RU142539U1 - AEROSOL CYLINDER CAP - Google Patents

Abstract

The cap of the aerosol can, made in the form of a hollow body, open on the installation side of the aerosol can, and containing a fixing collar in the area of its installation on the inner surface, on the end surface of the cap there is a push element in the form of a petal, on the inner surface of which there is a pipe with a channel for placing inside the outlet tube of the aerosol can communicated through the outlet channel with a throttle sleeve located at the outlet for spraying the aerosol composition into the external environment, mentioning the nipple is located mainly perpendicular to the end surface of the cap with the possibility of moving the aerosol can tube and thereby communicating the inner space of the can with the external medium through the throttle sleeve, while the convex section of the petal is equipped with a voltage compensator made in the form of an arcuate recess located on its peripheral section adjacent to to the pipe.

Description

Technical field

The proposed utility model relates to the field of packaging materials, preferably intended for use in vessels having one or two neck valves, flanges or fittings for transporting, storing and using compressed, liquefied or dissolved under pressure gases, and is an initiating cap designed for supplying contents to the external environment by gas pressure from the inside.

State of the art

The initiating cap of an aerosol can is known from the prior art (see MX 2013002100, class B65D 83/22, publ. 2013 [1]).

The known cap [1] is made in the form of a hollow body, open on the installation side of the aerosol can, the surface of the cap is made in the form of a pressure element, from the inner surface of which there is a pipe with a channel that is communicated through the output channel with the throttle spray sleeve located at the output, the nozzle is perpendicular to the surface of the cap, while the nozzle is made wider than the outlet channel.

To communicate the internal space of the container with the external environment, it is necessary to press on the pressure element, while due to the particular design of the cap, the direction of movement of the nozzle when pressing the pressure element is not provided strictly vertically, which can lead to premature damage to the tube and, accordingly, to the termination of the functioning of the aerosol container.

The initiating cap of an aerosol can is known from the prior art (see DE 102004057702, class B65D 83/20, publ. 2006 [2]).

The known cap [2] of the aerosol can is made in the form of a hollow body, which is open from the side of the installation on the aerosol can, while in the installation area of the cap on its inner surface a fixing collar is made, on the end surface of the cap there is a pushing element in the form of a petal, inside the cap there is a nozzle with a channel for placement inside the outlet tube of the aerosol can, communicated through the outlet channel with a sleeve located at the outlet of the throttle aerosol composition, the nozzle is placed the ability to move the tube of the cylinder and thereby communicating the internal space of the cylinder with the external medium through the throttle sleeve, while the pipe is made wider than the output channel.

In the known solution [2], a hole is made in the side wall of the cap, into which a throttle sleeve is inserted and a horizontal outlet channel is laid, turning into a vertically oriented pipe, forming a L-shaped element, the movement of which is carried out by means of a protrusion made on the inner surface pressure element.

The said protrusion of the pressing element, when pressed on the last, is in contact with the output channel in its central part, which forces the user to create additional force to launch the aerosol composition into the environment, and in addition there is a deviation of the L-shaped element from a strictly vertical position, which can contribute to damage to the tube and, as a result, termination of the correct functioning of the aerosol can.

The closest analogue of the proposed utility model is the initiating cap of the aerosol can, known from US 2010044401, class. B65D 83/20 publ. 2010 [3].

The well-known cap [3] is made of a hollow body, open from the side of the installation on an aerosol can, while in the zone of installation of the cap on its inner surface a fixing collar is made, on the end surface of the cap there is a pressure element with a pipe with a channel for placement inside the tube nozzle of the aerosol can, communicated through the outlet channel with a sleeve located at the outlet of the throttle spray aerosol composition, the nozzle is perpendicular to the end face the surface of the cap with the possibility of moving the tube of the aerosol can and thereby communicating the internal space of the can with the external medium through the throttle sleeve, the nozzle being made wider than the outlet channel.

In the known closest analogue, the movement of the pipe during the initialization of the composition occurs almost completely vertically, because the area for pressing the key is located above the end of the nozzle, which ensures its predominantly vertical movement and generally reliable functioning of the cap. However, the key of the cap for initiating the aerosol composition, in which the outlet channel with the nozzle passes, is made on one side with a significant thickening, which is associated with an increase in the amount of consumables in the manufacture of this aerosol cap.

Utility Model Disclosure

The objective of the proposed utility model is to create a cap of an aerosol can having improved production and technical and operational characteristics.

The technical result of the proposed utility model is the reduction of material consumption and increased reliability during operation of the proposed aerosol can cap.

This task and the technical result are achieved in that the cap of the aerosol can is made in the form of a hollow body open from the side of the installation on the aerosol can. The cap of the aerosol can contains a fixing collar in the area of its installation on the inner surface, on the end surface of the cap there is a presser element in the form of a petal, on the inner surface of which there is a nozzle with a channel for placement inside the exit tube of the aerosol can communicated through the output channel with the throttle at the output a sleeve for spraying an aerosol composition with an external medium, said nozzle is located mainly perpendicular to the end surface of the cap with the possibility of moving the tube of the aerosol can and communicating, thereby, the internal space of the can with the external medium through the throttle sleeve, while the convex section of the petal is equipped with a voltage compensator made in the form of an arcuate recess located on its peripheral section adjacent to the nozzle.

Thus, as a result of the fact that the proposed cap is made in the form of a hollow body that contains fixing flanges, the pressure element is made in the form of a petal, from the inner surface of which there is a pipe with a channel for placement inside the outlet tube of the aerosol can, communicated through the inlet channel with at the outlet a throttle sleeve for spraying the aerosol composition with the external environment, the nozzle is perpendicular to the end surface of the cap with the ability to move the aerosol tube th cylinder and communication, thereby, the inner space of the cylinder with the external environment through the throttle sleeve, and also due to the fact that the convex section of the petal is equipped with a voltage compensator made in the form of an arcuate recess located on its peripheral section adjacent to the nozzle reduces material consumption at the manufacture of an aerosol cap, as well as increased reliability during its operation.

These signs of the proposed aerosol cap form a set of essential features necessary and sufficient to achieve a technical result, which consists in reducing material consumption and increasing reliability during operation, which will accordingly improve the production characteristics of the cap, as well as its technical and operational characteristics.

Brief Description of the Drawings

The figure 1 shows a longitudinal section of the proposed cap of the aerosol can.

Utility Model Implementation

The utility model is illustrated by a specific implementation example, which, however, is not the only possible, but clearly demonstrates the achievement of a given set of essential features of a given technical result.

The figure 1 shows the side wall 1 of the cap of the aerosol can, the housing 2 of the aerosol can, the inner surface 3 of the side wall of the cap, the fixing flanges 4, the pressure element 5, made in the form of a petal, pipe 6, channel 7 of the pipe, tube 8 of the aerosol can, output channel 9, throttle bushing 10 and voltage compensator 11.

The cap of the aerosol can is made in the form of a hollow body open on the installation side of the aerosol can. The cap contains, in the area of its installation, fixing flanges 4 on its inner surface. On the end surface of the cap there is a press element 5, made in the form of a petal, from the inner surface of which the nozzle 6 with channel 7 is located. Inside the channel 7 there is an aerosol outlet tube 8 balloon. The channel 7 of the pipe 6 is communicated through the output channel with the throttle sleeve 10 located at the output with the external environment. The throttle sleeve 10 is designed to spray aerosol composition. The pipe 6 is located mainly perpendicular to the end surface of the cap and is made with the possibility of moving the tube 8 of the aerosol can and communicating, thereby, the internal space of the can with the external medium through the throttle sleeve 10. The convex section of the pressure element 5 is equipped with a voltage compensator 11, made in the form of an arcuate recess, located on its peripheral section adjacent to the pipe 6.

An aerosol can equipped with the proposed cap operates as follows.

When the user's finger presses on the convex section of the pressure element 5 made in the form of a petal, the nozzle 6 makes a vertical movement towards the end of the balloon, thereby moving the balloon tube 8, thereby initiating the release of the aerosol composition into the external environment through the throttle sleeve 10.

Thus, the reduction of material consumption, as well as increased reliability during operation of the proposed cap is achieved as a result of the fact that:

- The cap is hollow and contains a fixing collar 4 in the area of its installation on the aerosol can;

- on the end surface of the cap there is a pressing element in the form of a petal 5, from the inner surface of which there is a nozzle 6 with a channel 7 for placement inside the outlet tube 8 of an aerosol can, communicated through the outlet channel 9 with a throttle sleeve 10 located at the outlet for spraying the aerosol composition with an external environment;

- the pipe 6 is located mainly perpendicular to the end surface of the cap with the ability to move the tube 8 of the aerosol can with the external medium through the throttle sleeve 10;

- the convex section of the petal 5 is equipped with a voltage compensator 11, made in the form of an arcuate recess located on its peripheral section adjacent to the pipe 6.

Aerosol containers containing the caps offered for them will find wide application in industry, in particular, they are suitable for use in the field of household chemicals, as well as in the field of decoration, paint and varnish, in the field of construction, perfumery, etc.

Claims (1)

The cap of the aerosol can, made in the form of a hollow body, open on the installation side of the aerosol can, and containing a fixing collar in the area of its installation on the inner surface; placement inside the outlet tube of the aerosol can, communicated through the outlet channel with a throttle sleeve located at the outlet for spraying the aerosol composition into the external environment, mentioning the molded nozzle is located mainly perpendicular to the end surface of the cap with the possibility of moving the aerosol can tube and thereby communicating the inner space of the can with the external medium through the throttle sleeve, while the convex section of the petal is equipped with a voltage compensator made in the form of an arcuate recess located on its peripheral portion adjacent to the pipe.

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