FLOW TERMINAL FOR A CONTAINER DIP TUBE

Abstract

A flow diverting device is provided at the lower end of the dip-tube (D) in a bag-in-keg container (C) which is filled top-side-down, e.g. with beer. The device directs the incoming flow to run smoothly back down the outside of the dip tube, gently into the already pooled beer thus minimising any fountain effect and associated turbulence. The device can also be used with single-wall metal or plastic kegs to reduce the dispensing of sediment and allow a greater volume of beer to be withdrawn without fobbing.

Claims

1. A bag-in-keg container: a container body (C); a bag (J) within the container body; a two-port valve (V) providing a first pathway (A) for gas and a second pathway (B) for liquid, said first pathway communicating with a space between the container (C) and the bag (J), and the second pathway communicating with the interior of the bag; a container dip tube (D) within the bag connected to the second pathway (B) of the two port valve (V); characterised in that an end section of the container dip tube (D) has a flow terminal (1), said flow terminal defining a flow passage (8, 9) arranged to communicate with said liquid flow path and which includes a counter-flow portion (8) leading to an opening (4), wherein the direction of liquid flow through said opening (4) is reversed relative to the direction of liquid flow through said end section of the container dip tube (D).

2. A bag-in-keg container according to claim 1 wherein said flow terminal (1) includes an outer wall (2) to surround the end section of said dip tube, and wherein said counter current counter-flow portion (8) is defined by a space between said outer wall and said end section.

3. A bag-in-keg container according to claim 2 wherein said flow terminal (1) includes an end wall (3) closing one end of said outer wall.

4. A bag-in-keg container according to claim 2 wherein said flow terminal (1) includes retaining means (5; 15) to connect the flow terminal to said end section of the dip tube.

5. A bag-in-keg container according to claim 4 wherein said retaining means includes a plurality of fins (5) which extend radially inwards from said outer wall.

6. A bag-in-keg container according to claim 3 wherein said flow terminal (1) includes retaining means (5; 15) to connect the flow terminal to said end section of the dip tube and wherein said retaining means includes a pin (15) secured to said end wall (3).

7. A bag-in-keg container according to claim 6 wherein the pin (15) has a plurality of fins (18) extending radially outwards from a central axis.

8. A bag-in-keg container according to claim 3 wherein said flow terminal (1) includes spacer means (7; 17) forming a gap between said end section of the dip tube and said end wall (3).

9. A bag-in-keg container according to claim 8 wherein said flow terminal (1) includes a plurality of fins (5) which extend radially inwards from said outer wall (2) and wherein the spacer means is formed by a step (7) on the fins (5).

10. A bag-in-keg container according to claim 8 wherein said flow terminal (1) includes a pin (15) secured to said end wall (3) and wherein the spacer means (17) is formed by a step on the pin (15).

11. A bag-in-keg container according to claim 3 in which the end wall (3) contains a substantially conical projection (10) co-axial with the dip tube.

12. A bag-in-keg container according to claim 3 in which the junction between the end wall (3) and the outer wall (2) is internally smoothly curved (11).

13. A bag-in-keg container according claim 1 in which the opening (4) includes a mesh (12).

14. A method of filling a bag-in-keg container wherein a container according to claim 1 is filled top-side-down.

15. A bag-in-keg container: a container body (C); a bag (J) within the container body; a two-port valve (V) providing a first pathway (A) for gas and a second pathway (B) for liquid, said first pathway communicating with a space between the container (C) and the bag (J), and the second pathway communicating with the interior of the bag; a container dip tube (D) within the bag connected to the second pathway (B) of the two port valve (V); wherein an end section of the container dip tube (D) has a flow terminal (1), said flow terminal defining a flow passage (8, 9) arranged to communicate with said liquid flow path and which includes a counter-flow portion (8) leading to an opening (4), whereby the direction of liquid flow through said opening (4) is reversed relative to the direction of liquid flow through said end section of the container dip tube (D); wherein said flow terminal (1) includes an outer wall (2) to surround the end section of said dip tube, and wherein said counter-flow portion (8) is defined by a space between said outer wall and said end section; wherein said flow terminal (1) includes an end wall (3) closing one end of said outer wall; and wherein said flow terminal (1) includes spacer means (7; 17) forming a gap between said end section of the dip tube and said end wall (3).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0027] 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:

[0028] FIG. 1 is a sectional view of a conventional metal keg;

[0029] FIG. 2 is a detailed sectional view of a typical two-port valve as used in such a keg;

[0030] FIG. 3 is a sectional view of a typical filling head as used in top-side down keg filling equipment;

[0031] FIG. 4 is a sectional view of a preferred bag-in-keg container;

[0032] FIG. 5 is a sectional view of a partially filled bag-in-keg container being filled using top-side-down filling equipment;

[0033] FIG. 6 is a general view of a first form of flow terminal fitted to a container dip tube;

[0034] FIG. 7 is a similar view of the flow terminal detached from the dip tube;

[0035] FIG. 8 is a top plan view of the flow terminal;

[0036] FIG. 9 is an axial section through the flow terminal and dip tube;

[0037] FIG. 10 is a sectional view of a partially filled bag-in-keg container provided with the flow terminal during top-side-down filling;

[0038] FIG. 11 is a sectional view of a conventional plastic keg provided with the flow terminal, during dispensing;

[0039] FIG. 12 is a general view of a second form of the flow terminal fitted to a container dip tube;

[0040] FIG. 13 is a top plan view of the second flow terminal;

[0041] FIG. 14 is an axial section through the second flow terminal and dip tube;

[0042] FIG. 15 is a general view of a modified flow terminal which is fitted to a container dip tube.

DETAILED DESCRIPTION OF THE DRAWINGS

[0043] 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.

[0044] Referring to FIGS. 6 and 7, the flow terminal 1 is a one-piece plastic injection moulding for engagement with an end section of the container dip tube D which contains a liquid flow path extending axially thereof and exiting through an open end M of the dip tube. The flow terminal is generally cup-shaped with a cylindrical outer wall 2 and an end wall 3 closing one end of the outer wall. The opposite end of the outer wall 2 provides an annular opening 4. Retaining means are provided to enable the flow terminal to be connected to the end section of the dip tube D. In this embodiment the retaining means comprise fins 5 (six in the embodiment shown) which project radially inwards from the outer wall 2, as shown in FIG. 8. The fins 5 extend axially within the outer wall 2 from the opening 4 to the end wall 3, as shown in FIG. 9. The inner faces 6 of the fins 5 are substantially straight, with a small inward step 7 being provided in each fin to act as spacer means. The dip tube D is a push-fit between the fins 5 and is inserted into the flow terminal until the open end M contacts the inward steps 7. The fins 5 thus form an annular space 8 between the outer wall 2 and the end section of the dip tube D, with a gap 9 between the end of the dip tube and the end wall 3. The flow terminal may be held on the dip tube D by frictional engagement between the fins 4 and the dip tube, with or without additional attachment means such as adhesive, solvent welding etc.

[0045] 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.

[0046] 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 FIG. 15, is to include a fine mesh 12 within the opening 4. This mesh 12 further reduces turbulence and regularises the flow down the outside of the dip tube D, thereby further lowering the impact of the flow when it enters the pool. The mesh pattern can of course vary within the scope of the invention, and the mesh could be fixed in various ways.

[0047] 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 FIG. 10, the flow terminal 1 directs the incoming flow to run smoothly back down the outside of the dip tube D, passing gently into the already pooled beer at the lower end of the bag J, thus reducing or eliminating any fountain effect and associated turbulence.

[0048] 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 FIG. 11, the flow terminal reverses the flow into the dip tube D so that the outgoing liquid is not sucked from the bottom of the keg, but from the opposite direction. A dip tube fitted with this flow terminal 1 can extend further down into the container, reducing the risk of sediment S being dispensed and enabling a greater volume of liquid to be withdrawn before fobbing begins.

[0049] Referring to FIG. 12, the second flow terminal 1 is another one-piece plastic injection moulding for engagement with an end section of the container dip tube D which contains a liquid flow path exiting through an open end of the dip tube. The flow terminal is generally cup-shaped with a cylindrical outer wall 2 and an end wall 3 closing one end of the outer wall. The opposite end of the outer wall 2 provides an annular opening 4. Retaining means are provided to enable the flow terminal to be connected to the end section of the dip tube D. In this embodiment the retaining means comprise a pin 15 of cruciform cross-section which projects upwardly from the end wall 3, as shown in FIG. 13. The outer faces 16 of the pin 15 are substantially straight, with a small outward step 17 forming spacer means. The dip tube D is a push-fit onto the pin 15 and is inserted into the flow terminal until the open end M contacts the steps 17. An annular space 8 is formed between the outer wall 2 and the end section of the dip tube D, with a gap 9 between the end of the dip tube and the end wall 3. The flow terminal may be held onto the dip tube D by frictional engagement between the pin 15 and the dip tube, with or without additional attachment means such as adhesive, solvent welding etc.

[0050] 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.

[0051] 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.

[0052] 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 FIG. 15.

[0053] This second form of flow terminal can be used with bag-in-keg containers as well as single-wall containers as described above.

[0054] 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.

[0055] 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.