EP4090599A1

EP4090599A1 - Gassing apparatus and method for gassing a container

Info

Publication number: EP4090599A1
Application number: EP20701272.5A
Authority: EP
Inventors: Philippe DERENDINGER
Original assignee: Ferrum Packaging AG
Current assignee: Ferrum Packaging AG
Priority date: 2020-01-15
Filing date: 2020-01-15
Publication date: 2022-11-23
Also published as: CN114901557A; US11932433B2; CA3160328A1; US20230053801A1; BR112022008198A2; WO2021144011A1

Abstract

The invention relates to a gassing apparatus for gassing a container (100), comprising a rotatable gassing rotor (2) having a container receptacle (20) for receiving the container (100) and having a feed region (21) for feeding gas into the gassing rotor (2) via a feed opening (22), wherein the container receptacle (20) comprises a gassing nozzle (23), which gassing nozzle (23) is fluidically connected to the feed opening (22) of the feed region (21) via a channel (24) in order to gas the container (100); and a stationary gas supply line (3) having a stationary supply opening (31), which stationary supply opening (31) is arranged in the feed region in such a way that the supply opening can be fluidically connected to the feed opening, wherein, in the operating mode, the gas can be supplied to the gassing rotor (2) from the gas supply line (3) in that the feed opening (22) is moved towards the stationary supply opening (31) by means of rotation of the gassing rotor (2), as a result of which the feed opening (22) is fluidically connected to the supply opening (31), characterized in that the feed region (21) is contactlessly connected to the gas supply line (3) in the form of a labyrinth seal (4), such that the gassing rotor (2) is rotatable relative to the gas supply line (3) in the operating mode.

Description

Gassing device and method for gassing a container

The present invention relates to a gassing device for gassing a container, a closer with a gassing device according to the invention and a method for gassing a container according to the preamble of the independent claims. It is known from the prior art to close cans by means of a lid in order to produce a closed can. These can be cans in which, for example, a food is arranged; often the food is a drink such as beer.

When the can is closed, a lid is often separated from a stack of lids and conveyed into a closer such as a can folding machine by means of a lid receiving device. The lid is then placed on an opening of the can and is essentially firmly connected to the can, for example by folding. Such a device and such a method are known, for example, from US Pat. No. 2,840,963. In addition, it is known to convey a gas, such as an inert gas, to an underside of the lid at least during a section of the supply of the lid to the container closing device; the gas is conveyed essentially parallel to the underside of the lid. When used as intended, this underside faces the opening of the can. It can thus be ensured that a residual volume of the can, in which no food is arranged, is essentially filled with the gas before the closure, the air originally present in the residual volume being displaced as completely as possible by the gas. In this way, if necessary, a longer shelf life of the food arranged in the can can be achieved. For the supply of the gas, a gassing device is often used for at least one container in a closer, by means of which gas can be conveyed to an underside of a lid or to an opening of the container. For this purpose, the gassing device has a channel for the gas which, through baffles in a gassing rotor of the gassing device, guides the gas flow to a gassing nozzle on a container receptacle of the gassing device. The gas is fed into the rotatable gassing rotor from a stationary gas supply.

The known prior art, however, has the disadvantage that the gas feed into the rotatable gassing rotor are arranged in grinding / rubbing contact with one another, which can lead to wear on the gas feed and the gassing rotor. In addition, there is a permanent need to gass the containers more efficiently and to ensure that the containers are hygienically sealed. It is therefore an object of the present invention to avoid the disadvantages known from the prior art, in particular to provide an efficient, hygienic and low-wear gas-injection device.

These objects are achieved by the gassing device for gassing a container, the closer with the gassing device according to the invention and the method for gassing the container according to the preamble of the independent claims.

The dependent claims relate to preferred embodiments of the present invention.

The invention relates to a gassing device for gassing a container with a rotatable gassing rotor with a container receptacle for receiving the container and a lid and with a feed area for feeding a gas into the gassing rotor via a feed opening. The container receptacle has a gas injection nozzle which is flow-connected to the feed opening of the feed area via a channel for the purpose of gasifying the container. In addition, the gassing device comprises a stationary gas supply with a stationary feed opening, which feed opening is arranged on the feed area in such a way that the feed opening can be flow-connected to the feed opening. In the operating state, the gas from the gas supply can be supplied to the gassing rotor by moving the supply opening to the stationary supply opening by rotating the gassing rotor, whereby the supply opening is flow-connected to the supply opening. The gas supply device according to the invention is characterized in that the feed area (i.e. the gas supply rotor) is connected to the gas supply in the form of a labyrinth seal in a contactless manner, so that the gas supply rotor can be rotated relative to the gas supply in the operating state.

The gas can in particular be an inert gas such as nitrogen (N2), carbon dioxide (CO2), a noble gas or any combination of these gases. In a particularly important embodiment of the invention, the gas is carbon dioxide and the container is a beverage can or the gas is nitrogen and the container is a canned food.

In practice, the gas feed can comprise a groove and the feed area can comprise a web which is arranged in the groove of the gas feed and which are connected without contact in the form of the labyrinth seal. Alternatively, the feed area can comprise a groove and the gas supply can comprise a web which is arranged in the groove of the feed area and which are connected without contact in the form of the labyrinth seal. The labyrinth seal is preferably formed by at least one web which is arranged in at least one groove. So a (thin), usually U-shaped gap is formed between the web and the groove. The sealing effect is based on the extension of a flow path through the gap to be sealed, whereby the

Flow resistance of the gas is increased significantly. The lengthening of the path through the gap is achieved by the interlocking of the groove and web. There is therefore an interlocking of the rotatable gassing rotor and the stationary gas supply through the labyrinth seal. In practice, the feed area can also comprise a multiplicity of grooves and webs which are arranged (interlocked) in respective grooves and webs of the gas supply. The sealing effect can be increased with a larger number of grooves and webs, but the labyrinth seal is then also more difficult to clean.

The feed area is preferably arranged at a rotation center of the gassing rotor. In practice, a shaft rotatable about an axis for rotating the gassing rotor can be arranged in the center of rotation, which shaft is connected to the gassing rotor for rotation. The web (and also the groove) particularly preferably extend parallel to the axis of rotation (or to the shaft). The web is in particular a circular web and the groove is a circular groove. The channel can be arranged in an interior of the gassing rotor. In addition, the channel can be designed in such a way that it forms the shortest distance between the feed opening and the gas injection nozzle. The channel is preferably essentially formed by baffles in the interior of the gassing rotor, which extend along the direction of flow of the gas (that is to say in particular in a radial direction to the axis of rotation).

In a preferred embodiment, the gassing rotor comprises a plurality of container receptacles with gassing nozzles, the gassing nozzles being flow-connected to the feed area via the respective feed openings. In principle, each gassing nozzle can therefore be flow-connected to the supply opening via the respective channel, for which purpose each gassing nozzle is flow-connected to a respective feed opening. The container receptacles are preferably arranged along a circumference of the, in particular round, gassing rotor and are arranged, for example, at regular intervals from one another. In particular, the gassing rotor can be designed as a gassing star or a round plate.

The gas supply can particularly preferably comprise a nozzle ring with an annular opening. The ring opening is arranged on the supply opening in such a way that the supply opening can be selectively flow-connected to at least one of the supply openings via the ring opening by moving the at least one supply opening to the ring opening in the operating state by rotating the gassing rotor, whereby the supply opening is flow-connected to the ring opening and is thus fluidly connected to the feed opening. Thus, only a single container can be selectively gassed, while the other containers are not yet gassed at the other container receptacles, but only when their respective feed opening is flow-connected to the ring opening. Of course, no nozzle ring is required for this, in principle only a single container can be selectively gassed by the feed opening being flow-connected to the supply opening, while the other containers on the other container receptacles are not yet being gassed, but only when their respective feed opening is flow-connected to the supply opening (by rotating the gassing rotor). However, if the ring opening is larger than the feed opening in such a way that the ring opening extends along the circumference of the nozzle ring over several feed openings, (at least) two feed openings can also be flow-connected to the ring opening at the same time. This can serve to pre-gas a container receptacle / a lid before the container is guided with its opening to the lid, or to pre-gas the container receptacle before the container is taken up. A similar effect could be achieved without a nozzle ring with a feed opening which extends over several (eg two) feed openings. The ring opening or the extension of the supply opening allows the gas flow only in a specific / predeterminable segment of the gassing rotor.

In the embodiment of the invention, the feed openings can be arranged in a circle, the nozzle ring being arranged at the feed openings (above the feed openings) in such a way that the feed openings are closed / covered by the nozzle ring, so that only the feed opening which is arranged at the ring opening , is fluidly connected to the feed opening. By rotating the gassing rotor, another feed opening is moved to the ring opening.

In practice, the gassing rotor preferably comprises a container feed for supplying containers to the container receptacle and a container discharge for removing a fumigated container from the container receptacle. By rotating the gassing rotor, the container is transported from the container receptacle to the container discharge, the container being gassed, and preferably in Lid is applied to the opening of the container. In addition, the container discharge usually leads to a closing device for closing the container with the lid.

The gassing device can comprise a cleaning system which, for cleaning the labyrinth seal, is arranged on the labyrinth seal in such a way that a cleaning fluid can be fed to the labyrinth seal in the operating state. For this purpose, a gas can be supplied as cleaning fluid to the labyrinth seal and / or the feed opening through the cleaning system, for example, or separate cleaning channels can be provided for introducing a cleaning fluid, for example liquid.

The gas supply can in particular be designed as a cover with a gas pipe, which cover is arranged around the shaft and on the gassing rotor over the feed area. The cleaning channels can preferably be arranged in the cover and lead from a cleaning fluid feed of the cleaning system between the gas feed and the gassing rotor.

Suitable cleaning fluids include chlorine dioxide, ECA-based disinfectants, foam cleaners, in particular foam cleaners comprising amine oxides and phosphoric acid, alcohols and other disinfectants. The invention further relates to a closer for the container, in particular a can closer, comprising a cover feed device for feeding a cover to the container, the gas supply device according to the invention for feeding gas to the container and a closing device for closing the container with the cover. In practice, the container is gassed when it is received in the container receptacle of the gassing rotor and the lid is provided over the container. The container with the lid on the lid opening is then brought to the closing device and closed there. In particular, the container is a can which is crimped in the closing device with the lid in a known manner. An additional aspect of the present invention relates to a method for gassing the container. The procedure consists of the following steps:

• Provision of the gassing device according to the invention;

• Picking up a container through the container receptacle; · Moving the feed opening to the feed opening by rotating the

Gassing rotor;

• Feeding the gas from the gas supply into the gassing rotor;

• Gassing of the container from the gassing nozzle of the gassing rotor.

Then, as mentioned above, the container is introduced into the closing device together with the lid and closed there. The lid is usually placed on the container receptacle before the container is picked up.

Further features and advantages of the invention are explained in more detail below with reference to exemplary embodiments for better understanding, without the invention being restricted to the exemplary embodiments. The drawings show: FIG. 1 First perspective illustration of the inventive

Gas supply device;

FIG. 2 a first sectional view of the gassing rotor according to the invention according to FIG. 1;

3 shows a plan view of a closer according to the invention; 4 shows a sectional view of a further exemplary embodiment of the gassing rotor according to the invention;

FIG. 5 is a second sectional illustration of the gassing rotor according to the invention according to FIG. 1;

FIG. 6 Another perspective view of the gassing device according to the invention. 1 shows a perspective illustration of the gassing device 1 according to the invention. The gassing device 1 for gassing a container comprises a rotatable gassing rotor 2 which is connected to the shaft 5 in a rotationally test manner and can be rotated about the axis X in the operating state by rotating the shaft 5.

The gassing rotor 2 comprises a container receptacle for receiving the container, which is also shown in FIGS. 3 and 6 with the reference number 20.

The gassing rotor 2 has a feed area 21 for feeding a gas into the gassing rotor 2 via a feed opening 22. The feed area 21 is located at the center of rotation R, in which the shaft 5 is also arranged.

The container receptacle 20 according to FIGS. 3 and 6 comprises a gassing nozzle 23, which gassing nozzle 23 is in flow connection with the feed opening 22 of the feed area 21 via a channel 24 for gassing the container. In addition, the gassing device 1 comprises a stationary gas supply 3 with a stationary supply opening (shown as 31 in FIGS. 4 and 6), which stationary supply opening 31 is arranged on the feed area 21 in such a way that the supply opening 31 can be flow-connected to the supply opening 21. The gas supply rotor 2 can be supplied with the gas from the gas supply 3 in the operating state by moving the supply opening 22 to the stationary supply opening 31 by rotating the gas supply rotor 2 around the axis X, whereby the supply opening 22 is flow-connected to the supply opening 31. In FIG. 4, the feed opening 22 is flow-connected to the feed opening 31. The feed opening can also be viewed as a feed space 31. The feed area 21 is connected to the gas supply 3 in the form of a labyrinth seal 4 without contact, so that the gassing rotor 2 can be rotated relative to the gas supply 3 in the operating state. In the embodiment shown, the gas supply is arranged like a type of cover 33 around the shaft 5 and on the gassing rotor 2 above the feed area 21. Through the Labyrinth seal 4, a strong outflow of the gas from the gassing device, as well as grinding / rubbing contact between gassing rotor 2 and gas supply 3 is avoided.

Absolute tightness is not necessary with the contact-free labyrinth seal 4 according to the invention. In particular, a slight surface gas flow from the labyrinth seal 4 to the surface 34 of the gassing rotor 2, as well as to a periphery of the gassing rotor (on which the container receptacles are arranged, usually along a circumference of the gassing rotor), to create a gas atmosphere there to produce on the container of the container receptacle. Carbon dioxide is particularly preferred as the gas and creates a CO 2 atmosphere in a beverage container such as a can.

The gassing device 1 according to FIG. 1 also comprises a cleaning system 6 which, for cleaning the labyrinth seal 4, is arranged on the labyrinth seal 4 in such a way that a cleaning fluid can be supplied to the labyrinth seal 4 in the operating state. The embodiment of the labyrinth seal 4 shown has the advantage for the combination with the cleaning system 6 that no sump of cleaning fluid can form in the labyrinth seal 4, but that the cleaning fluid can simply flow away. The cleaning system 6 is described in more detail in FIG. 5. FIG. 2 shows a first sectional illustration of the gassing rotor 2 according to the invention, in which the section of the gassing rotor 2 with the labyrinth seal 4 is shown.

The labyrinth seal 4 is designed as follows. The gas supply 3 comprises a groove 42 and the feed area 21 comprises a web 41 arranged in the groove 42. The web 41 and the groove 42 are connected without contact in the form of a labyrinth seal 4, that is to say the web 41 is arranged in the groove 42 in such a way that a (thin) gap 43 is formed between the two. The sealing effect is based on the lengthening of a flow path through the gap 43, as a result of which a flow resistance is significantly increased. The lengthening of the path through the gap 43 is achieved by the meshing of groove 42 and web 41. So it lies an interlocking of the rotatable gassing rotor 2 and the stationary gas supply 3 through the labyrinth seal 4.

In principle, the feed area could comprise a large number of grooves and webs which are arranged (interlocked) in respective grooves and webs of the gas supply. The sealing effect can be increased with a larger number of grooves and webs. However, cleaning the labyrinth seal is made more difficult and the advantageous surface gas flow described above from the labyrinth seal 4 via the surface 34 is reduced.

The web 41 and the groove 42 extend parallel to the axis X (to the shaft 5) of rotation. The web is designed as a circular web and the groove as a circular groove.

3 shows a plan view of the closer 10 according to the invention.

The closer 10 for the container 100 comprises a cover feed device 11 for feeding the cover 101 to the container 100, a gas supply device 1 according to the invention for feeding gas to the container 100 and a closing device 14 for closing the container with the cover 101.

In the exemplary embodiment shown, the closer 10 is preferably designed as a can closer 10. The container 100 is a can which is folded in the closing device 14, which is designed as a can folding machine 14. Carbon dioxide or nitrogen is preferably supplied to the cans as the gas.

In the operating state, the cover 101 is introduced into the closer 10 along the arrow C by the cover feed device 11. Here, the covers 101 are arranged on the gassing rotor 2. By rotating the gassing rotor 2 about the axis X, the covers 101 are transported further. The containers 100 are then introduced into the container receptacles 20 of the gassing rotor 2 through the container feed 12. There the container 100 is gassed with the gas such as carbon dioxide or nitrogen and combined with the cover 101. The gassing takes place in that the supply opening 22 is moved to the supply opening 31 by rotation of the gassing rotor 2, so that the gas can be fed from the gas supply 3 into the gassing rotor 2. The gas is supplied along the arrow B from the gas supply 3 into the gassing rotor 2. The gas is supplied to the container 100 from the gassing nozzle 23 of the gassing rotor 2. An entire area D can preferably be gassed through an annular groove (as described for FIG. 6) instead of just gassing a single container.

The gassing rotor 2 comprises a multiplicity of container receptacles 20 with gassing nozzles 23, the gassing nozzles 23 being in flow connection with the feed area 21 via the respective feed openings 22.

The container is transported by the container discharge 13 from the gas injection device 1 to the closing device 14.

4 shows a sectional illustration of a further exemplary embodiment of the gassing rotor 2 according to the invention.

The stationary feed opening 31 is arranged on the feed area 21. In the configuration shown, the feed opening 31 is arranged above the feed opening 22 and is thus in flow connection with the feed opening 22.

The gas from the gas supply 3 can be fed to the gassing rotor 2 along the arrow D. There is thus a gas flow along the arrow F, which leads from the feed opening 31 of the gas feed 3 into the feed opening 22 of the gassing rotor 2. In the gassing rotor 2, the gas flows through the channel 24 in the interior 25 of the gassing rotor 2 to the gassing nozzle 23, where the container 100 is exposed to the gas. However, part of the gas atmosphere of the container 100 is also formed by the gas which flows from the labyrinth seal 4 in the form of the surface gas flow over the surface 34 of the gassing rotor to the container 100 and the cover 101.

The feed area 21 is connected to the gas supply 3 in the form of a labyrinth seal 4 without contact, so that the gassing rotor 2 in the Operating state is rotatable relative to the gas supply 3. The labyrinth seal 4 corresponds to the embodiment according to FIG. 2.

In the embodiment according to FIG. 4, the gas supply 3 is also sealed off from the shaft 5 by means of a shaft seal 7. FIG. 5 shows a second sectional illustration of the gassing rotor 1 according to the invention according to FIG. 1.

The cleaning system 6 comprises cleaning channels 61 and 62 which are arranged on the labyrinth seal 4 in such a way that a cleaning fluid in the form of a liquid or the gas for gassing the container is supplied to the labyrinth seal 4 to clean the labyrinth seal 4 in the operating state can. The shown embodiment of the labyrinth seal 4 with web 41 and groove 42 (described in more detail for FIG. 2) in combination with the cleaning system 6 has the advantage that no sump of cleaning fluid can form in the labyrinth seal 4, but that Cleaning fluid can easily flow off. This enables hygienic cleaning of the labyrinth seal 4 and the device according to the invention.

In addition, the cleaning system could also be used as an (additional) gas supply, whereby the surface gas flow over the surface 34 could be increased through the cleaning channel 61 in order to enlarge the gas atmosphere around the container.

6 shows a further perspective illustration of the gassing device 1 according to the invention.

The gassing rotor 1 comprises a plurality of container receptacles 20 with gassing nozzles 23, which are flow-connected to the feed area 21 and their respective feed openings 22 via a channel.

In addition, the gas supply 3 comprises a nozzle ring 32 with an annular opening 320. The annular opening 320 is arranged on the supply opening 31 in such a way that the feed area 21 can be selectively flow-connected to at least one of the supply openings 22 via the annular opening 320 by the at least one Feed opening 22 is moved in the operating state by rotation of the gassing rotor 2 about the axis X to the ring opening 320, whereby the feed opening 22 is flow-connected to the ring opening 320. If the feed opening 22 is flow-connected to the ring opening 320, it is also flow-connected to the gas supply 3 and supply opening 31. The supply opening 31 functions as an annular groove 31 and in this embodiment could also be viewed as a supply space which is at least partially arranged on, in particular above the nozzle ring 32 in the gas supply 3.

For example, only a single container can be selectively gassed, while the other containers at the further container receptacles 20 are not yet gassed, but only when their respective feed opening 22 is flow-connected to the ring opening 320.

The ring opening 320 is designed larger than the feed opening 22, however, in such a way that the ring opening 320 extends along the circumference U of the nozzle ring 32 over a plurality of feed openings 22. In this way, (at least) two feed openings 22 can also be flow-connected to the ring opening 320 at the same time. In this way, a feed opening 22 can be pre-gassed, while the container is gassed at another feed opening 22.

A similar effect can be achieved without a nozzle ring 32 with a feed opening 31 which extends over several (e.g. two) feed openings 22. The ring opening 320 or the extension of the supply opening 31 allows the gas flow only in a specific / predeterminable segment (D in FIG. 3) of the gassing rotor 3.

Claims

1 . Gassing device for gassing a container (100) comprising

• a rotatable gassing rotor (2) with a container receptacle (20) for receiving the container (100) and with a feed area (21) for feeding a gas through a feed opening (22) into the

Gassing rotor (2), the container receptacle (20) comprising a gassing nozzle (23), which gassing nozzle (23) for gassing the container (100) is flow-connected to the feed opening (22) of the feed area (21) via a channel (24); and

• a stationary gas supply (3) with a stationary supply opening (31), which stationary supply opening (31) in such a way at the feed area

(21) is arranged that the feed opening (31) with the feed opening

(22) is fluidly connectable; wherein the gas supply rotor (2) in the operating state, the gas from the

Gas supply (3) can be supplied in that the supply opening (22) is moved to the stationary supply opening (31) by rotation of the gassing rotor (2), whereby the supply opening (22) is flow-connected to the supply opening (31), characterized in that the feed area (21) with the gas supply (3) in the form of a labyrinth seal

(4) is connected in a contactless manner, so that the gassing rotor (2) can be rotated relative to the gas supply (3) in the operating state.

2. Gas supply device according to claim 1, wherein the gas supply (3) comprises a groove (42) and the feed area (21) comprises a web (41) arranged in the groove (42) and which is in the form of a labyrinth seal (4) without contact are connected.

3. Gas supply device according to claim 1, wherein the feed area (21) comprises a groove (42) and the gas supply (3) one in the groove (42) arranged web (41), which are connected in the form of a labyrinth seal (4) without contact.

4. Gassing device according to one of the preceding claims, wherein the feed area (21) is arranged at a rotation center (R) of the gassing rotor (2).

5. Gassing device according to claim 4, wherein a shaft (5) rotatable about an axis (X) for rotating the gassing rotor (2) is arranged in the rotation center (R) and is connected to the gassing rotor (2) for rotation test. 6. Gassing device according to one of the preceding claims, wherein the

Channel (24) is arranged in an interior (25) of the gassing rotor (2).

7. Aeration device according to one of the preceding claims, wherein the gassing rotor (2) comprises a plurality of container receptacles (20) with gassing nozzles (23), the gassing nozzles (23) in flow connection with the feed area (21) via the respective feed openings (22) are.

8. Gas supply device according to claim 7, wherein the gas supply comprises a nozzle ring (32) with an annular opening (320), wherein the annular opening (320) is arranged on the supply opening (31) in such a way that the feed area (21) selectively via the ring opening at least one of the feed openings

(22) can be flow-connected by moving the at least one feed opening (22) in the operating state to the ring opening (320) by rotating the gassing rotor (2), whereby the feed opening (22) is flow-connected to the ring opening (320). 9. Gassing device according to one of the preceding claims, wherein the

Gassing rotor (2) is designed as a round plate.

10. Gas supply device according to one of the preceding claims comprising a container feed (12) for supplying containers (100) to the container receptacle (20) and a container discharge (13) for discharging a gassed container (100) with a lid (101) from the container receptacle (20).

11. Gas supply device according to one of the preceding claims comprising a cleaning system (6, 61, 62) which is arranged for cleaning the labyrinth seal (4) on the labyrinth seal (4) in such a way that the

A cleaning fluid can be supplied to the labyrinth seal (4) in the operating state.

12. Gas supply device according to claim 11, wherein the cleaning system (6) comprises a first cleaning channel (61), which cleaning channel (61) is arranged on the labyrinth seal (4) so that the labyrinth seal (4) can be supplied with the cleaning fluid in the operating state is.

13. Gas supply device according to claim 12, wherein the cleaning system (6) comprises a second cleaning channel (62) which is arranged on the feed opening (22) in such a way that the feed opening (22) can be supplied with the cleaning fluid in the operating state. 14. Closer for a container (100), in particular a can closer

(10), comprising a lid supply device (11) for supplying a lid (101) to the container, (100) a gassing device (1) according to one of claims 1 -13 for supplying gas to the container (100) and a closure device ( 14) for closing the container (100) with the lid (101).

15. A method for gassing a container (100) comprising a) providing a gassing device (1) according to any one of claims 1-13; b) receiving a container (100) through the container receptacle (20); c) moving the feed opening (22) to the feed opening (31) by rotating the gassing rotor (2); d) Feeding the gas from the gas supply (3) into the gassing rotor

(2); e) gassing the container (100) from the gassing nozzle (23) of the gassing rotor (2).