The invention relates to a method for manufacturing a pressure regulating device for a beverage container. The invention further relates to a pressure regulating device, a beverage container and a filling line for beverage containers.
From EP1064221 a beverage container is known, comprising a pressure regulating device for maintaining a substantially constant pressure in the container. The beverage container can comprise dispensing means and can be ready for dispensing beverage from the container, independently from a tapping device, external CO2 containers and the like. A gas container of the pressure regulating device is filled with CO2 gas under pressure through an aerosol valve. Then a pressure regulator is mounted on the gas container for controlling opening and closing of the aerosol valve.
An object of the present invention is to provide an alternative method for forming a pressure regulating device. Another object of the invention is to provide an easy method of forming a pressure regulating device and/or a beverage container.
Another object is to provide a pressure regulating device and a beverage container comprising such pressure regulating device. Moreover an object is to provide a filling line for beverage containers.
In a first aspect the description discloses a method for manufacturing a pressurising device for a beverage container, wherein a gas container is provided having a filling opening. An amount of dry ice is inserted through the filling opening into the gas container. The filling opening is closed and the dry ice is allowed to sublimate.
In a second aspect the description discloses a pressure regulating device for a beverage container, comprising a gas container. The gas container is partly filled with dry ice.
In a third aspect the description discloses a beverage container comprising a pressure regulating device for regulating pressure in the beverage container. The pressure regulating device comprises dry ice or gas formed from sublimation of dry ice within the pressure regulating device.
In a fourth aspect the description discloses a filling line for beverage containers, wherein on the filling line a dry ice dispenser is provided for dispensing an amount of dry ice into a gas container of a pressure regulating device provided for the beverage container.
Embodiments of the present invention shall be described, with reference to the drawings, for elucidation of the invention. These embodiments should by no means be understood as limiting the scope of the invention in any way or form. In these drawings:
In this description and the drawings the same or similar elements have the same or similar reference signs. In this description the invention shall specifically be described with reference to a carbonated beverage container and a pressure regulating device therefore, especially for beer.
In this description dry ice has to be understood as at least comprising solidified gas, especially solidified CO2. Dry ice can be frozen CO2. Solid ice can be CO2 gas that is pressurised and/or cooled to a temperature and pressure such that the CO2 is transformed from gas to solid, for example −70 to −80° C. at about atmospheric pressure, and can change back, especially sublimate back to gas when the temperature is raised and/or the pressure is reduced. 1 kilo of dry ice 16 can for example sublimate into about 500 litre of CO2 gas.
In this description by way of example a beverage container 1 is shown, comprising a body 2 and a neck 3, wherein the neck 3 defines or at least comprises a dispense opening 4. The beverage container 1 can be made of metal but is preferably made of plastic, such as but not limited to PET or a PET blend, single or multi layer. The beverage container 1 can be blow moulded from a pre form, in a known manner. A beverage container can have a volume of for example a few litres, for example one to two litres of larger. A beverage container 1 can for example have an internal volume of about 5 litres or more, such as but not limited to more than 10 litres. A beverage container 1 can for example have an internal volume between about 10 and 25 litres, such as for example about 17 litres.
In
In the gas container 6 an amount of dry ice 16 is provided. The dry ice 16 is shown as a series of solid elements, such as granules 17. The dry ice can be provided as powder, ground ice, pellets or the like. In another embodiment the dry ice 16 can be provided as a single, solid element. The solid dry ice can sublimate in the gas container 6, when the temperature and pressure in the gas container are suitable for such sublimation. The dry ice 16 can be fed into the gas container 6 through the filling opening 8. The filling opening can be closed by a lid 19, which can for example be mounted onto the mounting means 11, for example by complementary screw threads. The lid 19 can close the gas container 6 such that gas, especially CO2 gas formed by the sublimation of the dry ice 16 cannot escape the gas container 6 through the filling opening 8, at least not in an uncontrolled manner.
In
In the embodiment shown in
A valve 27, for example an aerosol valve as described in EP1064221 is provided in a bottom 26 of the dispensing device 23, forming a connection between the inner space of the gas container 6 and a space 28 above the bottom 26. The bottom 26 can be an integral part of the dispensing device 23 or can be a separate part, which can be connected to the flange 14. At an opposite side of the space 28 a flexible wall part 29 of a pressure regulating chamber 30 is provided, resting against the valve 27. If the pressure in the space 28 drops below a regulating pressure, the wall part 29 will be forced, by pressure in the pressure regulating chamber 30, against the valve 27, opening the valve 27 and allowing gas to flow from the gas container 6 into the space 28. A passage 31 is provided through the bottom 26 and the flange 12, into the inner space of the beverage container 1. Thus pressure equilibrium will exist substantially between the space 28 and the inner space of the beverage container 1. When the pressure in the beverage container is back at the desired pressure, such as the equilibrium pressure, the wall part 29 will be pushed back and the valve 27 will close.
The pressure regulating chamber 30 can be a closed chamber. In an alternative embodiment a passage can be provided from the chamber 30 to an environment in which atmospheric pressure prevails.
A dip tube 32 extends from the inner space of the beverage container 1 past the gas container 6 and through the flange 14 into the dispensing device 23. The dispense tube 25 is connected to the dip tube 32 by a valve 33, which is in the embodiment shown can be a hose type valve, operationable by an arm 34 connected to an excentre 35. In
In
In the embodiment as shown in
Dry ice can for example be provided as a solid bock or as pellets, formed by for example extrusion of dry ice into rods or the like shapes and pelletizing the rods into pellets which can then be weighed or otherwise measured for providing a desired quantity of dry ice into a container 6. To this end for example liquid CO2 can be made to form powder snow which can be pressed into blocks and/or through an extruder. Dry ice pellets as such are known from for example dry ice blasting. Dry ice can also be formed by making powder snow, which can be measured to provide a sufficient amount in a container 6. The powder snow could be created before entering the container 6 or could be created directly in the container 6, for example by injecting liquefied CO2 into the container 6.
In an embodiment the dry ice dispenser 44 could comprise means for reducing the size of the dry ice, for example crushing or grinding means for crushing or grinding dry ice formed into smaller elements or particles, such as powder or granules, which may ease dosing of a specific amount in a reliable manner.
Upon sublimation of the dry ice 16 into gas, the volume of the CO2 will increase, filling the entire gas container 6 and increasing the pressure to for example above 4 bar, such as to about 6 to 12 bar. Especially when a plastic or thin walled metal gas container 6 is used, the gas container 6 will expand at least partly and at least slightly, especially in radial direction, such that its cross section inside the beverage container 1 may increase, such that the gas container cannot be retracted from the beverage container 1.
In
The gas container 6 can initially substantially have the shape of a preform for stretch blow moulding a bottle, as known in the art. The gas container 6 can initially substantially have the shape of a gas container as shown in
In order to blow the gas container into its final shape as shown in
Preferably the gas container 6 is inserted into the container 1 after filling the inner space 100 with a sufficient amount of liquid, such as beer. When thereafter the gas container 6 is blown into its desired shape, as for example shown in
By providing the gas container 6 in an upper portion of the container 1, the liquid will be forced to the lower portion of the container 1, when held with the neck 3 up, as shown in
Obviously the gas container 6 can also be blown up in a different manner, for example by directly forcing gas under pressure into the gas container.
In an alternative embodiment the pressure regulator device 5 can be filled with dry ice outside the beverage container 1, where after it is inserted at least partly into the beverage container and a dispensing device can be mounted to the beverage container. In another embodiment the pressure regulator and the dispensing device can be integrated, as shown for example in
In an exemplary embodiment an amount of about 4 gram of dry ice is inserted into a container 6 having an internal volume of about 0.15 litre. Then the container 6 is closed and the dry ice is allowed to sublimate into gas. This will lead to about 2 litres of gas, compressed to a pressure within the container of about 12-14 bar (1200 to 1400 kPa) absolute. This was at least sufficient to expel about a litre of carbonated beverage, especially beer from a container, through a neck portion of the container when standing, through a dispense tube. It shall be clear to the person skilled in the art that for any amount of liquid to be dispensed an appropriate amount of dry ice can be provided in a container of a desired volume, depending on for example allowable starting pressure within the fully filled container, the dispense conditions, such as but not limited to counter pressure, temperature, dispensing volume, beverage container geometry, liquid type and/or available space for the container 6.
The invention is by no means limited to the embodiments described and/or disclosed herein. These embodiments are mere examples. Many variants are possible within the scope of the invention as defined by the appending claims, including combinations of embodiments disclosed or parts thereof. Furthermore, for example the beverage container can be made of metal or another suitable material or combination of materials. Moreover, the beverage container can be of a bag in container type, wherein the beverage is provided in a flexible bag within a more rigid outer container, the pressure regulator 5 opening into the space between the bag and the outer container. This will compress the bag and there through dispense the beverage, without contact between the gas, such as CO2 gas, and the beverage. The pressure regulator can be made in different ways, and placed in different positions relative to the gas container and/or the beverage container. The pressure regulating device 5 can for example be mounted partly or entirely outside the beverage container 1, the pressure regulator opening into the beverage container for pressurising the beverage in the beverage container. These and other alternative embodiments are considered to have been disclosed herein as well.
Number | Date | Country | Kind |
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2006195 | Feb 2011 | NL | national |
2006197 | Feb 2011 | NL | national |
2006199 | Feb 2011 | NL | national |
PCT/NL2011/050367 | May 2011 | WO | international |
PCT/NL2011/050369 | May 2011 | WO | international |
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Number | Date | Country | |
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Parent | 13981432 | US | |
Child | 16401935 | US |