RU39049U1 - CONTAINER FOR STORAGE AND DELIVERY OF THE DRUG (OPTIONS) - Google Patents

Abstract

The utility model relates to packages for storing liquid substances and applying them to a treated surface, and can be used in cosmetology, medicine for applying drugs to the skin, as well as in other industries for applying various substances and processing the corresponding surfaces. The objective of this utility model is to ensure uniform distribution of the drug with a wide range of viscosities to the surface to be treated from an undeformable container for any volume of the remaining drug in it while maintaining the conductive capacity of the issued head, by equalizing the pressure in the cavity of the undeformable container with a decrease in the volume of the drug. The container according to the first embodiment contains a non-deformable container 1 with a neck 2, a transition element 3 and a dispensing head made of porous material. The transition element 3 is placed between the dispensing head and the neck 2 of the container 1. One part 4 of the dispensing head is directed into the cavity of the container 1, and the other part 5 of the dispensing head protrudes from the neck 2 of the container 1 outward. At the dispensing head is made at least one channel b of a rectilinear shape, connecting the cavity of the tank 1 with the atmosphere (Fig. 1). The container according to the second embodiment contains a non-deformable container 7 with a neck 8, a transition element 9 and a dispensing head of porous material. The transition element 9 is placed between the dispensing head and the neck 8 of the tank 7. One part 10 of the dispensing head is directed into the cavity of the tank 7, and the other part 11 of the dispensing head protrudes from the neck 8 of the tank 7 to the outside. At least one of the transition elements 9

Description

The utility model relates to packages for storing liquid substances and applying them to a treated surface, and can be used in cosmetology, medicine for applying drugs to the skin, as well as in other industries for applying various substances and processing the corresponding surfaces.

A device for storing and applying a preparation is known, comprising a non-deformable container with a neck, issued a head of porous material, installed in the neck of the container and a sealing cap placed above the neck of the container. At the same time, one part of the dispensing head protrudes outside the container, and the other part is directed into the cavity of the container. On the neck of the container there are protrusions that fix the dispensing head and prevent fluid from flowing out of the container (see European Patent Office Patent No. 0872193, A 45 34/04, publ. 21.10.1998).

A disadvantage of the known design is that the protrusions that prevent fluid from flowing out of the tank do not allow atmospheric air to enter the cavity of the tank when the pressure inside it decreases. Since the container is made of inelastic material, it is not possible to change the pressure in the cavity of the container by deformation of its walls. This leads to the fact that the issuance of the drug on the treated surface is uneven, and then completely stops. In addition, the design of the known device does not allow the widespread use of drugs with high viscosity, such as, for example, gels, oils. This is due to the fact that fluids with increased viscosity have less fluidity and their movement through the porous body without creating additional pressure inside the container is difficult, and when the pressure inside the cavity of the container decreases, it immediately stops.

A device for storing and applying a preparation is known, comprising a non-deformable container with a neck, a dispensing head made of porous material tightly installed in the neck of the container, and a sealing cap placed above the neck of the container (European Patent Office Patent No. 0435758, A 45 D 34/02, publ. . 07/03/1991 g.).

Tight installation of the issued head in the neck of a non-deformable container does not allow equalizing the pressure inside the container when dispensing the drug, which leads to the termination of its delivery to the treated surface. In addition, a tight fit in the neck of the capacity of the dispensing head leads to a change in its density and, accordingly, a change in its conductive ability. These shortcomings lead to uneven delivery of the drug to the treated surface.

The closest technical solution to the claimed utility model is a device for storing and applying a preparation containing a container with a neck in which a hole is made, a porous rod and a sealing cap, with one end of the porous rod protruding outside the container and the other directed into the cavity of the container. The capacity may be made of non-deformable material. To preserve the conductive ability of the porous rod, the device is equipped with a transition element installed in the opening of the neck of the vessel, while the transition element has a central hole in which the porous rod is located (RF certificate No. 28617 for utility model, IPC A 61 M 35/00, publ. 04/10/2003).

A disadvantage of the known design is that when a certain amount of the preparation is applied to the surface to be treated, the volume of liquid in the bottle decreases, the pressure inside the container drops. This leads to the fact that the supply of the drug through the porous rod, which serves as the dispensing head, to the treated surface is uneven, and then completely stops, which makes the device inoperative. In addition, this drawback limits the possibility of using preparations with a high viscosity in the known device for surface treatment.

The objective of this utility model is to ensure uniform distribution of the drug with a wide range of viscosity on the surface to be treated from an undeformable container for any volume of the remaining drug in it while maintaining the conductive ability of the dispensing head.

The technical result achieved by solving the task is to equalize the pressure in the cavity of the undeformable container with a decrease in the volume of the drug.

The problem is achieved in that in the container for storing and dispensing the drug according to the first embodiment, comprising a non-deformable container with a neck, a transition element and a dispensing head made of porous material, the transition element being placed between the dispensing head and the neck of the container, and one part

of the dispensing head is directed into the cavity of the container, and the other part of the issued head protrudes outward from the neck of the container, according to the utility model, at least one channel of a rectilinear shape connecting the cavity of the container with the atmosphere is made on the delivery head.

The channel is made in the form of a groove on the outer surface of the issued head and may have the same cross-sectional area or different cross-sectional area throughout the groove.

In addition, the channel can be made in the form of a through hole of the same cross-sectional area or a through hole of different cross-sectional area along the entire length of the hole.

The task is also achieved by the fact that in the container for storing and dispensing the drug according to the second embodiment, comprising a non-deformable container with a neck, a transition element and a dispensing head, the transition element being placed between the dispensing head and the neck of the container, and one part of the dispensing head is directed into the cavity capacity, and the other part of the dispensing head protrudes out of the neck of the container outward, according to a utility model, at least one channel of a straight shape is made on the transition element, connected pressure vessel cavity with atmosphere.

In this case, the channel can be made in the form of a groove on the surface covering the dispensing head or on the surface of the container covered by the neck and have the same cross-sectional area or different cross-sectional area throughout the groove.

In addition, the channel can be made in the form of a through hole of a constant cross-sectional area or a through hole of a variable cross-sectional area throughout the hole.

This object is achieved in that in the container for storing and dispensing the drug according to the third embodiment, comprising a non-deformable container with a neck, a transition element and a dispensing head, the transition element being placed between the dispensing head and the neck of the container, and one part of the dispensing head is directed into the cavity of the container and the other part of the dispensing head protrudes outward from the neck of the container, according to a utility model, at least one channel of a straight shape connecting cavity cavity with atmosphere.

In this case, the channel can be made in the form of a groove on the inner surface of the neck of the tank and have the same cross-sectional area or different cross-sectional area throughout the groove.

In addition, the channel can be made in the form of a through hole of a constant cross-sectional area or a through hole of a variable cross-sectional area throughout the hole.

The task is also achieved by the fact that in the container for storing and dispensing the drug according to the fourth embodiment, comprising a non-deformable container with a neck, a transition element and a dispensing head, the transition element being placed between the dispensing head and the neck of the container, and one part of the dispensing head is directed into the cavity capacity, and the other part of the dispensing head protrudes out of the neck of the container outward, according to a utility model, at least one step-shaped channel is made on the dispensing head, connecting the cavity of the tank with the atmosphere.

The channel can be made in the form of interconnected vertical and horizontal grooves on the outer surface of the dispensing head and have the same cross-sectional area or different cross-sectional area throughout the groove.

In addition, the channel can be made in the form of interconnected vertical and horizontal holes of the same cross-sectional area or different cross-sectional areas throughout the holes.

The task is also achieved by the fact that in the container for storing and dispensing the drug according to the fifth embodiment, comprising a non-deformable container with a neck, a transition element and a dispensing head, the transition element being placed between the dispensing head and the neck of the container, and one part of the dispensed head is directed into the cavity capacity, and the other part of the dispensing head protrudes from the neck of the container outwards, according to a utility model, at least one step-shaped channel is made on the transition element, I connect the cavity of the tank with the atmosphere.

In this case, the channel can be made in the form of interconnected vertical and horizontal grooves on the surface that covers the dispensing head or on the surface of the neck of the container and have the same cross-sectional area or different cross-sectional area throughout the groove.

In addition, the channel can be made in the form of interconnected vertical and horizontal holes of the same cross-sectional area or different cross-sectional areas throughout the holes.

The task is also achieved by the fact that in the container for storing and dispensing the drug according to the sixth embodiment, comprising a non-deformable container with a neck, a transition element and a dispensing head, the transition element being placed between the dispensing head and the neck of the container, and one part of the dispensing head is directed to the cavity of the tank, and the other part of the dispensing head protrudes from the neck of the tank outside it, according to a utility model, at least one channel of a step shape is made on the neck of the tank, connect s cavity with the atmosphere of the container.

In this case, the channel can be made in the form of interconnected vertical and horizontal grooves on the inner surface of the neck of the tank and have the same cross-sectional area or different cross-sectional area along the entire length of the groove.

In addition, the channel can be made in the form of interconnected vertical and horizontal holes of the same cross-sectional area or different cross-sectional areas throughout the holes.

The inventive combination of features of the variants of the utility model allows, while maintaining the conductive ability of the dispensing head, to compensate for the decrease in the volume of the drug inside the undeformable container with atmospheric air, which penetrates into the cavity of the container through the channel on the issued head or transition element or neck of the container, filling the vacated volume and increasing the pressure in the container cavity to atmospheric. At the same time, the rectilinear shape of the channel allows you to work most efficiently with high viscosity preparations, stepwise - with lower viscosity preparations. The stepped shape of the channel prevents the flow of a lower viscosity product due to the formation of a maze for fluid flow. At the same time, the stepped shape of the channel does not impede the free access of atmospheric air into the cavity of the tank, which contributes to an increase in pressure in it to atmospheric.

The inventive utility model is illustrated by the following drawings, where Figs. 1-6 show a container for storing and applying a preparation according to the first embodiment, an example of a dispensing head; 7-15 shows a container for storing and applying the drug according to the second embodiment, an example of a transition element; on Fig.21-21 shows a container for storing and applying the drug according to the third

option, an example of the neck of the container; on Fig-25 shows a container for storing and applying the drug according to the fourth embodiment, an example of the execution of the issued head; on Fig-31 shows a container for storing and applying the drug according to the fifth embodiment, an example of the transition element; on Fig-35 shows a container for storing and applying the drug according to the sixth embodiment, an example of the neck of the container.

The positions in the drawings indicate the following:

According to the first option: 1 - non-deformable capacity; 2 - the neck of the non-deformable container 1; 3 - transition element; 4 - part of the dispensing head directed into the cavity of the tank 1; 5 - part of the dispensing head, protruding beyond the neck 2 of the tank 1; 6 - channel of a rectilinear shape on the dispensing head.

According to the second option: 7 - non-deformable capacity; 8 - the neck of the non-deformable container 7; 9 - transition element; 10 - part of the dispensing head directed into the cavity of the tank 7; 11 - part of the dispensing head, protruding beyond the neck 8 of the container 7; 12 is a straight-line channel on the transition element 11.

According to the third option: 13 - non-deformable capacity; 14 - the neck of the non-deformable container 13; 15 - transition element; 16 - part of the dispensing head directed into the cavity of the tank 13; 17 - part of the dispensing head, protruding beyond the neck 14 of the tank 13; 18 - channel of a rectilinear shape on the neck 14 of the tank 13.

According to the fourth option: 19 - non-deformable capacity; 20 - the neck of the non-deformable container 19; 21 is a transition element; 22 - part of the dispensing head directed into the cavity of the tank 19; 23 - part of the dispensing head, protruding beyond the neck 20 of the tank 19; 24 - channel step form on the dispensing head.

According to the fifth option: 25 - non-deformable capacity; 26 - the neck of the non-deformable container 25; 27 - transition element; 28 - part of the dispensing head directed into the cavity of the container 25; 29 - part of the dispensing head, protruding beyond the neck 26 of the tank 25; 30 - channel stepped in the transition element.

According to the sixth option: 31 - non-deformable capacity; 32 - the neck of the non-deformable container 31; 33 - transition element; 34 - part of the dispensing head directed into the cavity of the tank 31; 35 - part of the dispensing head, protruding beyond the neck 32 of the tank 31; 36 - channel stepped in the neck 32 of the tank 31.

The container according to the first embodiment contains a non-deformable container 1 with a neck 2, a transition element 3 and a dispensing head made of porous material. The transition element 3 is placed between the dispensing head and the neck 2 of the tank 1. One

part 4 of the issued head is directed into the cavity of the container 1, and the other part 5 of the issued head protrudes from the neck 2 of the container 1 outwardly. At least one channel 6 of a rectilinear shape is made on the issued head, connecting the cavity of the container 1 with the atmosphere (Figs. 1-6).

Channel 6 may be made in the form of a groove on the outer surface of the issued head and may have the same cross-sectional area (Figs. 1 and 2) or different cross-sectional area (Fig. 3) along the entire length of the groove.

Channel b can be made in the form of a through hole of the same cross-sectional area (Figs. 4 and 5) or a through hole of different cross-sectional area (Fig. 6) along the entire length of the hole.

The container according to the second embodiment contains a non-deformable container 7 with a neck 8, a transition element 9 and a dispensing head of porous material. The transition element 9 is placed between the dispensing head and the neck 8 of the tank 7. One part 10 of the dispensing head is directed into the cavity of the tank 7, and the other part 11 of the dispensing head protrudes from the neck 8 of the tank 7 to the outside. At the transition element 9, at least one channel 12 of a rectilinear shape is made connecting the cavity of the tank 7 with the atmosphere (Figs. 7-15).

The channel 12 can be made in the form of a groove on the surface covering the dispensing head and have the same cross-sectional area (Figs. 7 and 8) or different cross-sectional areas (Fig. 9). The channel 12 can also be made in the form of a groove on the surface covered by the neck 8 of the container 7, and have the same cross-sectional area (FIGS. 10 and 11) or different cross-sectional area (FIG. 12) throughout the groove.

Channel 12 can be made in the form of a through hole of the same cross-sectional area (Figs. 13 and 14) or a through hole of different cross-sectional area (Fig. 15) along the entire length of the hole.

The container according to the third embodiment contains a non-deformable container 13 with a neck 14, a transition element 15 and a dispensing head of porous material. The transition element 15 is placed between the dispensing head and the neck 14 of the tank 13. One part 16 of the dispensing head is directed into the cavity of the tank 13, and the other part 17 of the dispensing head protrudes from the neck 14 of the tank 13 to the outside. At the neck 14 of the tank 13 is made at least one channel 18 of a rectilinear shape connecting the cavity of the tank 13 with the atmosphere (Fig.16-21).

The channel 18 can be made in the form of a groove on the inner surface of the neck 14 of the container 13 and have the same cross-sectional area (Fig. 16 and 17) or a different cross-sectional area (Fig. 18) throughout the groove.

Channel 18 can be made in the form of a through hole of the same cross-sectional area (Figs. 19 and 20) or a through hole of different cross-sectional area (Fig. 21) along the entire length of the hole.

The container according to the fourth embodiment contains a non-deformable container 19 with a neck 20, a transition element 21 and a dispensing head of porous material. The transition element 21 is placed between the dispensing head and the neck 20 of the tank 19. One part 22 of the dispensing head is directed into the cavity of the tank 19, and the other part 23 of the dispensing head protrudes from the neck 20 of the tank 19 to the outside. At the dispensing head is made at least one channel 24 of a stepped shape connecting the cavity of the tank 19 with the atmosphere (Fig.22-25).

Channel 24 can be made in the form of interconnected vertical and horizontal grooves on the outer surface of the dispensing head and have the same cross-sectional area (Fig. 22) or different cross-sectional area (Fig. 23) throughout the groove.

Channel 24 can be made in the form of interconnected vertical and horizontal holes of the same cross-sectional area (Fig. 24) or different cross-sectional areas (Fig. 25) along the entire length of the holes.

The container according to the fifth embodiment contains a non-deformable container 25 with a neck 26, a transition element 27 and a dispensing head of porous material. The transition element 27 is placed between the dispensing head and the neck 26 of the container 25. One part 28 of the dispensing head is directed into the cavity of the container 25, and the other part 29 of the dispensing head protrudes from the neck 26 of the container 25 to the outside. At the transition element 27 is made at least one channel 30 of a stepped shape connecting the cavity of the tank 25 with the atmosphere (Fig.26-31).

The channel 30 can be made in the form of a groove on the surface covering the dispensing head and have the same cross-sectional area (Fig. 26) or different cross-sectional area (Fig. 27) throughout the groove.

The channel 30 can also be made in the form of a groove on the surface of the neck 25 of the vessel 25 and have the same cross-sectional area (Fig. 28) or different cross-sectional area (Fig. 29) throughout the groove.

The channel 30 can be made in the form of interconnected vertical and horizontal holes of the same cross-sectional area (Fig. 30) or different cross-sectional areas (Fig. 31) along the entire length of the holes.

The container according to the sixth embodiment contains a non-deformable container 31 with a neck 32, a transition element 33 and an issued head of a porous material. The transition element 33 is placed between the issued head and the neck 32 of the tank 31. One part 34 of the issued head is directed into the cavity of the tank 31, and the other part 35 of the dispensing head protrudes from the neck 32 of the tank 31 to the outside. At the neck 32 of the tank 31 is made at least one channel 36 of a stepped shape connecting the cavity of the tank 31 with the atmosphere (Fig.32-35).

The channel 36 can be made in the form of interconnected vertical and horizontal grooves on the inner surface of the neck 32 of the tank 31 and have the same cross-sectional area (Fig. 32) or different cross-sectional area (Fig. 33) throughout the groove.

The channel 36 can be made in the form of interconnected vertical and horizontal holes of the same cross-sectional area (Fig. 34) or different cross-sectional areas (Fig. 35) along the entire length of the holes.

The container according to any of the options can be made, for example, of glass or non-deformable plastic and have a different cross-sectional shape, for example, round or ellipsoidal.

The transition element may be made of plastic, for example polyethylene.

The transition element allows you to first install the dispensing head in the transition element with a force that does not allow deformation of the porous rod. After that, the transition element, with the dispensing head located in it, is installed with great effort in the neck of the container, forming effective sealing surfaces at the contact point of the transition element with the neck of the tank and the transition element with the dispensing head. Due to the deformability of the material of the transition element, its part in contact with the neck of the container is slightly shifted in the radial direction, tightly covering the dispensing head. In this case, the seal lines expand in the transverse direction, forming a labyrinth sealing surface both between the neck of the container and the transition element, and between the transition element and the dispensing head, providing sealing of the device. In addition, the transition element allows you to maintain the integrity and quality characteristics of the porous rod, since the transition element weakens the effect on the surface of the porous

issued head compressive forces arising from its installation in the neck of the vessel.

The part of the issued head according to any of the options, protruding from the container to the outside, serves as a working tip and can have a different shape, for example, beveled at some angle, flat in the diametrical part, spherical, flat from the side of the end part. The shape of the part of the dispensing head protruding from the container to the outside is selected depending on the properties of the drug, on the procedure for applying the drug to the treated surface.

The container may be provided with a sealing cap (not shown in the drawings).

The use of a container for storage and application of the drug according to any one of the options is as follows.

To apply the drug to the surface to be treated, it is necessary to remove the sealing cap, turn the container with the dispensing head down. The drug comes into contact with the part of the dispensing head directed into the cavity of the container, and soaks it. Moreover, if the channel is made on the dispensing head (option 1 and 4), it is also filled with the drug. Due to the attractive forces acting between the pore molecules of the dispensing head and the preparation, and provided that the atmospheric pressure is equal to the pressure in the cavity of the container, the preparation is held on the surface of the dispensing head. If the channel is made on the tank or on the transition element (option 2, 3, 5 and 6), then it is blocked, for example, by pressing a finger.

The contact of the dispensing head, saturated with the preparation, with the treated surface, causes the displacement of the preparation along the porous body of the dispensed head and the release of the drug outward. Part of the drug is removed from the container, and the pressure in the cavity of the container drops.

After the procedure for applying the drug to the treated surface, the container in the opposite direction. If the channel is made on the container or on the transition element, then access to the channel must be opened (remove your finger from the hole on the container or transition element). The drug flows to the bottom of the container and opens a channel for access to atmospheric air. Atmospheric air enters the cavity of the vessel through the channel, the pressure in the cavity of the vessel equalizes, and the container is ready for reuse.

At each subsequent issue of a portion of the drug, its issued volume is replaced by atmospheric air. The performance of the container is maintained for any minimum volume of the drug remaining in the cavity of the container.

The inventive container can be used for various types of processing of various surfaces. The ability to use the entire volume of the drug allows you to store expensive drugs in a container. The design of the container provides ease of storage of the drug and ease of use. In this case, the drug is consumed economically, completely, and the user's hands remain clean.

Claims (36)

1. A container for storing and dispensing a preparation containing a non-deformable container with a neck, a transition element and a dispensing head made of porous material, the transition element being placed between the dispensing head and the neck of the container, one part of the dispensing head is directed into the cavity of the container, and the other part of the dispensing head protrudes out of the neck of the tank outward, characterized in that at the dispensing head is made at least one channel of a rectilinear shape connecting the cavity of the tank with the atmosphere. 2. The container according to claim 1, characterized in that the channel is made in the form of a groove on the outer surface of the dispensing head. 3. The container according to claim 1, characterized in that the channel has the same cross-sectional area along the entire length of the groove. 4. The container according to claim 1, characterized in that the channel has a different cross-sectional area throughout the groove. 5. The container according to claim 1, characterized in that the channel is made in the form of a through hole of the same cross-sectional area along the entire length of the hole. 6. The container according to claim 1, characterized in that the channel is made in the form of a through hole of various cross-sectional areas throughout the hole. 7. A container for storing and dispensing a preparation containing an undeformable container with a neck, a transition element and a dispensing head, the transition element being placed between the dispensing head and the neck of the container, one part of the dispensing head is directed into the cavity of the container, and the other part of the dispensing head protrudes from the neck containers outside it, characterized in that at least one channel of a rectilinear shape connecting the cavity of the container with the atmosphere is made on the transition element. 8. The container according to claim 7, characterized in that the channel is made in the form of a groove on the surface covering the dispensing head, or on the surface covered by the neck of the container. 9. The container according to claim 7, characterized in that the channel has the same cross-sectional area along the entire length of the groove. 10. The container according to claim 7, characterized in that the channel has a different cross-sectional area throughout the groove. 11. The container according to claim 7, characterized in that the channel is made in the form of a through hole of the same cross-sectional area along the entire length of the hole. 12. The container according to claim 7, characterized in that the channel is made in the form of a through hole of various cross-sectional areas throughout the hole. 13. A container for storing and dispensing a preparation containing a non-deformable container with a neck, a transition element and a dispensing head, wherein the transition element is placed between the dispensing head and the neck of the container, one part of the dispensing head is directed into the cavity of the container, and the other part of the dispensing head protrudes from the neck of the container outwardly, characterized in that at least one channel of a rectilinear shape connecting the cavity of the container with the atmosphere is made on the neck of the container. 14. The container according to item 13, wherein the channel is made in the form of a groove on the inner surface of the neck of the container. 15. The container according to item 13, wherein the channel has the same cross-sectional area throughout the groove. 16. The container according to item 13, wherein the channel has a different cross-sectional area throughout the groove. 17. The container according to item 13, wherein the channel is made in the form of a through hole of the same cross-sectional area along the entire length of the hole. 18. The container according to item 13, wherein the channel is made in the form of a through hole of various cross-sectional areas throughout the hole. 19. A container for storing and dispensing a preparation containing a non-deformable container with a neck, a transition element and a dispensing head, the transition element being placed between the dispensing head and the neck of the container, one part of the dispensing head is directed into the cavity of the container, and the other part of the dispensing head protrudes from the neck containers outside it, characterized in that at the dispensing head is made at least one channel of stepped shape connecting the cavity of the container with the atmosphere. 20. The container according to claim 19, characterized in that the channel is made in the form of interconnected vertical and horizontal grooves on the outer surface of the dispensing head. 21. The container according to claim 19, characterized in that the channel has the same cross-sectional area along the entire length of the groove. 22. The container according to claim 19, characterized in that the channel has a different cross-sectional area along the entire length of the groove. 23. The container according to claim 19, characterized in that the channel is made in the form of interconnected vertical and horizontal holes of the same cross-sectional area along the entire length of the holes. 24. The container according to claim 19, characterized in that the channel is made in the form of interconnected vertical and horizontal holes of different cross-sectional areas throughout the holes. 25. A container for storing and dispensing a preparation containing an undeformable container with a neck, a transition element and a dispensing head, the transition element being placed between the dispensing head and the neck of the container, one part of the dispensing head is directed into the cavity of the container, and the other part of the dispensing head protrudes from the neck capacity outside it, characterized in that at least one step-shaped channel is made on the transition element connecting the cavity of the container with the atmosphere. 26. The container according A.25, characterized in that the channel is made in the form of interconnected vertical and horizontal grooves on the surface covering the dispensing head, or on the surface covered by the neck of the container. 27. The container according A.25, characterized in that the channel has the same cross-sectional area along the entire length of the groove. 28. The container according A.25, characterized in that the channel has a different cross-sectional area along the entire length of the groove. 29. The container according A.25, characterized in that the channel is made in the form of interconnected vertical and horizontal holes of the same cross-sectional area along the entire length of the holes. 30. The container according A.25, characterized in that the channel is made in the form of interconnected vertical and horizontal holes of different cross-sectional areas along the entire length of the holes. 31. A container for storing and dispensing a preparation containing an undeformable container with a neck, a transition element and a dispensing head, wherein the transition element is placed between the dispensing head and the neck of the container, one part of the dispensing head is directed into the cavity of the container, and the other part of the dispensing head protrudes from the neck capacity outside it, characterized in that at least one channel of a step shape is made on the neck of the container, connecting the cavity of the container with the atmosphere. 32. The container according to p, characterized in that the channel is made in the form of interconnected vertical and horizontal grooves on the inner surface of the neck of the container. 33. The container according to p, characterized in that the channel has the same cross-sectional area along the entire length of the groove. 34. The container according to p, characterized in that the channel has a different cross-sectional area throughout the groove. 35. The container according to p, characterized in that the channel is made in the form of interconnected vertical and horizontal holes of the same cross-sectional area along the entire length of the holes. 36. The container according to p, characterized in that the channel is made in the form of interconnected vertical and horizontal holes of different cross-sectional areas along the entire length of the holes.