WO2002040368A1

WO2002040368A1 - Gas adsorption means for a container

Info

Publication number: WO2002040368A1
Application number: PCT/GB2001/005017
Authority: WO
Inventors: Alan Moulton; Mark Sillince
Original assignee: Cope Allman Plastic Packaging Limited.
Priority date: 2000-11-16
Filing date: 2001-11-14
Publication date: 2002-05-23
Also published as: AU2002223801A1

Abstract

Drinks containers have to withstand internal pressures that have built up due to gases released from carbonated liquids. Such containers have to be able to withstand pressures of up to 6 p.s.i. Other known containers such as coffee packets comprise pressure release valves to ensure that internal pressure does not exceed a safe working pressure. According to the present invention there is provided a container (1) for consumable produce and gas adsorption means (6, 7). Gas within the container (1) may be adsorbed by the gas adsorption means (6, 7).

Description

GAS ADSORPTION MEANS FOR A CONTAINER

The present invention relates to gas adsorption means for a container and a method for depressurising a container.

Some containers for food produce and containers for drinks produce have to withstand internal pressures. These pressures may be due to gases released from the produce. For example certain drinks containers that contain live beer have to withstand internal pressures of up to 6 p.s.i. The increase in the internal pressure is produced by fermentation gases released by the contents. For this reason any live beer container has to be able to withstand such pressures. Such live beer containers can be expensive.

Internal pressures in containers can also build up due to gases released from carbonated liquids stored therein. Other known containers such as coffee packets comprise pressure release valves to ensure the internal pressure of the packet does not exceed a safe working pressure. The internal pressure may build up due to gases released by the coffee.

According to a first aspect of the present invention there is provided a container for consumable produce, the container comprising gas adsorption means.

Preferably, the gas adsorption means is disposed in the upper region of the container.

The gas adsorption means preferably comprises a gas permeable membrane and a gas-adsorbing medium, the arrangement being such that, in use, gas within the container may pass through the gas permeable membrane and be adsorbed by the gas-adsorbing medium. Preferably, the gas permeable membrane is a semi-permeable membrane that substantially prevents a liquid from passing there through.

The gas-adsorbing medium is preferably a carbon based compound.

The container is preferably substantially non-rigid.

The gas adsorption means is preferably disposed within a chamber located in the upper regions of the container.

Alternatively, the gas adsorption means is disposed within a recess formed in a closure of the container.

Preferably, the arrangement of the closure and the gas adsorption means is such that when the closure is placed on a nozzle portion of the container the gas adsorption means is received by the nozzle portion.

According to a second aspect of the present invention there is provided a method for depressurising a container for consumable produce whereby the volume of gas within the container is reduced by the adsorption of an amount of the gas into a medium.

Preferably the adsorption of the gas is into a carbon medium.

According to a third aspect of the present invention there is provided a method for depressurising a drinks container whereby the volume of gas within the drinks container is reduced by the adsorption of an amount of the gas into a medium.

Preferably the adsorption of the gas is into a carbon medium. The present invention may be carried into practice in various ways but an embodiment will now be described, by way of example only, with reference to the accompanying drawings in which:

Figure 1 is an isometric view of a drinks carton;

Figure 2 is a side view through cross-section AA of the closure of the drinks carton shown in Figure 1 ;

Figure 3 is an isometric view of a soft packet comprising gas adsorption means; and

Figure 4 is a view through cross-section BB of the soft packet and gas adsorption means.

With reference to Figures 1 and 2, a drinks carton 1 is formed from sheet laminated paper board. The drinks carton 1 comprises a closure cap 2 formed with an internal thread (not shown) and a tubular nozzle 3 formed with a corresponding external thread 4. The cap 3 and the tubular nozzle 3 are made from a plastics material. Around the circumference of one end of the tubular nozzle 3 there extends radially outward an internal annular portion 5. The annular portion 5 is bonded the inner surface 9 of the carton 1 so forming a fluid tight seal there between. Cartons similar to the carton 1 are presently used for containing non-pressurised liquids such as milk, yoghurt and fruit juice.

Disposed within the closure cap 2 there is gas adsorption means comprising a block 6 of carbon and a semi-permeable membrane 7. The carbon block 6 is secured to the inner surface of the closure 2. The semi-permeable membrane 7 encases the carton block 6. The peripheral edges of the semi-permeable membrane 7 are sonically welded to the inner surface of the closure 2.

When the closure 2 is screwed onto the tubular nozzle 3 the carbon block 6 and the semi-permeable membrane 7 extend into the nozzle 3 (as shown in Figure 2) . The semi-permeable membrane 7 forms a fluid barrier between the carbon block 6 and the inner volume of the drinks carton 1. The semi-permeable membrane 7 prevents the liquid within the carton 1 from coming into contact with the carbon block 6.

In use the drinks carton 1 may contain a live beer. Gases produced by the fermentation process of the beer may pass through the semi- permeable membrane 7 and then be adsorbed by the carbon block 6. The pressure within the carton 1 may be either maintained at an acceptable level or reduced due to the adsorption of the fermentation gas by the carbon block 6. The adsorption of the fermentation gases into the carbon block 6 reduces the volume of the gases.

The person skilled in the art will appreciate that the size of the carbon block 6 required depends upon the volume of beer contained within the drinks carton 1 and the amount of fermentation gases produced. The overall strength of the drinks carton 1 may be reduced because of the depressurisation function of the gas adsorption means.

It will be appreciated that the carbon block 6 and semi-permeable membrane 7 may be placed anywhere on or in the carton such that there is access to the fermentation gas produced. However, there are advantages in placing the carbon block 6 and semi-permeable membrane 7 within the closure 2. One such advantage is the ease of access while assembling the carbon block 6 and semi-permeable membrane 7. With reference to Figures 3 and 4, there is shown a packet 20 formed from a suitable flexible sheet barrier material. The packet 20 comprises a chamber 22 that has a substantially cylindrical body portion 24 formed with a closed end 26 and an open end 28. The chamber 22 is injection moulded from a suitable plastics material. The closed end is formed with an annular flange 30 that is bonded to the packet 20 by ultrasonic welding so forming a fluid tight seal there between. The open end 28 of the chamber 22 is presented to the inside region of the packet 20. The chamber 22 contains gas adsorption means comprising a block 32 of carbon. The open end 28 of the chamber 22 is covered by a semi- permeable membrane 34.

When the chamber 22 is welded onto the packet 20 the carbon block 32 and the semi-permeable membrane 34 extend into the packet 20 (as shown in Figure 4) . The semi-permeable membrane 34 forms barrier between the carbon block 6 and the inner volume of the packet 20. The semi-permeable membrane 34 prevents any liquid or solid within the packet 20 coming into contact with the carbon block 32.

In use the packet 20 may contain coffee powder. Gases produced by the coffee powder may pass through the semi-permeable membrane 32 and then be adsorbed by the carbon block 34. The pressure within the packet 20 may be either maintained at an acceptable level or reduced due to the adsorption of the fermentation gas by the carbon block 32. The adsorption of the fermentation gases into the carbon block 32 reduces the volume of the gases.

The gas adsorption means of the present invention may be adapted for use on any suitable consumer produce containers such as, but not limited to, flexible foil packets, laminated cartons, plastic containers and glass bottles.

Claims

1. A container (1) for consumable produce, the container (1) comprising gas adsorption means (6, 7) .

2. A container according to claim 1 , wherein the gas adsorption means (6, 7) is disposed in the upper region of the container (1) .

3. A container according to claim 1 or claim 2, wherein the gas adsorption means comprises a gas permeable membrane (7) and a gas- adsorbing medium (6) , the arrangement being such that, in use, gas within the container (1) may pass through the gas permeable membrane (7) and be adsorbed by the gas-adsorbing medium (6) .

4. A container according to claim 3, wherein the gas permeable membrane (7) is a semi-permeable membrane that substantially prevents a liquid from passing there through.

5. A container according to claim 3 or claim 4, wherein the gas- adsorbing medium (6) is a carbon based compound.

6. A container according to any one of the preceding claims, wherein the container is substantially non-rigid.

7. A container according to any one of the preceding claims, wherein the gas adsorption means is disposed within a chamber (22) located in the upper regions of the container (20) .

8. A container according to any one of claims 1 to 6, wherein the gas adsorption means is disposed within a recess formed in a closure (2) of the container.

9. A container according to claim 8, wherein the arrangement of the closure and the gas adsorption means (6, 7) is such that when the closure is placed on a nozzle portion (3) of the container (1) the gas adsorption means (6, 7) is received by the nozzle portion (3) .

10. A method for depressurising a container (1) for consumable produce, whereby the volume of gas within the container (1) is reduced by the adsorption of an amount of the gas into a medium (6) .

11. A method for depressurising a drinks container (1), whereby the volume of gas within the drinks container (1) is reduced by the adsorption of an amount of the gas into a medium (6) .

12. A method according to claim 10 or claim 11 , wherein the adsorption of the gas is into a carbon medium (6) .