The invention relates to a filling element according to the preamble of claim 1 or 3 and to a filling machine according to the preamble of claim 10.
Filling elements for filling bottles or similar containers, in particular also for the pressure filling or counterpressure filling of containers, are known in various designs, specifically also in a design having the features of the preamble of claim 1.
One disadvantage of these known filling elements is, inter alia, that the liquid charge during the filling process generally flows towards the respective filling element or the liquid channel thereof in a direction of flow that is radial to a vertical filling element axis, and the direction of flow of the charge is deflected through 90° or approximately 90° after entering the liquid channel of the filling element, which generally leads to not inconsiderable turbulence within the charge. The charge then flows within the liquid channel over an initially relatively large flow cross-section towards the open liquid valve on the filling element, at which the flow cross-section suddenly or abruptly narrows due to the enlarged cross-section of a valve body there, which again leads to turbulence and to a reduction in the flow rate of the charge towards the respective container and in particular prevents the formation of a homogeneous, uniform flow of the charge, which has a negative effect inter alia on the performance of a filling system or filling machine (number of filled containers per unit time).
Specifically in the case of pressure-filling containers with a CO2-containing liquid charge, for example with beer, the situation moreover cannot be reliably avoided whereby, at the end of the respective filling process and of the pressure release to atmospheric pressure which takes place at that point and which partially takes place via a gas channel (return gas channel), a foaming of the charge and an associated rising of the foamed charge into this gas channel occurs. Due to the relatively small cross-section of the gas channel on known filling elements, in particular including on those having a probe which extends through the gas channel and which determines the filling level of the charge in the container, there is a considerable risk that even the penetration of very small quantities of the foamed charge into the gas channel will lead not only to contamination in this channel but also in adjoining gas spaces, gas channels or valves formed in the filling element.
The object of the invention is to provide a filling element which avoids the aforementioned disadvantages, ensures in particular the formation of a harmonious, uniform flow of the charge through the liquid channel when the liquid valve is open and/or avoids the penetration of foamed charge into critical areas of the gas channel and adjoining gas spaces and/or channels of the filling element.
In order to achieve this object, a filling element is configured according to claim 1. A filling machine forms the subject matter of claim 10.
One special feature of the invention lies in the fact that the liquid channel has, in a liquid channel portion upstream of the liquid valve and extending over a large part of the liquid channel, a constant or substantially constant flow cross-section, namely a flow cross-section which corresponds substantially to the flow cross-section in the region of the valve body, so that abrupt changes in the flow cross-section on the valve body are avoided and a homogeneous, uniform flow of the charge can form in said liquid channel portion when the liquid valve is open.
The further special feature of the invention lies in the fact that the gas tube (return gas tube), in a gas channel portion adjacent to the liquid valve or the valve body thereof but upstream of the valve body relative to the direction of flow of the charge in the liquid channel, is widened in terms of the internal cross-section and thus also in terms of the flow cross-section, namely in particular in comparison to the cross-section of the gas tube at its lower, open gas tube end. At the end of the respective filling process, any charge foam rising in the gas tube can thus be accommodated in this widened gas tube portion and thus does not enter critical areas of the gas channel and adjoining gas spaces and/or channels of the filling element.
In the context of the invention, the expression “substantially” means deviations of +/−10%, preferably of +/−5%, from the respective exact value.
Further developments, advantages and possible uses of the invention will also become apparent from the following description of examples of embodiments and from the figures. All the features described and/or shown form in principle, per se or in any combination, the subject matter of the invention, regardless of the way in which they are combined in the claims or the way in which they refer back to one another. The content of the claims is also included as part of the description.
The invention will be explained in more detail below with reference to the figures and on the basis of an example of embodiment. In the figures:
The filling valve shown in
Provided coaxial to the filling element axis FA is a gas tube 8 which protrudes downwards with its lower, open end beyond the discharge opening and the annular seal 6, extends with a partial length through the liquid channel 3 and is passed out of the liquid channel 3 at the top of the liquid channel 8 in a manner sealed by means of a seal 9 that is configured for example as a membrane.
Also provided coaxial to the filling element axis FA is a rod-shaped probe 10 which determines the filling level during the filling of the respective container, extends through the gas tube 8 and protrudes with its lower probe end out of the lower, open end of the gas tube 8, namely so as to form within the gas tube 8 an annular gas channel 11 (return gas channel) surrounding the probe 10. This gas channel 11 is open at the lower end of the gas tube 8 and opens at the upper end of the gas tube 8 into a chamber 12 which, like the gas channel 11, forms part of gas paths of the filling element 1 that control the respective filling process, as likewise known to the person skilled in the art.
Provided in the liquid channel 3 is a liquid valve 13 which, for the controlled discharging of the liquid charge, is opened and closed as a function also of the signal from the probe 10. For the liquid valve 13, the gas tube 8 is configured over a relatively short lower partial length, which is accommodated in the liquid channel 3, as a valve body 14 which cooperates with a valve seat 15 on the inside of the liquid channel 3. In order to open and close the liquid valve 13, the gas tube 8 can be moved up and down (double-headed arrow A) in a controlled way in the manner of a valve plunger in the direction of the axis FA by means of an actuating device 16 which is for example a pneumatic actuating device.
The filling of the respective container by the filling element 1 takes place by means of a filling method known to the person skilled in the art, for example a pressure filling or counterpressure filling method, in which the container located in a sealed position against the filling element is preloaded—for example after preliminary evacuation and flushing with inert gas (CO2 gas)—then filled under pressure and, at the end of the filling process, the pressure is at least partially released via the gas channel 11 until ambient pressure is reached.
The charge flowing into the liquid channel 3 via the connection 4 during the filling process undergoes immediately thereafter a change in the direction of flow through 90°. In addition, the flow cross-section of the liquid channel 3 narrows relatively abruptly in the region of the valve body 14 of the open liquid valve, which leads to considerable turbulence within the charge and prevents the formation of a homogeneous, uniform flow of the charge through the liquid channel 3 to the discharge opening 5. As a result, the performance (filled containers per unit time) of a filling machine equipped with the filling elements 1 is in particular also greatly reduced.
When filling the containers with a CO2-containing charge, for example beer, the situation cannot be avoided whereby a foaming of the charge occurs in the pressure release phase at the end of the respective filling process and foam thereby enters the gas channel 11. One disadvantage of the filling element 1 is that the annular gas channel 11 has a relatively small flow cross-section, so that the foamed charge possibly completely fills the gas channel 11 over its entire length and may even pass into the chamber 12 and possibly into further gas paths adjoining this chamber, and thus undesirable contamination occurs within the filling element and the gas paths therein. If an evacuation of the container located respectively in the sealed position against the filling element takes place via the gas channel 11 at the start of a filling process, then foamed charge residues present in the gas channel 11 are sucked off, as a result of which considerable product losses may occur.
One significant difference of the filling element 1a lies in the fact that the gas tube, denoted by 8a in
In the illustrated embodiment, in which the gas tube 8a has a circular internal and external diameter and the probe 10 has a circular external cross-section, in the gas channel portion 11a.1 the internal diameter of the gas tube 8a is approximately 2.5 to 4.0 times, preferably 3.5 times, the external diameter of the probe 10 and in the gas channel portion 11a the internal diameter of the gas tube 8a is approximately 2 to 3 times the external diameter of the probe 10.
In the illustrated embodiment, the axial length of the gas channel portion 11a.1 is at least 40%, preferably at least 50%-60%, of that partial length of the gas tube 8a which is accommodated in the liquid channel denoted by 3a in
Due to the described design of the gas tube 8a, the liquid channel 3 forms at the inlet 4 firstly a liquid channel portion 3a.1 which narrows in the direction of flow of the charge and surrounds the gas tube portion 8a.5 in an annular manner, then has a constant flow cross-section in a liquid channel portion 3a.2 which surrounds the gas tube portion 8a.1 in an annular manner, and the cross-section of the liquid channel 3a narrows only in the lower region to form the valve seat 15. An abrupt narrowing of the flow cross-section in the region of the valve body 14 is avoided in the case of the filling element 1a.
The liquid channel portion 3a.2 extends over most of the total length of the liquid channel 3a, for example in the illustrated embodiment over at least 50% or 60% of the total length of the liquid channel 3a which is formed between the top seal 9 and the discharge opening 5. In the illustrated embodiment, the external cross-section of the annular liquid channel 3a in the region of the liquid channel portion 3a.2 is approximately 1.3 to 1.5 times the external cross-section of the gas tube 8a.
The valve body 14 is provided on its circumference with a guiding and swirl-creating body 17 which forms at least one flow channel 18 that surrounds the filling element axis FA in the manner of a coil. Said flow channel is connected on one side to the flow channel portion 3a.2 and on the other side, when the liquid valve 13 is open, to the discharge opening 5 and is delimited in the circumferential direction by the inner face of the liquid channel 3a, inwardly by an annular portion 17.1 of the swirl-creating body 17 and axially by at least two wall portions 17.2 protruding beyond the outer face of this portion 17.1 and surrounding the filling element axis FA in the manner of a coil. In the illustrated embodiment, the external diameter of the annular portion 17.1 is equal to or approximately equal to the external diameter of the gas tube 8 in the region of the gas tube portion 8a.1.
The filling element 1a therefore comprises, inter alia, the following elements:
The filling of the respective container by the filling element 1a likewise takes place by means of a filling method known to the person skilled in the art, in particular by means of a pressure filling or counterpressure filling method, in which the container located in a sealed position against the filling element is preloaded—for example after preliminary evacuation and flushing with inert gas (CO2 gas)—then filled under pressure and, at the end of the filling process, the pressure is at least partially released via the gas channel 11a until ambient pressure is reached.
The particular advantage of the filling element 1a lies in the fact that abrupt changes in the flow cross-section in the liquid channel 3a are avoided, even in the region of the valve body 14, and a homogeneous flow or an improved flow vector of the flow of charge can be obtained during filling in the liquid channel portion 3a.2 which is relatively long in relation to the total length of the liquid channel 3a and which has a constant or substantially constant flow cross-section, thus ultimately leading to an increased performance of a filling system equipped with the filling elements 1a or of a corresponding filling machine.
Another significant advantage of the filling element la lies in the fact that the gas channel 11a has an enlarged cross-section next to the valve body 14 in the gas channel portion 11a.1 over a relatively large axial length, and thereby forms a sufficiently large volume for accommodating any product foam or charge foam rising in the gas channel 11a at the end of the filling process, so that said foam does not pass into critical areas of the gas paths on the filling element, i.e. into the upper region of the gas channel 11a and/or into the chamber 12 and/or into gas channels adjoining the latter. Contamination of the filling element 1a is thus prevented.
Furthermore, the design of the filling element 1a also has the advantage that any charge entering the lower regions of the gas channel 11a and thereby for example the gas channel portion 11a.1 due to foam formation can flow off more easily into the relevant container at the end of the respective filling process so that, even in the case of filling methods with preliminary evacuation of the respective container, less charge enters a vacuum channel of the filling system which creates the vacuum for the preliminary evacuation.
The invention has been described above on the basis of an example of embodiment. It will be understood that numerous changes and modifications are possible without thereby departing from the inventive concept on which the invention is based. For instance, the invention is of course not limited to filling elements or filling systems with probes which determine the filling level, but rather includes inter alia also filling elements and filling systems in which the quantity of charge introduced into the respective container is controlled in some other way, for example by measuring the inflowing quantity of charge and/or by detecting the weight of the respective container during filling. Furthermore, the filling element according to the invention is suitable both for pressure or counterpressure filling and for pressureless filling of containers.
1, 1a filling element
2 filling element housing
3, 3a liquid channel
3
a.1, 3a.2 liquid channel portion
4 connection or inlet
5 discharge opening
6 seal
7 centring bell
8, 8a gas tube
8
a.1, 8a.3 portion of the gas tube 8a
8
a.4, 8a.5 portion of the gas tube 8a
8
a.2 lower gas tube end
9 seal
10 probe
11, 11a gas channel
11
a.1, 11a.2 gas channel portion
12 chamber
13 liquid valve
14 valve body
15 valve seat
16 actuating device
17 swirl-creating body
17.1, 17.2 portion of the swirl-creating body 17
18 flow channel
A stroke of the valve body 14
FA filling element axis
Number | Date | Country | Kind |
---|---|---|---|
10 2010 022 874.5 | Jun 2010 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP11/01753 | 4/8/2011 | WO | 00 | 10/5/2012 |