US20100294762A1

US20100294762A1 - Overpressure Relief Device for Closed Containers

Info

Publication number: US20100294762A1
Application number: US12/665,161
Authority: US
Inventors: Philipp Kolon; Jens Weller; Marco Baldassi; Bernd Haussler; Peter Schneider
Original assignee: Individual
Current assignee: Huber Packaging Group GmbH
Priority date: 2007-06-21
Filing date: 2008-06-19
Publication date: 2010-11-25
Also published as: BRPI0812905A2; ATE549273T1; EP2170733B1; DE102007029450A1; ES2382183T3; EP2170733A1; WO2008155127A1

Abstract

The invention discloses a pressure release device for a closed container, in particular for a pressurized container for beverages, having a plug which can be sealingly fitted on an opening of the container and which comprises a passage opening, the passage opening being sealingly closed by a film.

Description

CROSSREFERENCES TO RELATED APPLICATIONS

This application is a continuation of international patent application PCT/EP2008/004982, filed on Jun. 19, 2008 designating the U.S., which international patent application has been published in German language and claims priority from German patent application 10 2007 029 450.8, filed on Jun. 21, 2007. The entire contents of these applications is incorporated herein by reference.

BACKGROUND OF THE INVENTION

Recently so-called party kegs with filling volumes of, mostly, 5 or 10 liters have come into use, especially for packaging beer. As part of that development, containers equipped with an integrated CO₂pressure accumulator are presently being developed. Pressure can be produced for example with the aid of a low-pressure cartridge (compare WO 2005/095229) or of a high-pressure cartridge (compare EP 1 642 862 A1). Such party kegs are designed as three-piece folded-joint cans. The main body comprises a lengthwise welded seam, the bottom and the upper bottom are connected with the main body by a folded joint. Such a container is dimensionally stable and tight up to a specified hydraulic inner pressure. When pressure rises above that pointed tip, the container gets deformed and, finally, becomes untight due to opening of the folded joint. This situation may lead to an abrupt pressure release. The use of an internal pressure accumulator entails the risk that in case of uncontrolled gas release due to some malfunction pressure may rise excessively inside the container and as a result bursting of the container may occur or the folded joint may open, as has been mentioned before.
For safety reasons it is, therefore, necessary to provide a pressure release device through which pressure can be released to the outside in the event an unexpected pressure rise should occur, before the folded joint gets overloaded or the container comes to burst.
Such a pressure release device is known from EP 1 688 814 A1.
However, the pressure release device known from that publication has a relatively complicated structure.
Further, there are known in the art so-called “bursting disks”, used for example in machinery and plant engineering. Such a bursting disk comprises a metal plate or a disk of defined thickness serving as a shutoff member in a pressure-loaded system. When the pressure rises above a defined critical value, the bursting disk will break, thereby releasing a flow passage through which the pressurized medium is permitted to escape.

SUMMARY OF THE INVENTION

In view of this, it is a first object of the present invention to disclose a pressure release device for a container which provides reliable operation.
It is a second object of the present invention to disclose a pressure release device for a container which is constructed in a very simple and easy way.
It is a third object of the present invention to disclose a pressure release device for a container which is particularly suited for the protection of pressurized party kegs.
These and other objects of the invention are achieved by a pressure release device for a closed container, in particular for a pressurized container for beverages, having a plug which is designed for being sealingly fitted in an opening of the container and which comprises a passage tightly sealed by a film.
The object of the invention is perfectly achieved in this way.
Closing the passage opening by a film provides a simple and reliable seal that will yield and release the passage opening when a defined pressure is exceeded.
The film may consist, for example, of metal, such as aluminum, or of a plurality of connected layers of metal or of a plastic material, i.e. of a compound film.
According to a further development of the invention, the film is connected with the plug by a sealed layer.
In an alternative embodiment, the substances of the film and of the plug are connected by a molding operation, preferably by a 2K-technique (2-component-technique).
In 2K-technique, two different plastic materials having different properties, for example a harder and a softer material, are joined one with the other by two successive injection molding operations. This leads to an especially
intimate connection with high adhesive strength between the two plastic materials.
This guarantees simple fastening on the plug, with reliable sealing effect, for closing the passage opening.
According to a preferred further development of that embodiment, the passage is closed by a flange on which the film is held.
This facilitates the operation of mounting the film on the plug in sealing relationship.
According to a further embodiment of the invention, that plug comprises a sleeve made from a harder plastic material, in which the passage opening is formed and on which the film is fastened, the sleeve being enclosed by an outer part made from a softer plastic material.
While the outer part consists of a softer material and permits the plug to be sealingly mounted in the opening of the container, the sleeve made from a harder plastic material provides an advantageous way of fastening the film.
In another variant of the invention, the sleeve may also form a predominant portion of the plug while the outer part encloses the sleeve only in the area intended to be sealingly fitted in the opening of the container.
According to a further variant of the invention, the film is coated with a sealable material, preferably a sealable lacquer.
It is possible in this way to make the coating of the film and the sleeve from a chemically very similar or identical material so that both the film and the sleeve will melt locally in the area of the sealable layer when a suitable energy is applied, for example by heating or by ultrasound, whereby a very intimate and sealing connection is achieved between the film and the sleeve.
According to a still further embodiment of the invention, the sleeve is connected with the outer part by a 2K-technique.
This allows a connection with especially good adhering effect to be achieved between the sleeve and the outer part.
According to an alternative variant of the invention, the sleeve is mechanically fitted in an opening of the outer part.
Provided the sleeve and the outer part are shaped adequately, a reliable connection with good adhesive effect can be ensured between the sleeve and the outer part by such a design as well.
According to a further embodiment of the invention, a pointed tip facing the film is provided in the sleeve.
Given the fact that under the action of pressure the film will bend from the interior of the container toward the outside it is possible, by arranging a pointed tip of suitable form in a suitable position near the film, to define the pressure at which the film will be opened and, thus, pressure will be released, more precisely than on the basis of the strength of the film only. The overpressure at which the pressure release device will respond can be adjusted with high precision in this way.
In a further embodiment of the invention, a protective cover is movably held at the passage opening of the sleeve.
This feature ensures that when the pressure release device responds the content of the container cannot be expelled from the container in the form of a sharp jet. Instead, the content of the container will be permitted to escape only through a gap between the protective cover and the passage opening so that any risks will be avoided.
According to a further embodiment of the invention, the protective cover is sealed relative to an outer surface of the plug in a first closed position.
The inner space of the plug in the area of the passage opening and of the film is thereby protected from external mechanical stresses and contamination.
According to a further embodiment of the invention, the protective cover is located on the sleeve for being mechanically locked in the desired position.
This permits easy mounting of the protective cover on the sleeve.
According to an additional further development of the invention, the protective cover has a first stop position in which the protective cover is fixed on the sleeve in such a way that when a defined retaining force is exceeded the protective cover will be released from the first stop position and will be displaced in axial direction to release the passage.
This ensures simple and reliable operation of the click-in cover, for releasing the passage opening to the outside when the film is open.
Preferably, the protective cover can be fitted in the sleeve from the outside in this case, whereby easy assembly is achieved.
According to an additional further development of that embodiment, the protective cover is provided with stop elements that permit the protective cover to be inserted into the sleeve from the outside, a stop means in a first position and an axial stop on holding elements of the sleeve in a second activated position in which the film has been opened and pressurized liquid in the container is permitted to flow from the interior of the container through the passage against the protective cover and to the outside.
This guarantees reliable operation of the protective cover and easy assembly.
According to further embodiment of the invention, the plug is designed as a closure plug for being tightly inserted into the filling opening of a container.
This allows the plug to be advantageously fastened in the filling opening of the container anyway available. The plug can then be integrated in the plug that is anyway required for closing the filling opening.
It is understood that the features of the invention mentioned above and those yet to be explained below can be used not only in the respective combination indicated, but also in other combinations, without leaving the scope of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

Further features and advantages of the invention will become apparent from the description that follows of a preferred embodiment, with reference to the drawing. In the drawings:

FIG. 1 shows a sectional view of a detail of a container with a fitted pressure release device in a closed position; and

FIG. 2 shows the container with pressure release device according to FIG. 1 in an activated position.

DESCRIPTION OF PREFERRED EMBODIMENTS

In FIG. 1 a detail of a container is indicated generally by reference numeral 11.
The container 11 may, for example, be a party keg having a capacity of 5 or 10 liters, being filled with beer, for example. Further, the container 11 is pressurized, preferably by a CO₂cartridge that is maintained by a control unit at an overpressure suitable for beer of approximately 0.2 to 1 bar (i.e. an absolute pressure of 1.2 to 2 bar), as is basically known from WO-A-2005/095229 or EP-A-1 642 862, for example.
The upper bottom 13 of the container 11 comprises a central opening 14 into which a pressure release device 10 according to the invention is inserted after filling.
The pressure release device 11 comprises a plug 15 having a central sleeve 18 made from a relatively hard plastic material and an outer part 20 made from a relatively soft plastic material which surrounds the sleeve 18. A central passage opening 16 is formed in the sleeve 18.
A circumferential groove 36, by which the outer part 20 can be fitted in the filling opening 14 of the container 11 in sealing engagement, is formed in the outer part 20. The plug 15 can thus be used as a closure plug for the filling opening 14.
In order to guarantee a sealing connection, the outer part 20 consists of a suitable plastic material, for example a thermoplastic elastomer (TPE). Compared with that, the sleeve 18 consists of a harder plastic material, such as PP or PE. The sleeve 18 may be produced jointly with the outer part 20 by a 2K-technique, which ensures an especially intimate mechanical connection between the two parts. Alternatively, the sleeve 18 and the outer part 20 may be produced separately one from the other, and the sleeve 18 can then be mechanically fitted in a suitably configured opening of the outer part 20 so that again a sealing connection is achieved between the two parts.
The sleeve 18 has a hollow-cylindrical design and comprises a flange 17 at its lower end facing the interior of the container 12. A film 38 in the form of an aluminum foil is sealed onto, and is tightly connected with the flange 17 over a circumferential sealing area 40. The film 38 is coated with a material known as “sealable lacquer”. The sealable lacquer is plasticized under the influence of heat and/or energy, for example by ultrasonic excitation. Given the fact that the material from which the sleeve 18 is made has similar properties as the sealable lacquer with which the film 18 is coated, the surface of the flange 17 can be plasticized simultaneously as the film 38 is sealed on so that an intimate connection is achieved between the film 38 and the sleeve 18 in the sealing area 40.
Alternatively, the film 38 may be connected with the sleeve 18 also by injection molding.
Now, the thickness of the film 38, its strength and the diameter of the passage opening are mutually adjusted so that when a specified inner pressure is reached in the inner space of the container 12, the film 38 will bend outwardly so that it will come to tear under the effect of the pressure.
In order to ensure the best possible defined response of the pressure release device, a pointed tip 21, arranged opposite the film 38, is received on a bridge 19 of the sleeve 18 at a suitable spacing from the film. The spacing between the pointed tip 21 and the film 38 is selected to ensure that tearing of the film 38 will occur when a defined overpressure is reached in the space of the container 12, the pressure at which the film will respond and tear being predefinable rather precisely.
In order to prevent pressurized material in the inner space of the container 12 from being expelled from the container through the passage opening 16 in the form of a sharp jet when the pressure release device responds by tearing of the film 38, a protective cover 28 is additionally fixed for axial movement in the passage opening 16. As can be seen in FIG. 1, in a first closed position the cover area 30 of the protective cover 28 comes to lie flush in a recess 26 on the outside of the outer part 20 and is sealed in that position relative to the outer part 20. Both the passage opening 16 and the hollow space above the film 38 are sealed off from the outside in this way. The protective cover 28 is provided for this purpose with a total of four tongues 32 projecting from the bottom of the cover surface 38 in the direction of the interior of the sleeve 18. Stop elements 34 are formed on the lower ends of the tongues 32. In the closed position of the protective cover 28 illustrated in FIG. 1, the stop elements 34 rest against a circumferential inner bead projecting to the inside in the form of a bulge 22. In this way, the protective cover 28 is securely fixed in the closed position.
When the pressure release device 10 responds, i.e. when the film 38 tears, the pressurized material, in the container escapes from the inner space 12 and enters the passage opening 16, and the pressure acting on the bottom surface of the cover area 30 causes the stop elements 34 to be released from their engaged position and the protective cover 28 to be displaced in outward direction until the stop elements 34 come into contact with a circumferential engaging edge 24 at the upper end of the sleeve 18. This then constitutes the second stop position illustrated in FIG. 2, where the pressure release device is indicated by reference numeral 10′. The pressurized material in the container can then escape to the outside through the passage opening 16 and the remaining annular gap between the cover surface 30 and the outer part 20.
The engaging edge 24 and the stop elements 34 are adapted one to the other so that for mounting the protective cover 28 it is initially inserted into the sleeve 18 from the outside over the engaging edge 24, for being engaged in the first closed position illustrated in FIG. 1, against the inner bead or the bulge 22. This then constitutes the closed position where the protective cover 28 occupies its first locked position. Further, the stop elements 34 and the engaging edge 24 are adapted one to other so that in the second activated position the stop elements 23 will safely come to rest against the engaging edge 24 and the protective cover 28 will be safely held in the second engaged position or the activated position illustrated in FIG. 2 even when material escapes from the container under pressure.

Claims

1-19. (canceled)

20. A pressure release device for a pressurized container for beverages, comprising:

a plug which can be sealingly fitted in an opening of the container, said plug comprising a sleeve through which a passage opening extends which is sealingly closed by a film;

a pointed tip provided on said sleeve facing said film and being arranged so that said film can be pierced by said pointed tip upon bending of said film toward said pointed tip under the action of internal pressure within said pressurized container;

a protective cover movably held in said passage opening;

at least one first stop element provided on said protective cover;

at least one second stop elements provided on said sleeve; and

at least one third stop element provided on said sleeve which is axially spaced from said second stop element;

wherein said protective cover is configured for insertion into said sleeve past said second stop element so that said first stop element engages said third stop element, thereby securing said protective cover in a closed position in which said passage opening is closed by said protective cover; and

wherein said first and third stop element engage with each other with a certain force allowing to release said protective cover from said closed position under the action of an internal pressure to move outwardly until said first stop element engages said second stop element in an activated position, wherein said protective cover is axially secured against further movement to the outside, but allows a flow of pressurized fluid through said passage opening and said sleeve to the outside.

21. The pressure release device of claim 20, wherein the film consists of a metal film or comprises a plurality of inter-connected layers consisting of metal or plastic.

22. The pressure release device of claim 20, wherein said film is coated with a sealable lacquer.

23. A pressure release device for a pressurized container for beverages, comprising:

a protective cover movably held in said passage opening;

at least one first stop element provided on said protective cover;

at least one second stop elements provided on said sleeve; and

24. The pressure release device of claim 23, further comprising a pointed tip provided on said sleeve facing said film and being arranged so that said film can be pierced by said pointed tip upon bending of said film toward said pointed tip under the action of internal pressure within said pressurized container.

25. The pressure release device of claim 23, wherein said film is made of metal film or comprises a plurality of connected layers consisting of metal or plastic.

26. The pressure release device of claim 23, wherein said film is connected with said plug by a sealed layer.

27. The pressure release device of claims 23, wherein said film and said plug are connected by a 2K-technique.

28. The pressure release device of claim 23, wherein said passage opening is closed by a flange on which said film is held.

29. The pressure release device of claim 23, wherein said sleeve is made from a first plastic material, wherein said passage opening is formed and on which said film is fastened, said sleeve being enclosed by an outer part made from a second plastic material which is softer than said first plastic material.

30. The pressure release device of claim 29, wherein said sleeve is connected with said outer part by a 2K-technique.

31. The pressure release device of claim 29, wherein said outer part is made from a thermoplastic elastomer (TPE).

32. The pressure release device of claim 23, wherein said sleeve is made of a material selected from the group consisting of polypropylene (PP) and polyethylene (PE).

33. The pressure release device of claim 23, wherein said film is coated with a sealable lacquer.

34. The pressure release device of claim 23, wherein the protective cover is sealed relative to an outer surface of the plug in a closed position.

35. The pressure release device of claim 23, wherein said plug is configured as a closure plug for being sealingly inserted into the filling opening of said container.

36. A pressure release device for a pressurized container, comprising:

a plug which can be sealingly fitted in an opening of said container;

said plug comprising a sleeve;

a passage opening extending through said plug and being sealingly closed by a film; and

a pointed tip provided on said sleeve facing said film and being arranged so that said film can be pierced by said pointed tip upon bending of said film toward said pointed tip under the action of internal pressure within said pressurized container.

37. The pressure release device of claim 36, wherein a protective cover is movably held in the passage opening of the sleeve.

38. The pressure release device of claim 36, wherein said protective cover is located on the sleeve for being mechanically locked in the desired position.

39. The pressure release device of claim 36, wherein the protective cover has a first stop position in which the protective cover is fixed on the sleeve in such a way that when a defined retaining force is exceeded the protective cover will be released from the first stop position and will be displaced in axial direction to release the passage opening.