HUP0900683A2 - Low pressure liquid feeder and process for sterile dosing of liquid with low pressure - Google Patents

Description

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Apparatus and method for sterile dispensing of liquids under low pressure

The invention relates to a device and method for the sterile dispensing of liquids under low pressure.

Non-alcoholic and carbonated or still drinks containing alcohol are sold in glass or plastic bottles. The outlet of these bottles is typically closed with a screw-type plastic cap or a pressed-on metal cap. When the cap is removed, external gases, primarily oxygen, nitrogen, etc., immediately flow into the bottle through the outlet and the liquid stored in the bottle begins to oxidize and deteriorate. This is especially typical for organic products that are bottled in an aseptic environment without the addition of preservatives.

One possible way to reduce quality deterioration is to mix various preservatives into the drinks. Another known way to preserve quality, which is mainly used for dispensing carbonated liquids, is to equip the bottle with a suitable dispensing head, which ensures that no external air, such as oxygen, can enter the bottle, thus the liquid in the bottle can be stored for a long time and dispensed without oxidation.

Such a dispensing head solution is described in the international application WO2004/092033 A3 and the patent registration number WO 95/31398. One of the main disadvantages of these solutions is that the liquids in the bottles must be dispensed through a so-called diving tube, which requires at least 6-7 bar of overpressure. This overpressure, however, causes such rapid flow and turbulence in the dispensing head system that it causes significant carbon dioxide loss and, with it, high foaming in certain products, primarily containing sugar, but also in other products (e.g. beer), which drastically reduces the enjoyment of the drink. Thus, a part of the (saturated) carbon dioxide gas absorbed into the liquid with the expensive technology is removed (precipitated) from the rapidly flowing liquids, and only a significantly reduced proportion of the carbon dioxide gas remains in the dispensed drink. In many cases, the loss of carbon dioxide is so great that it makes the consumption of the dispensed drink unenjoyable.

The aim of the invention is to provide a liquid dispensing device that is inexpensive to produce and easy to handle, which enables the dispensing of the liquid stored in the bottle in an oxidation-free (i.e. sterile) manner and at low pressure, i.e. close to external atmospheric pressure. Dispensing at low pressure is advantageous primarily in the case of beverages enriched with carbon dioxide, since the degree of turbulence in the flowing liquid is significantly reduced due to the low velocity of the liquid, which results in a significant reduction in the loss of carbon dioxide and thus in the foaming of the dispensed beverage.

A further aim of the invention is to provide the liquid storage container or bottle with a container closure unit that can be placed on the top filling opening of a conventional beverage bottle using conventional technology.

A further aim of the invention is to implement a modular dispensing device that allows the use of any number of liquid storage containers in succession.

The invention is based on the recognition that in a liquid storage container, for example a soft drink bottle, a gas space is created above the liquid space, in which a gas is stored, which is used after the beverage storage container is opened to continuously maintain a gas pressure in the gas space of the beverage storage container that is substantially the same as the external ambient air pressure. The pressure prevailing in the gas space of the beverage storage container preferably continuously exceeds the external ambient air pressure by a minimal amount, thereby ensuring a minimal overpressure in the beverage storage container for easier dispensing of the liquid.

The high-pressure gas filled into the beverage storage container during bottling is led into an external deformable (inflatable) gas container before the beverage storage container is opened, the maximum volume of which gas container is sized so that the pressure of the gas in the beverage storage container is reduced substantially to the ambient air pressure.

As a result, the gas flows back from the deformable gas container, which is part of the dispensing device, to the place of the dispensed liquid, while the volume of the deformable gas container gradually decreases, thereby preventing a vacuum from forming in the liquid storage container, which would cause the inflow of external air. In addition, due to the relatively low gas pressure prevailing in the liquid storage container, the liquid leaves the container at a relatively low speed when it is filled. Due to the low pressure prevailing in the liquid storage container, the liquid is preferably filled in a free-flowing manner. With the device according to the invention, not only liquid enriched with carbon dioxide gas can be dispensed without deterioration in quality, sterilely, at a low speed, but also any non-carbonated so-called still drink, such as tea, milk, fruit juices, tomato juice, etc.

Although the liquid dispensing device according to the invention is particularly advantageously applicable for dispensing beverages, especially carbonated beverages, the field of application of the device is not limited to food, so it can be used either in the chemical industry, in medicine, or in any other field.

The set goals are achieved on the one hand by implementing a dispensing device for the sterile dispensing of liquids at low pressure, which includes

- a substantially rigid-walled liquid storage container having an upper filling opening, a liquid space of a predetermined volume and a gas space of a predetermined volume,

- a deformable gas tank arranged outside the liquid storage tank,

- a tank closure unit, which is sealed to the upper filling opening of the liquid storage tank and to the external gas tank and contains

- a first means for dispensing the liquid contained in the liquid storage container, and

- a second means for establishing a gas connection between the gas space of the liquid storage tank and the external gas tank, said second means comprising a two-position valve structure which, in a first position, allows gas to flow from the gas tank to the liquid storage tank and, in a second position, from the liquid storage tank to the gas tank; and

- an actuating unit which is detachably connected to the container closure unit and which comprises members for externally actuating the first means and the second means of the container closure unit.

The deformable gas container is preferably an initially flattened, inflatable bag.

The inflatable bag may have flexible walls or inflexible walls. In the latter case, the bag is preferably provided with a weight that exerts external pressure on the bag wall.

In a preferred embodiment of the dispensing device, the first means comprises a liquid outlet passage and a movable closure element associated therewith. The liquid outlet passage is, for example, a flexible-walled hose, and the closure element is in this case preferably a throttle element adapted to compress the hose.

It is particularly advantageous if the actuator unit comprises a multifunctional actuator lever which, in a first position, closes the liquid outlet passage and maintains the two-position valve mechanism in the first position; in a second position, opens the liquid outlet passage while maintaining the two-position valve mechanism in the first position; and in a third position, closes the liquid outlet passage and maintains the two-position valve mechanism in the second position.

The actuator unit and the external gas tank are preferably attached to a rigid support structure.

The gas space of the liquid storage container preferably contains a protective gas, such as nitrogen. The initial pressure of the gas in the gas space is preferably at most about 5 bar.

On the other hand, the set goals are achieved by a process for the sterile dispensing of liquids at low pressure, during which

- a defined amount of liquid and a defined amount of high-pressure gas are filled into a substantially rigid-walled liquid storage container through the upper filling opening of the liquid storage container,

- we seal the upper filling opening of the liquid storage tank with a tank closing unit,

- an actuating unit and a deformable, external gas tank having a predetermined maximum volume are connected to the tank closure unit of the liquid storage tank,

- using the operating unit, before the first opening of the liquid storage container, a portion of the high-pressure gas is discharged from the gas space thereof into the deformable, external gas container so that a gas pressure substantially equal to the external air pressure is generated in the gas space of the liquid storage container, and

- using the actuating unit, liquid is dispensed from the liquid storage container, while gas is released from the deformable, external gas container back into the liquid storage container in such a way that the gas pressure in the gas space of the liquid storage container is always substantially the same as the external air pressure.

The liquid storage container is preferably filled with a protective gas, such as nitrogen.

It is advisable to initially keep the deformable, external gas container at a minimum volume and to expand the gas container to a maximum volume when the pressure of the initially high-pressure gas in the liquid storage container is reduced.

The liquid is preferably discharged from the liquid storage container in a free-flowing manner.

The advantage of the liquid dispensing device according to the invention is that instead of the dispensed liquid, external air, usually contaminated, which in the case of food causes food spoilage, is introduced into the liquid storage container, but purified, oxygen-free gas, usually nitrogen or carbon dioxide, which is factory-filled into the container and suitable for storing food, flows back from the external gas container so that the liquid storage container always has essentially external pressure. This prevents contamination and oxidation of the stored liquids, thus ensuring the preservation of the quality of the liquids stored in the liquid storage containers at least until the time that the manufacturer guarantees without opening the liquid storage container.

Another advantage of the solution is that due to the low, essentially external pressure in the tank, the liquid can be filled from the tank at a low speed, thereby reducing its foaming - and especially in the case of carbonated drinks, the loss of carbonation.

- is significantly reduced, which in the case of beverages greatly enhances the enjoyment value of the liquid dispensed in this way.

A further advantage of the device according to the invention is that the liquid outlet passage and the passages for equalizing the pressure of the filling gas are both formed in the container closure unit, thereby the container closure unit can be placed on conventional beverage bottles, which enables a wide range of uses.

The device according to the invention is also advantageous in that it has a modular design, so that after the liquid storage tank is emptied, a new, unopened liquid storage tank can be connected to the operating unit and the external gas tank, thereby allowing the operating mechanism and the external gas tank to be used multiple times.

The preferred embodiments of the low-pressure dosing device according to the invention are described with the help of the attached drawing, without limiting the practical applicability of the invention nor the claimed scope of protection to the embodiments shown as examples. In the drawing:

- Figure 1 is an enlarged sectional view of the upper end of a liquid container forming part of the liquid dispensing device according to the invention;

- Figures 2.a and 2.b show the universal insert of the container closure unit in longitudinal sectional view and top view, respectively;

- - Figure 3 is a side sectional drawing of the bottle holder structure and the associated operating unit;

- Figures 4.a-4.c illustrate a possible embodiment of a gas tank with inelastic walls in front view, side view and perspective view;

- Figure 5 illustrates the liquid storage container and the bottle holder structure in perspective view before the liquid container is inserted into the bottle holder structure;

- Figure 6 is an enlarged sectional view of the upper part of the assembled liquid dispensing device, with the operating lever in the gas release position;

- Figure 7 shows the entire assembled liquid dispensing device in a sectional view, with the operating lever in the gas release position;

- Figure 8 is an enlarged sectional view of the upper part of the assembled liquid dispensing device, with the operating lever in the liquid dispensing position;

- Figure 9 illustrates another possible embodiment of the device according to the invention in sectional view; and

- Figure 10 is a flow chart showing the main steps of the method according to the invention.

Figure 1 shows an enlarged sectional view of the upper end of a liquid container forming part of a first possible embodiment of a liquid dispensing device according to the invention. The liquid storage container 2, which is typically a beverage bottle, has an upper filling opening, which serves to fill the liquid to be stored and the process gas. The liquid storage container 2 has a liquid space 15 and a gas space 16 for receiving the liquid. A container closure unit 1 is sealedly connected to the upper opening of the liquid storage container 2. The container closure unit 1 and the upper filling opening of the liquid storage container 2 can be connected to each other by a threaded design, in which case the container closure unit 1 must be screwed tightly onto the top of the liquid storage container 2. As shown in Figure 1, the container closure unit 1 is preferably snap-fastened to the upper opening of the liquid storage container 2 so that the fastening shoulder 4 on the shell 3 of the container closure unit 1 snaps under the fastening ring 5 formed on the liquid storage container 2 when pressed against the liquid storage container 2.

Between the liquid storage tank 2 and the tank closure unit 1, there is a universal insert 8 comprising a hose 6 made of a flexible material and a two-position valve structure 7 for releasing and returning the gas in the gas space 16 of the liquid storage tank 2.

In the basic position of the container closing unit 1, the liquid outlet passage, which is preferably designed as a hose 6, is closed and opened by a movable closing element, for example a movable throttle element 9. The outer end 10 of the hose 6 is closed by the throttle element 9, for example by pressing it against the upper edge of a closing rib 11. By moving the throttle element 9, the hose 6 is opened and it becomes possible to fill the liquid from the liquid storage container 2. Teeth 13 project from the upper surface 12 of the throttle element 9, which allow the throttle element 9 to be moved by an external operating lever to be presented later, thereby opening and closing the hose 6 forming the liquid outlet passage of the liquid storage container 2. The teeth 13 are made inaccessible from the outside by a tear-off cover element 14. The integrity of the cover element 14 - typically a tearable paper, plastic or metal foil - indicates the unopened condition of the liquid storage container 2.

Figures 2.a and 2.b show a longitudinal sectional view and a top view of the universal insert 8 made of flexible material, which integrally contains the hose 6 and the two-position valve structure 7. Indentations 38 are formed in two places on the front surface 37 of the universal insert 8, which serve to release a part of the technological gas in the liquid storage tank 2 into the environment in the event of an overpressure greater than the permissible, i.e. they act as a safety valve. The valve structure 7 of the universal insert 8 includes, on the one hand, passages 31 through which a part of the gas in the gas space 16 of the liquid storage tank 2 escapes into the external gas tank (via the actuating unit to be presented later), and on the other hand, a one-way flap valve 32 through which the gas in the external gas tank can flow back into the liquid storage tank 2 when the liquid is filled.

Figure 3 shows a side sectional view of a support structure 20, which is part of a preferred embodiment of the dispensing device according to the invention, as well as the actuating unit 18 and the external, deformable gas tank 21 attached thereto. The support structure 20 has a fastening tab 34 which enables the support structure 20 to be stably fastened to a shelf or other sheet-like support surface during use of the dispensing device.

A deformable gas container 21 made of a gas-tight material and having a predetermined maximum volume is disposed inside the support structure 20. The gas container 21 preferably has a flexible wall, i.e. after its initial filling and inflation with gas, it is able to contract on its own as the gas contained therein flows back into the gas space 16 of the liquid storage container 2 when the liquid storage container 2 is emptied. The gas container 21 is connected to the liquid storage container via a gas line 22.

One possible variant of the gas container 21, various views of which are shown in Figures 4.a-4.c, has an inelastic wall. The inelastic walled gas container 21 in this case comprises, for example, a polyethylene bag 23, into one half of which a suitably sized weight 24 is placed in order to ensure the necessary contraction of the gas container 21 when the liquid is emptied, and thereby to maintain the appropriate gas pressure (essentially corresponding to the external ambient pressure) in the gas space 16 of the liquid storage container 2.

Figure 5 shows a perspective view of the holding structure 20 combined with the liquid storage container 2 and the actuating unit 25 before the liquid storage container 2 is inserted into the holding structure 20. The intact cover plate 14 is clearly visible on the container closure unit 1 of the liquid storage container 2, which must be removed from the container closure unit 1 immediately before the liquid storage container 2 is inserted into the holding structure 20. The actuating unit 25 is firmly attached to the holding structure 20, which in this case has a multifunctional actuating lever 27. The actuating unit 25 is adjusted to the uppermost position by means of fastening lugs 26, thereby providing space for the liquid storage container 2 together with the container closure unit 1 on it.

Figure 6 is an enlarged sectional view of the upper part of the combined liquid dispensing device, illustrating in detail the elements of the operating unit 25. In Figure 6, the operating lever 27 of the operating unit 25 is in the gas discharge position. The operating lever 27 is in operative relationship with a pressure lever 28, which exerts a force on a valve rod 29 when the initially high-pressure gas in the gas space 16 of the liquid storage tank 2 is discharged. The lower end of the valve rod 29 rests on the upper surface of the valve structure 7. In Figure 6, the valve assembly 7 is shown in its second position, when it is slightly shifted towards the liquid storage tank 2, whereby the high-pressure gas in the gas space 16 flows through the passage 31 of the valve assembly 7, then through the channels 30c and 30b of the actuator unit 25, and finally through the channel 30a of the support structure 20 into the gas tank 21. The flap valve 32 is designed to allow gas to flow in only one direction, namely only when the pressure in the gas tank 21 is higher than the pressure prevailing in the gas space 16 of the liquid storage tank 2.

Figure 7 illustrates the entire combined liquid dispensing device in a sectional view, where the operating lever 27 is in the gas discharge position corresponding to Figure 6 and most of the gas in the gas space 16 has escaped into the gas tank 21, which is shown in Figure 7 in its fully expanded, i.e. inflated, state.

Figure 8 shows an enlarged sectional view of the upper part of the combined liquid dispensing device, where the operating lever 27 is in the liquid dispensing position. When the dispensing lever 27 is rotated in the opposite direction to the container 2, the throttle element 9 moves due to the rotation of the gear 36, which engages with the teeth 13 and rotates together with the operating lever 27, thereby opening the hose 6 in the container closing unit 1 and allowing the liquid in the liquid storage container 2 to be filled. When the liquid is filled, the technological gas 19 can flow into the space freed in the liquid storage container 2 from the gas tank 21 through the plate valve 32, so that no vacuum is created in the liquid storage container 2.

Figure 9 illustrates another possible embodiment of the dispensing device according to the invention in a sectional view, where instead of the operating lever used in the first embodiment, an operating lever 40 is used that can be moved with the filled liquid receiving cup, so that the liquid can be dispensed conveniently with one hand.

The operation of the liquid dispensing device according to the invention is described with the aid of the flow chart shown in Figure 10 and the previously described Figures 6 and 8.

In step S100, a predetermined amount of liquid and a predetermined amount of high-pressure process gas are charged into the substantially rigid-walled liquid storage tank 2 through its upper filling opening. The gas, for example nitrogen or carbon dioxide, is preferably charged into the liquid storage tank 2 after (or in a special case before) the liquid has been charged using a gas charging device known per se provided on the charging line.

Then, in step S102, the liquid storage tank 2 is sealed with the tank sealing unit 1 within the shortest possible time (before the liquid or solid gas 19 changes to a gas state). The added liquid or solid gas 19 changes to a gas state within a short time (a few seconds), thereby filling the gas space 16 of the liquid storage tank 2 with high-pressure gas. The pressure of the gas 19 is then preferably approx. 4-5 bar.

When the liquid storage tank 2 is put into use, in step S104, it is connected to the operating unit 25 and to the external gas tank 21, which has a predetermined maximum volume. Then, in step S106, the high pressure prevailing in the gas space 16 of the liquid storage tank 2 is reduced to substantially the ambient air pressure by diverting a (Qelentös) part of the high-pressure gas 19 from its gas space 16 into the deformable external gas tank 21. With the appropriate dimensioning of the gas tank 21, a (low) gas pressure is generated in the gas space 19 - and thus also in the gas tank 21, which is essentially the same as the external air pressure.

As shown in Figure 5, in a preferred embodiment of the device according to the invention, before the first use of the liquid storage container 2, the cover 14 on the container closure unit 1 is removed, and the liquid storage container 2 is placed in the support structure 20 so that the operating unit 25 is brought to the uppermost position by means of the fixing tabs 26, as mentioned earlier. Subsequently, when the liquid storage container 2 is already in place, the fixing tabs 26 are released and the operating unit 25 is pressed onto the container closure unit 1. This provides the possibility of establishing a hermetic connection between the gas space 16 of the liquid storage container 2 and the gas tank 21 by moving the operating lever 27 in the direction of the liquid storage container 2. Together with the operating lever 27, the pressure lever 28 also moves, which pushes the valve rod 29 in front of it, which opens the valve mechanism 7, thereby allowing the high-pressure gas 19 in the gas space 16 to pass through the passage 31 and the channels 30a, 30b and 30c into the gas tank 21. As a result of the expansion of the gas tank 21, the pressure in the liquid storage tank 2 decreases. After reducing the high gas pressure prevailing in the liquid storage tank 2, the operating lever 27 is returned to its starting position, thereby the connection between the channel 30c of the valve structure 7 and the passage 31 is terminated, so that the low-pressure gas 19 in the gas tank 21 can now only flow in one direction through the plate valve 32, into the liquid storage tank 2, through the channels 30a, 30b.

The dispensing of the liquid can then begin, which is performed in step S108 by placing the support structure 20 that holds the liquid storage container 2 in a horizontal position. Optionally, the support structure 20 can be attached to a shelf in the interior of a refrigerator using the attachment tab 34 provided for this purpose. In this position, the liquid storage container 2 is tilted forward and the liquid stored therein enters the hose 6 of the container closure unit 1, while the gas 19 in the liquid storage container 2 occupies the highest space of the liquid storage container 2.

To dispense the liquid, the operating lever 27 is rotated in the opposite direction to the liquid storage container 2, whereby the throttle element 9 moves due to the rotation of the gear 36 gripping the teeth 13 and opens the hose 6, through which the liquid in the liquid storage container 2 can be filled - preferably with free flow. Due to the low pressure prevailing in the liquid storage container 2, the liquid flows out at a low speed, thereby minimizing the degree of foaming and, in the case of carbonated drinks, the loss of carbon dioxide from the filled drink. During the filling of the liquid, the gas flowing back from the gas tank 21 into the liquid storage container 2 passes through the liquid into the gas space 16. Due to the pressure equalization of the gas tank 21 and the gas space 16, the gas tank 21 gradually contracts when the liquid is filled. From the point of view of the device according to the invention, it is advantageous if the essentially ambient pressure prevailing in the gas space 16 exceeds the ambient air pressure to a minimal extent, since this ensures that external air does not enter the gas space 16 through the liquid flowing out of the liquid storage container 2.

Although the preferred method of filling the liquid has been mentioned above as the free-flowing discharge of the liquid, it is obvious to the skilled person that the liquid can be filled from the liquid storage container 2 in other ways at a low speed, for example by using a suitably designed pump.

Due to the one-way flap valve 32 and the essentially ambient pressure prevailing in the gas space 16, when the liquid is filled, ambient air does not enter the liquid storage container 2 from the outside until it is completely emptied. When the liquid storage container 2 is completely emptied, the pressure in the gas container 21 is equalized with the ambient air pressure via the flap valve 32, and although external air can then enter the empty liquid storage container 2, the one-way flap valve 32 still prevents external air from entering the gas container 21.

The liquid dispensing device and method according to the invention have been described above through specific embodiments. However, it is obvious to a person skilled in the art that the device and method according to the invention can be modified as desired within the scope of protection defined by the claims.

Claims (14)

Patent claims 1. A dispensing device for the sterile dispensing of liquids at low pressure, characterized in that the device comprises - a substantially rigid-walled liquid storage container (2) having an upper filling opening, a liquid space (15) of predetermined volume and a gas space (16) of predetermined volume, - a deformable gas tank (21) arranged outside the liquid storage tank (2), - a tank closure unit (1), which is sealedly connected to the upper filling opening of the liquid storage tank (2) and the external gas tank (21) and contains - a first means for dispensing the liquid contained in the liquid storage container (2), and - a second means for establishing a gas connection between the gas space (16) of the liquid storage tank (2) and the external gas tank (21), said second means comprising a two-position valve assembly (7) which, in a first position, allows gas to flow from the gas tank (21) to the liquid storage tank (2) and in a second position, from the liquid storage tank (2) to the gas tank (21); and - an actuating unit (25) detachably connected to the container closure unit (1) and comprising members for externally actuating the first means and the second means of the container closure unit (1). 2. A dispensing device according to claim 1, characterized in that the deformable gas container (21) is an initially collapsed, inflatable bag. 3. The dispensing device according to claim 2, characterized in that the inflatable bag has flexible walls. 4. A dispensing device according to claim 2, characterized in that the inflatable bag (23) has an inelastic wall and is provided with a weight (24) exerting external pressure on the wall of the bag (23). 5. A dispensing device according to claim 4, characterized in that the first means comprises a liquid outlet passage and a movable closure element associated therewith. 6. A dispensing device according to claim 5, characterized in that the liquid outlet passage is a flexible-walled hose (6), and the closing element is a throttle element (9) adapted to compress the hose (6). 7. A dispensing device according to any one of claims 1 to 6, characterized in that the actuating unit (25) comprises a multifunctional actuating lever (27) which - closes the liquid outlet passage in the first position and holds the two-position valve mechanism (7) in the first position; - opens the liquid outlet passage in the second position while maintaining the two-position valve assembly (7) in the first position; and - in the third position, it closes the liquid outlet passage and keeps the two-position valve mechanism (7) in the second position. 8. A dispensing device according to any one of claims 1-7, characterized in that the actuating unit (25) and the external gas tank (21) are attached to a rigid support structure (20). 9. The dispensing device according to any one of claims 1-8, characterized in that the gas space (16) of the liquid storage container (2) contains a protective gas, preferably nitrogen. 10. A dosing device according to any one of claims 1 to 9, characterized in that the initial pressure of the gas in the gas space (19) is at most about 5 bar. 11. A method for sterile dispensing of a liquid at low pressure, characterized in that during the method - a defined amount of liquid (15) and a defined amount of high-pressure gas (19) are filled (S100) into a substantially rigid-walled liquid storage container (2) through the upper filling opening of the liquid storage container (2), - sealingly closing (S102) the upper filling opening of the liquid storage tank (2) with a tank closing unit (1), - connecting (S104) an actuator unit (25) and a deformable external gas tank (21) having a predetermined maximum volume to the tank closure unit (1) of the liquid storage tank (2), - using the actuating unit (25), before the first opening of the liquid storage container (2), a part of the high-pressure gas (19) is discharged (S106) from the gas space (16) thereof into the deformable, external gas tank (21) so that a gas pressure substantially equal to the external air pressure is generated in the gas space (16) of the liquid storage container (2), and - using the actuating unit (25), liquid is dispensed (S108) from the liquid storage container (2), while gas (19) is released from the deformable, external gas container (2) back into the liquid storage container (2) in such a way that the gas pressure in the gas space (16) of the liquid storage container (2) is always substantially the same as the external air pressure. 12. The method according to claim 11, characterized in that the liquid storage tank (2) is filled with a protective gas, preferably nitrogen. 13. The method according to claim 11 or 12, characterized in that the deformable, external gas container (21) is initially kept in a minimum volume state and when the pressure of the initially high-pressure gas (19) in the liquid storage container (2) is reduced, the gas container (21) is expanded to a maximum volume. 14. The method according to any one of claims 11-13, characterized in that the liquid is discharged from the liquid storage container (2) in a free-flowing manner.