RU25276U1 - LIQUID STORAGE AND DRIPPING CONTAINER - Google Patents

Abstract

to the description of the utility model

LIQUID STORAGE AND CHANNEL DOSING CONTAINER

The utility model relates to the field of polymer packaging and can be used in medicine, veterinary medicine, cosmetology and other industries for packaging and drip dosing of liquid, semi-liquid or gel-like materials and preparations.

The task is to ensure a guaranteed drip fluid supply with excess pressure on the walls of the tank.

The container for storing and drip dosing of liquid contains an elastic container with a neck closed by a cap, in which a nozzle with a droplet-forming channel is installed. In the neck of the vessel, a diaphragm overlapping it is made with at least one capillary hole.

The nozzle can be made in the form of a glass equipped with a tip coaxially located in it, which is interfaced with the inner surface of the bottom of the glass. The nozzle is oriented in the neck of the container with the outer surface of the bottom towards the diaphragm, and a drop-shaped; the channel is located in the tip. The longitudinal axis of symmetry of the capillary hole and drop-like; its nozzle channel are offset relative to each other and the offset value is (0,, 45) D, where D is the diameter of the diaphragm.

1 N.P.F., 4 Z.P.F., 4 ill.

ESSAY

Description

MPK-7: A 61J 01/00 V 65D 47/18

LIQUID STORAGE AND CHANNEL DOSING CONTAINER

The utility model relates to the field of polymer packaging and can be used in medicine, veterinary medicine, cosmetology and other industries for packaging and drip dosing of liquid, semi-liquid or gel-like materials and preparations.

Known sealed elastic container for storing and supplying a medicinal substance, containing a housing of elastically deformable material with a tubular tip, sealed from the end and equipped with a protective cap having an element for opening the end of the tubular tip and with a sealing assembly (see USSR copyright certificate No. 1835286, IPC A61J 1/00, published on 08.23.1993). To depressurize a container by piercing its wall, a needle is made in the protective cap. Before using the container, the protective cap is located on the tubular tip so that the needle does not reach the container wall. To access the drug, the cap is advanced along the tip to puncture the wall of the container. After that, they squeeze the walls of the container with their fingers, displacing the contents.

A design drawback of the known elastic container is that for accurate drop formation it is necessary to regulate the force of the fingers on the container wall, since when the fingers exert pressure on the container wall, the liquid flows out, which leads to unjustified consumption of the drug and the impossibility of accurately counting the required amount of the drug .

Also known is a container for liquids containing a hollow body mating with a neck, a sleeve located on the neck and made with an external thread, and a protective cap, while the sleeve has an outlet opening, divided along the perimeter into two parts by a sealed partition, one part being holes face in the neck

the housing, and the other to the outside, on the inner surface of the housing at the interface with the sealed partition, a drip channel of liquid is formed, and a pin is provided on the inner surface of the protective cap that enters the outer part of the bore of the sleeve (see US Patent No. 5464122, IPC A 61F 9 / 00, B 65D 51/22, publ. 11/07/1995). The protective cap is installed on the thread of the sleeve, while the cap pin is placed in the outer part of the hole of the sleeve at a certain distance from the sealed partition. To open the container, it is necessary to turn the protective cap along the sleeve. In this case, the cap pin, moving axially along the bore of the sleeve, exerts pressure on the highest attachment point of the sealed partition, shifts it down, opening the outlet from the drip dosing channel located on the inner surface of the housing. Next, the cap is screwed from the sleeve and the liquid from the cavity of the container body through the drip dosing channel flows into the external outlet of the sleeve and further out.

A disadvantage of the known container is that when pressure is exceeded on the container body, liquid can escape by a stream. This leads to an unjustified consumption of the drug and its overdose, which is not permissible in the treatment of certain diseases.

Known nozzle for the droplet distribution of drugs, made in the form of a sleeve installed in the neck of an elastic bottle, including an elongated channel with an inlet diameter smaller than the diameter of the outlet (see EPO patent No. 0956904, IPC B 65D 47/18, publ. 17.11. 1999). The size of the droplet formed under pressure on the bottle body is determined by the length of the elongated channel, which is calculated by selecting the diameters of the inlet and outlet of the channel and the angle between the vertical axis and the inner wall of the channel.

However, when exposed to the walls of the vessel with the hand of the user, the dropping process becomes uncontrollable. This can lead to an overdose and unjustified consumption of the drug if the pressure on the walls of the bottle is exceeded, and if the pressure on the bottle walls is not enough, a drop will not form.

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Also known is a container for medicines containing an elastic container with a neck, a sleeve installed in the neck with a drop-forming tip, in which a channel is made, the diameter of the inlet of which is smaller than the outlet (see US patent No. 6076709, IPC B 65D 47/18, publ. 06/20/2000).

In a known container, the pressure exerted on the container body directly affects its contents, therefore, with pressure drops, the droplet formation process becomes unregulated.

The closest technical solution to the claimed is a well-known container for medicines containing an elastic container with a neck closed by a cap, inside of which there is a sleeve with a droplet-forming tip, in which a channel with inlet and outlet openings is located, while an annular protrusion is made on the channel outlet (see EPO patent. No. 0431885, IPC B 65D 47/18, publ. 06/12/1991).

In a known container, the size of the droplets of different viscosities and surface tension of the liquids generated when the fluid flows from the tank depends on the geometric parameters of the channel of the droplet forming tip. However, when the pressure exerted externally on the walls of the elastic container container increases, the pressure on the liquid inside the container increases accordingly and the rate of liquid outflow through the drop-forming channel increases. This leads to the fact that the liquid flows out of the stream, which prevents the dosage of the drug.

The objective of this utility model is to provide a guaranteed drip fluid supply at overpressure on the walls of the tank.

The technical result is a decrease in the pressure of the liquid located in the immediate vicinity of the droplet-forming channel, leading to a decrease in the rate of fluid flow through the droplet-forming channel.

This object is achieved in that in a known container for drip dosing of liquid, containing an elastic container with a neck closed by a cap, in which a nozzle with a droplet-forming channel is installed, according to a utility model, a diaphragm with at least one capillary opening overlapping it is made in the container neck .

It is advisable that the nozzle was made in the form of a cup equipped with a tip coaxially located in it, which is mated to the inner surface of the bottom of the cup, while the nozzle is oriented in the neck of the container with the outer surface of the bottom to the diaphragm, and the droplet-forming channel is located in the tip. The nozzle can be installed in the neck of the container with the formation of a gap between the outer surface of the bottom of the glass and the diaphragm.

In addition, the longitudinal axis of symmetry of the capillary hole and the droplet-forming channel are mixed relative to each other, and the displacement of the longitudinal axis of symmetry of the capillary hole of the diaphragm and the droplet-forming channel is (0,, 45) D, where D is the diameter of the diaphragm.

The execution in the neck of the container diaphragm with a capillary hole dramatically reduces the flow area of the neck. This makes it possible to control the rate of fluid outflow through the droplet-forming nozzle channel by dosing the pressure of the fluid flow coming from the reservoir to the outside, providing an adjustable and guaranteed drip fluid supply through the droplet-forming channel at any pressure on the walls of the reservoir.

The mutual arrangement of the longitudinal axes of symmetry of the capillary hole and the droplet-forming channel eliminates the possibility of direct liquid from the capillary opening to the droplet-forming channel, which also helps to control the rate of fluid flow through the droplet-forming channel of the nozzle.

The shape of the nozzle and its location in the neck determine the volume of liquid in front of the drop-forming channel, which also helps to reduce the pressure of the liquid passing through the drop-forming channel.

The inventive utility model is illustrated by the following drawings: figure 1 shows a container for storing and drip dosing of liquid, General view, cross section; in FIG. 2 - remote element I in FIG. 1, the axis Oj-Oi denotes the longitudinal axis of symmetry of the capillary hole, the axis O2-O2 denotes the longitudinal axis of symmetry of the droplet-forming channel; in FIG. 3 shows a cross-sectional view of the container and nozzle disassembled; in FIG. 4 shows a cross-sectional view of the container at the time of droplet formation, arrows indicate the direction of application of pressure on the walls of the container and the direction of fluid movement at the time of droplet formation.

The positions in the drawings indicate the following: 1 - elastic capacity; 2 neck; 3 - nozzle; 4 - drop-forming channel in the nozzle 3; 5 and 6 - inlet and outlet of the droplet-forming channel 4 of the nozzle 3; 7 - aperture; 8 capillary hole in the diaphragm 7; 9 - tip; 10 - the bottom of the glass; 11 and 12 - the inner and outer surfaces of the bottom 10 of the glass; 13 - hold; th flange of the nozzle 3; 14 - a cap.

The container for drip dosing of liquid contains an elastic container 1 with a rigid neck 2, in which a nozzle 3 with a drop-forming channel 4 is installed. The drop-forming channel 4 has an inlet 5 and an outlet 6 holes. The size of the inlet 5 is smaller than the size of the outlet 6. The selection of the sizes of the holes 5 and 6 is drop-forming, its channel 4 controls the process of droplet formation of liquids of different viscosity and surface tension.

In the neck 2 of the tank 1 is made overlapping, its diaphragm 7 with a capillary hole 8.

The nozzle 3 can be made in the form of a cup with a tip 9 coaxially located in it. In this case, the tip 9 is mated with the bottom 10 of the cup on its inner surface 11. The nozzle 3 is installed in the neck 2 of the tank 1 so that the outer surface 12 of the bottom 10 is facing to the diaphragm 7 with the formation of a gap between them. Drop-forming channel 4 is located in the tip 9.

The longitudinal axis of symmetry OpOi of the capillary hole 8 and the longitudinal axis of symmetry O2-O2 of the droplet-forming channel 4 are displaced relative to each other, and the displacement is (0,, 45) D, where D is the diameter of the neck 2 of the vessel 1. Displacement of the longitudinal axis of symmetry of the capillary hole 8 and the droplet forming channel 4 by a value less than 0.25D leads to a significant convergence of the capillary hole 8 and the inlet 5 of the droplet forming channel 4, which worsens the conditions for reducing the pressure of the liquid passing through the droplet forming channel 4. Longitudinal axis offset

the symmetry of the capillary hole 8 and the droplet-forming channel 4 by a value greater than 0.45D is impractical, since the capillary hole 8 will shift beyond the diaphragm 7, which will lead to its inoperability.

To eliminate the possibility of lowering the nozzle 3 directly onto the diaphragm 7 and to create a gap on the nozzle 3, a holding flange 13 is made.

To ensure tightness during storage and transportation of the liquid, the container is equipped with a cap 14 mounted on the neck 2 of the tank 1.

The container works as follows.

The user presses the walls of the container with his hand 1. In this case, the volume of liquid in the container rests against the diaphragm 7 and through its capillary hole 8 flows into the gap between the diaphragm 7 and the outer surface 11 of the bottom 10 of the nozzle 3, from where it enters the inlet 5 of the droplet-forming channel 4 at the tip 9. The pressure applied to the walls of the tank 1 is transferred to the fluid in it, which, in turn, exerts pressure on the diaphragm 7. When the fluid flows through the capillary hole 8, the pressure drops, and the process ss drop formation is stable.

The user counts out the required number of drops and stops applying pressure to the walls of the container 1. In this case, the walls of the container 1 take their initial position, and the liquid remaining in the drop-forming channel 4 is sucked back into the container 1.

Using the proposed container for storage and drip dosing of liquid allows for an adjustable and guaranteed drip supply of liquid at any pressure on the walls of the tank.

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Claims (5)

1. A container for storing and drip dosing of liquid, containing an elastic container with a neck closed by a cap, in which a nozzle with a droplet-forming channel is installed, characterized in that a diaphragm overlapping it with at least one capillary hole is made in the container neck.  2. The container according to claim 1, characterized in that the nozzle is made in the form of a cup equipped with a tip coaxially located in it, which is mated to the inner surface of the bottom of the cup, while the nozzle is oriented in the neck of the tank with the outer surface of the bottom to the diaphragm, and the drop-forming channel is located at the tip.  3. The container according to claim 1, characterized in that the longitudinal axis of symmetry of the capillary hole and the droplet-forming channel of the nozzle are offset relative to each other.  4. The container according to claims 2 and 3, characterized in that the displacement of the longitudinal axis of symmetry of the capillary hole of the diaphragm and the droplet-forming channel is (0.25-0.45) D, where D is the diameter of the diaphragm. 5. The container according to claim 1, characterized in that the nozzle is installed in the neck of the container with the formation of a gap between the outer surface of the bottom of the glass and the diaphragm.