EP0633190A1 - Method and apparatus for filling aerosol cans - Google Patents

Abstract

In a method for filling aerosol cans (3), the aerosol to be decanted is provided in a supply container (1) and is introduced into the aerosol can (3) by means of a filling head (4) which can be placed onto the aerosol can (3). After the filling of the aerosol can (3) and before the filling head (4) is lifted off from the aerosol can (3), excess aerosol is extracted by suction. <IMAGE>

Description

The invention relates to a method and a device for filling aerosol containers according to the preamble of the respective independent patent claim.

Today aerosols are common forms of administration of active pharmaceutical substances. Many nasal and oral substances are available in this dosage form and are administered as an aerosol (e.g. sprays). These active substances are stored in an aerosol container in a mixture of active substances and propellant gases. If necessary, the user removes a desired amount of the aerosol from the container, usually by means of a removal device (spray valve) provided on the container.

Such aerosol containers are filled, for example, as described in GB-A-2,236, 146. First, the active substance is filled into the aerosol container in the form of a solution or suspension by means of a filling head through the valve tube (stem) of the aerosol container. For this purpose, the filling head is provided with a channel via which a storage container, in which the solution or suspension is provided, can be communicatively connected to the interior of the aerosol container via the valve tube (stem). To do this, the filling head is placed on the container, the valve tube is pressed down and the container is then filled.

When the aerosol container is filled, a certain amount of solution or suspension is first filled into the aerosol container from the storage container through a first inlet and then through the channel of the filling head. A certain amount of propellant gas is then poured into the container through a second inlet, but through the same channel of the filling head, and added to the solution or suspension, with no solution or suspension being fed through the inlet for the solution or suspension Propellant gas can flow out. Through the order in which the container is filled, namely first solution or suspension and then propellant, the solution or suspension still in the channel of the filling head or in the valve tube (stem) is supplied with the aid of the following Propellants are filled in the container and do not remain in the channel or in the valve tube. After a certain amount of propellant gas has been filled into the container, the propellant gas supply is stopped and the filling head is removed from the container.

Although this method and the associated device are fundamentally functional, they still have some disadvantages. After the aerosol container has been filled, propellant gas remains in the channel or in the valve tube (stem) of the aerosol container, which escapes ("fizzles out") when the filling head is removed and can lead to environmental pollution. On top of this, the ratio of solution or suspension to propellant gas cannot be precisely controlled during the filling process, since the solution or suspension and the propellant gas are filled into the container in two successive steps. Only a final check after filling is possible. However, this is unsatisfactory, particularly in the case of pharmaceutically very active substances, since here the proportion of active substance is often only very low and the ratio of solution or suspension to propellant gas must be adhered to very precisely, so that the user also receives exactly the desired amount of active substance when the aerosol is removed takes.

Another known filling method does not have this disadvantage. With this filling process, the aerosol is already provided in the storage container exactly in the desired ratio of solution or suspension to propellant gases. This ratio no longer changes during filling, so that after the aerosol container has been filled, the ratio of solution or suspension to propellant gases in the aerosol container corresponds exactly to the desired ratio. After filling the container, the filling head is removed from the container again. In addition to the advantage of the exact ratio of solution or suspension to propellant gases, this method also has the advantage that it is a filling method which, compared to the previously required two filling steps (first solution or suspension and then propellant gases), only comprises one filling step . However, after filling and removing the filling head from the aerosol container, the portions of solution or suspension still in the channel of the filling head can escape from the channel and become so dirty that the containers have to be subjected to extensive cleaning before they can be delivered . On top of this, the propellant gas still in the channel of the filling head or in the valve tube of the aerosol container can escape and lead to environmental pollution.

It is therefore an object of the invention, when filling aerosol containers, to substantially reduce contamination of the container and environmental pollution caused by escaping propellant gases, or even to avoid it altogether.

In terms of the method, this object is achieved in that excess aerosol is sucked off from the aerosol container after the aerosol container has been filled and before the filling head has been removed. Aerosol, which is still in the channel of the filling head or in the valve tube of the aerosol container, is thus suctioned off, so that contamination of the container and environmental pollution caused by escaping ("deflagrating") propellant gases can be avoided. In an advantageous variant of the method, propellant gas is recovered again after suction.

A further advantageous method variant is characterized in that in the state in which no aerosol container is filled, the aerosol is circulated back through the filling head back into the storage container. This allows a so-called "stand-by" operation and avoids that the device is started each time for filling and that it is switched off each time after a container has been filled. This also prevents undesirably high pressures from building up in supply lines.

Another process variant is characterized in that the temperature of the filling head is monitored and regulated. In this way, the formation of solid bodies ("icing") and thus a blockage of the channel of the filling head can be avoided.

In terms of the device, the object is achieved in that the device has a suction device which can be connected in a communicating manner to the channel of the filling head, and a controller which connects the suction device with the channel of the filling head in a communicating manner after the aerosol container has been filled.The advantages already correspond to those on the occasion of Explanation of the advantages mentioned according to the method. In a particularly advantageous embodiment of the device according to the invention, the suction device is connected to a device for recovering propellant gas.

Another advantageous exemplary embodiment of the device according to the invention is characterized in that the conveying device comprises a pump and a metering device connected downstream of the pump. There is a closing valve in the filling head provided which, in the operating state in which the aerosol container is not filled, closes the channel and the pump conveys the aerosol back through the filling head, but past the channel, back into the storage container. This enables so-called '' stand-by '' operation. Furthermore, a check valve is provided between the pump and the filling head and after the filling head. To fill the aerosol container, the control first closes the check valves and then opens the shut-off valve of the channel. The metering device then doses a defined amount of aerosol into the aerosol container through the channel.

In a further embodiment of the invention. The filling head is equipped with a thermostat in order to avoid `` icing '' of the filling head channel.

A further exemplary embodiment of the device according to the invention is characterized in that it comprises a bypass line which branches off the pump from the supply line from the storage container to the filling head and which can be opened by means of a valve. To fill the aerosol container, the control opens the bypass line after closing the check valves using this valve. As a result, the '' stand-by '' operation can also be maintained while the aerosol container is being filled, although the two non-return valves are closed and a '' stand-by '' operation through the filling head past the channel is not possible . Above all, this enables the use of continuously delivering pumps without undesirably high pressures building up in the feed lines.

Fig. 1

ein Ausführungsbeispiel der erfindungsgemässen Vorrichtung,

Fig. 2

ein Ausführungsbeispiel eines Sprühventils eines zu befüllenden Aerosolbehältters, dessen Ventilröhrchen (Stem) in geschlossener Stellung ist (keine Befüllung des Behälters möglich),

Fig. 3

das Sprühventil der Fig. 2 mit dem Ventilröhrchen in geöffneter Stellung (Befüllung des Behälters möglich)

und

Fig. 4

eine Variante der erfindungsgemässen Vorrichtung, die zum Reinigen der Sprühventile der Aerosolbehälter dient

The invention is explained in more detail below with the aid of the drawing, which show partly in schematic, partly in perspective or in section:

Fig. 1

an embodiment of the device according to the invention,

Fig. 2

an exemplary embodiment of a spray valve of an aerosol container to be filled, the valve tube (stem) of which is in the closed position (filling of the container is not possible),

Fig. 3

2 with the valve tube in the open position (filling of the container possible)

and

Fig. 4

a variant of the device according to the invention, which is used to clean the spray valves of the aerosol containers

In the exemplary embodiment of the device according to the invention shown in FIG. 1, a storage container 1 can be seen, in which the aerosol 2, which is to be filled into an aerosol container 3, is provided. A supply line 10 leads from the storage container 1 to a filling head 4 which is placed on the aerosol container 3 in FIG. 1. A pump 5 is connected between the storage container 1 and the filling head 4 and conveys aerosol 2 from the storage container 1 through the feed line 10. A bypass line 11 branches off the supply line 10 downstream of the pump 5. This bypass line 11 can be opened by means of a valve V1, which causes a control 6, the functions of which will be discussed in more detail below. In the further course of the feed line 10 to the filling head 4, that is to say after the bypass line 11 has branched off from the feed line 10, a check valve V2 is provided in the feed line 10. Between this check valve V2 and the filling head 4, a metering device 7 is arranged, through which the aerosol enters the filling head 4

In the filling head 4 there is a channel 40 which is closed by a closing valve V3. The filling head 4 also has an inlet 41 which leads to an annular space 42 which surrounds the closing valve V3. From the annular space 42 an outlet 43 leads to a return line 12, in which a further check valve V4 is provided. The return line 12 is further led back to the reservoir 1. In the further course of the return line 12, the bypass line 11 then opens into this return line 12.

The closure valve V3, which closes the channel 40 in the filling head 4, can be actuated by means of an organ 44, so that it can open the channel 40. The channel 40 leads through the filling head 4 to a valve tube (stem) 30 of the aerosol container 3, which is to be filled with aerosol 2. 1 shows that aerosol 2 has already been filled into the container 3. An example of how the stem 30 can be designed and how the container 3 is filled is shown in FIGS. 2 and 3 are explained in detail. At the end of the filling head 4, which faces the aerosol container 3, the filling head 4 is provided with a sealing O-ring 45, which seals the channel 4 and the stem 30 to the outside when the filling head 4 is placed on the container 3 Filling head 4 on the container 3, the filling head 4 is provided with a centering bell 46, in which stops 47 are provided. The centering bell 46 is screwed onto the outer wall of the filling head. Furthermore, the filling head is also equipped with a thermostat 48, with the aid of which the temperature of the filling head can be monitored and regulated.

1 also shows a suction device 8 which can be connected in a communicating manner to the channel 40 of the filling head 4. In the exemplary embodiment shown in FIG. 1, the core of this suction device 8 is very similar to the closure valve V3 with its actuating member 44. A branch 400 is provided in the duct 40, which leads to an intake duct 80, which is closed by a closure valve V5 of the suction device 8. The closure valve V5 can be actuated by means of an organ 84. An annular space 82 is provided around the closure valve V5 and is connected to an outlet 81. This outlet 81 is connected to a discharge line 83, which leads to a suction pump 85, for example. In turn, a device 9 for recovering propellant can be connected to this suction pump 85.

When the device is operating, the filling head 4 is initially in the so-called `` stand-by '' mode, i.e. no container 3 is filled. The pump 5 conveys aerosol 2 from the storage container 1. The valve V1 and thus the bypass line 11 are closed, the check valve V2 is open. From the storage container 1, the pump 5 conveys aerosol to the inlet 41 of the filling head 4 through the feed line 10 and through the metering device 7. The closure valve V3 in the filling head 4 is closed, so that the aerosol cannot get into the channel 40. Rather, it gets into the annular space 42, which surrounds the closure valve V3 and then through the outlet 43 into the return line 12. The check valve V4 is also open, so that the aerosol is fed back through the return line 12 back into the storage container 1.

The following will now explain how an aerosol container 3 is filled. For this purpose, the centering bell 46 is placed on the container 3 or on its spray valve 3a until the O-ring 45 is seated on the stem 30. Then the filling head together with the screwed on Centering bell 46 lowered until the stops 47 in the centering bell 46 strike the container 3. As a result, the stem 30 of the container is lowered to such an extent that the container can be filled, which will be explained below with reference to FIG. 2 and FIG. 3. The closure valve V5 of the suction device 8 initially remains closed.

2 shows an embodiment of a spray valve 3a of an aerosol container 3 to be filled, the stem 30 being in a position in which the container cannot be filled. The stem 30 is held in this position in the idle state by a valve spring 31. The stem 30 projects through an opening 32 and an inner seal 33 provided at the opening into a metering chamber 34 which is formed in a valve housing 35 which is held in the valve capsule 36. This inner seal 33 seals the interior of the valve 3a (and thus also the interior of the container) and in particular also the metering chamber 34 from the outside. In the upper part, the stem 30 has a type of blind hole 300 which has an opening 301 near the end of the blind hole. The lower part of the stem 30 is designed as a solid pin 302

The valve housing 35 has in its further course circumferential projections 350 projecting inward from its inner wall. One end of the valve spring 31 is supported against these projections 350, the other end of the valve spring 31 is supported against an outwardly projecting annular projection 303 of the stem 30. In the part of the stem 30 which is designed as a solid pin 302, the outside diameter tapers in one place from a larger outside diameter 304 to a smaller 305. The larger outside diameter 304 is almost exactly the same size as the inside diameter of the circumferential projections 350 Smaller outer diameter 305 is smaller than the inner diameter of the circumferential projections 350. In the rest position of the stem 30 shown in FIG. 2, there is therefore a small gap between the circumferential projections 350 and the solid pin 302.

Now the filling head 4 (FIG. 1) is lowered until the stops 47 of the centering bell 46 strike the container 3 or the spray valve 3a. As a result, the stem 30 with its opening 301 is also pressed into the metering chamber 34. This position of the stem 30 is shown in FIG. 3. By pushing the stem 30 into the metering chamber 34, the part of the stem 30 which is designed as a solid pin 302 is also pressed, so that the solid pin 302 with the larger outside diameter 304 gets between the projections 350 of the valve housing 35. Now through the blind hole 300 and the opening 301 through which the aerosol is filled into container 3 under high pressure (for example under approx. 40 bar). Because of the high pressure, the inner seal 33 is compressed from below so that the aerosol 2 can pass between the valve housing 35 and the inner seal 33 into the container interior, as indicated by the arrows in FIG. 3.

For this purpose, the stem 30 must be supplied with aerosol through the channel 40 of the filling head 4 (FIG. 1). Since the aerosol is already provided in the desired ratio of solution or suspension to propellant gas in the storage container 1, the following steps are still necessary: First, the control 6 closes the check valves V2 and V4 and opens the valve V1, so that the continuously operating pump 5 now pumps the aerosol 2 removed from the container 1 through the bypass line 11 back into the storage container 1. This means that the device can remain in the “stand-by” mode even when a container 3 is being filled, so that it is not necessary to switch off and restart. The controller 6 now opens the closing valve V3 of the filling head 4 by means of the organ 44. The seal 440 above the closing valve V3 can deform with the movement of the valve V3, the closing valve V3 is therefore movable and sealed at the same time. The closure valve V5 of the suction device 8 is still closed.

Now the dosing device 7 doses a desired amount of aerosol 2 into the container 3, as is explained on the basis of the explanation of FIG. 3. The metering device 7 is therefore indicated symbolically in FIG. 1 by a displaceable piston, wherein the piston stroke can be variable and a variable piston stroke means that different amounts of the aerosol can be filled into containers of different sizes. The ratio of solution or suspension to propellant gases is adhered to exactly regardless of the amount to be filled in, since the aerosol is already present in the desired composition.

After the container 3 has been filled, the filling head 4 is raised again to such an extent that the stem 30 is just returned to its rest position by the valve spring 31, but is still sealed off from the outside by the O-ring 45. However, there is still aerosol in the channel 40 and in the blind hole 300 of the stem 30. Therefore, the control by means of the organ 84 now opens the valve V5 of the suction device 8 connected to the suction pump 85, all of which are still in the filling head 4 and in the blind hole 300 of the Stems 30 sucks aerosol This aerosol can either be disposed of without polluting the environment, but it is also conceivable in particular to recycle it, ie to lead it back into the storage container. As already explained, the propellant gas contained in the aerosol can also be recovered in the device 9 for propellant gas recovery.

After the suction has ended, the controller 6 closes the closure valve V5 of the suction device 8 again by means of the organ 84, then the closure valve V3 of the filling head 4 by means of the organ 44. Furthermore, the controller 6 then closes the valve V1 and thus the bypass line 11 and opens the check valves V2 and V4 again. The metering device 7 is also reset again. The filling process is ended and the filling head 4 together with the centering bell 46 can be removed from the container 3 again.

As already mentioned above, this type of filling means that on the one hand the environment cannot be polluted by escaping propellant gases, but on the other hand it also enables contamination-free filling of the containers so that they do not have to be subjected to extensive cleaning after filling .

Furthermore, the thermostat 48 is also provided on the filling head. When the valve V5, whose seal 840 is also deformable, is opened, the aerosol can relax and low temperatures can occur, which can lead to solidification (icing) in the duct or in the lines. With the help of the thermostat 48, the temperature of the filling head 4 can be regulated to a temperature at which such solid formation is excluded. Of course, it is also conceivable to supply appropriately heated air through the opening 49 in the filling head 4 and the opening 89 in the suction device 8 and thus to achieve a sufficient temperature of the filling head 4 and the lines.

With the filling head 4 described, it is not only possible to fill containers 3 that have already been completed, that is to say finally assembled, as has been explained so far. With the filling head 4 it is also possible to first clean the spray valves 3a of the containers 3 before they are placed on the container 3 and the containers are then finally assembled and then filled. The variant of the device according to the invention which is suitable for this is shown in FIG. 4, with some parts of the device being simply compared to FIG have been omitted. When they are delivered, the spray valves 3a can often still contain dust particles or similar impurities, for example. In order to eliminate this in a first step, the spray valve 3a can first be placed on a hollow cylindrical body 36 which is open on both sides instead of a container. The lower opening of this hollow cylindrical body 36 is tightly connected to a recycling station R, which is equipped with filters and / or other suitable cleaning devices.

The filling head 4 with its centering bell 46 is now placed on the spray valve 3a placed on the hollow cylindrical body 36 until the stops 47 of the centering bell 46 strike the spray valve 3a. Subsequently, the filling head 4 together with the centering bell 46 is lowered, as a result of which a sufficiently tight, but later releasable connection between the spray valve 3a and the hollow cylindrical body 36 is achieved. At the same time, the valve stem 30 is pressed down as when the container 3 is being filled. In order to clean the spray valve 3a, aerosol is not now filled into the hollow cylindrical body, but instead of the aerosol either propellant gas or air 2a is supplied from a propellant gas or air reservoir 1a by means of the pump 5a in order to "blow out" contaminants from the spray valve 3a. This resulting mixture of propellant gas or air and impurities is fed through the lower opening of the hollow cylindrical body 36 to the recycling station R and cleaned by filters and / or other cleaning devices in the recycling station R, so that the cleaned propellant gas or the cleaned air e.g. can be returned and reused. The suction device 8 of the filling head 4 then sucks off the propellant gas or air still located in the channel 40 of the filling head 4 and in the valve stem 30, in the same way as is described when the container 3 is filled with aerosol. This propellant gas or the air extracted by the suction device 8 can also be cleaned and e.g. be returned for further use.

The main difference in the cleaning process is that there is simply no filling of a container, but only the cleaning ("flushing") of the spray valve 3a described. After the propellant gas or the air has been drawn off from the channel 40 of the filling head 4 and from the valve stem 30, the suction device 8 is deactivated again and the centering bell 46 is lifted again from the spray valve 3a placed on the hollow cylindrical body. The spray valve 3a is now cleaned ("rinsed") and can be placed on a container and this container can then be finally assembled. A Such assembled containers can then be filled in a subsequent step in the manner already described. Thus, contaminants that may still be present in spray valves 3a, for example due to production, can be effectively removed from these valves and, as a result, contaminant-free containers can be assembled. The spray valves 3a can be cleaned with a filling head 4 of the same type as is then possible for filling the finally assembled container 3, which distinguishes the filling head in a special way.

Claims (9)

Device for filling aerosol containers (3), with a storage container (1) for providing the aerosol to be filled (2), with a filling head (4) which has a channel (40) via which the filling head (4) communicates with the container (3) can be connected, and with a conveying device (5) which is connected to the storage container (1) and the filling head (4) and which, during filling, the aerosol (2) from the storage container (1) through the filling head (4) through to the aerosol container (3), characterized in that the device has a suction device (8) which can be communicatively connected to the channel (40) of the filling head (4), and a controller (6) which, after filling the aerosol container (3) communicates with the suction device (8) with the channel (40) of the filling head (4). Device according to claim 1, characterized in that the suction device (8) is connected to a device (9) for the recovery of propellant gas. Device according to one of claims 1 or 2, characterized in that the conveying device comprises a pump (5) and a metering device (7) connected downstream of the pump, and in that in the filling head (4) a closure valve (V3) is provided which is in the operating state , in which the aerosol container (3) is not filled, closes the channel (40) and the pump (5) the aerosol (2) through the filling head (4), but past the channel (40), back into the predicate container ( 1) promotes back, and that a check valve (V2, V4) is also provided between the pump (5) and the filling head (4) and after the filling head (4), the controller (6) initially being used to fill the aerosol container (3) closes the check valves (V2, V4), then opens the closing valve (V3) of the channel (40) and finally the dosing device (7) doses a defined amount of aerosol (2) into the aerosol container (3) through the channel (40) . Device according to one of claims 1 to 3, characterized in that the filling head is provided with a thermostat (48). Device according to one of claims 3 or 4, characterized in that it comprises a bypass line (11) which is arranged downstream of the pump (5) and from a supply line (10) provided between the pump (5) and the filling head (4). branched off, the bypass line (11) being openable by means of a valve (V1), and that the control (6) for filling the aerosol container (3) after closing the check valves (V2, V4) by means of this valve (V1) the bypass line (11) opens Method for filling aerosol containers, in which the aerosol to be filled is provided in a predicate container (1) and is filled into the aerosol container (3) by means of a filling head (4) which can be placed on the aerosol container (3) to be filled, characterized in that after filling of the aerosol container (3) and excess aerosol is removed from the aerosol container (3) before the filling head (4) is removed. A method according to claim 6, characterized in that propellant gas is recovered after suction. Method according to one of claims 6 or 7, characterized in that in the state in which no aerosol container (3) is filled, the aerosol (2) is circulated back through the filling head (4) back into the predicate container (1). Method according to one of claims 6 to 8, characterized in that the temperature of the filling head (4) is monitored and regulated.

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