner conical portion of the deformable portion 28.

The exhaust valve 16 is formed by a flap 30 and a seat 32. The exhaust valve 30 is made of an elastic material, and the exhaust valve seat 32 is made of a rigid material. The release valve seat 32 may extend between the metering chamber 24 and the outlet end 14 in the case where the metering device 10 includes a metering chamber 24. The outlet valve gate 30 may be generally tubular in shape, and extend from the deformable portion 28 towards the outlet end 14.

A portion of the valve 30 may have a conical shape and taper towards the outlet end 14. Alternatively, the valve 30 may have a conical shape along its entire length along the seat 32 in the axial direction.

The outlet valve 16 is switchable between an open position and a closed position. In the open position, an outlet port 34 is formed between the flapper 30 and the valve seat 32 (see FIG. 3), thereby allowing fluid to move towards the outlet end 14. In the closed position, the flapper 30 abuts the seat 32, thereby closing the outlet port. 34.

The outlet valve 16 is designed as a normally closed valve. The valve flap 30 is configured such that its inner diameter (inner surface diameter) is smaller than the diameter (outer surface diameter) of the valve seat 32. Thus, the valve flap 30 is pressed against the valve seat 32, so that a pressing force is applied to the valve seat 32 from the flapper 30. Thus, a normally closed valve is formed. In the closed position, the outlet valve 16 reliably prevents the penetration of bacteria into the outlet channel 34, and prevents product residues from flowing into the dosing device 10.

The exhaust valve 16 includes a first valve section 36 and a second valve section 38. The first valve portion 36 is formed by a portion of the valve 30 or the “first valve element 40” and a corresponding portion of the seat 32 “or the first seat element 42”. The second valve portion 38 is formed by the remainder of the valve 30 or the “second valve element 44” and a corresponding portion of the seat 32 or the “second seat element 46”. The second valve portion 38 is located closer to the outlet end 14 than the first valve portion 36.

The exhaust valve 30 may be configured such that, when the exhaust valve 16 is in the closed position, a greater driving force is applied by the first valve element 40 to the first seat element 42 than is applied by the second valve element 44 to the second element. 46 saddles. As a result, the first valve element 40 offers greater resistance than the second valve element 44 to a force acting in a direction away from the corresponding seat element 42 or 46. In other words, the first shutter element 40 has a higher stiffness than the second shutter element 44.

At the outlet end 14, an opening 48 or channel may be defined through which fluid is to be released when the assembly 100 is activated.

As shown in FIG. 3, the dispensing device (FIG. 1) may include an axial projection 50 extending from the gate 30 beyond the seat 32 and a radial projection 52 extending radially inward from the axial projection 50 to form an opening 48.

In operation, the deformable portion 28 is compressed inwardly, as shown by arrows A1 in FIG. 2, to compress the metering chamber 24 (FIG. 1). Due to the fact that the portion loading valve 18 prevents the reverse movement of the fluid product into the chamber 112, the specified fluid product under pressure is forced to flow into the outlet valve 16, where the fluid product moves the valve 30 away from the valve seat 32 towards the pressing force, thereby forming between the valve 30 and the valve seat 32, the outlet port 34. When the deformable portion 28 is compressed completely, or when the deformable portion 28 comes into contact with the thrust portion 26, a metered amount of fluid product that was contained in the metering chamber 24 is ejected from the outlet end 14 through the opening 48, for example , in the form of a drop D.

Upon completion of the dispensing operation and removal of the pressure applied to the deformable portion 28, the outlet valve 16 returns to the closed position in which the flapper 30 abuts the seat 32 to close the outlet port 34.

Because the first valve portion 36 is subjected to a greater pressing force than the second valve portion 38 in the closed position, the first valve portion 36 returns to the closed position faster than the second valve portion 38. As the first valve portion 36 moves back to its original position, said first valve portion 36 pushes any remaining product beyond the first valve portion 36, and further into the second valve portion 38. When the second valve portion 38 is then returned to the closed position, the residual product is pushed out of the metering device 10 and little or no residual product remains in the outlet valve 16. At the same time, any bacteria or unwanted objects that were in the outlet channel 34 are also ejected from the dispensing device 10.

In this way, the metering device 10 is protected from any unwanted objects that might otherwise penetrate the outlet valve 16, or flow back into the first valve portion 36 from the second valve portion 38. This is particularly useful in the field of ophthalmology, where bacterial contamination of a fluid product can cause serious consequences to the user's eyes.

According to FIG. 3, the outlet valve 16 may be configured such that fluid flows from the outlet port 34 to the opening 48 through the guide channel 54. The guide channel 54 connects the outlet port 34 and the outlet end 14 with each other, and extends substantially at right angles to the outlet channel 34. In accordance with this scheme, the flowing product changes the direction of flow, the speed of its movement decreases, and the jet throw into the eye is eliminated, but at the same time the formation of a drop is ensured at the outlet end 14.

In addition, with such a guide channel 54 provided between the hole 48 and the outlet channel 34, the hole 48 has a smaller diameter than the diameter of the outlet channel 34. This facilitates the release of the droplet from the dispensing device 10. The guide channel 54 may be formed by one or more grooves, formed at the end of the exhaust valve seat 32 (see FIGS. 3 and 4). The groove(s) may be configured to extend radially and meet at a center that corresponds to the position of the hole 48. Alternatively, the exhaust valve seat 32 may be formed with a radial passage (not shown) to form a guide passage 54. Even without radial groove(s) or radial channel, a guide channel 54 can be formed between the radial projection 52 and the end of the exhaust valve seat 32.

As discussed above, when the exhaust valve 16 is in the closed position, a greater driving force is applied to the first seat member 42 by the first valve element 40 than is applied to the second seat member 46 by the second valve element 44. This configuration can be implemented in various ways.

For example, as shown in FIG. 1, the elastic element forming the deformable part 28 and the exhaust valve flap 30 may be structurally designed to have a hollow, tapering conical shape. This elastic element may also have a thickness that gradually decreases or increases towards the outlet end 14.

Alternatively or additionally, the outlet valve 16 may be configured such that the thickness of the first damper member 40 is greater than the thickness of the second damper member 44 . The thickness of the exhaust valve flap 30 is determined by the size of the flap 30 measured in a direction tangent to the contact surface (or in a direction perpendicular to the contact surface in the case of a flat contact surface) between the valve flap 30 and the valve seat 32.

According to a different or additional design, the exhaust valve 16 may be constructed such that there is a different interference fit between the first valve portion 36 and the second valve portion 38. More precisely, the first valve portion 36 can provide greater flap tension than the second valve portion 38 . For example, the interference may be in the range of 0.15-0.30 mm in the first valve section 36, and 0.05-0.2 mm in the second valve section 38. With this design, the first valve portion 36 provides a tighter fit and returns to the closed position faster than the second valve portion 38, thereby maintaining the dispensing device 10 in a clean and sterile condition.

In a different or additional design, the exhaust valve 16 may be constructed such that the first damper member 40 is made of a material that is stiffer than the material of the second damper member 44 . This design also facilitates the sequential closure of the exhaust port 34 by the exhaust valve 16.

In fig. 5 illustrates another possible design in which the exhaust valve flap 30 is provided with one or more reinforcing members 56 in the first valve portion 36. These reinforcing elements 56 are suitably spaced from each other and extend radially outward from the valve flap 30. Such reinforcing elements 56 serve to increase the rigidity of the first valve portion 36 relative to the second valve portion 38 . The reinforcing elements 56 may be the same shape or may differ in shape from each other depending on the required rigidity.

In fig. 6 and 7 show another example of an assembly 200 for packaging and dispensing a fluid product. The assembly 200 includes a container 110 and a dispensing device 10. The assembly 200 is different from the assembly 100 shown in FIG. 1, in that the metering device 10 does not include a metering chamber 24, and the elastic element forming the exhaust valve flap 30 is located radially within the rigid element forming the exhaust valve seat 32.

In this embodiment, the container 110 is made of an elastic material, and thus the pressure of the fluid inside the container 110 can change when a compressive force is applied to the container 110. When the chamber 112 of the container 110 is compressed, the fluid contained in the container 110 is forced towards the outlet valve 16 to open the outlet passage 34.

As shown by the arrows in FIG. 7, through an opening 60 formed in the base, fluid flows into the guide channel 54. The fluid, under the influence of increased pressure, forces the valve flap 30 away from the seat 32 to form an outlet channel 34. The fluid is introduced into the outlet channel 34 and released at the outlet end. 14, which is also shown by arrows in FIG. 7.

Similarly, as in the above-discussed embodiment, the exhaust valve 16 of this embodiment may be configured such that a greater driving force is applied to the first valve portion 36 than to the second valve portion 38 when the exhaust valve is in the closed position.

Therefore, when the pressure previously applied to the container 110 is released, the first valve portion 36 returns to its original position, with the first valve portion 36 pushing the remaining product out of the first portion 36 and further into the second valve portion 38. When the second valve portion 38 then returns to the closed position, the product residues are pushed out of the dispensing device 10 and little or no product residue remains in the outlet passage 16. At the same time, any bacteria or unwanted objects that were present in the outlet channel 34 are also expelled from the dispensing device 10.

In this way, the dispensing device 10 can be protected from any unwanted objects that might otherwise penetrate the outlet valve 16, or flow back into the first valve portion 36 from the second valve portion 38.

In fig. 8 depicts another example of an assembly 300 for packaging and dispensing a fluid product. The assembly 300 in this embodiment differs from the assembly 200 shown in FIGS. 6 and 7 in that the outlet 34 must be formed in a direction perpendicular to the opening 48 at the outlet end 14, or in a radial direction.

According to this embodiment, the product storage chamber 112 of the container 110 is compressed and the fluid product is forced to flow into the guide channel 54 through the hole 62 formed in the elastic member forming the outlet valve flap 30. The guide channel 54 extends perpendicular to the outlet channel 34 formed between the flapper 30 and the valve seat 32. Likewise, as in the embodiments discussed above, the fluid pressure is sufficient to move the valve 30 away from the seat 32 and form the outlet channel 34.

Similarly, as in the above-discussed embodiment, the exhaust valve 16 of this embodiment may be configured such that a greater pressing force is applied to the first valve portion than to the second valve portion when the exhaust valve 16 is in the closed position.

Therefore, when the pressure previously applied to the container 110 is released, the first valve portion 36 returns to its original position, with the first valve portion 36 pushing the remaining product out of the first portion 36 and further into the second valve portion 38. When the second valve portion 38 then returns to the closed position, the product residues are pushed out of the dispensing device 10 and little or no product residue remains in the outlet passage 16. At the same time, any bacteria or unwanted objects that were present in the outlet channel 34 are also expelled from the dispensing device 10.

In this way, the dispensing device 10 can be protected from any unwanted objects that might otherwise penetrate the outlet valve 16, or flow back into the first valve portion 36 from the second valve portion 38.

When the stiffness of a valve flap made of elastic material is increased, higher pressure is required to open the normally closed valve and form an outlet passage between the flapper and the corresponding valve seat. For dispensing devices, it is important to find the proper balance between the tightness of the dispensing device seal and the ease of actuation when releasing the product.

To reduce the force required to lift the valve flap away from the seat, the flapper 30 may be provided with one or more grooves, such as annular groove(s) 70 formed on the surface facing the valve seat 32. As shown in FIG. 9, multiple annular grooves 70 may be provided in the case where the shutter 30 has a tubular shape. If the surface of the shutter 30 runs parallel to the valve seat (see FIG. 8), then one or more elongated grooves may be formed on the shutter 30. The depth of such a groove can be a maximum of 0.10 mm. The grooves 70, up to 0.10 mm deep, help the flapper to move away from the seat 32, and at the same time, the accumulation of product residues in the grooves is avoided.

On the other hand, the grooves 70 can have a depth of up to 0.40 mm. In this case, the shutter 30 may not come into contact with the seat 32 in areas where the grooves 70 are formed.

In the case where more than one groove is provided, the depth of an individual groove can be made greater than that of an adjacent groove that is located closer to the outlet end 14, and thereby the force required to open the first valve portion 36 can be reduced.

Also, thanks to one or more grooves 70, the fluid product is distributed evenly in a circular direction, i.e. There are 32 valves around the seat, helping the exhaust valve move to the open position.

Instead of or in addition to one or more grooves on the exhaust valve, one or more projections 72 may be formed on the surface of the seat 32 facing the valve 30. In FIG. 10 depicts an embodiment of the invention in which the exhaust valve seat 32 is provided with more than one projection 72. If more than one projection 72 is provided, an individual projection may extend further than an adjacent projection located closer to the outlet end.

Said groove(s) or protrusion(s) can help regulate the tightness of the valve 30 to the valve seat 32. Consequently, less force may be required to retract the flapper 30 from the valve seat 32, thereby facilitating the formation of the exhaust port 34.

Although not shown, in accordance with an embodiment of the invention, the surface of the exhaust valve flap 30 facing the valve seat 32 has a greater roughness in the area of the first flapper element 40 than in the area of the second flapper element 44. The roughness may be in the range of 3-5 μm in the first section 36 of the valve. The roughness in the second valve section 38 may be in the range of 0.3-3 μm to prevent bacteria from sticking to the second valve section 38. In contrast, the valve seat 32 may have a smooth surface.

On the other hand, the exhaust valve seat 32 may have different levels of surface roughness facing the valve flap 30 between the first valve portion 36 and the second valve portion 38. More specifically, the valve seat 32 may have a higher roughness in the first valve portion 36 than in the second valve portion 38 . In this case, the valve blade 30 may have a smooth surface. Because a rough-surface-smooth-surface pair operates between the flapper 30 and the valve seat 32, less force is required to move the flapper 30 away from the valve seat 32, thereby facilitating the formation of the exhaust port 34.

In the case where the exhaust valve 30 and/or exhaust valve seat 32 have a predetermined level of surface roughness, the rough surface of the valve 30 and/or seat 32 may alternate with a smooth mating surface.

In addition, the metering chamber 24 may have a shape that tapers towards the outlet valve 16, as shown in FIG. 1. Due to the fact that the metering chamber 24 has a tapering shape, when the fluid contained in the metering chamber 24 flows into the outlet valve 16, the pressurized liquid creates an outward pushing force to help move the valve flap 30 away from the seat 32. Therefore, it can be The outlet channel 34 is securely and easily formed.

Claims (28)

1. Dosing device (10) for dosed release of a fluid product, containing: - outlet end (14), configured to release said product through it, - a connecting end (12) for attachment to a container (110) containing said product, and - an outlet valve (16) located between the connecting end (12) and the outlet end (14) and formed by an elastic element (28,30) and a rigid element (26, 32), wherein the outlet valve (16) is switchable between an open position, in which an outlet channel (34) is formed between the elastic element (28, 30) and a rigid element (26, 32), allowing the product to flow towards the outlet end (14), and a closed position, in which the outlet channel (34) closed, characterized in that the outlet valve (16) includes a first valve portion (36) and a second valve portion (38), wherein the second valve portion (38) is located closer to the outlet end (14) than the first valve portion (36), wherein the outlet valve (16) ) is designed so that a greater pressing force is applied to the rigid element (26, 32) from the side of the elastic element (28, 30) in the first valve section (36) than in the second valve section (38) when the outlet valve (16) is in closed position. 2. Device (10) according to claim 1, characterized in that the elastic element (28, 30) in the first section (36) of the valve has greater rigidity than in the second section (38) of the valve. 3. Device (10) according to claim 1 or 2, characterized in that the elastic element (28, 30) and the rigid element (26, 32) are designed to create a greater tension in the first section (36) of the valve than in the second section (38) valve. 4. Device (10) according to any one of claims. 1-3, characterized in that the elastic element (28, 30) in the first section (36) of the valve contains a reinforcing element (56). 5. Device (10) according to any one of claims. 1-4, characterized in that the elastic element (28, 30) in the first section (36) of the valve has a greater thickness than in the second section (28) of the valve. 6. Device (10) according to any one of claims. 1-5, characterized in that the elastic element (28, 30) has an at least partially conical shape, tapering towards the outlet end (14). 7. Device (10) according to any one of claims. 1-6, characterized in that the elastic element (28, 30) in the first section (36) of the valve is made of a material that is more rigid than the material from which the elastic element (28, 30) in the second section (38) of the valve is made. 8. Device (10) according to any one of claims. 1-7, characterized in that the elastic element (28, 30) contains a surface facing the rigid element (26, 32), which has a greater roughness in the first valve section (36) than in the second valve section (38). 9. Device (10) according to any one of claims. 1-8, characterized in that the rigid element (26, 32) contains a surface facing the elastic element (28, 30) having a greater roughness in the first valve section (36) than in the second valve section (38). 10. Device (10) according to any one of claims. 1-9, characterized in that the elastic element (28, 30) in the outlet valve (16) contains one or more grooves (70) formed on a surface facing the rigid element (26, 32). 11. Device (10) according to claim 10, characterized in that the elastic element (28, 30) in the outlet valve (16) contains more than one groove (70) on the surface facing the rigid element (26, 32), with In this case, the depth of an individual groove is greater than the depth of the adjacent groove located closer to the outlet end (14). 12. Device (10) according to any one of claims. 1-11, characterized in that the rigid element (26, 32) in the outlet valve (16) contains one or more projections (72) on a surface facing the elastic element (28, 30). 13. Device (10) according to claim 12, characterized in that the rigid element (26, 32) in the outlet valve (16) contains more than one projection (72), with an individual projection protruding further than an adjacent projection located closer to the outlet end (14). 14. Device (10) according to any one of claims. 1-13, characterized in that it further comprises a metering chamber (24) located between the outlet valve (16) and the connecting end (12), and configured to store a measured amount of product, wherein the metering chamber (24) is formed between the rigid element ( 26) and an elastic element (28), which is spaced outward from the rigid element (26). 15. Device (10) according to claim 14, characterized in that the dosing chamber (24) at least partially has a shape tapering towards the outlet valve (16). 16. Device (10) according to claim 15, characterized in that the elastic element (28, 30) defining the dosing chamber (24) contains an internal conical section tapering towards the outlet valve (16). 17. Device (10) according to claim 14 or 15, characterized in that the rigid element (26) defining the dosing chamber (24) contains an outer conical section tapering towards the outlet valve (16). 18. Device (10) according to any one of claims. 1-17, characterized in that the outlet channel (34) and the outlet end (14) are connected by a guide channel (54) extending substantially at right angles to the outlet channel (34). 19. Device (10) according to claim 18, characterized in that the guide channel (54) is formed by at least one groove or at least one hole made on or in the rigid element (26, 32). 20. Device (10) according to any one of claims. 1-19, characterized in that the elastic element (28, 30) is located coaxially around the rigid element (26, 32), and the elastic element (28, 30) contains an axial protrusion (50) extending beyond the rigid element (26, 32 ), and a radial projection (52) extending radially inward from the axial projection (50) to define an outlet opening (48) at the outlet end (14). 21. Assembled product (100, 200) for packaging and dosed release of a fluid product, containing: - a container (110) configured to store the product, and - dosing device (10) as described in any of the previous paragraphs.

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