EP0085360A2 - Seal member - Google Patents

Abstract

A cap closure for containers with pharmaceutical contents, in which a pierceable stopper-shaped or disc-shaped sealing element is provided for sealing on the container neck and overlaid by a sealing cap, is improved in terms of its use properties and its production in that the sealing element consists of an open support part (1) and there is an elastic filler part (14) produced by injection into this support part and firmly connected to it, which forms a seal against the container neck (FIG. 3).

Description

The invention relates to a cap closure for a container with pharmaceutical content, in particular for bottle-shaped containers with substances intended for infusion, transfusion or injection, in which a pierceable stopper-shaped or disk-shaped sealing element is provided for sealing on the container neck, which is overlaid by a closure cap. In addition, a method for producing the sealing element used is specified.

Cap closures for containers with pharmaceutical contents are known using metal crimp caps or welded plastic caps, for example by DE-OS 27 27 737 and DE-PS 23 27 553. The bottle neck is sealed with the aid of a pierceable, disc-shaped or stopper-shaped, elastic sealing element, which is overlaid by a closure cap that can be removed in the central region and / or as a whole. In the case of metal crimp caps, this closure cap is fastened to the neck of the bottle by flanging an edge bead or, in the case of plastic caps, by welding with a flange to the neck of the plastic bottle.

The stopper-shaped or disc-shaped sealing elements used to pre-close the bottle are made of solid rubber or a plastic with corresponding rubber-elastic properties. This solid design results in a considerable waste of material of the relatively expensive elastic rubber material. There is also the risk that rubber components, in particular plasticizer substances, penetrate into the container contents during the storage period, mix with it and contaminate it in the process. When punching the solid rubber plugs, there are also stuck punch fragments that can be easily inserted into the container. When piercing the rubber stopper with a transfusion or injection Particles detached from the needle tip are also inserted into the container content and passed on with the container content.

The invention is based on the task of designing a cap closure of the type defined at the outset in such a way that the stopper-shaped or disc-shaped sealing element largely avoids the disadvantages of the known solid rubber design. There should be no significant migration of rubber constituents during the storage period, nor should the contents of the container mix with the particles that are created when closing or pushing through. The cap closure with the novel sealing element should also allow simple and inexpensive largely automated mass production in the manufacture and closure of the containers.

The characteristic of the invention is to be seen in the fact that the sealing element has an open support part and an elastic filler part, which is produced by injection into the support part and is firmly - preferably non-detachably - connected to it, which forms a seal against the container neck. Such a further development appears to be particularly advantageous in which a membrane part which is integrally formed and pierceable with it is provided in the support part.

Due to the firm connection of a relatively dimensionally stable supporting part forming a supporting skeleton part with an injected elastic filling part, a sufficient dimensional stability and sealing effect can be achieved with economical use of materials. The surfaces of the elastic filling part which are connected to the interior of the container can be kept relatively low.

The optionally attached pierceable membrane part, which is formed in one piece with the support part, in particular in the central region, prevents particles of the filling part detached from the needle tip from being inserted into the container contents and passed on with the latter.

The elastic support layer, which the filling part can form on the membrane part, holds infusion and injection needles in place due to their clamping action. When penetrating the relatively thin-walled membrane part (thickness preferably less than 0.5 mm), a stripping effect occurs there, which keeps particles ejected from the filling part and the like away from the container contents.

Another expedient embodiment can provide that an edge-tight holder for a piercing part is arranged on the membrane part. In a thick case, on a support layer of the filling part on the membrane part is dispensed with. The piercing part, which can be designed in a known manner in the form of a skewer or also as a cannula, is then held, for example, by means of a tube attachment with lip seals projecting on the inside wall.

In an expedient embodiment of the sealing element in the form of a stopper, the support part can have an upper cover part with a flange edge, which is connected in one piece to a cylindrical insert part. Passage recesses for injecting the filling part are advantageously provided between the upper cover part of the support part and the hollow cylindrical plug-in part. The filler part forms in the cover part a middle layer overlaying the membrane part, which extends over the passage recesses from the inner cavity of the flange edge into the area of the outside of the cylindrical plug-in part and forms the sealing there against the inner wall of the container neck.

So that the support of the filling part on the outside of the cylindrical plug-in part has a flawless boundary, it appears expedient to spread the filling material lengthways in the injection molding process limit the surface of the cylindrical plug-in part by means of an appropriately molded edge strip.

In the version with a disc-shaped sealing element, it may be advantageous that the support part is a disc with a protruding edge, in the middle of which there is an insert part, and that the filler part consists of an annular disc-shaped section and a cylindrical center section connected to it through passage recesses, which acts as a support layer lies on the membrane part.

In order to facilitate the automatic feeding of the disk-shaped sealing element when the containers are mechanically closed, it can furthermore be expedient for the edge of the supporting part to be designed geometrically such that an orientation of the sealing element in a defined position is possible. For this purpose, the edge of the support part can either be conical or be provided with other orientation approaches. This makes it possible to orient the sealing elements supplied from a storage container in such a way that the elastic sealing surface points towards the container edge when it is placed on the container. Due to the possibly appropriate covering of the annular disk-shaped section of the filling part with an elastic The covering membrane can be used to produce a disc-shaped sealing element which, after the interior of the container, only has the surfaces of the filler which are absolutely necessary for sealing.

In a configuration in which the filling part forms a support layer on the membrane part, it may be expedient to place an annular outer reinforcing strip on this membrane part, which encloses an annular inner reinforcing strip which is likewise placed on the membrane part. Puncture orientation recesses for the ring and circular surface formed by the reinforcement strips are preformed on the membrane part on the surface of the support layer of the filling part. These orientation recesses enable the targeted insertion of the transfusion needle or an additional injection needle.

An additional use advantage when pulling out the sealing element designed as a sealing plug can possibly be achieved in that a pull-off element is integrally formed on the supporting part. In this embodiment, the pulling element can expediently be designed in a ring shape, its height essentially corresponding to the thickness of the cover part enclosed by the pulling ring. The pull ring practically forms the outermost edge of the lid part and can be covered with this through the crimp cap.

Various pharmaceutically compatible plastics, in particular polypropylene, are suitable as the material for the essentially dimensionally stable but not always rigid support part. Since the support part, as a dimensionally stable base body, does not have to have any significant elastic properties, it can be selected primarily from the point of view of a material which is well compatible with the contents of the container. The required elastic properties are generated by the elastic filler. A sprayable rubber compound appears to be particularly suitable for this.

An embodiment appears expedient in which the weight fraction of the support part is more than 25% of the filler part. As a result, in addition to the favorable properties mentioned, a significant cost reduction is brought about. The use of the expensive elastic filling material remains limited to the areas in which elastic properties for edge sealing or for the additional holding of Puncture needles must be available.

An expedient method for producing a sealing element for a cap closure of the type described at the outset can be that the support part is injection molded in a first operation and that the elastic filler is injected into the finished support part in a subsequent second operation. This results in a favorable workflow and the desired firm anchoring of the filling part in the support part. Such a further development of the manufacturing process appears to be favorable, in which the support part is formed in one mold recess of a displaceable or rotatable injection mold and in which the filler part is injected into the support part remaining after the mold has been converted, while the other part is injected Molded a support part is injected. This enables cyclical work at high working speeds.

By applying the features of the invention, a cap closure is created with a pierceable sealing element in the form of a stopper or disc, which combines favorable sealing properties with high dimensional stability and largely prevents the penetration of undesired components into the container contents. The novel sealing element, in which a support is partially connected to an elastic filler, which remains largely shielded from the interior of the container, excludes the impairment of the contents of the container and enables inexpensive production as a mass article.

• Fig. 1 einen Längsschnitt durch einen Stützteil für ein hohlstopfenförmiges Abdichtelement,
• Fig. 2 eine Draufsicht auf den Stützteil nach Fig.1,
• Fig. 3 einen Längsschnitt durch einen kompletten Hohlstopfen mit alternativer Ausbildung des Stützteils,
• Fig. 4 einen Längsschnitt durch einen kompletten Hohlstopfen mit zusätzlioher Halterung.
• Fig. 5 einen Längsschnitt durch einen kompletten Hohlstopfen mit Abziehring.
• Fig. 6 einen Längsschnitt durch einen Kappenverschluß mit einem scheibenförmigen Abdichtelement.

In the drawing, embodiments of the object of the invention are shown schematically; show it:

• 1 shows a longitudinal section through a support part for a hollow plug-shaped sealing element,
• 2 shows a plan view of the support part according to FIG. 1,
• 3 shows a longitudinal section through a complete hollow plug with an alternative design of the support part,
• Fig. 4 shows a longitudinal section through a complete hollow plug with additional bracket.
• Fig. 5 shows a longitudinal section through a complete hollow plug with a pull ring.
• Fig. 6 shows a longitudinal section through a cap closure with a disc-shaped sealing element.

FIGS. 1 and 2 show a support part 1, which consists of an upper cover part 2 with a flange edge 3 that is open on the underside and a cup-shaped end part 5, which forms part of a hollow cylindrical plug-in part 4. a membrane part 6 is molded in one piece into the bottom of the end part 5. The connection between the pot-shaped end part 5 and the cover part 2 is made via webs 7 which are integrally connected to both parts 2.5. The lower edge of the cup-shaped end part 5 is drawn up in a conical outer part 8 up to the sealing surface which occurs when the plug is completely closed.

The cover part 2 is provided with injection recesses 9 through which the material of the filling part can be injected and connected to the support part 1. The embodiment of the complete sealing plug essentially corresponds to FIG. 3.

On the membrane part 6, annular reinforcement strips 10, 11 are arranged, which on the membrane part 6 have an outer annular puncture surface 12 and Define inner circular puncture surface 13. Orientation recesses 15, 16 are formed in the filling part 4 (see FIG. 5). These serve to guide the infusion needle into the inner circular puncture surface 13 and to guide an injection needle into the outer circular puncture surface 12 of the membrane part 6 and thus to add additional substances into the container contents. In the embodiment according to FIG. 5, a pull-off ring 17 is integrally connected to the cover part 2 via a connecting web 18 in order to pull the closure plug out of the bottle neck. The dashed position of the pull ring 17 corresponds to the position of use. The height of the pull ring 17 is adapted to the thickness of the cover part 2.

In the embodiment according to FIG. 3, the filling part 14 is formed as a support layer 19 on the hollow cylindrical solid insertion part 4. The connection between the support layer 20 of the filling part 14 resting on the membrane part 6 and the support layer 19 is made via passage recesses 21.

FIG. 4 shows a support part 1 corresponding to FIG. 3, in which the membrane part 6 is not covered by a support layer of the filling part 14. Rather, in the edge region of the membrane rope 6 is a pipe bracket 22nd provided with lip seals. 23, which clamp a piercing part 24 after severing the membrane part 6 under edge sealing.

The bearing layer 19 of the filling part 14 is delimited in the edge region of the hollow cylindrical plug-in part 4 by an integrally molded edge strip 25.

The complete cap closure is shown in the embodiment of FIG. 6. One can see the neck of a bottle-shaped container 26, the edge bead 27 of which is covered by a metal crimp cap 28 with the interposition of a disk-shaped sealing element 29. In the cover surface of the metal-tight crimp cap 28 there is a prepared tear line 30, along which a circular disk-shaped central part 31 can be pulled out with the help of a ring trigger 32. The ring trigger 32 is connected to a hollow rivet 33 formed in one piece from the material of the crimp cap.

The disk-shaped sealing element 29 consists of the support part 1 and the rubber-elastic filler part 14.

The filling part 14 is made up of an annular disk-shaped section 34 and a cylindrical middle section 36 connected thereto via passage recesses 35 composed. This middle piece 36 forms a support layer on the membrane part 6.

The sealing element, consisting of an open support part and a filler part produced by injection and thereby firmly connected to this, has been explained in the preceding description as part of a cap closure. However, the stopper-shaped design of the sealing element, with or without a pull-off element attached to the edge of the cover, can, if appropriate, also be useful on its own, i.e. can be used without closing cap to close containers. In this case, the overlapping closure cap can advantageously also be replaced by an open closure strip, a cover film or the like.

Claims (18)

1. Cap closure for a container with pharmaceutical content, in particular for bottle-shaped containers with substances intended for infusion, transfusion or injection, in which a pierceable stopper-shaped or disc-shaped sealing element is provided for sealing on the container neck, which is overlaid by a closure cap, characterized in that that the sealing element has an open support part (1) and an elastic filler part (14) produced by injection into the support part (1) and firmly connected to it, which forms a seal against the container neck. 2. Cap closure according to claim 1, characterized in that in the support part (1) with this integrally formed, pierceable membrane part (6) is provided. 3. cap closure according to claim 2, characterized in that the filling part (14) forms a support layer (20) on the membrane part (6). 4. Cap closure according to claim 2, characterized in that an edge sealing bracket (22, 23) for a piercing part (24) is arranged on the membrane part (6). 5. Cap closure according to claim 1 or 2, d a - characterized in that the support part (1) with plug-shaped design of the sealing element has an upper cover part (2) with a flange (3) which is integrally connected to a cylindrical insert part (4). 6. Cap closure according to claim 5, characterized in that the supporting part (1) between the upper cover part (2) and the hollow cylindrical insert part (4) has passage recesses (21) for injecting the filler part (14). 7. Cap closure according to claim 6, characterized in that the support layer (19) of the filling part (14) on the outer wall surface of the cylindrical insert part (4) is limited by an integrally formed edge strip (25). 8. cap closure according to claim 2, characterized in that the support part (1) is a disc-shaped sealing element is a disc (29) with a protruding edge, in the middle of which the membrane part (6) lies, and that the filler part (14) consists of an annular disc-shaped section (34) and a cylindrical center piece (36) connected therewith via passage recesses (35), which lies as a support layer on the membrane part (6). 9. Cap closure according to claim 8, characterized in that the annular disc-shaped section (34) of the filling part (14) is covered with an elastic covering membrane. 10. Cap closure according to claim 8, characterized in that the edge of the disc-shaped support part (29) is geometrically designed such that an orientation of the sealing disc in a defined position is possible. 11. Cap closure according to claim 2 and 3, characterized in that on the membrane part (6) has an annular, outer reinforcement strip (10) which surrounds an annular, inner reinforcement strip (11) placed on the membrane part (6), and that on the surface of the support layer (20) of the filler part (14) puncture orientation recesses (15, 16) -for the ring and circular surface (12, 13) formed by the reinforcing strips (10, 11) on the membrane part (6) are preformed. 12. Cap closure according to claim 1 or 2, characterized in that a pull-off element (17) is integrally formed on a stopper-shaped sealing element on the support part (1). 13. Cap closure according to claim 5 and 12, characterized in that the pull-off element (17) is designed annular, the height substantially corresponding to the thickness of the cover part (2) enclosed by the pull-off ring (17). 14. Cap closure according to claim 1, characterized in that the support part (1) consist of an injection-molded substantially rigid plastic and the elastic filling part (14) made of a rubber compound. 15. Cap closure according to claim 1 or 2, characterized in that the weight proportion of the support part (1) is more than 25% of the filler part (14). 16. Sealing plug for a container with pharmaceutical content, characterized in that the sealing plug consists of an open support part (1) and an elastic filler part (14) which is produced by injection into the support part (1) and is firmly connected to the latter. 17. A method for producing a sealing element for a cap closure according to any one of claims 1-16, characterized gekennzeichn e t that the support part is injection molded in a first operation, and that the elastic filler is injected into the finished support part in a subsequent second operation. 18. The method according to claim 17, characterized in that the shaping of the support part takes place in one mold recess of a displaceable or rotatable injection mold, and that in the support part remaining after the conversion of the mold in the mold recess, the filling part is injected while in the other Molded a support part is injected.

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