EP2765115A1 - Device and method for treating at least one container - Google Patents

Abstract

The device (1) has a net chamber (20) enclosed in a housing (2), for treating a container. A fixed housing portion (22) is arranged relative to a moved housing portion (24). First and second surge tanks (3, 4) are arranged for sealing the fixed housing portion in relation to the moved housing portion. First surge tank is provided with specific water level, which is greater than preset water level in the second surge tank. A fluid connection (5) is formed between a discharge portion (36) of the first surge tank and an inlet portion (48) of the second surge tank. An independent claim is also included for a method for cold-aseptic filling of product into container.

Description

Technical area

The present invention relates to a device and a method for treating at least one container, preferably for the cold aseptic filling of a filling material in at least one container, for example for the cold aseptic filling of milk products in a beverage filling plant.

State of the art

In the field of devices for the treatment of containers and especially in devices for cold aseptic filling of a filling in containers, such as for cold aseptic filling of dairy products in containers, it is known, the respective parts of the plant, in which the actual container treatment takes place through a so-called clean room to enclose. Here are certain equipment parts, such as stretch blow molding machines, transfer star wheels, rinsers, sterilizers, fillers and / or capper, arranged with their coming into contact with the respective container, closure and the respective filling product areas in the clean room. Thus, the respective conveyor line, in which the container and the filling product would be susceptible to contamination, performed in the clean room.

In the clean room, a defined atmosphere is preferably produced and maintained, which preferably has a reduced number of germs and spores in order to contaminate the filling product and the containers as little as possible. A bottling in this way makes it possible to achieve the longest possible shelf life of the bottled products. In order to achieve an advantageous Abfüllergebnis, a defined temperature and a defined humidity are maintained in the clean room usual way.

The clean room is usually formed by a housing surrounding the corresponding areas, which protects the clean room from the ingress of germs and allows the formation of a defined atmosphere.

In the beverage filling plants usually designed as rotary machines plant components, such as stretch blow molder, conveyor star, rinser, sterilizer, filler or capper, corresponding peripheral system parts are provided, which include corresponding mitbewegte housing parts. Fixed housing parts, such as side walls, are also provided. There are also usually aggregates such. Drives, valves or sensors of the individual system parts and associated piping and wiring outside the respective moving housing part, for example, outside of the clean room final housing roof. Here, aggregates of individual treatment organs, for example, of closure organs, outside the clean room can be arranged. The corresponding translational and rotational movements of the driven members then take place correspondingly relative to the respective housing part.

Accordingly, a transition between the fixed housing parts and the relatively moving housing parts must be created, which together form the cleanroom enclosing housing. At the transition between the fixed and the rotating housing parts therefore seals are usually provided, which are for example as labyrinth seals using a positive pressure in the clean room, which provides a constant, outwardly directed gas flow through the labyrinth seal, are formed. Furthermore, so-called water locks can be used, in which a sword-shaped housing part is immersed in a trough-shaped housing part, wherein in the trough-shaped housing part, a corresponding barrier medium is provided. The latter type of seal is also called a siphon seal.

It is also known to seal individual, through a housing part extending therethrough treatment organs, such as closure members, via a suitably trained water lock. By means of such a water lock, for example, the components of the treatment member, which perform a rotational and / or translatory movement relative to the housing, can be sealed against the housing. In order to achieve the appropriate sealing effect between the fixed and rotating housing parts, it is necessary that the water locks are always up to an intended height with the respective barrier medium are filled. For this purpose, it is known from the prior art to perform a filling of each individual trough discontinuously whenever it is determined via a corresponding level probe that a predetermined filling level is reached. A disadvantage of such a device is that any overfilling and thus overflow of the blocking medium into other machine areas either can not be detected, or else a further level probe for detecting the overfilling and an additional automation effort is needed.

Furthermore known from the prior art is to fill the respective trough continuously and remove the excess barrier medium via an overflow. This is for example from the DE 10 2006 007 481 B3 known, in which each trough a water castle separately filling is supplied and is determined separately at each water lock via a flow meter, whether the appropriate degree of filling is achieved. Accordingly, the automation effort is also quite high here.

Presentation of the invention

It is therefore an object of the present invention to provide an apparatus and a method for treating at least one container, in which the reliability of the overall system is increased and the cost of automation is reduced.

This object is achieved by a device for treating at least one container with the features of claim 1. Advantageous developments emerge from the subclaims.

Accordingly, an apparatus for treating at least one container, preferably for cold aseptic filling of a filling material in a container proposed comprising a housing enclosing a clean room, in which the treatment of the container is feasible, with a fixed housing part and a relative to this moving housing part to seal the stationary housing part relative to the moving housing part, at least one first water lock is provided on a first level and an at least second water lock is provided on a second level below the first level. According to the invention, there is a fluid connection between an outlet of the first water lock and an inlet of the second water lock.

The fact that there is a fluid connection between an outlet of the first water lock and an inlet of the second water castle, it can be achieved that the first water castle, so the upper water castle, and the second water castle, so the lower water castle, via a common inlet to the barrier medium be supplied. Furthermore, by the resulting cascading, ie the flow of the barrier medium of a higher water castle in a lower water castle, on an additional promotion of the blocking medium, for example by a pump, be dispensed with, since the barrier medium due to the difference in height and the resulting resulting hydrostatic pressure from the first water lock to the second water lock is pressed.

The barrier medium commonly used herein may be water, purified water and / or water provided with a disinfecting and / or sterilizing agent. Any other barrier medium can also be used.

Another advantage of the proposed device results from the fact that a flow for the barrier medium must be connected only to the first water lock and therefore the piping and the cost of supplying the barrier medium to the second water lock can be reduced. By reducing the number of parts involved, especially for control and valves, the reliability of the device can be increased and the cost of automation can be reduced.

Furthermore, the device makes it possible to check the correct level of the first water lock on the behavior of the barrier medium in the downstream second water lock. For example, if the second water lock filled with barrier medium, it can be assumed that the first water lock is filled with barrier medium, otherwise a flow of the barrier medium from the first water lock to the second water castle and the filling achieved by the second water castle would not have occurred. In other words, first the first water lock, so the upper water lock, filled with the barrier medium, and when this filling is complete, the barrier medium to the second water castle, so the lower water castle, overflowed, even in the second water castle a full filling is reached.

In this way, the cost of a possible automation can be reduced because, for example, a correct filling of the two water locks can be detected by means of a single common flow sensor after the second water lock. The filling process of the respective water locks is further simplified, since only one pass of the barrier medium from the upper water lock to the lower water castle must take place and no separate control of the introduction of the barrier medium for the lower water castle is necessary. For this purpose, a flow sensor is preferably provided at the outlet of the second water lock, which is used for common verification of the filling of all upstream water locks.

Accurate monitoring of the filling of the water locks can be achieved by also measuring the flow of barrier media flowing into the inlet of the first water lock by means of a flow sensor provided upstream of an inlet of the first water lock. By forming the difference with the leakage medium flow leaving the second water lock, irregularities, for example a leak or a blockage and a concomitant overflow of the blocking medium into other plant areas, can accordingly be inferred.

It also follows immediately that due to the fluid connection between the outlet of the first water lock and the inlet of the second water lock a separate signaling for the two water locks is no longer necessary, but in the presence of a correct level in the second water castle or in detection of an outflow from the second water lock can be deduced to a correct level and the first water castle. The presence of a complete and proper seal by means of water locks can therefore be issued via a simple signaling when the lower water lock is completely filled.

Particularly easy maintenance of a predetermined filling level in the first and in the second water lock can be achieved if the outlet of the respective water castle is designed as a filling level of the water castle predetermining overflow. Accordingly, first the first, above, water lock is filled with the barrier medium until it has reached the predetermined by the overflow level. Only then does the barrier medium pass over and into the second, below it, moated castle. So it can be ensured that the first water lock is filled to the predetermined filling level and only then the second Water lock is filled to the specified filling level. A correct filling of all water locks can then be determined by measuring at least the presence of a barrier media flow from the outlet of the second water lock.

Furthermore, the first water lock and the second water lock can be charged via a barrier medium reservoir arranged above with the blocking medium. In this case, for example, a closure disinfection basin, which has a corresponding outlet, can be used to feed the first water lock and the second water lock. It then takes place preferably only a flow of the corresponding barrier medium from the liquid reservoir arranged above it to the first water lock and then on to the second water lock arranged underneath, without a pump having to be used. In this way too, the complexity of the overall system can be reduced, thereby increasing reliability. At the same time energy can be saved.

By means of the fluid connection between the outlet of the first water lock and the inlet of the second water lock, integration of the device in a circulation line or else in discontinuous systems can furthermore be achieved since there is a flow from the upper water lock to the lower water lock, which is capable of circulation. However, this flow can also be operated via a discontinuous, for example timed, system. For this purpose, a flow to an inlet of the first water lock, as well as a return from an outlet of the second water lock in a circulation line are preferably involved, and preferably a circulation of the barrier medium from the flow through the first water lock, through the fluid connection and through the second water lock through to Return provided. The barrier medium runs through the water locks cascade from top to bottom.

To check whether both the upper water lock and the lower water lock are completely filled with the barrier medium, a flow sensor at the outlet of the second water lock is preferably provided by means of which it can be checked whether the barrier medium expires from the second water lock and correspondingly a complete filling the first and the second moated castle is present.

In a preferred embodiment, moreover, a drainage line is provided in fluid communication with the lowest point of the first water lock and the second water lock to allow complete emptying of the respective water locks, for example for maintenance and cleaning purposes of the entire system.

About the drainage line the water locks can also be emptied individually and independently, if the respective outlet of the other water castle, for example, due to the formation as overflow, remains blocked.

Preferably, a check valve and / or check valve downstream of the outlet of at least the second water lock is provided to prevent overflow of the blocking medium into the lower water lock due to the hydrostatic pressure when emptying the upper water lock.

The system described above by means of two water locks may particularly preferably have between the level of the first water lock and the level of the second water lock at least one further water lock, which communicates via the fluid connection in the same way with the first water lock and the second water lock. A further water lock arranged between the first and the second water lock can be charged with the blocking medium in the same way as described above. Accordingly, in turn can be deduced from the flow of the barrier medium from the lowest water castle on the filling of all upstream water locks. The barrier medium flows through all connected water locks cascading from top to bottom. It is accordingly a series connection of the different water locks.

In order to achieve trouble-free flow through all the water locks connected to one another via the fluid connection, the fluid connection is preferably designed so that the barrier medium can flow through the water locks arranged on the different levels in a cascade.

Particularly preferred is a water seal which seals off a rotational and / or translational movement of a treatment member, and the first water lock and / or the second water lock is sealing with the treatment member Water lock connected cascading over the fluid connection. In this way, a continuous supply of the individual water locks can be achieved, wherein the barrier medium then flows through the water locks cascading from top to bottom.

The first and / or the second water lock may also be formed by such a water lock sealing a rotational and / or translational movement of a treatment member.

In a further preferred embodiment, a flow, a return and / or a drainage over at least one distribution track of a media rotary distributor is transferred to the moving housing part. In this way, co-rotating troughs and co-rotating water locks, for example, for sealing a treatment member, can be supplied with the corresponding barrier medium.

The object described above is also achieved by a method having the features of claim 13. Advantageous developments emerge from the subclaims dependent on this claim.

Accordingly, a method for treating at least one container, preferably for cold aseptic filling of a filling material in a container, proposed in a clean room enclosing housing having a fixed housing part and a relative to this moving housing part, wherein for sealing the stationary housing part relative to the moving Housing part at least a first water lock on a first level and at least a second water lock are provided at a level lying below the first level. According to the invention, a barrier medium is conducted from the first water lock into the second water lock.

By the management of the barrier medium from the first water lock to the second water lock and the advantages mentioned above with respect to the device are achieved.

Brief description of the figures

Figur 1

eine schematische Darstellung einer Vorrichtung zur Behandlung mindestens eines Behälters; und

Figur 2

eine schematische Darstellung einer Vorrichtung zur Behandlung mindestens eines Behälters in einer weiteren Ausführungsform.

Preferred further embodiments and aspects of the present invention are explained in more detail by the following description of the figures. Showing:

FIG. 1

a schematic representation of an apparatus for treating at least one container; and

FIG. 2

a schematic representation of an apparatus for treating at least one container in a further embodiment.

Detailed description of preferred embodiments

In the following, preferred embodiments will be described with reference to the figures. In this case, identical, similar or equivalent elements in the different figures are denoted by identical reference numerals and a repeated description of these elements will be omitted in the following description in part in order to avoid redundancies.

FIG. 1 schematically shows a device 1 for treating at least one container, comprising a housing 2, which encloses a clean room 20. The housing 2 has a fixed housing part 22 and a housing part 24 which is movable relative thereto. The movable housing part 24 is, for example, in a device for cold aseptic filling of a filling in containers in the form of a housing part, such as a plant roof, together with the respective plant part, such as a rinser, a sterilizer, a filling machine or a capper, rotating housing part. The fixed housing part 22 is for example a side wall of such a system.

To seal the stationary housing part 22 relative to the moving housing part 24, a first water lock 3 is provided, which is arranged on a first level N ₁ . Furthermore, a second water lock 4 is arranged on a second level N ₂ . The trough 30 of the first water lock 3 and the trough 40 of the second water lock 4 are in the in FIG. 1 shown embodiment attached to the stationary housing part 22.

In an alternative, an attachment of the respective trough 30, 40 or the entire water lock 3, 4 may be provided on the moving housing part 24. A recording of a whole water lock on the moving housing part 24 is particularly the case, for example, if individual treatment organs such as closure members are arranged on the moving housing part 24 and rotate together with the moving housing part 24. The sealing of the rotary or - a corresponding depth of immersion of a corresponding sword in a corresponding trough presupposed - translational movement of a corresponding treatment member relative to a housing roof can be achieved accordingly by a co-rotating as a whole about the axis of rotation of the device 1 moated castle. In this case, preferably a supply, a drainage and / or a return or a supply line or a discharge for the co-rotating troughs of the corresponding water locks via a corresponding track of a media rotary distributor supplied and / or removed.

In the in FIG. 1 shown schematic representation, only a first water lock 3 and a second water lock 4 are shown. However, it can also be provided several water locks, depending on the geometric design of the overall device. In particular, several water locks can be connected to one another in the manner described below.

The first water lock 3 comprises an annular trough 30, which surrounds at least a part of a plant part concentric with its axis of rotation and in which a barrier medium 32 is accommodated, which is filled up to a predetermined filling level h ₁ . The barrier medium 32 is, for example, water, purified water and / or water added with a disinfectant and / or sterilant.

In the barrier medium 32 immersed with the moving housing part 24 annular sword 34 dives. The sword 34 can rotate about the axis of rotation of the plant part. By immersing the sword 34 in the barrier medium 32, a gas-tight seal of the located on the inside and the outside of the sword 34 spaces is achieved against each other accordingly. To ensure reliable sealing even during a relative movement of the housing parts 22, 24 to reach each other, a certain minimum filling must be achieved in the trough 30, preferably, the predetermined filling level for ₁ hour.

The second water lock 4 has a substantially identical structure and accordingly also has a trough 40, which is filled with a barrier medium 42 up to a filling level h ₂ . In the barrier medium 42 dives a sword 44, which is attached to the moving housing part 24.

The first water lock 3 is in direct communication with the second water lock 4 via a fluid connection 5. In this case, the fluid connection 5 is designed such that it leads from an outlet 36 of the first water lock 3 to an inlet 48 of the second water lock 4. Accordingly, barrier medium 32 flows out of the first water lock 3 via the outlet 36 and via the fluid connection 5 to the inlet 48 of the second water lock 4 and fills the second water lock 4 corresponding to the leaked from the first water lock 3 barrier medium.

In the in FIG. 1 shown embodiment, the outlet 36 of the first water lock 3 is formed as an overflow, by means of which a simple level position of the barrier medium at the predetermined filling level h ₁ can be achieved. Accordingly, the barrier medium 32 from the first water lock 3 only runs out of the outlet 36 designed as an overflow when it has reached the desired filling level h ₁ in the trough 30. An overflow of the trough 30 is prevented in this way but also because the filling level can not exceed the predetermined by the trained as overflow outlet 36 height.

Since the level N _{1 of} the first water lock 3 is above the level N _{2 of} the second water lock 4, and in particular the filling level h _{1 of} the first water lock 3 is above the desired filling level h _{2 of} the second water lock 4, by the leakage of the blocking medium 32 via the outlet 36 of the first water lock 3 a reliable filling of the second water lock 4 can be achieved without the need for a special control or regulation would be necessary. Furthermore, it is also possible to dispense with a pump or another conveying device for the blocking medium, which supplies the second water lock 4 directly.

The filling level h _{2 of} the second water lock 4 is in the in FIG. 1 embodiment shown also reached via an overflow outlet 46, which ensures that the filling level is maintained.

The barrier medium is supplied via a supply line 6 to the corresponding inlet 38 of the first water lock 3. Via a valve 60, the flow can be controlled and via a flow sensor 70, the flow of the barrier medium to the inlet 38 can be measured. If the barrier medium completely fills the first water lock 3 in such a way that it flows over the outlet 36, it flows via the fluid connection 5 to the inlet 48 of the second water lock 4. Although the second water lock 4 is completely filled so that the barrier medium overflows the outlet 46, it can be detected via a arranged on a return flow sensor 8 72, the return flow. A first drainage valve 90 and a second drainage valve 94, which will be discussed below, are closed during the filling process. In a connecting line 7 between the outlet 46 and the return 8 is a check valve 80 which is open during the filling process and during plant operation. Advantageously, the connecting line 7 opens in front of the flow sensor 72 in the return 8 a. This ensures that the barrier medium can actually be detected by the flow sensor 72.

If no loss of fluid occurs and both water locks 3, 4 are completely filled, ideally corresponds to the feed stream to the return flow. By providing appropriate tolerances can here any liquid loss, for example, by evaporation or by slight splashing due to the relative movement of the fixed housing parts 22 relative to the moving housing parts 24, are compensated. When a certain tolerance is exceeded, however, an alarm signal can be output, such that a leak is suspected and the entire system is stopped, for example.

Accordingly, after a predetermined filling time in which both the first water lock 3 and the second water lock 4 are completely filled with the barrier medium, a constant volume flow in the return line 8 is expected, which substantially corresponds to the volume flow in the inlet 6.

In this way, a very simple monitoring of both water locks 3, 4 can already be achieved by measuring the outflowing volume flow.

To monitor whether both water locks 3, 4 are actually filled, the flow meter 72 in the return line 8 is completely sufficient. By means of this flow meter 72 can be determined, if ever a liquid flow through the two water locks passes. If this is the case, it can be assumed that both water locks are filled up to the predetermined filling level h ₁ or h ₂ with the respective barrier medium, since otherwise no overflow via the outlet 36 or the outlet 46 from the first water lock 3 or the second water lock. 4 would be done.

In order to still allow accurate monitoring of the level of the first water lock 3 and the second water lock 4, a fill level sensor 74 and the second water lock 4 also a level sensor 76 may be provided on the first water lock 3, which are optional, but by means of which a precise Determining the fill level.

In order to be able to empty the first water lock 3 and the second water lock 4, a drainage line 9 is furthermore provided. By means of the first drainage valve 90, a drain 92 preferably located at the lowest part of the trough 30 of the first water lock 3 can be opened. By means of the drainage valve 94, a drain 96 located preferably in the lowest point of the trough 40 of the second water lock 4 can be opened. By opening the first drainage valve 90, the first water lock 3 can be correspondingly completely emptied of blocking medium 32, and by opening the second drainage valve 94, the second water lock 4 can be completely emptied analogously. Advantageously, first the first water lock 3 can be emptied, wherein the complete emptying can be detected via the flow sensor 72. Alternatively, this is also possible at this point by a blank detection probe when the barrier medium from the first water lock 3 has completely run into a channel connection (not shown) in the return 8. During the emptying of the first water lock 3, the shut-off valve 80 is closed in the connecting line 7. As a result, it can be advantageously prevented that, due to the hydrostatic pressure, fluid flowing out of the first water lock 3 from the first water lock 3 is pressed into the second water lock 4 via the connecting pipe 7 and causes it to overflow. Instead of the check valve 80, for example, a check valve may be provided which prevents overflow of barrier medium from the first water lock 3 in the second water lock 4 via the connecting line 7. After complete emptying of the first water lock 3, the second drainage valve 94 can be opened for emptying the second water lock.

An emptying of the upper water lock 3 can be monitored both via the flow meter 72 and via the fill level sensor 74. An emptying of the lower water lock 4 can likewise be monitored via the flow meter 72 or the lower fill level sensor 76.

The flow 6 may be configured in a preferred variant so that the barrier medium over a above the filling level h ₁ arranged supply tank, so that, accordingly, an introduction of the barrier medium is made possible by a simple shrinkage. This is achieved, for example, by means of a closure disinfection basin with a corresponding overflow arranged above the upper water lock 3. In this way, can be dispensed with a pumping of the corresponding barrier medium.

The flow 6 and the return 8 may further be integrated in a circulation line, by means of which the barrier medium circulates in this system area or in other areas of the plant. The cascaded flow through the barrier medium through the first water lock 3 and the second water lock 4 and any number of interposed water locks so a cycle is possible. In this way, it is further ensured that always optimally treated barrier medium is used, which accordingly fulfills an optimal barrier effect and disinfecting effect.

In FIG. 2 a further embodiment of a device 1 is shown, wherein here again a housing 2 enclosing a clean room 20 is provided which has a fixed housing part 22 and a housing part 24 which is moved relative thereto. A first water lock 3 and a second water lock 4 arranged underneath are provided in order to seal the stationary housing part 22 relative to the moving housing part 24.

The moving housing part 24 rotates about an axis of rotation R, along which a fixed distribution column 220 extends. A distributor sleeve 240, which can also serve to support the moving housing part 24, rotates about the stationary distribution column 220. On the moving housing part 24 is further schematically a treatment member 10, which is shown here schematically as Verschließorgan provided. The treatment member 10 rotates together with the moving housing part 24 about the rotational axis R. The treatment member 10 itself performs indicated by the arrows rotational and translational movements, wherein a drive portion 12 is disposed outside the clean room 20, and a treatment area 14 is disposed within the clean room 20. The implementation of the rotary and translational drive of the drive region 12 to the treatment area 14 through the moving housing part 24 is again sealed by a water lock 100, wherein an annular trough 110 and a corresponding annular sword 120 are provided. The water lock 100 is located on the first (uppermost) level N ₁ , the second water lock 4 on the underlying second level N ₂ and the first water lock 3 at a lying between the first level N ₁ and the second level N ₂ level.

Accordingly, in the manner already described above, a blocking medium from the uppermost water lock 100 can flow cascade-shaped via a fluid connection 5 to the first water lock 3 and then via a fluid connection 5 to the second water lock 4. A separate pump for guiding the blocking medium from the topmost water lock 100 to the first water lock 3 and the second water lock 4 is accordingly not necessary.

A supply line 6 to the uppermost water lock 100 is guided in the stationary distribution column 220 to the rotary distributor sleeve 240, wherein the transfer is achieved by a corresponding distribution track 246 of a media rotary distributor.

A return 8 is also guided in the fixed distribution column 220 and passes from the moving housing part 24 via a corresponding distribution track 248 of a media rotary distributor in the distribution column 220th

The drainage of the troughs 110, 30, 40 is - as described above - carried out via a drainage line 9, which is provided with corresponding, not shown here, drainage valves. The drainage line 9 is also transferred via a corresponding distributor track 249 from the moving housing part 24 to the stationary distribution column 220.

Where applicable, all individual features illustrated in the individual embodiments may be combined and / or interchanged without departing from the scope of the invention.

LIST OF REFERENCE NUMBERS

1

Device for treating at least one container

10

treatment member

12

driving range

14

treatment area

100

water Castle

110

trough

120

sword

2

casing

20

cleanroom

22

fixed housing part

24

moving housing part

220

fixed distribution column

240

rotating distributor sleeve

246

Distribution track forerun

248

Distribution track return

249

Distribution track drainage

3

first moated castle

30

trough

32

barrier medium

34

sword

36

outlet

38

Intake

4

second moated castle

40

trough

42

barrier medium

44

sword

46

outlet

48

Intake

5

fluid communication

6

leader

7

connecting line

70

Flow sensor at the flow

72

Flow sensor on the return

74

level sensor

76

level sensor

8th

returns

80

shut-off valve

9

drainage line

90

drainage valve

92

outflow

94

drainage valve

96

outflow

N ₁

first level

N ₂

second level

h ₁

first filling level

h ₂

second filling level

R

axis of rotation

Claims (15)

Device (1) for treating at least one container, preferably for cold aseptic filling of a filling material into a container, comprising a housing (2) enclosing a clean room (20), in which the treatment of the container is feasible, with a fixed housing part (22) and a relative to this moving housing part (24), wherein for sealing the stationary housing part (22) relative to the moving housing part (24) at least a first water lock (3) on a first level (N ₁ ) and at least a second water lock (4) a second level (N ₂ ) lying below the first level (N ₁ ),
characterized in that
a fluid connection (5) between an outlet (36) of the first water lock (3) and an inlet (48) of the second water lock (4). Device (1) according to claim 1, characterized in that the outlet (36) of the first water lock (3) is designed as a filling level (h ₁ ) of the first water lock (3) predetermined overflow. Device (1) according to claim 1 or 2, characterized in that the outlet (46) of the second water lock (4) is designed as a filling level (h ₂ ) of the second water lock (4) predetermined overflow. Device (1) according to one of the preceding claims, characterized in that a flow sensor (72) is provided at the outlet (46) of the second water lock (4) for the joint verification of the filling of all water locks (3, 4) and / or
a flow sensor (70) is provided in front of an inlet (38) of the first water lock (3), for measuring a barrier media flow flowing to the inlet (38) of the first water lock (3). Device (1) according to one of the preceding claims, characterized in that a with the inlet (38) of the first water lock (3) communicating flow (6) via a above the level (N ₁ ) of the first water lock (3), preferably above the filling level (h ₁ ) of the first water lock (3) arranged barrier media storage is fed, preferably from a closure disinfection tank. Device (1) according to one of the preceding claims, characterized in that a flow (6) to an inlet (38) of the first water lock (3), and a return (8) from an outlet (46) of the second water lock (4) are incorporated in a circulation line, and preferably a circulation of the barrier medium from the flow (6) through the first water lock (3) through the fluid connection (5) and through the second water lock (4) through to the return (8) is provided. Device (1) according to one of the preceding claims, characterized in that a drainage line (9) is provided, which in fluid communication with a preferably at the lowest point of the first water lock (3) arranged outflow (92) and at a lowest point of the second water castle (4) arranged drain (96) is connected and preferably via at least one drainage valve (90, 94) is closed. Device (1) according to one of the preceding claims, characterized in that a check valve (80) and / or check valve downstream of the outlet (46) of at least the second water lock (4) is provided. Device (1) according to one of the preceding claims, characterized in that between the level (N ₁ ) of the first water lock (3) and the level (N ₂ ) of the second water lock (4) at least one further water lock is provided which over the Fluid communication with the first water lock (3) and the second water lock (4) communicates. Device (1) according to one of the preceding claims, characterized in that the fluid connection (5) is formed so that barrier medium can flow on the different levels (N ₁ , N ₂ ) arranged water locks (3, 4) cascade. Device (1) according to one of the preceding claims, characterized in that a rotational and / or translational movement of a treatment member (10) sealing water lock (100) is provided and the first water lock (3) and / or the second water lock (4) with the treatment member (10) sealing water lock (100) via the fluid connection (5) is cascaded,
and or
the first water lock (3) and / or the second water lock (4) is formed by a water lock which seals off a rotational and / or translatory movement of a treatment member (10). Device (1) according to one of the preceding claims, characterized in that a flow (6), a return (8) and / or a drainage via at least one distribution track (246, 248, 249) of a media rotary distributor to the moving housing part (24) is handed over. Method for treating at least one container, preferably for cold aseptic filling of a filling material in a container, in a housing (2) surrounding a clean room (20), which has a fixed housing part (22) and a housing part (24) moved relative to it for sealing the stationary housing part (22) relative to the moving housing part (24), at least one first water lock (3) at a first level (N ₁ ) and at least one second water lock (4) at a second level below the first level (N ₁ ) Level (N ₂ ) are provided,
characterized in that
a barrier medium from the first water lock (3) in the second water lock (4) is passed. A method according to claim 13, characterized in that the barrier medium flows through the water locks (3, 4) in cascade. A method according to claim 13 or 14, characterized in that the filling of all water locks (3, 4) via a flow sensor (72) at the outlet (46) of the second water lock (4) is checked.

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