EP0450377A1 - Device for filling containers with a liquid - Google Patents

Abstract

A device for filling containers (7) with a metered quantity of a liquid, in particular a carbonated liquid, is described. This device consists of a rotating storage container (1) which holds the liquid to be introduced in readiness and has a number of filling members (4) arranged on its periphery and each having a metering chamber (14) and centring and sealing means (6) for coupling to containers to be filled. The liquid passage (16) from the storage container (1) to the metering chamber (14) and the liquid outlet (17) to the container (7) to be filled can be mutually opened and closed by means of a double seat valve (18) with a common valve member (19). To actuate the valve (18), a switching device (36, 37) is provided, which makes the speed of switching the valve member (19) independent of the rotational speed of the storage container (1). …<IMAGE>…

Description

The invention relates to a filling device for filling containers, in particular bottles or cans, with a predetermined amount of a liquid, in particular a pressurized, carbonated liquid, with a storage container holding the liquid to be filled and at least one filling element, which has a filling element with a Passage valve closable liquid passage with the storage container metering chamber for volumetric measurement of a predetermined amount of liquid and a closable with an outlet valve liquid outlet of the metering chamber with centering and sealing means for docking containers to be filled.

Filling devices for filling liquids into containers such as cans, bottles or the like usually have a storage container in which the liquid to be filled is kept ready and which has a gas space above the liquid. A control device ensures that the liquid level in the storage container is kept as constant as possible in order to create defined and reproducible conditions for the filling process. The reservoir is usually designed as a rotating bowl, for example as a ring bowl, with a central liquid supply. Along its circumference there are a large number of filling heads with centering and sealing means for docking successive containers to be filled, which contain the necessary liquid passages and valves as well as air and gas lines with the associated actuators. With such filling devices, liquids of all kinds can be filled into containers. These devices are preferably used for filling drinks, both for still drinks, such as still water, juices, Milk or the like, and especially for carbonated drinks that are filled under counter pressure. The necessary equipment, such as tension and return gas lines, are integrated in the filling head. A known filling head for a filling device is described for example in DE-OS 30 25 786.

A filling head of the type specified at the outset, which offers the possibility of volumetric metering of the liquid to be filled, is described in DE-OS 22 57 449. There are distributed on the reservoir in the circumferential direction a plurality of metering containers, each of which is connected to the reservoir via a liquid passage. The liquid passage of each metering container can be closed with a liquid valve which can be actuated through the storage container. The outlet of each metering container has centering and sealing means for docking containers to be filled and can be closed by means of an outlet valve which can also be actuated through the storage container. The valves can be operated independently of one another. Since the actuation of the valves is cam-controlled, the speed at which the valves open and close depends on the circulating speed of the storage container. The construction and the mode of operation of this filling device and the associated valve arrangement are relatively complex and require extensive installations and conversions on the storage container. In addition, the dosing container is filled from above, the gas (air) from the dosing container having to rise in bubbles through the liquid in the storage container. This device is therefore not suitable for measuring and filling carbonated liquids under pressure.

The invention has for its object to provide a further filling device of the type described above.

This object is achieved according to the invention in that the passage valve and the outlet valve are designed as double-seat valves with a common valve body, which blocks the liquid passage in a first closed position and opens the liquid outlet and blocks the liquid outlet in a second closed position and opens the liquid passage. This results in a structurally and functionally very simple filling device with a filling element, which requires a valve arrangement with a single valve body for filling and emptying the metering chamber and thus manages with little effort for valve actuation.

Advantageous refinements and developments of the invention with independent inventive rank are contained in the subclaims. Claim 2 contains features of a filling device according to the invention of high working speed and work productivity, with which the continuous filling of successive containers with the liquid to be filled is made possible. The features of claim 3 relate to a preferred embodiment and arrangement of the filling elements on the storage container, which makes it possible to fill the dosing chamber from below, which prevents foam formation in the case of carbonized liquids. At the same time, the mutual actuation of the passage valve and the outlet valve is also possible with a common actuating means. The claims 4 to 7 contain features of an actuator for switching the passage and exhaust valve, which are independently inventive importance. The actuator is designed so that it ensures two stable closed positions of the valve body and the switching of the valve body from one closed position to the other is permitted at a speed that is independent of the rotational speed of the storage container. Claims 6 and 7 contain the special features of such an actuating device.

Claim 8 relates to the actuation of the actuating device during the circulation of the storage container. Claims 9 and 10 contain features of the liquid passage and the liquid outlet, with which it is ensured that sliding seals in the area of the passage and outlet valve are not required and that the liquid in the metering chamber can nevertheless be measured with a sufficiently high level of accuracy. These features also have independent inventive significance. Finally, claims 11 and 12 relate to an embodiment of the valve which, at the same time, allows the flow through both valves, that is to say the passage valve and the outlet valve, at the same time in predetermined phases of switching, but on the other hand limits the flow rate through the valves.

The invention provides in a very advantageous manner a structurally and functionally very simple and at the same time very powerful filling device for filling liquids into bottles, cans and similar portion containers. The device is especially designed for filling pressurized carbonized liquids. The filling element itself and all the switching and actuating elements required for the dosing and filling processes are accommodated below or outside the storage container, so that apart from the attachment of the liquid passages, no modifications and installations are required for the filling elements on the storage container. The operation of the passage and the outlet valve is very simplified and optimally coordinated. The valves have no sliding seals. The throttle sections provided instead according to the invention along the switchover path of the valve body limit the flow rates during the switchover process and reduce the metering error to a minimum. At the same time, the switching speed of the double-seat valve is independent of the rotating speed of the storage container, which also limits the flow rate during the switching process and makes it a defined and therefore calculable quantity. Filling is guaranteed with consistently high dosing accuracy at any working speed. Overall, the invention offers the advantage of a filling device of simple construction, reliable functioning and high dosing accuracy with high work productivity.

Fig. 1

einen Schnitt durch ein bevorzugtes Ausführungsbeispiel einer Füllvorrichtung nach der Erfindung in schematischer Darstellung,

Fig. 2

einen Schnitt durch ein weiteres Ausführungsbeispiel einer Füllvorrichtung nach der Erfindung in schematischer Darstellung,

Fig. 3

einen Schnitt durch ein Schaltorgang nach der Erfindung entlang der Linie III-III in Fig. 1 und

Fig. 4a-c

eine schematische Ansicht des Schaltorgans in Richtung des Pfeils A in Fig. 3 in drei verschiedenen Arbeitspositionen.

The invention will now be explained in more detail with reference to the drawing.
Show it:

Fig. 1

2 shows a section through a preferred exemplary embodiment of a filling device according to the invention in a schematic illustration,

Fig. 2

3 shows a section through a further exemplary embodiment of a filling device according to the invention in a schematic illustration,

Fig. 3

a section through a switching gear according to the invention along the line III-III in Fig. 1 and

4a-c

is a schematic view of the switching element in the direction of arrow A in Fig. 3 in three different working positions.

In Fig. 1 an embodiment of a filling device according to the invention is shown schematically in a cross section. 1 designates a storage tank designed as an annular vessel, which contains a liquid 2 to be filled and a gas space 3 with a gas under a predetermined pressure, for example CO₂. Around the circumference of the storage container 1, filling elements 4 with centering and sealing means 6 for docking successive containers 7 to be filled are attached to the underside thereof at regular angular intervals. The storage container 1 is connected in a known manner via feed lines 8 for the liquid to be filled and gas lines 9 to a central supply unit, not shown in the drawing. With known means, not shown in the drawing, the liquid level in the reservoir is kept at a predetermined level. Likewise, the pressure in the gas space 3 is regulated as constant as possible in order to create as constant conditions as possible for the filling of the liquid. The storage container 1 runs around a vertical axis (not shown), successive containers 7 to be filled being docked, filled and released again one after the other onto the filling members 4. This process is known and need not be described here.

In the bottom 11 of the storage container 1, openings 12 are provided next to one another in the circumferential direction, to which downwardly extending container extensions 13 are attached. The container lugs 13 are preferably designed as cylindrical tube pieces which are flanged around the bottom openings 12 on the storage container. Each container extension 13 protrudes from above into a metering chamber 14 and has at its lower end a liquid passage 16 from the reservoir 1 to the metering chamber 14. The metering chamber preferably forms a structural unit with the attachment of the container, the attachment of which the reservoir does not require any further modifications or additions to the reservoir.

The dosing chamber is provided at its lower end with a liquid outlet 17, to which the centering and sealing means 6 known per se and therefore not shown in more detail are assigned for docking the containers 7 to be filled. The dosing chamber has a dosing space 23 for receiving a predetermined amount of the liquid to be filled and above it a gas space 24 which limits the dosing space 23 in the dosing chamber 14 upwards. A return gas line 26 connects the metering chamber 23 of the metering chamber to the gas chamber 3 of the storage container. The return gas line 26 opens below the gas space 24 in the dosing chamber 14. The gas space 24 is closed off from the outside and thus contains a gas buffer which limits the dosing volume of the dosing chamber upwards. The metering volume of the metering chamber 23 of the metering chamber 14 can be changed with a displacer body 27 that is vertically adjustable from the outside. For adjusting the height of the displacer 27, an actuating rod 28 is provided, which extends outside the storage container 1 and consequently does not require any conversions or installations on the storage container.

The liquid passage 16 and the liquid outlet 17 are arranged opposite one another so that they can be closed alternately by means of a double-seat valve 18 with a common valve body 19. A valve seat 21 on the liquid passage 16 defines a first closed position of the valve body 19, in which the liquid passage from the reservoir 1 to the metering chamber 14 is blocked and the liquid outlet 17 of the metering chamber is open. The second closed position of the valve body 19 is determined by a valve seat 22 of the liquid outlet 17 of the metering chamber 14. In this closed position of the valve body 19, the liquid outlet 17 is blocked, while the liquid passage 16 is open.

The valve body 19 is fixedly attached to a return gas pipe 29, which connects the inside of the container 7 to be filled with the gas space 3 of the storage container and can be closed at its upper end with a gas valve 31. The gas valve 31 can be opened and closed via a sliding sleeve 32 concentrically surrounding the return gas pipe 29 by means of an actuating member 33 with a cam-controlled eccentric 34.

A force element in the form of a spring 36, which is fastened on the one hand inside the container neck 13 and on the other hand outside on the return gas pipe 29, acts on the valve body 19 via the return gas pipe 29 so that it is brought into its upper closed position on the valve seat 21, in which it Liquid passage from the reservoir to the metering chamber is blocked. However, as long as atmospheric pressure is present at the liquid outlet 17 from the outside, so long as no container 7 to be filled is docked or a docked container has not yet been biased, the valve body 19 is against the force of the spring 36 by the pressure of the liquid in the metering chamber and the reservoir in it lower closed position held on the valve seat 22, in which it blocks the liquid outlet. The force of the spring 36 is therefore less than the force with which the valve body 19 is pressed against the valve seat 22 by the liquid.

In order to move the valve body 19 against the pressure of the spring 36, which holds it in the upper closed position on the valve seat 21, into its lower closed position on the valve seat 22, a switching element 37 is provided. This switching element has a bearing housing 38 attached to the outside of the container shoulder 13 for a shaft 39 on which on the one hand an eccentric tilting element 41 and on the other hand an eccentric 42 are fastened. The eccentric 42 acts on a driver 43 which is attached to the return gas pipe 29. The structure of the switching element is shown in FIGS. 3 and 4. FIGS. 3 and 4c show the return gas pipe 29 with a stop 44 on which the compression spring 36 acts with an upward force. The tilting element 41 is designed as a segment of a circle that can be pivoted about the axis 39 and can assume two end positions defined by stops, not shown. A second force element in the form of a tension spring 46 holds the tilting element 41 in one of the two end positions. The spring 46 is fastened on the one hand to a bolt 49 attached to the tilting element 41 and on the other hand to the housing 38 via a holder 51. The base points of the spring 46 are selected such that the tilting element 41 can be pivoted against the force of the spring from a first stable switching position via an unstable equilibrium position to a second stable switching position. This arrangement thus represents a mechanical FLIP-FLOP element with two stable switching positions.

4a shows the tilting element in a first stable switching position. It is moved during the rotation of the storage container 1 in the direction of the arrow 47 and comes in contact with a stationary control element 48 in the form of a curve piece in a predetermined path section, which moves the tilting element 41 into the unstable equilibrium position shown in FIG 4c shown second stable switching position pivots. From this second stable switching position, the tilting element 41 is pivoted back into its first switching position in a second track section by a second stationary control element 52. The speed of the pivoting movement of the tilting element 41 from its first switching position in the unstable equilibrium position shown in FIG. 4b is dependent on the rotation speed of the storage container 1 because of the interaction with the curve piece 48. The further movement of the tilting element 41 from the unstable equilibrium position into the second stable switching position, however, is independent of the rotation speed of the storage container because it is determined solely by the tensile force of the spring 46. The switching process therefore always takes place at the same speed regardless of the rotational speed of the storage container 1.

As long as no container 7 is docked to the centering and sealing means 6 of the liquid outlet 17, the valve body 19 is in its lower closed position on the valve seat 22 in order to block the liquid outlet. Since there is atmospheric pressure on the outside of the liquid outlet, the valve body is held in this closed position against the force of the spring 36 by the increased pressure prevailing in the interior of the storage container and the metering chamber. The force of this spring is therefore less than the force with which the liquid presses the valve body 19 against the valve seat 22 of the liquid outlet 17.

As long as atmospheric pressure prevails at the liquid outlet 17, the gas valve 31 of the return gas pipe 29 to the gas space 3 is closed in order to avoid a pressure loss in the gas space 3.

As the storage container 1 continues to circulate, a container 7 to be filled is docked onto the centering and sealing means 6 of the filling element 4. By means of the cam-controlled actuating member 33, the gas valve 31 is now opened in order to apply the pressure of the gas space 3 to the container, that is to say to prestress it.

After the pressure equalization between the interior of the container to be filled and the gas space 3 of the storage container, the force with which the liquid has held the valve body in its lower closed position is eliminated. The force of the spring 36 is now sufficient to press the valve body 19 into its upper closed position on the valve seat 21 and thereby to block the liquid passage 16 from the reservoir to the metering chamber. At the same time, the liquid outlet 17 is opened so that the amount of liquid measured in the metering chamber 14 can flow through the liquid outlet 18 into the container 7. The gas contained in the container 7 escapes through the return gas pipe 29 into the gas space 3 of the storage container.

During this filling process, the storage container 1 with the filling member 4 and the container 7 to be filled continues to rotate in the direction of the arrow 47 in FIG. 4. As soon as the entire measured amount of liquid is in the container 7, the tilting element 41 becomes (see FIGS. 4a to 4c) of the switching element 37 by means of the control cam 48 from its upper first switching position, in which the upper closed position of the valve body 19 on the valve seat 21 is released, via the unstable equilibrium position (FIG. 4b) to the second stable switching position (4c), in which the eccentric 42 presses the return gas pipe 29 with the valve body 19 in its lower closed position on the valve seat 22 and thus blocks the liquid outlet 17. The tilting element 41 remains in this second switching position until the pressure of the liquid flowing from the reservoir into the metering chamber 14 is sufficient to hold the valve body 19 against the force of the spring 36 in its lower closed position on the valve seat 22. Only then is the tilting element 41 moved from the second switching position shown in FIG. 4c into its stable starting position by means of a further stationary curve piece 52 switched back, the eccentric 42 releases the valve body 19 for the next filling process.

After closing the liquid outlet 17 and opening the liquid passage 16, the liquid volume of the metering chamber 23 of the metering chamber 14 is refilled, the gas contained in the gas chamber 24, which cannot escape, being used as a gas cushion to limit the metering volume of the metering chamber 14.

After the liquid outlet 17 has been closed, the return gas valve 31 of the return gas pipe 29 is closed and a relief valve 53 is opened. Now the filled container 7 can be removed. The arrangement is ready for a new filling process.

As the description of the operation of the filling element 4 shows, the valve body 19 moves from its first closed position on the valve seat 21 into the second closed position on the valve seat 22 under the action of the spring 46 of the switching element 37. The valve body 19 moves from its second closed position on Valve seat 22 back into its first closed position on valve seat 21 is effected by spring 36. Both movements are thus independent of the speed of rotation of the storage container 1, which results in defined and reproducible conditions for the filling process.

As the drawing shows, the double seat valve 18 is designed so that the movement of the valve body 19 does not require sliding seals. The valve body 19 has sealing surfaces 69 and 71 which are inclined conically to the valve axis and cooperate with corresponding sealing surfaces of the valve seats 21 and 22. As soon as the valve body 19 when opening the Has liquid passage 16 detached from the valve seat 21, the liquid passage 16 is open before the liquid outlet 17 is closed. The amount of liquid flowing through during this changeover does not impair the dosing accuracy of the filling head, because it can be determined and taken into account due to the constant switching time of the valve and the constant pressure conditions. However, in order to limit this flow rate of the liquid, throttling sections 54 and 56 can be assigned to the liquid passage 16 and the liquid outlet 17, which only open a narrow liquid passage during the movement of the valve body 19. The throttle section 54 consists of an annular gap 57, which is delimited radially outwards by an axial extension 58 of the container extension 13 and radially inwards by the outer circumferential surface of the valve body 19. The annular gap 57 can be chosen to be as narrow as desired in order to limit the liquid flow when the valve body 19 is switched over to a value which is as small as possible and which is not significant as a metering error. In the area of the liquid outlet 17, such an annular gap is also formed by the outer peripheral surface of the valve body and a cylindrical housing section 59 of the metering chamber.

FIG. 2 shows another embodiment of the filling device according to the invention, in which, however, essential parts correspond to the embodiment according to FIG. 1. The same parts are therefore provided with the same reference numerals in FIG. 2 as in FIG. 1.

In the embodiment according to FIG. 2, the essential difference from that according to FIG. 1 is that the return gas line does not run through the valve body 19. The valve body 19 is attached to an operating rod 61, via which on the one hand again the spring 36 and on the other hand the switching element 37 act on the valve body 19. The function is the same as described in connection with FIG. 1. The return gas line connecting the interior of the container 7 to be filled with the gas space of the storage container 1 now runs through a pipe section 62 which is fixedly connected to the filling element, through a line section 63 which is fixedly arranged in the metering chamber and extends through the container opening 12 into the gas space 3 of the storage container Further pipe section 64. The valve 66, which can be actuated by means of an actuating device 67, can be used to interrupt the return gas line in order to prevent pressure loss in the gas space 3 of the storage container 1 as long as no container 7 is docked to the filling element.

In both cases shown, the filling element 4 is designed such that it can be attached to the bottom opening 12 of the storage container 1 without further modifications or installations to the storage container being necessary.

Claims (12)

Filling device for filling containers, in particular bottles or cans, with a predetermined amount of a liquid, in particular a pressurized carbonated liquid, with a storage container holding the liquid to be filled and at least one filling element, which has a liquid passage with a Dosing chamber connected to the storage container for volumetric measurement of a predetermined amount of the liquid and a liquid outlet of the dosing chamber which can be filled with an outlet valve and having centering and sealing means for docking, containers which are to be filled, characterized in that the passage valve (16) and the outlet valve (17) act as double seat valves ( 18) are formed with a common valve body (19) which blocks the liquid passage (16) in a first closed position and opens the liquid outlet (17) and in a second The closed position blocks the liquid outlet (17) and opens the liquid passage (16). Apparatus according to claim 1, characterized in that the storage container (1) is designed as a rotating boiler, on the circumference of which the filling elements (4) for the continuous filling of successive containers (7) are arranged at uniform angular intervals. Apparatus according to claim 1 or 2, characterized in that the filling elements (4) are attached to the underside of the storage container (1), with one container attachment (13) of the storage container (1) each having a liquid passage (16) at its lower end. has, protrudes from above into the metering chamber (14) that opposite the liquid passage in the bottom of the Dosing chamber (14) of the liquid outlet (17) is arranged and that the liquid passage (16) and the liquid outlet (17) with a double seat valve (18) with a common valve body (19) are mutually shut off and open. Device according to one of claims 1 to 3, characterized in that an adjusting device (29, 36; 37) for switching the valve body (19) of the double-seat valve (18) from one closed position to the other and vice versa is provided, which one on the valve body (19) in the direction of a closed position to act force element (36) and a switching element (37) which is designed to move the valve body against the action of the force element in the other closed position. Apparatus according to claim 4, characterized in that the actuating device is designed to move the valve body (19) from one closed position to the other and vice versa at a speed which is independent of the rotational speed of the rotating storage container (1). Apparatus according to claim 4 or 5, characterized in that the switching element (37) for switching the valve body (19) from one closed position to the other and vice versa has a mechanical FLIP-FLOP element (41, 46). Device according to one of Claims 4 to 6, characterized in that the switching element (37) has a tilting element (41) which can be pivoted about an axis of rotation (39) and has two stable switching positions, and in that the tilting element in a switching position which releases the defined closed position of the valve body (19) and during the transition to its second switching position by means of a second Force element (46) moves the valve body (19) against the action of the first force element (36) into its second closed position. Device according to one of claims 4 to 7, characterized in that stationary control elements (48, 52) are assigned to the rotating storage container (1) for actuating the switching elements (37). Device according to one of claims 1 to 8, characterized in that at the liquid passage (16) and / or at the liquid outlet (17) to the metering chamber (14) at least one flow restricting section defining the liquid passage during the switching movement of the valve body (19) ( 54, 56) is arranged. Apparatus according to claim 9, characterized in that the throttle section (54, 56) is formed by an annular channel (57) which is formed on the one hand by a peripheral surface of the valve body (19) and on the other hand by a flow channel from the valve seat (21, 22) forth in the metering chamber extending wall section (58, 59) is formed. Apparatus according to claim 9 or 10, characterized in that the valve body (19) has a cylindrical circumferential section (68), the axial length of which is dimensioned such that it delimits both throttle sections (54, 56) over a half switchover distance. Device according to one of claims 1 to 11, characterized in that the valve body (19) has two sealing surfaces which are oriented opposite to one another transversely and concentrically to its axis (69, 71), which cooperate with the corresponding sealing surfaces of the valve seats (21, 22), and that both the passage opening (16) and the outlet opening (17) open during the movement of the valve body (19) from one closed position to another are.

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