The invention relates to processing containers, and in particular, to container filling.
The process of mass-producing containers that contain liquid includes far more than simply placing a container under a spigot and allowing liquid to flow into it. In known filling systems, the container must be purged of any ambient air. This is because oxygen in the air may be detrimental to long-term storage of the beverage. In some cases, depending on the nature of the container, the container must be pre-tensioned before filling. Finally, during the filling itself, the incoming liquid displaces whatever gas happens to be in a container. Thus, there must be some way to dispose of this gas while the liquid actually flows into the container. Finally, the filling element must place the correct amount of liquid in each container.
A filling element must therefore be able to do more than just turn a spigot on and off. It must manage the various gas flows that are required during filling. These gas flows have different requirements. Known filling elements face difficulty in controlling these sometimes contradictory demands without considerable complexity.
Additionally, the various gases that are used during this process are not without cost. Known filling elements tend to behave as if this were not the case. As a result, copious amounts of various process gases are used up. This drives up the cost of filling containers.
An object of the invention is to provide a filling system and a method for treatment of containers with a process gas that facilitates a particularly effective purging of the container's interior with a minimal consumption of purging gas.
In one aspect, the invention relates to a filling system for filling bottles or similar containers with a liquid product. The filling system includes a product vessel in which, during filling, a lower liquid space occupied by the product and above it a gas space are formed. The filling system also has at least one filling element arranged below the product vessel.
The filling element has a filling-element housing in which is configured a liquid duct that connects to the liquid space and that forms a product dispensing opening at an underside of the filling-element housing. This underside is the side that faces away from the product vessel.
A liquid valve arranged in the liquid duct has a valve body, provided on a valve plunger arranged coaxially with a filling element axis. The valve body moves axially for opening and closing the liquid valve and for a controlled release of the product.
A first gas-duct is formed in the valve plunger. At its upper end, the first gas-duct opens into the gas space of the product vessel. At its lower end, it opens into a headspace of the container. A first gas-valve in the first gas-duct has a gas-valve body that is movable for opening and closing the first gas-valve. At least one actuator interacts with the first gas-valve's gas-valve body.
The gas-valve body has a second gas-duct that can at least temporarily make a fluid-tight connection with the first gas-duct. The gas-valve body can thus create a second gas-valve for charging the container's interior with a process gas at a volumetric flow-rate that is lower than that which occurs upon opening the first gas-valve. As a result, the second gas-duct, having been configured as a gas-valve body, permits multi-stage charging of the container with a process gas, with the volumetric flow of the gas fed into the container's interior being different in the different stages.
In some embodiments, the second gas-duct has a cross-section that is smaller than that of the first gas-duct, thus restricting the volumetric flow of process gas through the reduced cross-section in the second gas-duct.
In some embodiments, a restrictor in the second gas-duct reduces flow of gas through that duct. The volumetric flow through the second gas-duct, and hence the volumetric flow of process gas introduced into the container, can be further reduced as a result. The restrictor preferably defines a bore with a diameter of 0.5-2.0 mm that extends along the flow direction by 0.3-1.0 mm.
In some embodiments, the gas-valve body comprises an opening that is arranged in the gas space to form a second gas-valve. When the second gas-valve opens, gas flows through the first and second gas-duct into the container present at the filling element.
In other embodiments, the second gas-duct and the first gas-duct, which is configured in the valve plunger, form a fluid-tight connection with each other. This makes it possible to control the supply of process gas present in the gas space via the second gas-duct, the first gas-duct, and a gas tube extending into the headspace of the container by opening and/or closing the second gas-valve. This, in turn, makes it possible to purge the container with a reduced supply of process gas from the gas space.
In some practices of the invention, the purging operation is carried out in two successive process steps. The first process step is to connect the container's interior to a vacuum source, thus evacuating the container's interior. The second process step is to actually purge the container by blowing in the purging gas.
In other practices, during the purging operation, the container's interior remains connected to the vacuum source so that purging gas being blown into the container's interior faces only a vacuum, and thus meets with little resistance as it flows. For example, in some practices, the evacuation of the container in the first process step of purging occurs in such a way that a pressure of around 0.05-0.4 bar arises in the container. In other practices, the pressure in the container is around 0.05-0.25 bar. In other practices, there is a vacuum of around 0.6 bar to 0.95 bar. In yet other practices, the vacuum is 0.75-0.95 bar compared with ambient pressure.
In some practices, introducing purging gas includes restricting the volumetric flow in the second gas-duct or the pressure present in the gas space in such a way that there is at most a minimal pressure increase in the container's interior. Some practices include keeping this pressure increase as low as of 0.05 bar to 0.2 bar.
Some embodiments are controlled to keep the connection with the vacuum source open for a certain period of time after the supply of purging gas has been closed so as to restore the original vacuum in the container. This is by no means essential however.
In some embodiments, a partial stroke of the actuator opens or closes the opening. Preferably, only the second gas-valve opens while the first gas-valve remains closed, i.e. the second gas-duct is connected to the first gas-duct in a fluid-tight manner. A first partial-stroke by the actuator can thus purge the container's interior with a process gas at a restricted volumetric flow .
In some embodiments, the gas-valve body can move on the axis of the filling element to open and close the first gas-valve, interacting with a valve face configured in the first gas-duct. In other words, to open the first gas-valve, the actuator raises the gas-valve body along the filling-element axis so that the seal seat of the gas-valve body is lifted off the bore provided in the valve plunger or off the valve seat that is provided there. Conversely, to close the first gas-valve, the actuator lowers the gas-valve body along the filling element axis to achieve a seal seat between the gas-valve body and the valve seat configured in the valve plunger.
A second partial-stroke of the actuator moves the gas-valve body. This second partial-stroke is coaxial with the first. In this way, it is possible for one actuator to actuate both the first and second gas-valves provided the actuator can carry out the required two-stage stroke movement.
In some embodiments, the first gas-valve facilitate a greater gas flow per unit of time than the second gas-valve. Thus, opening the second gas-valve results in a volumetric flow rate into the container's interior than that which would result by opening the first gas-valve.
In one embodiment, the first gas-valve's body is accommodated for part of its length in the first gas-duct out of which it projects by an upper end. Among these embodiments are those in which it interacts by its upper end with the actuator. The first gas-duct can be configured in an incremental manner, with it being extended incrementally upwards by the increment. An upper region of the first gas-duct can thus at least partially accommodate the gas-valve body.
In another embodiment, the opening in the gas-valve body that forms the second gas-valve is provided on a partial length that projects beyond the first gas-duct, in particular on the upper end face of the gas-valve body. In this embodiment, a section of the actuator, or an element provided thereon, opens and closes the opening of the second gas-valve.
In some embodiments, two coaxial lifting-elements form the actuator. These lifting elements can be implemented by piston-cylinder arrangements.
A first lifting-element acts through a plunger and an adapter on the gas-valve body; whereas a second lifting element forms a stop for the stroke movement of the first lifting element. In a first state of the second lifting-element, the stop limits the stroke of the first lifting-element to a first partial-stroke. In a second state of the second lifting-element, a second partial-stroke lifts the second lifting-element so as to increase the extent of the total stroke of the first lifting-element to the sum of the extends of the first and second partial-strokes. This results in a two-stage stroke movement of the plunger with only the second gas-valve being opened on the first partial stroke but with the first gas-valve also being opened on completion of the further second partial-stroke that follows the first partial-stroke.
In one embodiment, when the lifting element is in the lowered state the adapter brings about a sealing of the opening and hence a closing of the second gas-valve. The adapter preferably comprises a surface section that, in the lowered state of the first lifting-element, presses on a seal or sealing face provided at the opening so as to close the second gas-valve.
When the lifting element is raised by the first partial stroke, the adapter, and more particularly the surface section of the adapter that brings about the closing, is preferably lifted clear of the opening. This opens the second gas-valve. The first gas-valve on the other hand remains closed because the gas-valve body is still lowered. On completion of the first partial-stroke therefore the second gas-valve can be opened through the multi-stage stroke movement of the actuator by separating the adapter's seal seat from the gas-valve body.
In some embodiments, the adapter includes a first control-surface that. During the first partial-stroke, the first control-surface does not come to rest on the gas-valve body. During the second partial stroke of the lifting element, the gas-valve body partly rests on the first control-surface so as to lift the gas-valve body out of the sealed position of the valve face configured in the first gas-duct.
More particularly, the adapter has a hook-shaped section that engages behind a projection of the gas-valve body, also referred to as a control section hereinafter. The first control-surface, which rests on the projection of the gas-valve body during the second partial-stroke, and which thus raises the gas-valve body when the plunger moves upward, is provided on this hook-shaped section. Because the first control-surface does not rest on the gas-valve body during the first partial-stroke, the surface section of the adapter that seals the opening of the second gas-valve is lifted clear of the opening of the gas-valve body. However, during this first partial stroke, the gas-valve body has yet to be lifted. Accordingly, the first gas-valve has yet to open.
In some embodiments, the adapter has a second control-surface that interacts with the valve plunger to close the liquid valve. The second control-surface is a surface lying opposite the first control-surface on the hook-shaped section of the adapter. Using this second control-surface, the adapter acts on the top of the valve plunger, for example on a flange-like projection thereof. This means that when the actuator returns to its initial position, in which the plunger is fully extended into the vessel, the valve body presses against the valve seat. This closes the liquid valve. The actuator therefore advantageously not only actuates the first or second gas-valve but also actively closes the liquid valve.
In another embodiment the liquid valve comprises an opening spring that pre-tensions the liquid valve in its open state. This opening spring, which is more particularly configured as a compression spring, has a spring constant selected such that when the container's internal pressure reaches a certain pre-tensioning pressure, the opening spring's force overcomes the weight of the valve body or valve plunger and of the column of liquid weighing down on the valve body, less friction forces. This automatically opens the liquid valve without the intervention of any other actively operated drive.
The second gas-duct can be connected at least temporarily with a further gas space that is independent of the product vessel's gas space. This is effected, for example, by way of a gas duct provided in the plunger of the actuating device that establishes a connection with the further gas space, for example, via at least one further line and, if necessary, at least one valve.
More particularly, the second gas-duct can be configured so that it can be connected with the gas space for purging the container to be filled, and with the further gas space for pre-tensioning the container. In this way it is possible that the pre-tensioning process and the purging to be carried out with different gases. This means that pre-tensioning can be carried out with a less expensive process gas.
The invention also relates to a method for the treatment of containers with a process gas prior to filling, using a filling element at which the respective container is present in sealed position during the treatment and through which a process gas is introduced into the container and through which a process gas and a gaseous and/or vaporous medium displaced from the container, for example air, is discharged from the container; before a process gas is introduced the container is evacuated or charged with the vacuum of a vacuum source; the filling element comprises a first gas-duct that, at an upper end, issues into the gas space of the product vessel and at the lower end into a headspace of the container arranged at the filling element; a first gas-valve having a gas-valve body that can be moved to open and close the first gas-valve is provided in the first gas-duct. After the container has been charged with the vacuum, a first process gas for purging the container is introduced by the opening of a second gas-valve via a second gas-duct that is configured in the gas-valve body, is at least temporarily connected with the first gas-duct in a fluid-tight manner and that comprises the second gas-valve; the container remains connected to the vacuum source during purging. Once the container has been purged, the first gas-valve is opened to effect a pre-tensioning of the container with a second process gas; the volumetric flow of this second process gas through the first gas-valve during the pre-tensioning of the container is greater than the volumetric flow of the first process gas through the second gas-valve during the purging of the container.
The first process gas can be the same as the second process gas here, but the use of different process gases is preferable.
In a preferred embodiment the volumetric flow of the first process gas introduced into the container during purging, and the vacuum of the vacuum source, are selected so that in the case of the first process gas flowing through the container's interior, a purging pressure inside the container that is equal to or slightly above or below ambient pressure is obtained. This achieves an effective purging of the bottle's interior while significantly reducing the consumption of purging gas and consequently a significant cost saving.
More particularly, the pressure and/or volumetric flow of the first process gas and the pressure of the vacuum source can be selected to obtain a purging pressure of between 0.05 bar and 0.45 bar, these being absolute values. An especially effective purging process is achieved with a purging pressure set in this way.
In a preferred embodiment, in a first process step the container is evacuated to a pressure ranging between 0.05 bar and 0.2 bar, and in a second, subsequent process step the first process gas is introduced or blown into the container and preferably in such a way that the pressure inside the container is not increased by the introduction or blowing-in of the first process gas or is increased only minimally, say by 0.05 bar-0.2 bar.
It is especially preferable if the first process gas for purging the container is introduced via a second restrictor provided in the gas duct. The restrictor preferably has a bore with a diameter of 0.5-2.0 mm for a thickness of the restrictor in the direction of flow of the gas of 0.3 mm-1 mm.
In an alternative embodiment, a first partial-stroke of the actuator that interacts with the gas-valve body opens and closes the second gas-valve. In this embodiment, the actuator raises or lowers the gas-valve body to open and close the first gas-valve.
In another aspect, the invention features an apparatus for filling containers with liquid product. Such an apparatus includes a product vessel and a filling element arranged below the product vessel. When the apparatus is operating, liquid product partially fills the product vessel, thus defining a liquid space occupied by the filling product and a first gas-space above the liquid space. The filling element includes a filling-element housing having a liquid duct formed therein to connect the liquid space, and a dispensing opening disposed on an underside of the filling-element housing facing away from the product vessel. The filling element also includes a liquid valve having a valve plunger aligned coaxially with a filling-element axis, and a liquid-valve body provided on the valve plunger. The liquid-valve body is movable along the filling-element axis to open and close the liquid valve. The filling element also includes an actuator and a gas tube provided on the valve plunger. In operation, the gas tube extends into a headspace of a container that is arranged to be filled at the filling element. The valve plunger and the gas tube cooperate to define a first gas-duct that extends through the valve plunger and through the gas tube. The first gas-duct has an upper end that extends into the first gas-space of the product vessel and a lower end that opens into an interior of the container. Along the first gas-duct is a first gas-valve having a gas-valve body that interacts with a valve seat configured in the first gas-duct. This first gas-valve transitions between an open and closed state in response to the actuator. The gas-valve body includes a second gas-duct formed through it. This second gas-duct at least temporarily engages the first gas-duct in a fluid-tight manner. The gas-valve body includes a valve face and a valve opening that cooperate to form a second gas-valve that, when open, allows a flow of gas through the first and second gas-ducts to enter the container.
Embodiments include those in which the gas-valve body is configured as a hollow needle.
Other embodiments include those in which the cross-section of the second gas-duct is smaller than that of the first gas-duct, as well as those that include a restrictor in the second-gas duct to reduce volumetric gas flow through the second gas-duct.
Further embodiments include those in which the actuator opens or closes the valve's opening by executing a first partial-stroke, a length of which is restricted by an obstruction to travel.
In some embodiments, the gas-valve body is movable along the filling element axis for opening and closing the first gas-valve by interacting with a valve face in the first gas-duct. Among these are embodiments in which the actuator moves the gas-valve body along first and second coaxial partial-strokes.
Also among the embodiments are those in which opening the first gas-valve causes a greater gas flow rate than opening the second gas-valve.
In yet other embodiments, the first gas-duct accommodates part of a length of the gas-valve body of the first gas-valve. In these embodiments, the gas-valve body includes an upper end that projects out of the first gas-duct. This upper end interacts the actuator. Among these embodiments are those in which the valve opening of the gas-valve body is provided on an upper end face of the gas-valve body and projects beyond the first gas-duct.
Some embodiments also have a plunger and an adapter. In these embodiments, the actuator includes first and second lifting-elements that are coaxial with the filling-element axis. The first lifting-element acts through the plunger and the adaptor on the gas-valve body. The second lifting-element forms a stop for a stroke of the first lifting-element. The second lifting-element transitions between first and second states. In the first state, the stroke is limited to a first partial-stroke; in the second state, the second lifting-element is raised by a second partial-stroke such that the stroke of the first lifting-element has a length that increases to a sum of the first and second partial strokes. Among these embodiments are those in which the adapter seals the opening and closes the second gas-valve when the first lifting-element is in a lowered state. Also among these embodiments are those in which, when the first lifting-element is in a raised state, the adapter is lifted off the opening, and the second gas-valve opens. Also among these embodiments are those in which the adapter includes an adapter surface that interacts with the plunger for closing the liquid valve.
Some embodiments include an adapter with a hooking surface. In these embodiments, during the first partial-stroke, the hooking surface remains separated from the gas-valve body. But in the second partial-stroke, the hooking surface engages the gas-valve body so as to raise the gas-valve body out of the sealed position of the valve face in the first gas-duct.
Additional embodiments include a spring that pre-tensions the liquid valve into an open state thereof.
Some embodiments include a second gas-space that is independent of the first gas-space. In these embodiments, the second gas-duct connects at least temporarily to the second gas space. Among these embodiments are those in which the second gas-duct transitions between a first state for purging the container and a second state for pre-tensioning the container. In the first state, the second gas-duct connects to the first gas-space; and in the second state, the second gas-duct connects to the second gas space.
In another aspect, the invention features a method for treating a container with a gas prior to filling the container using a filling element against which the container is sealed during treatment, through which gas is introduced into the container, and through which gas displaced from the container passes through. The filling element includes a first gas-duct that opens, at an upper end thereof, into a gas-space of a product vessel and that opens, at a lower end thereof, into a headspace of the container. The first gas-duct has a gas-valve body that is movable to open and close a first gas-valve and in which a second gas-duct is configured. The second gas-duct is connected at least temporarily with the first gas-duct in a fluid-tight manner. The method includes, before pre-tensioning the container with a first process gas stored in the gas space, evacuating the container with a vacuum provided by a vacuum source, opening a first gas-valve to pre-tension the container with the first process gas, the first process gas flowing at a pre-tensioning volumetric flow rate, and, with the container still connected to the vacuum source, opening a second gas-valve to introduce a second process gas for purging the container through the second gas-duct, the second process gas flowing at a purging volumetric flow rate, wherein the purging volumetric flow rate is less than the pre-tensioning volumetric flow rate.
In some practices, the first process gas and the second process gas are the same gas, whereas in others, they are different gases.
Other practices include selecting the purging volumetric flow rate and the vacuum such that when the second process-gas flows into the container's interior, the interior is maintained at a purging pressure that is within a pre-set tolerance around ambient pressure.
In some practices, the purging pressure is within 0.1 bar and 0.45 bar of ambient pressure.
In other practices, evacuating the container includes evacuating to a pressure ranging between 0.05 bar and 0.2 bar in a first process step, and in a second, subsequent process step introducing the second process gas into the container in such a way that pressure in the container increases by less 0.2 bar.
Yet other practices include passing the second process gas through a restrictor provided in the second gas-duct. Among these are practices in which the restrictor includes a bore with a diameter of 0.3-1 mm for a restrictor length in the direction of flow of the gas of 0.5 mm.
Alternative practices include those in which opening a second gas-valve includes causing an actuator to execute a first partial-stroke that results in an interaction the gas-valve body, and those in which opening a first gas-valve to pre-tension the container with the first process gas includes causing an actuator to move the gas-valve body.
In yet another aspect, the invention features a filling element that includes an actuator, a liquid valve, and a gas tube on a plunger that extends into a container. The plunger and the gas tube define a first gas-duct that extends through the plunger and the gas tube. The first gas-duct has ends that extend respectively into a gas-space of a product vessel and the container's interior. A first gas-valve along the first gas-duct has a gas-valve body that interacts with a valve seat in the first gas-duct. The gas-valve body has a second gas-duct formed through it. This second gas-duct at least temporarily engages the first gas-duct in a fluid-tight manner. The gas-valve body has a valve face and a valve opening that cooperate to form a second gas-valve through which, when the second gas-valve opens, gas flows through the first and second gas-ducts and enters the container.
As used herein, references to a container sealed against a filling element refer to a container that lies with a mouth thereof pressed tightly against the filling element or against a seal located at the filling element in a way that isolates the container's interior from the atmosphere.
As used herein, the term “containers” refers to cans and bottles, whether made of metal, glass, plastic, and combinations thereof.
As used herein, the expressions “essentially,” “in essence,” and “around” mean variations from the respective exact value by ±10%, preferably by ±5% and/or variations in the form of changes insignificant for the function.
Further embodiments, advantages, and possible applications of the invention arise out of the following description of embodiments and out of the figures. All of the described and/or pictorially represented attributes whether alone or in any desired combination are fundamentally the subject matter of the invention independently of their synopsis in the claims or a retroactive application thereof. The content of the claims is also made an integral part of the description.
These and other features of the invention will be apparent from the following detailed description and the accompanying figures, in which:
Part of the rotor includes an annular vessel 1 for holding the liquid filling-product. In operation, the liquid filling-product partially fills the annular vessel 1 to some controlled level. This level divides the annular vessel 1 into a lower liquid space 1.1 occupied by the product and, above it, a first gas-space 1.2 filled, for example, with an inert gas such as CO2 gas, nitrogen, or sterile air.
The filling position 3 is one of a multiplicity of identical filling positions formed on an underside of the annular vessel 1. A fixed angle separates each filling position from its neighboring filling position. Each filling position has a filling element 4 and a container carrier 5. During filling, a container 2 stands upright on its base on the carrier 5 with its mouth pressed tightly against a ring seal of a centering tulip 6.
In the illustrated embodiment, each filling element 4 has a flat, plate-like filling-element housing 7. A liquid duct 8 passes through the filling-element housing 7. One end of the duct 8 connects to the liquid space 1.1 through a vessel opening 9 in the base of product vessel 1. The other end forms a product-dispensing opening 10 that is surrounded by the ring seal and through which the product flows to the container 2 during filling.
Within the duct 8, a liquid valve 11 controls the release of liquid product to the container 2. The liquid valve 11 includes a liquid-valve body 12. When the liquid valve closes, the liquid-valve body 12 rests against a valve seat formed within the liquid duct 8. A tubular valve plunger 13 arranged coaxially with a vertical filling element axis FA moves the liquid-valve body 12 up and down along the filling element axis FA to open and close the liquid valve 11. A radially extending upper portion of the plunger 13 defines a plunger flange 13.1.
A first gas-duct 14 passes through the valve plunger 13 and continues on into a gas tube 15. During operation of the filling element 4, with a container 2 sealed against the filling element 4, the gas tube 15 extends through the container's mouth and into a headspace of the container 2. The gas tube's lower end forms the lower opening of first gas-duct 14.
A first gas-valve 16 along an upper portion of the first gas-duct 14 has a hollow needle-shaped gas-valve body 17 that is coaxial with filling element axis FA. Raising the gas-valve body 17 relative to the valve plunger 13 opens the first gas-valve 16; lowering it relative to the valve plunger 13 closes the first gas-valve 16.
When the first gas-valve 16 closes, a valve face at the lower end of the gas-valve body 17 rests against a valve seat formed in first gas-duct 14. The gas-valve body 17 has an outer cross-section that is selected so that the gas duct 14, surrounding the gas-valve body 17 at a distance therefrom, extends as far as an upper open end of the valve plunger 13.
A second gas-duct 21 coaxial with the first gas-duct 14 passes through the full length of what is, as a result, a tubular gas-valve body 17. Upon opening of the first gas-valve 16, the lower free end of the second gas-duct 21 thus connects to the first gas-duct 14 in a fluid-tight manner. The upper end of the first gas-duct 14 defines a second gas-valve 23.
An actuator 18 controls both the first gas-valve 16 and the second gas-valve 23. In some embodiments, the actuator 18 is a pneumatic actuator on top of, and preferably outside of, the vessel 1. The actuator 18 acts on the upper end of gas-valve body 17 through a plunger 19 arranged coaxially with filling element axis FA and an adapter 20 coupled to the plunger 19. Since the plunger 19 passes through the vessel 1 in the process, it is useful to provide a bellows to prevent contamination of the vessel 1.
To facilitate interaction with the plunger 19, an upper end of the gas-valve body 17 includes a control section implemented as a gas-valve collar 17.1 that extends the gas-valve body 17 radially outwards at its upper free end so as to configure an external ledge of the gas-valve body 17.
Through electro-pneumatic control valves, the actuator 18 causes controlled two-stage axial movement of the plunger 19 and hence of the adapter 20 along the filling element axis FA. To carry this out, the actuator 18 includes an upper piston-cylinder arrangement 18b and a lower piston-cylinder arrangement 18a that form corresponding pneumatic lifting elements.
The lower piston-cylinder arrangement 18a includes a lower piston 18.2 that acts directly on the plunger 19. In effect, the plunger 19 can be viewed as a piston rod of the lower piston-cylinder arrangement 18a.
The upper piston-cylinder arrangement 18b has an upper piston 18.1 provided on another piston rod that is also coaxial with the filling element axis FA. A bellows seal seals off the region in which the plunger 19 penetrates the top of the product vessel 1.
The actuator 18 causes the upper piston-cylinder arrangement 18b to execute an upper partial-stroke H2. This upper partial stroke H2 causes the upper piston-cylinder arrangement 18b to transition between an upper position and a lower position.
When the upper piston-cylinder arrangement 18b is in its lower position, its piston rod forms a stop for the piston rod of the lower piston-cylinder arrangement 18a. This stop limits the travel of the lower piston-cylinder arrangement 18a to a lower partial-stroke H1.
On the other hand, when in its upper position, the upper piston-cylinder arrangement 18b permits the lower piston-cylinder arrangement 18a to execute a longer lower stroke. This longer lower stroke has a length that is equal to the sum of the lengths of the upper partial-stroke H2 and the lower partial-stroke H1.
Referring to
As the hook 20a moves upward, the hooking surface 20.1 engages the gas-valve collar 17.1. It does so by hooking the gas-valve collar 17.1 from below. In particular, the gas-valve collar 17.1 has first and second surfaces extending along a plane perpendicular to the filling-element axis FA with the second surface being closer to the container than the first surface. The hook 20a, and in particular, the hooking surface 20.1 thereof, engages the second surface.
The adapter 20 also has an adapter surface 20.2 that interacts with a sealing face at an opening 24 provided on the top of the gas-valve body 17. This interaction configures the second gas-valve 23.
When the adapter surface 20.2 rests against the sealing face at the opening 24, the hooking surface 20.1 is offset from the gas-valve collar 17.1 along the filling-element axis FA. For reasons that will be apparent, the offset between the hooking surface 20.1 and the adapter surface 20.2 should be equal to or greater than an extent of the lower partial-stroke H1.
The lower partial-stroke H1 raises the plunger 19, thus lifting the adapter surface 20.2 off the sealing face of opening 24 and opening the second gas-valve 23. It also raises the hooking surface 20.1 by the same amount. However, as a result of having correctly chosen the offset, even after having been raised, the hooking surface 20.1 is still at some distance away from, or at best, just barely contacts, the gas-valve collar 17.1. This means that the plunger 19 does not lift the gas-valve body 17. Therefore, the lower partial-stroke H1 opens only the second gas-valve 23 and not the first gas-valve 16.
When the plunger 19 is in its lowest position, so that as much of it as possible extends into the vessel 1, the adapter surface 20.2 of the adapter 2 lies opposite the seal provided at the opening 24. This closes the second gas-valve 23. In addition, the gas-valve body 17 is now fully pushed into the first gas-duct 14. This, in turn, closes the first gas-valve 16 and causes the second gas-duct 21 to connect to the first gas-duct 14 in a fluid-tight manner.
When the piston rod of the upper piston-cylinder arrangement 18b is positioned in its lower position, actuating the lower piston-cylinder arrangement 18a raises the plunger 19, and with it, the adapter 20, by an extent of the lower partial-stroke H1. As a result, the adapter surface 20.2 lifts off the opening 24, and the second gas-valve 23 opens. Because the opening 24 opens into the first gas-space 1.2, some of the gas in the first gas-space 1.2 flows through the opening 24, through the second gas-duct 21, through the first gas-duct 14, through the gas tube 15, and finally, into the container's headspace.
Preferably, the second gas-duct 21 has a smaller cross-section than the first gas-duct 14 so as to restrict the flow of gas from the first gas-space 1.2 into the container 2. Further restriction of this flow can be carried out with a suitable restrictor in the region of the opening 24.
Raising the piston rod of the upper piston-cylinder arrangement 18b into its upper position removes the restriction that the plunger 19 can only be lifted by the extent of the lower partial-stroke H1. With the upper piston-cylinder arrangement 18b thus raised, the lower piston-cylinder arrangement 18a can now lift the plunger 19 by a length that is equal to the sum of the extents of the lower partial-stroke H1 and the upper partial-stroke H2. This is enough to not only cause the hooking surface 20.1 to engage behind the gas-valve collar 17.1, but to enable the hook 20a to pull the gas-valve body 17 upwards at least partially out of the first gas-duct 14 and thereby opening the first gas-valve 16.
A spring 25 inside the vessel 1 acts between the plunger flange 13.1 and a tube 27 that defines a space that surrounds the valve plunger 13 to form a product inlet. In the illustrated embodiment, the spring is a compression spring oriented such that application of a force vector oriented along the filling-machine axis FA will cause the spring 25 to exert a restoring force in a direction opposite to the applied force. The spring 25 ultimately opens the liquid valve 11 in the manner described below.
A vacuum control-valve 28 disposed along a vacuum duct 29 in the filling-element housing 7 selectively connects a vacuum source 30 to the container's interior. The vacuum source 30 and the vacuum control-valve 28 are preferably activated in such a way that results in a pressure of 0.05-0.25 bar within the container's interior. In some embodiments, the vacuum source 30 evacuates the container 2 to a 95% vacuum.
Because the gas tube 15 extends far down into the interior of container 2, the purging gas that exits the gas tube 15 travels as far as the bottom of container 2. Meanwhile, because of the reduced-cross section of the second gas-duct 21 and/or because of the restrictor arranged near the opening 24, the purging gas flow remains low enough so that purging raises the vacuum pressure by only a small amount, for example by an amount between about 0.05 bar and 0.2 bar. As a result, during the purging operation, the internal pressure within the container 2 remains considerably below ambient pressure, for example around 0.15 bar to 0.45 bar below ambient pressure. To intensify purging, the supply of purging gas can be provided in a time-controlled manner and continuously. Alternatively the purging gas can be supplied at intervals, i.e. in a sequence of steps.
As shown in
To more quickly pre-tension a container 2 prior to filling it, the actuator 18 moves the piston rod of the upper piston-cylinder arrangement 18b into an upper position as shown in
The spring 25 applies a spring force that is great enough to lift the liquid-valve body 12 up off its valve seat when the pressure in the container's interior is equal to the pressure in the vessel 1. As a result, liquid filling-product in the vessel 1 enters the container's interior through the liquid duct 8 and the product-dispensing opening 10. The inert gas that is used to pre-tension the container 2 then flows backs through the gas tube 15, through the first gas-duct 14, and through the open first gas-valve 16 on its way back to the first gas-space 1.2 of the vessel 1.
In some embodiments, the spring force is slightly greater than the weight of the liquid-valve body 12, the valve plunger 13, or the column of liquid of the product contained in vessel 1 acting on the liquid-valve body 12 less friction forces.
In some embodiments, a gas barrier 12.1 in a region immediately above a valve disk of the liquid-valve body 12 ensures that gas from the container's headspace will not pass beyond the liquid-valve body 12 and on into the liquid space 1.1 of the vessel 1.
The actuator 18 seals the liquid valve 11 using the valve plunger 13 to push the adapter 20 so that the pushing surface 20.3 of the hook 20a pushes against the plunger flange 13.1. In particular, as the piston rod of the lower piston-cylinder arrangement 18a returns to its lower initial position, the pushing surface 20.3 comes to rest against the plunger flange 13.1. In doing so the pushing surface 20.3 pushes the liquid-valve body 12 against the spring force of the spring 25 such that the liquid-valve body 12 rests in a fluid-tight manner against the filling-element housing 7. Resetting the plunger 19 closes both the first and second gas-valves 16, 23 again, thus separating the first and second gas-ducts 14, 21 from the first gas-space 1.2.
Referring now to
Upon completion of depressurization, the container carrier 5 lowers the container, thus breaking the seal between the container 2 and the filling element 4.
In the embodiment of
A third gas-valve 32 selectively connects the second gas-space 26 via a preferably flexible second-gas-space gas-line 33 with a third gas-duct 34 that extends through the piston rod of the actuator 18. The third gas-duct 34 passes through the piston rod longitudinally along the filling element axis FA.
At its lower end, the opening 24 connects the third gas-duct 34 to the second gas-duct 21 upon closing the second gas-valve 23, where the adapter surface 20.2 of the adapter 20 rests against the opening 24. This also closes the first gas-valve 16. As a result, a continuous gas channel extends from the second gas-space 26 to the container's interior. This continuous gas channel extends through the second-gas-space gas-line 33, the third gas-duct 34, the second gas-duct 21, the first gas-duct 14, and the gas tube 15 into the container's interior.
An advantage to the embodiment shown in
The actuator 18 can be configured to cause only a single-stage stroke in which the stroke's travel opens only the second gas-valve 23. This means that, during pre-tensioning, the first and second gas-valves 16, 23 will be closed. As a result, the only gas that makes it to the container's interior is the gas stored in the second gas-space 26. This results in a less expensive pre-tensioning procedure.
Some embodiments include a trinox gas space 36 that connects with the container's headspace via a trinox duct 35 coupled to the vacuum duct 29. This arrangement causes the product level of the filled container 2 to be level with the bottom end of the gas tube 15. In this embodiment, any filling-product that lies above the bottom end of the gas tube 15 is pushed through the gas tube 15 and all the way up to the second-gas-space gas-line 33 toward a connecting duct 37 that connects the second-gas-space gas-line 33 to the vessel 1. As a result, the excess filling-product is returned to the vessel 1 and used again to fill another container.
Unlike the embodiment shown in
Also unlike the embodiment shown in
The first-branch restrictor 41 and the second-branch restrictor 42 are dimensioned to cause different volumetric flow rates assuming constant pressure in the second gas-space 26. In one embodiment, the first-branch restrictor 41 has a smaller bore than the second-branch restrictor 42.
Depending on the nature of the purging method therefore, the volumetric flow through the third gas-duct 34 or through the second-gas-space gas-line 33 can be selected by choosing which one of the first-branch control-valve 32a and the second-branch control-valve 32b to open and which one to close.
The ability to control flow rate during the purging process represents a considerable advantage especially when containers that are to be filled at the filling element include those that are typically filled with vacuum assistance, such as glass bottles, and those that are typically filled without vacuum assistance, such as PET bottles. These applications are best carried out at different purging pressures. As a result, it becomes possible to choose the flow rate as a function of the purging pressure prevailing in the container to be filled.
The invention has been described hereinbefore by reference to a number of embodiments. It goes without saying that numerous variations as well as modifications are possible without departing from the inventive concept underlying the invention.
Having described the invention, and a preferred embodiment thereof, what is claimed as new, and secured by letters patent is:
Number | Date | Country | Kind |
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10 2013 107 256.9 | Jul 2013 | DE | national |
This is the national stage of PCT/EP2014/064200, filed on Jul. 3, 2014, which claims the benefit of the Jul. 9, 2013 priority date of DE 102013107256.9, the contents of which are herein incorporated by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/064200 | 7/3/2014 | WO | 00 |