This application claims the benefit of priority of German Patent Application No. 10 2009 032 794.0, filed Jul. 10, 2009, pursuant to 35 U.S.C. 119(a)-(d), the disclosure of which is incorporated herein by reference in its entirety as if fully set forth herein.
The present disclosure relates to an apparatus for filling containers with multicomponent liquids.
Apparatuses for filling containers with multicomponent liquids have long been known from the prior art and are used for example to produce carbonated mixed beverages. In such a case, a carbonated liquid is enriched with a syrup or the like and is in this way filled into a container.
For filling purposes, use is usually made of filling devices which have a valve, by means of which the filling process can be controlled. Such apparatuses usually also have a volumetric dosing chamber which is connected via a controllable inlet valve to a reservoir for the liquid and via a controllable outlet valve to a filling nozzle.
Beverages such as fruit juices sometimes cause certain problems. These fruit juices sometimes contain fruit pieces or pulp fractions. These fruit pieces can cause undesired lateral splashes and the like at the valve of the filling devices.
An apparatus for bottling liquids is known from DE 43 24 799 A1. Therein, at least one sensor which reacts to the filling level is arranged in dosing chambers, said sensor controlling an inlet valve and an outlet valve. Also provided is at least one additional reservoir for a liquid, to which each dosing chamber can be connected.
EP 0 354 130 A1 describes a method for adding a product to a liquid. In this case, a dose of the product to be added is determined and this dose is mixed into the main product.
U.S. Pat. No. 2,372,899 describes a bottle filling installation, in particular an installation for producing carbonated beverages into which syrup is mixed.
It may be desirable to provide an apparatus which, particularly in the case of beverages containing fruit pieces, prevents soiling or undesired splashes by the filling device. It may also be desirable to provide a possibility of equipping such an apparatus with standard filling devices, such as standard full-jet valves for example. Further, it may be desirable to reduce the costs of producing such installations.
In accordance with various aspects of the disclosure, an exemplary apparatus for filling containers with liquids and in particular with beverages comprises a filling device which fills the liquid into the container, wherein the filling device has a valve device for controlling the liquid flow into the container. The apparatus also comprises a first supply line for supplying a first liquid to the filling device. Also provided is a second supply line for supplying a second liquid to the filling device, said second liquid in particular being different from the first liquid, wherein the first supply line and the second supply line are separate from one another at least in some sections.
According to the disclosure, the apparatus has a control device which is configured in such a way that, at the start and at the end of a filling process for a given container, this container is filled only with the first liquid.
It is therefore proposed according to the disclosure that the container is filled in such a way that firstly the first liquid is filled in up to a certain quota, then quotas which also contain the second liquid are filled in and finally, at the end of the filling process, once again only the first liquid is filled into the given container.
In order to ensure that the second liquid is completely rinsed out in the case of small filling quantities, e.g. between 100 ml and 300 ml, the dosing of the second liquid may advantageously also be started here at the same point in time as the filling process.
Preferably, the first liquid is a clear liquid and/or a liquid which contains no fruit pieces and the like. It is thus ensured, particularly in the time segments in which the filling valve opens and closes, that no fruit pieces pass the latter. In this way, splashes due to the filling process are prevented. Furthermore, by virtue of this procedure, it is possible to use standard valves. More specifically, the situation is achieved whereby a pulp dose is located in the middle of the overall liquid dose which is filled into the container. No crushing of the pulp by the valve cone or other valve elements can thus occur.
In an exemplary method, the second supply line opens into the first supply line. This procedure may be suitable in a particularly advantageous manner for supplying pulp doses to the first liquid and/or for forming pulp plugs within the first liquid.
When bottling small filling quantities, e.g. between 100 ml and 300 ml, it has proven to be advantageous if the dosing of the second liquid takes place directly into the filling device and not into the first product line upstream of the filling device. It is thus ensured that sufficient first liquid is passed through the filling device after the plug of second liquid, in order to achieve complete rinsing of the second product out of the filling device.
In an exemplary embodiment, the apparatus has a measuring device for determining the quantity of the second liquid to be supplied. Advantageously, this measuring device has a measuring probe. This measuring probe can check for example the filling level in an intermediate container and in this way can ensure that only a predefined quantity of second liquid passes into the container.
In an exemplary embodiment, the apparatus has a dosing device for dosing the second liquid. By virtue of this dosing device, it can be ensured that in each case only certain quantities of liquid pass into the first liquid line. The abovementioned measuring device may advantageously form part of the dosing device.
A pulp dosage therefore preferably takes place by means of a probe. The use of a probe has the advantage that the conductivity of the pulp or of the second liquid need not be given. Furthermore, there may optionally be no need for a second annular container for the second liquid, since the dosing chamber is independent from upstream pressure fluctuations through valves on the inlet and outlet side.
In some aspects, the dosing device has at least one diaphragm valve. This means that the pulp dose is controlled by means of at least one diaphragm valve. This ensures a closing behaviour which is gentle on the product. In some aspects, the dosing device has two diaphragm valves. In an exemplary embodiment, the measuring probe or measuring device is arranged between these two diaphragm valves.
In an exemplary embodiment, the apparatus has a second measuring device which determines the quantity of liquid that has been filled into the container. This second measuring device may be for example a throughflow measuring device which may be provided downstream relative to the supply of the second liquid. In some aspects, however, this second measuring device is a weight measuring device which determines the weight of the bottle filled with the product. The valves of the filling devices can accordingly be controlled on the basis of the data from this second measuring device.
In an exemplary embodiment, the apparatus has a rinsing device for rinsing components of the apparatus with a rinsing medium. It is thus possible that a cleaning medium is conducted through the filling device in the context of a CIP cleaning process, but it is also possible that this rinsing medium or cleaning medium is conducted through the dosing device.
In an exemplary embodiment, the dosing device is incorporated into the method in such a way that an optionally separate CIP cleaning both of the first product path and of the second product path can also take place. As a result, for example, the main product can remain in the product path while the product path for e.g. pulp-containing bottling product is being cleaned. In this way, a rapid changeover of the filling apparatus from a first bottling product with a first additional product to a second bottling product with a second additional product can take place without any loss of the main product located in the product path.
The present disclosure also relates to a method for filling containers with liquids, such as for example with beverages, wherein a mixture of a first liquid and a second liquid is supplied to a container by means of a filling device and the first liquid is supplied to the filling device by means of a first supply line.
According to the disclosure, at the start and at the end of a filling process, only the first liquid is supplied to the container and, at least during a further time segment of the filling process between the start and the end of the filling process, at least also the second liquid is supplied to the container.
It is therefore also proposed with regard to the method that the start and the end of the filling process takes place using the first liquid which is in particular clear or free from fruit pieces. The time segment during which also the second liquid is supplied may be advantageously provided in a middle region of the overall temporal filling process.
In an exemplary method, the second liquid is dosed into the first supply line, in which the first liquid flows. This supply already into the first supply line means that a standard filling device can be used as the filling device.
In an exemplary method, a mixture of the first and second liquid is supplied to the container using a valve device, and the second liquid passes this valve device only in an essentially completely open state of the valve device. In this case, the second liquid is advantageously once again such a liquid which may contain fruit pieces or the like, i.e. for example pulp.
In an exemplary method, a filling state of the containers is measured. The filling state can be determined for example by means of load cells. A dosing may thus advantageously take place here by means of a weighing cell and advantageously also by means of a probe for the second liquid. In this way, a favourable standard deviation during the filling of the containers may be achieved.
Instead of measuring the respective doses, it would also be possible to carry out the dosing of the pulp via a timer switch or a similar dosing.
In an exemplary method, the second liquid is supplied marginally to the first liquid. By virtue of this marginal supply, it can be ensured in a particularly advantageous manner that, during the opening and closing process of the valve, the second liquid does not pass this valve.
In an exemplary method, a quantity to be supplied of the second liquid is determined, as has been explained in greater detail above.
Some further advantages and embodiments may become evident from the attached drawings.
In the drawings:
According to various aspects, an outlet starwheel 68 of the rinsing device 66 picks up the rinsed containers and transfers them via a transfer starwheel 70 and a filler inlet starwheel 72 to an apparatus 1 for bottling the beverages. Here, two-component beverages are bottled using this apparatus 1. References A to G denote different method steps which are carried out during the bottling of the beverages. In a step A the container is pressed onto a filling device, and in a step B a preloading takes place and the container is acted upon by a gaseous medium, such as carbon dioxide for example. In a step C a clear filling of the container takes place with a main product, such as for example a carbonated beverage. In a step D a secondary product can be supplied or a secondary product plug can be filled into the main product. In the region E a topping-up of the main product takes place. Reference TE denotes the end of filling of the container with the beverage.
In a step F a settling or a release of pressure from the bottled beverage can be carried out, and in step G the container can be removed from the filling device.
Reference 78 denotes an outlet starwheel of the apparatus 1 and reference 80 denotes a closing device for closing the containers with caps, wherein reference 82 denotes a supply device for the container caps. Reference 84 denotes an outlet starwheel of the closing device and reference 86 denotes a discharge device for conveying away the filled containers.
Reference 76 denotes a dead angle in which no containers are filled and no containers are arranged at corresponding filling stations. In this dead angle between the filler outlet starwheel and the filler inlet starwheel, a dosing of the additional product to the main product is possible. This angle is thus also used for the filling process and in this way the overall performance of the filler can be increased. This dosing will be described in more detail with reference to the further figures. With regard to the method, therefore, it is proposed that the dosing of the further liquid to the first liquid takes place in a manner temporally offset from the filling of the container.
The apparatus shown in
This filling device has a valve device 4 or a valve body which can control the flow of liquid to the container or which can at least block or enable said flow.
The first liquid F1 is supplied to the filling device 2 from a reservoir 18 via a first supply line or liquid line 12. This first liquid F1 is in particular a clear liquid. Reference 42 denotes a drive unit for actuating the valve body 4.
Via a second supply line 14, which in this case opens into the first supply line 12, the filling device 2 is supplied with a further liquid which may in this case be pulp. This second liquid is supplied to the first supply line 12 via a feed line 15, a dosing device 20 and a supply line 14. The supply of the second liquid takes place as indicated by the black dots F2, marginally into the first liquid F1. In some aspects, these margins are supplied in such a way that, at the start and at the end of a process of filling the containers 10, only the first liquid F1 is supplied. The dosing unit 20 has two diaphragm valves 44 and 46 for dosing the second liquid, i.e. in this case the pulp. A measuring device 22 which has a measuring probe 26 is provided between these two diaphragm valves in order to check the respectively supplied margin of liquid F2. Reference 26 denotes a suitable capacitive probe.
A control device 30 controls the valve device 4. Furthermore, this control device 30 also controls the two diaphragm valves 44 and 46 in order in this way to achieve a precise dose of the second liquid F2. References 32, 34 and 36 denote appropriate (electric) line connections between the control device and said elements. The measuring probe 26 is also connected to the control device via a line connection 38. It can also be seen that the filling level of the second liquid is higher than the filling level of the first liquid F1. This difference in filling level is denoted by reference U. This ensures that the second liquid F2 can always be pushed into the first liquid F1.
Reference 52 denotes a CIP dispenser for carrying out a CIP cleaning process. The CIP dispenser is represented by the connection between the apparatus 1 and a CIP installation (not shown) and is sufficiently well known to the person skilled in the art with regard to its structure and possible embodiments. It can be seen here that a connecting line 54 cleans both the filling device 4 via an annular cleaning channel 56 and also components of the dosing unit 20 via a rinsing line 45. Reference 48 denotes an annular channel for supplying the second liquid F2.
To this end, the shut-off valve 41 and also the diaphragm valves 44 and 47 are closed. The diaphragm valves 43 and 46 are opened. Cleaning medium can then be conducted via the feed line 15 through the measuring device 22, shown here with a floating probe, and also the rinsing line 45, the annular channel 48 and the connecting line 54. Once the measuring device 22 has been sufficiently rinsed, the diaphragm valve 47 is opened. Since the second supply line 14 and also the rinsing line 49 in each case have a larger diameter than the rinsing line 45, the main flow of cleaning medium is now conducted from the measuring device 22 through the line 14 and the rinsing line 49 to the annular cleaning channel 56. It is also possible to close the diaphragm valve 43, as a result of which the entire flow of cleaning medium runs through the last-mentioned path. After the cleaning with e.g. sodium hydroxide solution, a cleaning with acid for example takes place in the same way, followed by a post-rinsing process using water to remove all the cleaning media.
Finally, the valves 41 and 47 are closed. A second liquid can then be passed into the dosing device via the feed line 15 for the purpose of bottling in combination with the first liquid. This additional product may in this case differ from the originally bottled product.
As shown in
It will be apparent to those skilled in the art that various modifications and variations can be made to the apparatuses and method for filling containers of the present disclosure without departing from the scope of the invention. Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. It is intended that the specification and examples be considered as exemplary only.
Number | Date | Country | Kind |
---|---|---|---|
10 2009 032 794 | Jul 2009 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
2372899 | Kantor | Apr 1945 | A |
4538652 | Valentin et al. | Sep 1985 | A |
4635825 | Tulasne | Jan 1987 | A |
6655421 | Kohashi et al. | Dec 2003 | B2 |
7243483 | Clusserath et al. | Jul 2007 | B2 |
20090236007 | Clusserath et al. | Sep 2009 | A1 |
20110000578 | Krulitsch et al. | Jan 2011 | A1 |
Number | Date | Country |
---|---|---|
43 24 799 | Jan 1995 | DE |
296 17 228 | Dec 1997 | DE |
10 2006 045 987 | Apr 2008 | DE |
10 2008 010 078 | Sep 2009 | DE |
0 159 259 | Oct 1985 | EP |
0 354 130 | Feb 1990 | EP |
0 483 988 | May 1992 | EP |
0 775 668 | May 1997 | EP |
2009103426 | Aug 2009 | WO |
2010017888 | Feb 2010 | WO |
Entry |
---|
German Search Report Jul. 10, 2009. |
Number | Date | Country | |
---|---|---|---|
20110005635 A1 | Jan 2011 | US |