1. Field of the Invention
This invention relates to a method for filling a plastic container having a neck, and to the attachment of a capsule thereon, in a bottling installation, wherein the capsule is of plastic deformable material, with substances enclosed therein in a solid, liquid or pourable condition, which are to be dispensed into the plastic container. First, the plastic container is filled in an aseptic manner and afterwards the container neck is sealed with a membrane, whereupon the capsule is attached onto the membrane, and a cap or closure is placed over the capsule onto the container neck. The capsule is manufactured of two aluminium films which are welded to one another, wherein the lower film forms a deep drawn receiver space, and the upper, covering aluminium film is planar, so that both films together have a planar edge around the receiver space.
2. Discussion of Related Art
Containers, in which a substance is located, to which further substances must be added before consumption, are increasingly offered on the market. This concept has one advantage that the substances which must finally be added into the fluid and which to some extent are light-sensitive, are also supplied on the container, packaged in capsules, so that the substances which are to be dispensed into the fluid located in the container, are not applied into the fluid until the user applies them. This system has been provided successfully today for the most varied of dairy mixing products, pharmaceutical preparations, vitamin-enriched drinks, and the like.
The capsules, which are used with this, are present in different forms on the market and are also manufactured in different manners. For example, a method for manufacturing capsules, as may be applied here, is known from U.S. Pat. No. 6,823,649. With these capsules, two aluminium films are added over one another, the lower film deep drawn, so that a receiver space forms, in which the substance to be dispensed is filled, in a liquid, solid or free-flowing condition. The second aluminium film is welded thereover. This film thus remains absolutely planar. The two films which are to be connected to one another are supplied in rolls, and the capsules are thus manufactured in a coherent manner as endless strips. These endless strips may then be cut in arcs, or the capsules may be pushed directly out of these strips.
In many cases of application, the fluid filled into the container must be aseptically filled and subsequently sealed directly by way of a membrane. With different methods used today, the capsules are inserted into the caps or closures by suitable handling machines and these closures are charged with the capsules delivered to the bottler. This is extremely problematic, since this is not in accordance with the logistics. In principle, the capsules in the plastics-processing companies must be inserted directly in the vicinity of the injection molding machines, since otherwise the extremely complex closures must be individualized again in special, very expensive handling machines, aligned and thereafter the capsules inserted and secured therein. The plastics-processing companies are usually not equipped for this purpose. Added to this is the fact that with this method, there exists the danger that the capsules become leaky and at the point in time at which the closure gets onto the filled containers, the contents of the capsules have already experienced a quality reduction or even a complete decomposition. This problem has been recognized and accordingly a method developed, as is known from PCT International Publication WO 2006/056082. With this method, two possibilities are offered, specifically in the case with which the capsule formation is effected directly on the bottle neck. With the second solution, which is of particular interest here, the capsule is placed onto the first membrane and there connected. It has been suggested to weld the capsule onto the already present membrane in the container neck region. This method has been found to be relatively slow, and also has been found to be extremely critical to realize a second welding of the capsule to the membrane over an already present welding between the container neck and the first membrane, without the first welding thereby becoming damaged.
In order to avoid this problem, installations have been changed, so that the capsules are bonded on the first membrane in turn only in the region above the container neck, by way of a foodstuff-allowable adhesive. Although the result was satisfactory, this method too does not permit an increased production speed, and also the adhesive has led to a large dirtying of the bottling installations.
It is one object of this invention to improve a method of the initially described type, so that the previously mentioned problems are avoided and preferably the production speed increased.
This object is achieved by a method of the initially mentioned type, which in a first step, the edge which is formed together by the two films of the capsule, is bent out of the plane surface by less than 90°, but more than 45°, so that a peripheral collar arises with a diameter of the magnitude of the container neck, on which the capsule is placed so that it is held on the container neck with a positive and/or friction fit, whereupon the cap is stuck on, the cap holding the capsule at least on the container neck in the required position.
Further advantageous forms of the method according to the invention are to be deduced from this specification and the claims.
The method according to this invention is explained in view of the accompanying drawings and the elements which are applied with the method are shown in various method situations alone, and the method is shown schematically, wherein:
The design of the capsules is first discussed for an improved understanding of the method according to this invention.
A second film 6 lies over the first film 2. The second film 6 is completely planar. The second, planar film 6 covers the receiver space 3. The second, planar film 6 also comprises a horizontal edge 7, which runs above the horizontal edge of the first film. In the region of the horizontal edges 5 and 7, these are connected to one another by an annular sealing 8. Usually, the two films 2 and 6 are provided as strips from large rolls. Accordingly, a multitude of capsules 1 are formed from these strips. In this case, the capsules 1 after welding or during welding are not completely punched out, but break-off location bridges 9 remain. The capsules 1 thus remain firmly connected to the film remains 10. So-called blister sheets 1 arrive at a bottling installation. The blister sheets 11 thus comprise a multitude of capsules 1 with film remains 10 which lie therebetween and which are connected to the capsules 1 via the break-off location bridges. The term blister sheet is correct inasmuch, with regard to the first film 2, because it is an aluminium film coated with plastic. This film is plastically deformable despite the plastic coating which means that the aluminium share is larger than the plastic share deposited thereon. After a deformation of the first film, this thus does not deform back in an elastic manner. The same also applies to the second film 6, which likewise is essentially of aluminium. This too comprises a plastic coating which is suitable for the thermal welding of the second film 6 to the first film 2.
In principle, it is also possible to use the capsules in a completely punched out manner, for the method. The design of blister sheets 11 is preferred because it is ensured up to the introduction of the capsules 1 into the filling procedure, that their edges remains at least approximately planar. If one completely punched out these capsules beforehand and provided them as a protective product, then the edges would certainly be deformed and no longer completely planar. This would compromise the subsequent method. For this reason, one may preferably use the method along with using blister sheets, with which the capsules 1 are still held together.
Such a blister sheet is shown in a partial view in
In
The individual steps of the method according to this invention are explained further by way of
In the next step C, the tear-off tab 81 and the projecting edge 82 are turned over and pressed onto the bottle neck 50. This may for example be effected by a pressing head which may be pushed thereover, or the container 54 is led past or beyond a pressing strip while the container 54 is simultaneously rotated, with which the projecting edge 82 and the tear-off tab 81 are pressed onto the container neck 5. In a subsequent step, which is not shown in
The collar 58, with respect to the receiver space 3, is directed upwards away. The capsule 1, as represented in the successive step D in
With the outwardly directed inclination of the collar 58, the capsule 1 positions itself on the container neck 50 in a centering manner. Thus, a sufficient positive-fit is achieved, which ensures that the capsule 1 does not fall down from the container neck 50 with the further transport. Also, in practise, a certain clamping is achieved by way of the already previously turned over projecting edge 82 of the membrane 80, so that the capsule 1 is not only held on the container neck 50 with a positive fit, but mostly also with a friction fit.
In the subsequent step E, the now bent-up collar 58 of the capsule 1 is fastened on the container neck 50 with an absolutely positive fit by a pressing strip 90. As evident from the already described
The last method step which is represented in
With packaging of this type, one attempts wherever possible, to always use material in a saving manner. Thus one manufactures the container 54 as thin-walled as possible. Because the method of interest requires a connection which is as exactly fitting as possible, the pressing of the cap or the closure 100 on the container 54 under certain circumstances would lead to the container 54 thereby being deformed, so that its volume is reduced and the fluid contents is pressed upwards and the membrane 80 is destroyed. In order to reduce these forces, it has been found to be advantageous to preheat the closures or caps 100. Because the caps 100 or closures are of plastic, they deform more easily in the warm condition and a thermal expansion simultaneously takes place. The cap or the closure 100 may thus be stuck on with a reduced force by two effects. In
The already described horizontal residual edge 57 is preferably dimensioned so that this at least has the width which corresponds to the wall thickness of the container neck 50. This, in the case that it is found to be necessary, also permits the realization of a point welding between the capsule 1 and the membrane 80. One would then usefully carry this out directly subsequent to step D.
One would press the capsules 1 out of the blister sheets 11 before carrying out the step D. With the arrangement of the capsules 1 in the blister sheet 11, the capsules may be attached so that these equally correspond to the alignment of the containers 54 in the bottling installation, so that in the bottling installation, the step D, specifically the placing of the capsules 1 and the bending up of the collar 58 with a simultaneous destruction of the break-off location bridges 9 may be effected in one working run. With such a procedure, one would also guide a punch over the respective capsule, by which, as already mentioned, the break-off location bridges are destroyed while simultaneously the respective collar is formed. This is not compelling. It is also possible to punch the capsules 1 out of the sheets in a separated manner and subsequently form the collar 58 by flanging.
Although the membrane 80 is welded or sealed on the container neck 50, preferably in step C, such a connection may also be effected by bonding. For the aseptic packaging however, an absolutely sealing connection between the membrane 80 and the container neck 50 is required and this may be achieved better with little effort by welding technologies.
Because the method steps shown here are conventionally used for other methods and these method steps individually have already been realized in bottling installations, with the exception of the special capsule deformations which are adapted here, one may assume that the method according to this invention may also be carried out without any problem also in bottling installations with high production speeds.
Number | Date | Country | Kind |
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0381/08 | Mar 2008 | CH | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/CH2009/000091 | 3/12/2009 | WO | 00 | 11/23/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2009/111901 | 9/17/2009 | WO | A |
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3305368 | Bourelle | Feb 1967 | A |
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3834580 | Ludwig et al. | Sep 1974 | A |
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5370222 | Steigerwald et al. | Dec 1994 | A |
5503282 | Montgomery | Apr 1996 | A |
5927549 | Wood | Jul 1999 | A |
6823649 | Pauchet | Nov 2004 | B1 |
7828141 | Epp et al. | Nov 2010 | B2 |
20080006599 | Muhlemann | Jan 2008 | A1 |
20090272712 | Muhlemann | Nov 2009 | A1 |
Number | Date | Country |
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891341 | Mar 1962 | GB |
WO 2006056082 | Jun 2006 | WO |
Entry |
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U.S. Appl. No. 10/566,528, filed Jan. 30, 2006; inventor Rolf Muehlemann; title Plastic Drinks Bottle With Cap (Abandoned). |
Notification of Transmittal of Translation of the International Preliminary Report on Patentability, Form PCT/IB/338 (1 page), dated 2010. |
Translation of the Written Opinion of the International Searching Authority, Form PCT/IB/373 (5 pages), dated 2010. |
Number | Date | Country | |
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20110061761 A1 | Mar 2011 | US |