The invention relates to a method for filling containers, for example bottles, cans or similar, with a filling material consisting of two components in accordance with the preamble of claim 1. The invention further relates to a filling point for controlled dispensing of the filling material into containers according to the preamble of claim 14 and to a filling machine having several such filling points in accordance with the preamble of claim 25.
The problem of the invention is to demonstrate a method with which containers can be filled easily with a filling material consisting of at least two components, in particular with reproducible proportions of the components in the containers. To solve this problem, a method according to claim 1 has been devised. A filling point and a filling machine for carrying out the method are the subject matter of claims 14 and 25 respectively.
According to the invention, the components are each introduced separately into the container, so that any amalgamation and/or mixing of these components only takes place in the respective container. Preferably the components are introduced in each filling cycle in chronological sequence into the container concerned, so that the filling quantity (filling quantity) assigned to each component can be introduced into the respective container in an exactly controlled or adjusted fashion and, as a result, reproducible conditions, and especially in relation to the proportions (quantity or volume percent or ratio) of the components ensue in the respective filled container.
In one preferred embodiment of the invention, the filling of each container with all the components to be introduced into the respective container occurs at one and the same filling point or using one and the same filling element, and preferably using a filling element with at least one dispensing opening to dispense the filling material, at least one gas trap being assigned to the dispensing opening. At the end of each filling cycle, the sequentially last component of each filling cycle remains in the fluid channel or fluid channel segment formed above the gas trap in the filling element, i.e. it is filled with the component introduced into a container at the end of the filling cycle. This sequentially last component then forms the sequentially first in the subsequent filling cycle, i.e. the component to be introduced first into the respective container.
A filling cycle within the meaning of the invention is that cycle or that filling sequence in which the individual components are introduced into the respective container, and preferably in the initially empty container, which at the end of the filling cycle is filled with the necessary filling quantity or to the necessary fill level.
The particular advantages of the invention consist e.g. in the fact that the individual components are reproducibly introduced into the containers with great accuracy. There is also the option with the invention of equipping the filling elements used, in the area of their dispensing openings, with gas traps, which are traversed during filling by the filling material and enable the respective filling cycle to be completed without emptying the filling elements or their fluid channels and without the risk of dripping by the filling material.
In particular, by the presence of just one gas trap, the opening cross section of the container can be optimally used and nevertheless almost no concessions need be made with respect to the determination (weight) and delimitation (mixing in the pipeline) of different fluid phases.
Refinements, advantages and potential applications of the invention will also become apparent from the following description of exemplary embodiments and from the figures. Here all the features described and/or graphically illustrated, per se or in whatsoever combination, are in principle the subject matter of the invention, regardless of their summary in the claims or back-references thereto. The content of the claims is also an integral part of the description.
The invention will next be described in more detail on the basis of the figures showing exemplary embodiments. The figures show:
In
For filling, the respective bottle 3 is arranged standing upright, i.e. with its bottle axis in the vertical direction and along the same axis or essentially along the same axis with a filling element axis FA at the filling point so that the bottle mouth 3.1 lies directly opposite a dispensing opening 4 formed on the underside of the filling element 1 for the liquid filling material, and in the open jet filling shown, at a distance from this dispensing opening 4. The bottle 3 thereby stands with its bottle base 3.2 on the container support 2 or on an electrical weighing device 5 forming a bottle pad, the measurement signal from which is used to control the filling element 1, i.e. for mass-controlled dispensing of components A and B of the liquid filling material into the bottles 3.
A fluid channel 7 which has the dispensing opening 4 is formed in a housing 6 of the filling element 1, and this channel can be connected in controlled fashion, via two fluid valves 10 and 11, each having an independent control and actuation device 8 and 9 respectively, with a channel 12 to supply component A (fluid valves 10) and with a channel 13 to supply component B (fluid valve 11). The channel 12 is connected to a boiling vessel common to all the filling elements 1 of the filling machine, containing component A. In similar fashion, the channel 13 is connected with a further boiling vessel, likewise common to all the filling elements of the filling machine, containing component B. In particular, in order to avoid any emptying of the fluid channel 7 and dripping of the liquid filling material at the end of the respective filling cycle, a gas trap 14 is arranged in the dispensing opening 4, said trap consisting in the simplest case of a sieve-like insert, but preferably of an insert which has a plurality of channels, each of which is open to the fluid channel 7 and also on the underside of the filling element 1 and which are traversed when components A and B are being filled.
The aim is to combine or to mix both components A and B only in the respective bottle 3 to be filled, so as e.g. to avoid a component, for example component A, when the fluid valve 11 is open, undesirably getting into the channel 13 for component B or vice versa. For this reason, for example, any mixing of the components in the fluid channel 7 is also not desired. A further aim is to introduce components A and B individually and sequentially into the respective bottle 3, so as to be able to control or regulate the filling quantity of each of component A and B precisely.
In the method shown in positions a)-d) in
Using this filling method as shown in
In a first filling cycle, the filling of the bottle 3 concerned takes place, starting with component A, for which the fluid valve 10 is opened via the control device 8 (position a1 in
A subsequent filling cycle to fill a further bottle 3 begins with the opening of the fluid valve 11 by the control device 9 to feed component B into the bottle 3 (position a2 in
In the method shown in
Since at the end of each filling cycle the respective fluid channel 7 or 7.1 and 7.2 each contain only one component A or B, but never a mixture of these components, reproducible starting conditions for each filling cycle are created, so that an exact control or regulation of the filling quantities of the two components introduced into the bottles and hence an exact mix ratio of these components in the bottles 3 is possible.
As
As shown in
At the end of each filling cycle, both fluid channels 7.1 and 7.2 above the gas trap 14 are filled, and each fluid channel 7.1 or 7.2 only with the respective component A or B assigned to it.
In all of the embodiments described above, the controlled closing of the fluid valves 10 and 11 takes place as a function of the filling quantity introduced in each case into the respective bottle 3, triggered by the measuring signal delivered by the weighing device 5.
In order to enable a precise measurement of the respective filling quantity introduced, and thereby in particular also the quantity of the component first introduced in the respective filling cycle, by using the respective weighing device 5, it is necessary when using the method described above, but at least useful, that, within each filling cycle, after introducing the first component, a filling pause is inserted, as indicated in the method shown in
The precise measurement of the filling quantities introduced makes it possible e.g. to undertake a corrective filling, for example with the first or last introduced component. Precise measurement of the filling quantities introduced also makes it possible, e.g. with the measured values from a filling cycle, to conduct a correction of the filling quantities in the respective subsequent filling cycle or else to document the actual filling quantities and their deviation from desired values for filling quantities, etc.
Especially in the case of filling machines for filling containers in the form of bottles 3, the filling element 1 has the advantage over the filling element 1a that in the filling element 1, the cross section of flow of the dispensing opening 4 can adapted to the cross section of the bottle opening 3.1 by being selected to be as large as possible, so that for both components A and B a dispensing opening 4 with a large cross section is produced. In the case of the filling element 1a, however, the cross sections of flow of both dispensing openings 4.1 and 4.2 must together be adapted to the cross section of the bottle opening 3.1, as the result of which a reduced cross section of flow arises for each dispensing opening 4.1 and 4.2 compared with the dispensing opening 4. When filling containers in the form of bottles 3, higher performance (filled filling material quantity or filled bottles 3 per unit of time) is thus possible in principle with a filling machine containing the filling elements 1 than with a filling machine containing the filling elements 1a, and this applies when the construction size of the filling machine and of the rotor with the filling elements are the same.
In
There is also the option of providing the two dispensing openings 4.1 and 4.2, in particular when the dispensing opening 4.2 is annular in form, at different levels, for example dispensing opening 4.1 is set back, i.e. at a greater distance from the bottle opening 3.1 than the dispensing opening 4.2.
There is also the option, both for the filling element 1 and for filling element 1a, of embodying the dispensing openings 4.1 and 4.2 adjustably in the direction of the filling element axis FA, and in particular such that the respective gas trap 14 is arranged to be axially adjustable in the section of the associated fluid channel 7, 7.1 and 7.2 respectively forming the dispensing opening 4, 4.1 and 4.2.
Each filling element 1 and 1 a is also designed so that, in particular on the areas coming into contact with the filling material or components A and B, it can be cleaned, rinsed and/or disinfected with a gaseous, vaporous and/or liquid medium, for example also with water, hydrogen peroxide (H2O2), and in particular also in a CIP method.
The invention has been described above on the basis of exemplary embodiments. It goes without saying that amendments and modifications are possible without thereby departing from the basic concept of the invention.
1, 1a filling element
2 container support
3 bottle
3.1 bottle opening
3.2 bottle base
4, 4.1, 4.2 dispensing opening
5 weighing device
6, 6a housing
7, 7.1, 7.2 fluid channel
8, 9 control and actuation device
10, 11 fluid valve
12, 13 channel
14 gas trap
A, B components of the filling material
FA filling element axis
Number | Date | Country | Kind |
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10 2008 010 078.1 | Feb 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/000783 | 2/5/2009 | WO | 00 | 8/18/2010 |