KR20120116413A - Measuring cap for a container that can house a pressurized fluid, and container provided with one such cap - Google Patents

Abstract

The present invention provides a measuring cap (1) for a pressurized container (2), comprising: a body (2) having an axial fluid passage (12) formed to enter the container (2) through a neck (5); A sealing joint 15 supported at a portion of the body 8; An assembly ring 16 which is used to detachably secure the measuring cap 1 to the container 2 and is detachable; And a sealing member 17 for selectively opening and closing the fluid discharge channel 12.

Description

MEASURING CAP FOR A CONTAINER THAT CAN HOUSE A PRESSURIZED FLUID, AND CONTAINER PROVIDED WITH ONE SUCH CAP}

The present invention relates to pressurized vessels capable of storing fluids, and more particularly to means for sealing pressurized vessels.

Known as pressurized vessels are aerosol type vessels.

An aerosol is a set of solid or liquid chemical particles in suspension form in the gaseous medium.

In everyday life, the term "aerosol" also refers to a container that stores a mixture of product and propellant gas. Propellant gas creates pressure inside the vessel. When the discharge valve is opened, the mixture is discharged out of the pressurized container. The material is sprayed in the form of aerosols, ie in the form of particulates in the form of a suspension in air.

The propellant gas usually uses nitrogen because it is an inert gas and therefore less dangerous than propane, butane and other flammable hydrocarbons, but these gases do not affect the ozone layer.

Known aerosol containers have a bottom, side walls and neck and are usually made of aluminum. The thickness of the vessel is designed to withstand pressures up to 18 bar inside. These aerosol containers have various capacities.

Such containers are described in particular in US Pat. No. 3,977,576, French Patent Publication FR 2909981 A1, US Patent Publication US 6,253,970 B1 and US Patent Publication US 3,187,962.

These containers are sealed by an inseparable discharge valve. Therefore, the container cannot be recycled. When pressure is applied to the actuating member connected to the discharge valve, the seal is released so that the material in the container passes through the valve and is discharged out of the container.

Aerosols, ie pressurized vessels with inseparable discharge valves, must follow very strict and severe safety standards. For all types of aerosols, the discharge valve is inseparable and cannot effectively measure the material coming from the pressurized container. The internal pressure allowed by the safety standard is limited to 12 bar at 50 ^° C. In addition, the filling of conventional aerosols is limited to 66% of the volume by strict standards, the amount of which is up to 1 liter.

Conventional aerosols function only when they contain fluids that are not particulates, otherwise the discharge valve is blocked and the aerosols cannot discharge fluids.

The first object of the present invention is to devise a means of sealing a pressurized container capable of storing a fluid that can be separated and can measure the discharged material and can be safely used up to a pressure of 20 bar or more. will be.

A second object of the present invention is to devise a pressurized container which can be stored and discharged even in the case of particulate fluids using intermittent thrust.

Since aerosols do not play a role for particulate fluids, aerosol valves cannot achieve the above-mentioned object.

The underlying idea of the present invention is to provide a measuring cap that is reliable and detachable in use, and also to a pressure much higher than the pressure generally accepted in the case of aerosols, for example about 30 bar. The measuring cap described above can be used in conjunction with a container for storing fluid under pressure.

In order to achieve the above and other objects, according to the first aspect, the present invention provides a measuring cap of a pressurized container for storing a fluid, the container comprising a bottom and a substantially cylindrical side wall, the side wall being In the measuring cap, which narrows towards the neck with the front face and the inner edge,

A body having a longitudinal axis,

An intrusion comprising a radial periphery that enters the neck of the container and engages in contact with the inner edge of the neck;

A projection having an axial fluid outlet in communication with the interior of the vessel and in communication with the exterior of the vessel via the fluid discharge passage,

A body having a sealing shoulder formed in the connection between the intrusion and the protrusion;

A sealing joint supported on the sealing shoulder and the front face;

An assembly ring detachably secured to the protrusion of the body while axially clamping a first sealing joint relative to the front face and the sealing shoulder; And

And a sealing member which is controlled by an actuating member accessible to the protrusion of the body and which selectively opens and closes the fluid discharge passage.

This measuring cap can be removed. Thus, the container in which the measuring cap is closed is easy to reuse, thus reducing the amount of waste. Such measuring caps are thus environmentally friendly. This measuring cap does not contain a valve. If the volume of the vessel is less than 1 liter and the pressure generated per volume is less than 50 bar per liter, the pressurized vessel with a detachable measuring cap is not bound by strict aerosol standards or by other regulations.

This measuring cap is of simple construction; It includes only three main components that can be preassembled and also includes a fourth component that is assembled to couple the measuring cap to the pressurized container. Therefore, it is also simple to use.

The measuring cap is also compatible with the body of a conventional container used for aerosols, and thus can be benefited by lowering the cost of mass produced containers.

Furthermore, since the container according to the invention is a measuring cap, the user can adjust the flow rate of the material coming out of the pressurized container.

Preferably, the radial periphery has a truncated cone portion, the cone angle of the truncated cone portion being approximately equal to the inclination of the inner edge of the neck of the container.

Thus, the physical pushing force on the neck of the container is well distributed.

Preferably, the intrusion comprises at least one concave side, the width formed by the concave side being smaller than the diameter of the neck of the container.

Thus, the main body can be easily inserted into the pressurized container.

Preferably, the one or more concave sides are provided such that local deformation occurs at the neck so that leakage occurs when a predetermined predetermined pressure inside the container is exceeded.

In this way, the safety element can be easily and cheaply implemented.

Preferably, the measuring cap is made of metal or plastic.

The use of plastic material reduces the manufacturing cost of the measuring cap because plastic material is cheaper than metal. However, the use of metal will give better mechanical strength.

Preferably, in the case of a metal measuring cap, the metal is stainless steel or aluminum alloy.

Such metals are well known, and methods of forming these metals through numerical control or other methods are well known.

Preferably, the assembly ring is fixed to the body by screwing, pressing or cottering.

By this type of assembly, a detachable measuring cap can be obtained.

Preferably, the intrusion of the body may comprise two side flats on each side of the longitudinal axis of the body. One of the two flats forms a side.

Preferably, the assembly ring has a peripheral skirt surrounding the neck of the container, forming a leak space between the end edge and the side wall of the container.

This is an inexpensive and easy-to-implement safety factor, in which the fluid ejected from the container through the sealing joint is guided away from the user when excessive pressure is created.

By surrounding the neck of the container, the assembly ring also functions to reinforce the neck, allowing it to counter the internal pressure of the container that is intended to expand the neck.

Preferably, according to the first embodiment, the sealing member is a rod mounted to slide in the axial fluid passage between the closed position and the open position, and includes two annular grooves for receiving the annular sealed joint.

The sealing element moves between two predefined positions. This can prevent the sealing element from suddenly deviating from the axial fluid passage.

According to a second embodiment, the sealing member is preferably a locking screw that is screwed into or separated from within the body.

When inserting the lock screw in the main body, the user can precisely adjust by screwing the lock screw more or less. This structure is also suitable when the fluid comprises a powder or a solid suspension.

Preferably, the closure member also includes a closure element located in an axial fluid passage proximate to the neck of the container and maintained spaced from the container by a spring or an internal pressure of the container.

The sealing element has a dual function, namely a valve function during filling and a safety element function.

As a second aspect, there is provided a container which is sealed by a measuring cap according to the first aspect of the invention and capable of storing compressed fluid having an initial internal pressure of more than 20 bar.

Such containers do not need to meet aerosol standards because they do not include a fixed valve and the cap can be removed.

Other objects, features, and advantages of the present invention can be understood by referring to the following detailed description of exemplary embodiments with reference to the accompanying drawings:
1 is a longitudinal sectional view of a pressure vessel with a measuring cap according to a first embodiment of the invention;
2 is an exploded perspective view of the elements assembled to make the measuring cap of FIG. 1;
3 is a perspective view of the main body of the measuring cap of FIG. 1 when entering the neck of the container;
4 is an enlarged view of the longitudinal section of the measuring cap of FIG. 1;
FIG. 5 is a longitudinal cross section when in the closed position of the measuring cap of FIG. 1; FIG.
6 is an enlarged longitudinal cross-sectional view of the annular groove of the measuring cap of FIG. 1 when in the intermediate position;
7 is a longitudinal cross section when the cap of FIG. 1 is in the open position;
8 and 9 are longitudinal sectional views of the pressure vessel with measuring cap according to the second embodiment;
10 and 11 are longitudinal cross-sectional views of the pressure vessel with measuring cap according to the third embodiment.

1 to 7 show a first embodiment of the present invention, in which the measuring cap 1 is screwed to a pressurized receptacle 2. In this figure, like reference numerals denote like elements.

1 shows the container 2 closed with a measuring cap 1.

The container 2 comprises a bottom 3 and a cylindrical side wall 4, which narrows gradually toward the neck 5. The neck 5 is inclined at an inclination angle β. The neck portion 5 is formed by folding the material constituting the container 2 outward. The neck part 5 comprises a front face 6 and a lower inner edge 7. The container 2 is configured to contain a compressed fluid.

In order to explain the measuring cap 1, the components constituting the measuring cap 1 are shown in more detail in FIG. 4.

The measuring cap 1 comprises a body 8 formed along the longitudinal axis I-I, a sealing joint 15, an assembly ring 16, a sealing member 17 and an operating member 18.

The main body 8 includes an intrusion 9 and a projection 11, which meet at the sealing shoulder 14 facing towards the projection 11.

The intrusion 9 comprises a substantially cylindrical distal end and a radial peripheral protrusion 10 at the proximal end. Radial peripheral protrusion 10 comprises a truncated cone portion 10a having a cone angle α (FIG. 2).

The cone angle α is equal to the inclination angle β so as to distribute the physical force of the measuring cap 1 in the container 2.

The intrusion 9 comprises two lateral flats 19a, 19b (FIGS. 2 and 3) on each side of the longitudinal axis I-I of the body 8. These two side flat portions 19a, 19b are parallel to the longitudinal axis II, which allows the intrusion 9 of the body 8 to enter the container 2 through the neck 5. have.

For this purpose, the width 190 of the penetration 9 in the two side flat portions 19a and 19b is smaller than the diameter D of the neck 5 of the container 2.

As another example, the intrusion 9 of the body 8 may comprise non-parallel and asymmetrical sides, or one side. It is important that the intrusion 9 enters the neck 5 to provide a sufficient front face for the sealing joint 15.

The protrusion 11 includes a penetrating axial fluid passage 12, a fluid discharge passage 13, and a threaded portion 11a on the outer front surface adjacent the sealing shoulder 14. Once the measuring cap 1 is connected to the container 2, the fluid discharge passage 13 and the axial fluid passage 12 communicate with each other so that the substance contained in the container 2 can flow.

The axial fluid passage 12 is disposed at an intermediate position between the fluid discharge passage 13 and the upstream opening 12a of the axial fluid passage 12 and has an intermediate shoulder portion 30 having a front surface facing upstream. Include.

The sealing joint 15 is annular and is supported by the sealing shoulder 14 and the front surface 6.

The assembly ring 16 includes a substantially cylindrical portion 25, which has a threaded through opening 24 and a peripheral skirt 20. The thread of the threaded through opening 24 of the assembly ring 16 corresponds to the thread of the threaded portion 11a of the projection 11.

The sealing member 17 may selectively open and close the fluid discharge passage 13. This operation can be controlled by an actuating member 18 accessible to the protrusion 11 of the body 8.

The sealing member 17 is a rod comprising two annular grooves 22a, 22b, which has a truncated conical profile and is less than the axial distance between the fluid outlet passage 13 and the intermediate shoulder 30. Longer distances are offset from one another in the longitudinal direction (FIG. 4).

Each annular groove 22a, 22b is provided with the sealing joint 23a, 23b, respectively. Each hermetically sealed joint 23a, 23b is made of elastomer and has a cylindrical and tubular shape with a circular cross section of constant thickness. The upstream annular groove 22a decreases in depth in the direction of the upstream opening 12a.

The sealing member 17 includes an intermediate portion 170 between two annular grooves 22a and 22b, which is cylindrical in the embodiment of FIGS. However, the middle portion 170 may be truncated cone-shaped, or in a broader sense, a shape determined according to the result of particle size analysis of the discharged fluid.

5 to 7 show that the sealing member 17 slides in the axial fluid passage 12.

5 shows a state in which the measuring cap 1 is in the closed position P1, in which case the substance contained in the container 2 does not escape out of the container 2: the upstream sealing gasket 23a discharges the fluid. Coupled to the cylindrical portion of the smaller axial fluid passage 12 between the passage 13 and the intermediate shoulder 30, the axial fluid passage 12 is sealed and blocked.

Figure 6 shows an enlarged view of the sealing member 17 in the intermediate position (P). In this intermediate position P, the upstream closure joint 23a is collinear with the middle shoulder 30 and forms a partial opening, so that the user can adjust it by moving the closure member 17 in the axial direction. The compressed fluid is allowed to pass through. The annular groove 22a has a truncated conical shape, which gradually applies a force to the upstream sealing joint 23a so that it can be gradually opened.

FIG. 7 shows the measuring cap 1 in the open position P2, in which the substance contained in the container 2 can come out of the container 2.

As can be seen in FIG. 5, when the sealing member 17 is in the closed position P1, the fluid cannot escape because the axial fluid passage 12 is closed by the sealing member 17. . Through the pressure inside the container 2, the sealing member 17 is pushed outward, the distance of which is limited by the shoulder portion 26 provided in the sealing member 17, the shoulder portion 26 being the shaft It is supported in the axial direction with respect to the middle shoulder portion 30 of the directional fluid passage 12, so that the sealing member 17 does not escape.

Sealing takes place in the closed position P1 by the upstream closure joint 23a, the upstream closure joint being conically pressurized against the wall of the axial fluid passage 12.

If the pressure inside the container 2 exceeds a predetermined pressure value, leakage may occur in the space E between the peripheral skirt 20 and the container 2 via the sealing joint 15.

When the user applies the force F to the operating member 18 (FIG. 7), the rod of the closure member 17 slides in the axial fluid passage 12. The fluid does not escape because of the upstream sealing gasket 23a which is always pressing the wall of the axial fluid passage 12. As can be seen from FIG. 6, the cylindrical sealing joint 23a coupled to the truncated conical annular groove 22a is effectively and very economically sealed.

7 shows the components in the open position P2 at which the fluid is discharged. By bringing the sealing member 17 down sufficiently, the sealing is eliminated in the upstream sealing gasket 23a.

Therefore, it is possible to discharge through the axial fluid passage 12 and the discharge passage 13 to the outside while adjusting the fluid. It can be sealed by the second hermetic gasket 23b, thereby preventing a considerable amount of fluid from escaping towards the operating member 17.

The actuating member 18 is a hood having a threaded bore 18a for fixing by screwing in the threaded distal end 17a of the sealing member 17. As another example, the actuating member 18 may be secured by clipping, crimping, hooping or adhesive bonding.

In the embodiment described, an elastic means 17b in the form of a helical compression spring is sandwiched between the actuating member 18 and the body 8 so that when the pressure in the container 2 is too low or when the viscosity of the fluid is high Will assist.

However, the elastic means 17b is not necessarily necessary, and it is usually considered that the pressure in the container 2 is sufficient for the sealing member 17 to slide to the closed position P1 at which the proper fluid is discharged.

If necessary, the fluid in the vessel must already be filtered.

2 illustrates the assembly sequence of the components for making the measuring cap 1.

The sealing joint 15 is arranged inside the assembly ring 16 and once the assembly is completed as a whole, sealing is made at the neck 5 of the container 2 by the sealing joint 15. The sealing member 17 is mounted so as to slide in the axial fluid passage 12 without the operating member 18, and is coupled through the upstream hole 12a. The sealing gaskets 23a and 23b are previously mounted in the respective annular grooves 22a and 22b in the sealing member 17. The assembly ring 16 with the gasket 15 is coupled to the body 8. The actuating member 18 is screwed to the distal end 17a of the sealing member 17 to fix the sealing member so as not to rotate through engagement with a screwdriver in the slot 17c at the proximal end of the sealing member 17 ( lock). As another example for the slot 17c, other kinds of fastening means may be used, and the slot 17c may have other types of profiles.

Next, the intrusion 9 can enter the neck 5 of the container 2 at an angle. This entry can in particular be made through two lateral flats 19a, 19b. Next, the measuring cap 1 is arranged so that the radial peripheral protrusion 10 is engaged while contacting the inner edge 7 of the neck.

Subsequently, the assembly ring 16 is screwed onto the thread in the protrusion 11 of the body 8. The assembly ring 16 clamps the first gasket 15 axially with respect to the front face 6 and against the sealing shoulder 14. The measuring cap 1 and the container 2 are connected.

The peripheral skirt 20 surrounds the neck 5 of the container 2, leaving a leak space E between the edge 21 and the peripheral wall 4 of the container 2.

The present invention also ensures the safety of the user by causing a leak to occur when a predetermined maximum pressure is reached in the container 2. To this end, the side flat portions 19a and 19b are concavely arranged so that the neck portion 5 is slightly deformed locally, thereby forming a region of somewhat weak strength. Thus, when a predetermined pressure is reached, the neck 5 deforms outward and the gasket 15 is less crushed, resulting in a safe leak.

This first embodiment is particularly suitable for fluids having a particle size of less than 500 μm.

8 and 9 show a second embodiment of the invention, in which case the container 2 (FIG. 1) is closed by a measuring cap 100. As in the first embodiment, the measuring cap 100 is threadedly coupled to the container 2.

The same means are denoted by the same reference numerals as in Figs.

The measuring cap 100 comprises a body 80 having a longitudinal axis II-II, an assembly ring 16 and a sealing element 40.

The main difference between the first embodiment and the second embodiment is that in the second embodiment, the sealing member 41 and the operating member 42 are composed of one single part to form the sealing element 40. . As another example, the actuating member 42 may be a component attached through adhesive bonding, clipping, hooping or screwing.

The axial fluid passage 12 includes a threaded upper portion 12b, a lower shoulder portion 43, and a middle shoulder portion 44a. The lower shoulder portion 43 lies in an intermediate position between the fluid discharge passage 13 and the upstream opening 12a of the axial fluid passage 12.

The sealing element 40 can selectively open and close the fluid discharge passage 13. This operation can be directly adjusted by the user with respect to the operating member 42 which is accessible from the protrusion 11 of the body 80.

The sealing member 41 is a rod including four parts. The first upper portion 41a is partially threaded near the operating member 42. The second portion 41b is reduced in diameter and comprises an annular groove 45 having a truncated cone double profile.

However, the annular groove 45 can be in other forms to create a convex bulge, such as for example a spherical profile.

The first portion 41a and the second portion 41b meet through the shoulder portion 44a. The third portion 41c has a truncated conical profile and encounters the fourth portion 41d at the point where the rod ends.

The annular groove 45 has a sealing joint 46. As in the previous embodiment, the hermetic joint 46 is made of an elastomer and preferably has a tubular and cylindrical shape with a circular cross section of constant thickness. The annular groove 45 increases in depth in the direction of the upstream opening 12a.

In this embodiment, the measuring cap 100 also comprises a sealing element, such as a ball 47, which is fixed by the conical spring 48 in combination with the axial passage 12 when moving in the axial direction. . The diameter of the ball 47 is determined not to enter the container 2 but also to the size at which the seal is made when the ball 47 contacts the lower shoulder 43.

In one embodiment, not shown, the spring can contact the plunger tube 49 as a straight spring (FIGS. 8 and 11) and the inner diameter is smaller than the diameter of the ball 47.

The function of the measuring cap 100 will be described in detail below.

In the position shown in FIG. 9, the measuring cap 100 is in a closed position, in which case the substance contained in the container 2 cannot escape out of the container 2. The pointed fourth portion 41d of the sealing member 41 cooperates with the narrow portion 50 of the axial fluid passage 12 upstream of the fluid discharge passage 13. The narrow portion 50 forms a seat that the fourth portion 41d can support, thus making a sealed closure of the axial fluid passage 12.

When the sealing member 41 is in the intermediate position, the pointed fourth portion 41d no longer cooperates with the narrow portion 50 of the axial fluid passage 12. In this way, a partial opening is formed such that the pressurized fluid passes at a predetermined speed, which speeds up the user while axially moving the sealing member 41 by screwing the sealing element 40 more or less. I can regulate it. It may be gradually opened by the pointed shape of the fourth portion 41d.

In order to adjust the flow rate of the fluid according to the particle size of the discharged fluid, the diameter of the third portion 41c and the shape of the fourth portion 41d may be modified.

In the open position, the material in the container 2 is discharged out of the container 2 because the third part 41c no longer contacts the narrow part 50 of the axial passage 12. Therefore, there is an effect that the sealing function is lost.

When the user rotates and opens the sealing element 40, the rod of the sealing member 41 is raised in the axial fluid passage 12. By means of a hermetic seal 46 which is continually pressurized against the wall of the axial fluid passage 12, the fluid does not flow towards the actuating member 42.

The ball 47 performs two functions as a filling valve and a safety valve. The function of the safety valve is shown in FIG.

For the filling operation, the sealing element 40 is removed, the fluid discharge passage 13 is blocked, and the ball 47 is pushed toward the lower shoulder 43 through the conical spring 48. Through contact between the ball 47 and the lower shoulder 43, a seal is formed.

During filling, the fluid entering under pressure pushes the ball 47 into the interior of the container 2, so that the ball 47 is no longer in contact with the lower shoulder 43, and the compressed fluid is contained in the container 2 Will pass toward the inside.

The ball 47 acts as a non-return valve, thereby preventing the fluid in the container 2 from exiting, because the fluid 47 moving toward the outlet contacts the lower shoulder 43. This is because it pushes to form a seal and also prevents the pressurized fluid from draining out of the container 2.

In addition, the ball 47 also serves as a safety valve, because if the sealing element 40 is released by chance, the ball 47 is raised to contact the lower shoulder 43 to form a seal. As a result, the pressurized fluid does not come out of the container 2.

10 and 11 show a third embodiment of the present invention. The difference from the second embodiment is that there is no conical spring. The ball 47 is kept in a fixed state by sufficient pressure inside the container 2 (FIG. 10).

8-11 show a plunger tube 49 which guides the fluid from the inside of the vessel 2 to the outside.

The ball 47 is larger in diameter than the inner diameter after inserting the plunger tube 49, so that the ball 47 does not fall into the container 2 (FIG. 11). As such, the ball 47 is coupled between the plunger tube 49 and the lower shoulder 43.

The plunger tube 49 is not shown in FIGS. 1 to 7, but may be configured to perform in particular the same function of limiting movement of the ball 47 or of supporting the spring 48.

8-11, preferably the cone of the needle 41d may have an angle of about 60 ^° and damage to the ball 47 when the needle 41d contacts the ball 47. The tip of the needle is cut off so as not to give it.

The second and third embodiments are particularly suitable for fluids having a particle size of less than 2 mm.

If the container is to store and discharge fluid for food use, the measuring cap can be made of any material having properties associated with food. The measuring cap can be made of plastic material or metal (for example stainless steel or aluminum alloy).

The fluid outlet 13 may take the form of an extension tube for ergonomically discharging the fluid.

In an embodiment not shown, the cone angle α of the truncated cone portion of the radial periphery 10 does not coincide with the slope β of the inner edge of the neck of the container. Therefore, when the intrusion part 9 rotates, the lower part is shaved and the main body 8 is firmly fixed.

Although not shown, another embodiment based on the embodiment of FIGS. 8-11, wherein the ball 47 is, if possible, smaller in diameter than the diameter of the axial fluid passage 12 and larger than the inner diameter of the spring 48. It can also be replaced by a large cylinder. This cylinder may have a nearly truncated conical groove, such as groove 22a (FIG. 6). A hermetically sealed joint, such as hermetically sealed joint 23a, is provided in the groove. Sealing takes place as shown in FIG. 6, and the sealing joint is in contact with the narrowing portion of the axial fluid passage, such as narrowing section 50 (FIGS. 8-11).

The invention is not limited to the embodiments described above, but includes various modified forms and generalized forms falling within the scope of the claims.

Claims (12)

Measuring cap (1; 100) of a pressurized container (2) for storing fluid, the container (2) comprising a bottom (3) and a substantially cylindrical side wall (4), the side wall being the front face (6). In the measuring cap, which narrows towards the neck 5 with the inner edge 7)
A body (8; 80) having a longitudinal axis,
An intrusion (9) entering the neck (5) of the container (2) and comprising a radial peripheral protrusion (10) which engages and engages with the inner edge (7) of the neck,
A projection 11 having an axial fluid outlet 12 in communication with the interior of the container 2 and in communication with the outside of the container 2 via the fluid discharge passage 13, and
A body (8; 80) with a sealing shoulder (14) formed at the connection between the intrusion (9) and the projection (11);
A sealing joint (15) supported on the sealing shoulder (14) and the front face (6);
Assembly ring 16 detachably secured to protrusion 11 of body 8; 80 while axially clamping first sealing joint 15 to the front face 6 and to sealing shoulder 14. ); And
A sealing member (17; 41), which is controlled by an actuating member (18; 42) accessible to the protrusion (11) of the body (8; 80), which selectively opens and closes the fluid discharge passage (12); Measuring cap, characterized in that it comprises. The method of claim 1,
The radial periphery 10 has a truncated conical portion 10a, wherein the cone angle α of the truncated cone portion is approximately equal to the inclination of the inner edge 7 of the neck of the container 2. cap. The method according to claim 1 or 2,
The intrusion 9 comprises at least one concave side 19a; 19b, wherein the width 190 formed by the concave side is smaller than the diameter D of the neck 5 of the container 2. Measuring cap made with. The method of claim 3,
The one or more concave side surfaces 19a, 19b are provided so that a predetermined deformation occurs locally at the neck 5 so that leakage occurs when a predetermined predetermined pressure inside the container 2 is exceeded. Measuring cap made with. 5. The method according to any one of claims 1 to 4,
The measuring cap is a measuring cap, characterized in that made of metal or plastic. The method of claim 5,
And the metal is stainless steel or aluminum alloy. 7. The method according to any one of claims 1 to 6,
The assembly ring (16) is characterized in that it is fixed to the body (8; 80) by screwing, pressing or coating. 8. The method according to any one of claims 1 to 7,
The assembly ring 16 has a peripheral skirt 20 surrounding the neck 5 of the container 2, so that the leaking space (between the end edge 21 and the side wall 4 of the container 2) E) forming a measuring cap. The method according to any one of claims 1 to 8,
The sealing member 17 is a rod mounted to slide in the axial fluid passage 12 between the closed position P1 and the open position P2, and two annular grooves accommodating the annular hermetically sealed joints 23a and 23b. And measuring caps (22a, 22b). The method according to any one of claims 1 to 8,
The sealing member 41 is a measuring cap, characterized in that the locking screw which is screwed or separated in the main body (80). The method of claim 10,
The closure member 41 is also located in the axial fluid passage 12 proximate the neck of the vessel 2 and spaced apart from the vessel by a spring 48 or an internal pressure of the vessel 2. A measuring cap, characterized in that it comprises a sealing element (47) for holding. Container (2) for storing compressed fluid, which is sealed by the measuring cap (1) according to any one of the preceding claims, wherein the initial internal pressure is greater than 20 bar.

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