This invention relates to a flow terminal for a container dip tube, e.g. for beer kegs.
Kegs may be used to hold and transport various liquids. They are frequently used to transfer beer from a brewery to the point of dispense for example. Typically, a beer keg has a capacity of 10 to 50 litres and consists of a pressure resistant metal or plastic container with a combined two-port valve.
Kegs are normally dispensed with the valve orientated upwards (top-side-up). This gives convenient access for the operator to connect and disconnect a coupling connector. Pressurised gas in introduced through the first flow path A into the top of the keg thus allowing the beer to be drawn off from the bottom of the keg via the dip tube D through the second flow path B. Kegs are normally refillable, and as the contents of the kegs are normally intended for human consumption the kegs need to be cleaned before each filling cycle. Theoretically, they could be filled top-side-up however, the dip tube cannot practically reach the lowermost part of the keg as this would block the tube and thus prevent flow, so it would not be possible to effectively remove 100% of any cleaning agents used. For this reason kegs are normally filled with the valve oriented downwards (top-side-down).
The filling process aims to maintain strict hygiene and normally takes several minutes. A typical filling process is as follows:
It is generally accepted that the beer should not be subjected to excessive turbulence as it enters the keg as this creates foam and can have a detrimental effect on the beer quality. As the beer enters at the bottom of the keg, there is a relatively short period of turbulence on initial entry, but as the beer pools in the bottom this dampens the effect and the remainder of the fill is relatively free from excessive turbulence. When the desired amount of beer has been introduced both paths are closed and the connecting coupler is detached.
A relatively recent innovation in beer kegs is the so-called bag-in-keg container. In this case a flexible bag is used within the keg to hold the beer and physically separate the gas and beer. This gives some qualitative advantages to the system. It is not practical to re-use the bags as they are extremely difficult to clean effectively after use. Therefore, bag-in-keg systems are invariably single use with the container, chimes and two-port valve being of recyclable plastics. In these systems, the bag is connected to the second flow path of the two-port valve with the first flow path serving the space between the bag and the outer container. In a preferred configuration, a dip-tube is included within the bag. This dip tube ensures that the liquid is dispensed for the bottom of the keg and therefore minimises a phenomenon known as ‘fobbing’ during dispense. Fobbing is the presence of significant amounts of gas/foam being dispensed with or instead of liquid. In conventional kegs, fobbing occurs normally when the keg empties of liquid, and the level falls below the bottom of the dip-tube. This can cause problems with the dispense system, and often so-called anti-fobbing devices are fitted to shut-off the beer flow if fobbing is detected.
It is not necessary to use a dip-tube in a bag-in-keg system, as the displacing gas pressure acting on the outside of the bag is enough to literally ‘squeeze’ the beer out through the second path. However, in bag-in-keg configurations without a dip-tube, fobbing can occur at any time during dispense if the dispensing gas pressure falls below carbonation pressure of the liquid. In this case, the low pressure allows gas to effervesce from the liquid and as the outlet port is at the top of the bag, the gas is dispensed along with or instead of the beer.
While the dip tube minimises the possibility of fobbing during dispensing, it can cause some undesirable effects when dispensing liquids that have suspended particulates e.g. craft beers. In these cases, a sediment can form on the bottom surface of the keg during the time between filling and dispensing. If the dip-tube is extended substantially toward this bottom surface, it can cause some of this sediment to be sucked-up during dispense. For this reason, it is generally preferred to position the bottom end of the dip tube further away from the bottom surface, but this often results in increased risk of fobbing when the liquid level reaches the end of the dip tube.
One objective of the present invention is to providing a simple but effective means of reducing frothing and turbulence when filling bag-in-keg containers with a dip tube using top-side-down filling equipment.
A second objective is to provide a means of reducing the risk of fobbing and the dispensing of particulates in any keg having a dip tube.
This invention provides a bag-in-keg container:
During filling of the bag-in-keg container the flow terminal re-directs the incoming flow to run smoothly back down the outside of the dip tube, gently into the already pooled liquid thus minimising any fountain effect and associated turbulence.
The following description and the accompanying drawings referred to therein are included by way of non-limiting example in order to illustrate how the invention may be put into practice. In the drawings:
The drawings show two forms of flow terminal for use with a container dip tube of a bag-in-keg container of the kind described in the introductory paragraphs above. The flow terminals can also be used with conventional single-wall kegs formed of metal or plastics, which are also described above.
Referring to
A continuous flow passage is thus provided from the interior of the dip tube D through open end M, into the gap 9, which in turn leads into the space 8 between the dip tube D and the outer wall 2, exiting through the opening 4. The space 8 provides a counter-flow portion leading to the opening 4, so that the direction of liquid flow through the opening 4 is reversed relative to the axial direction of liquid flow through the dip tube D.
Several features are incorporated in this flow terminal which help to minimise turbulence and ensure smooth linear flow exiting from the opening 4. Firstly, the end wall 3 is provided with a generally conical projection 10 located co-axially with the open end M of the dip tube D, which distributes the flow evenly in all radial directions. Secondly, the junction between the end wall 3 and the outer wall 2 is internally smoothly curved at 11 to continue the smooth flow of liquid into the counter-flow space 8. Thirdly, the fins 5 divide the axial flow through the space 8 into six parallel sub-passages which helps to ensure that the flow exiting from the opening 4 is parallel to the axis of the dip tube D and non-turbulent. A further feature which can usefully be included, one embodiment of which is shown in
When used in a bag-in-keg container with a two-port valve, such as a beer keg, during top-side-down filling as shown in
The flow terminal can also be used with conventional single-wall kegs of metal or plastics fitted with a two-port valve when dispensing craft beers or other liquids that have suspended particulates. As shown in
Referring to
Although a pin 15 with a cruciform cross-section is easy to mould it will be appreciated that any regular cross-sectional shape could be used which has a plurality of radially-projecting fins 18 extending outwards from a central axis, e.g. three, five or six fins. The important thing to note is that the pin 15 acts to divide the flow of liquid within the dip tube into a number of equal and parallel streams.
A continuous flow passage is provided from the interior of the dip tube D through open end M, into the gap 9, which in turn leads into the space 8 between the dip tube D and the outer wall 2, exiting through the opening 4. The space 8 provides a counter-flow portion leading to the opening 4, so that the direction of liquid flow through the opening 4 is reversed relative to the axial direction of liquid flow through the dip tube D.
Features incorporated in this flow terminal help to minimise turbulence and ensure smooth linear flow exiting from the opening 4. The pin 15 divides the flow into a number of equal streams and distributes the flow evenly in all radial directions. The junction between the end wall 3 and the outer wall 2 is also internally smoothly curved at 11 to continue the smooth flow of liquid into the counter-flow space 8 which helps to ensure that the flow exiting from the opening 4 is parallel to the axis of the dip tube D and non-turbulent. A mesh 12 could advantageously be included in the opening 4 as described above in relation to
This second form of flow terminal can be used with bag-in-keg containers as well as single-wall containers as described above.
It should be noted that in the flow terminals described herein the outer wall 2 need not be cylindrical, e.g. hexagonal. Furthermore, the flow terminal could be integrally formed with the dip tube.
Whilst the above description places emphasis on the areas which are believed to be new and addresses specific problems which have been identified, it is intended that the features disclosed herein may be used in any combination which is capable of providing a new and useful advance in the art.
Number | Date | Country | Kind |
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1908215.5 | Jun 2019 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/GB2020/051384 | 6/8/2020 | WO | 00 |