EP3856656A1 - Sealing cap having a push-button for emptying a capsule formed thereby - Google Patents

Abstract

The invention relates to a fillable sealing cap (1), which forms a capsule (18), which is open to the bottom and can be sealed by a sealing washer (3), in the interior thereof. A central push-button (2) for depressing the capsule lid (6), thereby deforming the capsule lid, is formed on the outside of the capsule lid (6). A central stamp (7) protruding axially downward is formed on the inside of the capsule (18) underneath the push-button (2). At least three spreading legs (8) protruding downward and outward at an acute angle to the sealing-rotation axis (21) are formed distributed about the stamp. The capsule lid (6) is corrugated about the stamp (7) in the radial direction, wherein said capsule lid (6) has a thinner wall thickness in the first, interior region (10) of the radius thereof than in the second, outer region (11). The lid wall is flexed in two phases in the event of pressure from above on the push-button (2). The stamp (7) presses on the sealing washer (3), initially tensioning the sealing washer and then opening sealing washer while the ends (26) of the spreading legs (8) slide outward and press the sealing washer (3) downward on the circumference thereof and then hold the sealing washer pivoted downward.

Description

 CAP WITH PRESSURE BUTTON FOR EMPTYING THROUGH YOU

 SHAPED CAPSULE

This invention relates to a fillable cap, which forms a capsule inside, which can be opened by pressing a push button, so that its content falls from the capsule down into a container equipped with the cap.

Many drinks are already produced today by mixing a concentrate with water. Instead of distributing the finished mixture, it would be much more efficient if the bottle fillers could only fill water on site and the concentrate was only added to the water in the bottle by the consumer when the bottle was opened for the first time and then mixed with it. Such a closure can also be used to add all kinds of sensitive active ingredients and light-sensitive vitamins.

A known solution for metering a separate liquid is a plastic metering cap and associated container neck for a container. It consists of a threaded cap, a capsule that can be filled separately and sealed with a film or closed after filling, and an associated container neck. The capsule with its sealing film is held inside the container neck facing downwards. When the cap is placed on the container neck, it protrudes into the interior of the container neck, and there is a piercing and cutting device at the lower edge of the container neck, by means of which the closing film at the lower end of the capsule can be opened when the plastic dosing closure is opened for the first time, so that the Substance contained in the capsule falls into the container. The threaded cap is rotated counterclockwise when rotating counterclockwise - i.e. in the loosening direction at first on the container neck, whereby the film of the capsule is pressed through a piercing and cutting device and thus cut open, while the threaded cap on the container neck stops finds. If the threaded cap is turned further in the loosening direction, it takes along the neck of the container, which in turn sits with a thread on the container neck, but which thread requires a greater torque to unscrew. If the threaded cap is rotated further, it takes the container neck and the now empty capsule with it and the entire closure is screwed away from the container neck. The elegance of this solution lies in the fact that it requires a single action, namely only a continuous unscrewing of the threaded cap in the loosening direction. Then everything happens automatically one after the other. The disadvantage of this solution, however, is that it is complex to construct and implement, since left and right-handed threads are required, and the assembly of the closure is also not unproblematic.

Another known solution for metering in a separate liquid is a plastic metering closure and associated container neck for a container as is apparent from WO 2012/175'317 A1. It is a fillable closure with a push button to release, which works with a separately filled capsule. The closure consists of a closure cap which can be screwed onto the threaded connector of a container and into which this separately filled capsule can be inserted from below in the closed state, with the sealing film of the capsule pointing downwards. The top of the capsule used is designed to be deformable and can be pressed axially downward, so that the downward-pointing sealing film of the capsule can be broken or burst. According to this document, this is brought about by an axially downwardly projecting profile which is formed on the underside of the closure cap and which fits into a recess in the deformable upper side of the capsule which is suitable for the cross section of this profile. By pressing this profile into the recess, the outer lower corners of the profile are pressed indirectly onto the sealing film of the capsule. The sealing film is provided with lines of weakness so that these corners meet the bisector of the circle segments formed by the lines of weakness and after the bursting along the lines of weakness they are pivoted downwards from the corners of the profile and can then be kept pivoted downwards. In practice, however, it turns out that this solution works in principle, but not always perfectly, that is not in 100% of the cases. So this solution is for an implementation in practice in which hundreds of thousands of closures have to be delivered and everyone individual must work perfectly, too little suitable. There is a particular challenge with carbonated drinks. Because the beverages outgas and thus the pressure in the container or bottle rises, the gas presses from below onto the sealing film of a sealed capsule that is accommodated in the container closure and sealed at atmospheric pressure. If the inside of the capsule rests in the center of the sealing film and at a short distance from it there is a stamp which is attached to the inside of the top of the capsule and which, together with the top of the capsule, is to be pressed down to open, there is the following risk: The pressure in the container or bottle presses the sealing film from below towards the capsule and bulges it upwards. It can happen that the sealing film hits the stamp and the sealing film tears open unintentionally along its lines of weakness. This danger must be avoided.

The object of the present invention is, in view of the circumstances mentioned above, to provide a fillable closure cap with an internally formed, fillable capsule, this closure cap being easier to manufacture and assemble, and wherein it should be ensured that The contents of the capsule can be opened and emptied with a simple push of a button, which can be easily applied with a finger, and the entire contents of the capsule safely fall down into a container that is equipped with this cap. At the same time, the cap with the fillable capsule formed therein should also be suitable in a special design for outgassing drinks, and an inadvertent opening of the capsule by bursting of the closure disc as a result of the increasing pressure in the container of the bottle due to outgassing should be avoided.

This object is achieved by a fillable, screw-on or attachable closure cap to a threaded connector of a container with a push button for triggering the emptying of a molded under this push button, open at the bottom and closable with a closure disc capsule with encircling capsule wall and capsule lid, for receiving one Substance that can be emptied into a container equipped with this cap, wherein a central push button is formed on the outside of the capsule lid to depress the capsule lid under its deformation, and this cap is characterized by the characterizing features of claim 1. In the figures, an embodiment of the closure cap is shown and it is described in detail below and its operation will be explained.

Figure 1: shows the closure cap shown in a diametrical section, before pressing the push button;

Figure 2: shows a closure disc in plan view;

Figure 3: shows the closure disc of Figure 2 shown in a diametrical section;

Figure 4: shows a further closure disc, through lines of weakness in

 Shape of thin spots or slits divided into three equal circle segments;

Figure 5: shows a further closure disc, through lines of weakness in

 Shape of thin spots or slits divided into four equal circle segments;

Figure 6: shows a closure disc, on the one hand arranged in a star shape

 Lines of weakness in the form of thin spots or slits and, on the other hand, such lines of weakness arranged around the circumference with three interruptions;

Figure 7: shows a closure cap from obliquely below, without the closure

Disc;

FIG. 8: shows the closure cap according to FIG. 7 obliquely from below with the closure disc sealed on;

FIG. 9: shows a closure cap in a diametrical section, at the time of the pretensioning and shortly before the lines of weakness burst in the form of thin spots or slits of the closure disk;

FIG. 10: shows a closure cap in a diametrical section, at the point in time after the lines of weakness burst in the form of thin spots or slits and pivoting of the closure disk segments through the spreading legs; FIG. 11: shows a closure cap with a stamp, which also acts as a support for the sealing film, so that the closure cap is suitable for containers or bottles with outgassing drinks;

FIG. 12: shows a closure disc for a closure cap according to FIG. 11, which is suitable for containers or bottles with degassing beverages;

FIG. 13: shows a closure cap with a further variant of a stamp, which also acts as a support for the sealing film in contact, so that the closure cap is suitable for containers or bottles with degassing drinks;

Figure 14: shows a closure disc in a diametrical section, seen obliquely from below;

Figure 15: shows the closure disc of Figure 14 also in a diametrical section, seen obliquely from above.

First of all, the question must be asked what it takes for the opening of the inner capsule to be achieved in the simplest and safest way with such a closure cap, with minimal effort. For closures with a handle to open a floo space in the closure, the high level of user-friendliness by consumers is a decisive criterion. On the one hand, force is required to push the pusher or push button down and, on the other hand, additional force is required to open the capsule, and this force depends on the way in which the capsule is closed. The capsules are often sealed with sealing foils that are tough and require a corresponding amount of force to pierce them and then open them in such a way that the sealing foil is pivoted away as completely as possible from the passage. However, the total necessary forces should be as low as possible. In order for this to be possible, various forces have to be applied in stages in order to break an otherwise necessary peak force.

The solution shown in Figure 1 offers these advantages. The closure cap 1 is equipped with an internal thread 16 and forms in its interior a tubular socket 17 which projects downward from the cap cover 20 of the closure cap 1. Instead of the closure cap 1 being able to be screwed onto a threaded connector, a variant can also be implemented in which the closure cap 1 is different is placed on a nozzle, for example by being bounced or welded or glued on. Within this connecting piece 17, a capsule 18 is integrally connected to it on its inner wall. The capsule wall 25 extends slightly inclined upwards towards the center of the cap 18 and then merges into a capsule cover 6. This is designed wavy in the radial direction. In the center, the capsule cover 6 forms a central push button 2. Below this, a stamp 7 extends downward in the axial direction along the axis of rotation 21 of the closure cap 1.

The push button 2 runs down to a certain extent in a tumbled cup 9, the walls of which are slightly inclined towards the outside. Spreading legs 8 are formed by recesses 15 from the walls of this cup 9, which run downwards into a thinned end region which is elastically flexible and is curved outwards, as indicated by number 26. At the lower end of the capsule 18, a shoulder is formed, on which a sealing disk 3 is welded or glued or sealed. This sealing disk 3 has to be opened efficiently and safely in order to let the contents of the filled capsule fall down. As a special feature, a stamp 7 extends axially downward from the push button 2, almost down to the closure disk 3. The spreading legs 8 arranged around him also touch the disk 3 approximately.

Above the pusher surface 24 of the push button 2 is strongly concave, so that a finger pad is ideally placed therein, as shown in FIG. 1. Due to this concave shape of the pusher surface 24, the circumferential edge of the pusher surface 24 ends in an acute-angled edge 14. This ensures that the person operating this closure cap 1 places his finger correctly on the push button 2 and then presses it down in the axial direction. The capsule cover 6 is designed to be corrugated from the center in the radial direction, as can be clearly seen in FIG. 1. First comes in a first area 10, first of the central push button 2, an all-round wave trough 12, followed by a wave crest 13. In this area 10, the wall thickness of the capsule cover 6 is made thin. This area 10 is followed by an area 1 1 towards the outside, which begins again with a wave trough 4, which, however, has a thicker wall and ends in another such wave crest 5, and this finally merges into the peripheral side wall 25 of the capsule 18, which again is made thicker. The outer region 11 of the capsule cover 6 is therefore thicker and thus stronger than in the inner region 10, and the capsule wall 25 is again dimensioned stronger. As a result of the shape of the capsule cover 6, it can be walked when the push button 2 is pressed down.

So if the push button 2 is pressed from above, as shown in FIG. 1 with the finger, the capsule cover 6 is first deformed in the region 10 by a flexing, while the stronger region 11 of the capsule cover 6 is barely in its place Location changed. The depressed push button 2 causes the stamp 7 to press on the sealing disk 3 running underneath and initially to prestress it. At the same time, the spreading legs 8 have been pressed onto the closure disk 3 and, due to their elasticity, their ends 26 shift outwards, that is to say the ends 26 of the spreading legs 8, to a certain extent their feet, slide a little radially on the closure disk 3 Outward direction. If the push button 2 is pressed further down in the axial direction, then the outer region 11 of the capsule cover 6 is also tumbled and the plunger 7 pressed further down finally causes the closure disk 3 to burst. In the meantime, the feet of the spreading legs 8 have slid further towards the peripheral region of the closure disk 3 and, in the final phase of pressing the push button 2 downward, the ends 26 of these spreading legs 8 shear the burst closure disk 3 with their ends 26, so that their respective segments formed are folded down and from now on are held in this swung-down position by the spreading legs 8.

FIG. 2 shows a possible sealing disk 3, which here has a special feature of a line of weakness 39 running almost completely around the circumference of the sealing disk 3, which is implemented in the form of thin spots or slots, with two diametrically opposite regions 32, 33 where the sealing disc 3 remains intact. The line of weakness 39 with its thin points or slots extends further from the peripheral region through an S-shaped line through the diameter. Along this weakening line 39, the closure disk 3 is opened by the punch 7 and the spreading leg ends 26 with sufficient pressure. For this sealing disk 3, two spreading legs 8 are provided around the punch 7 on the sealing cap 1, offset diametrically. The two intact areas 32, 33 mentioned remain, here at the top and bottom of the image. Around these material bridges, the two exposed tabs of the closure disk 3 are finally removed from the Spreading legs 8 pivoted downward by 90 ° by the spreading leg feet 26 coming to rest on these two material bridges and then pressing the tabs down around them, the areas 32, 33 acting as hinges.

Figure 3 shows this closure disc 3 in a diametrical section. The line of weakness 39 in the form of thin spots or slits is produced by a notch 19, which here points downward at an obtuse angle. The cross-section of the indentation can of course also have other shapes, from acute-angled to semicircular, so that a thin wall thickness of the closure disk 3 is produced at specific points, at which point it finally bursts.

FIG. 4 shows a closure disk 3 with lines of weakness 39 in the form of thin spots or slots, which divide the closure disk 3 into three circle segments 22 of the same size. To open such a closure disc 3, three spreading legs 8 are provided on the closure cap 1 and distributed around the circumference. The feet 26 of the spreading legs 8, after the locking disk 3 has burst along the three radial lines of weakness and thus hang three circular segment-shaped tabs, press on the same in the edge region in the middle of the circumferential line of these three circular segments, that is to say at the pressure points 23 shown , and the circular segments 22 are subsequently pivoted down along one secant each and held in this position.

FIG. 5 shows a closure disk 3 with lines of weakness 39 in the form of thin spots or slots, which divide the closure disk 3 into four circle segments 22 of the same size. To open such a closure disk 3, four spreading legs 8 are provided on the closure cap 1 and distributed around the circumference. The feet 26 of the spreading legs 8, after the closure disk 3 has burst along these four radial weakening lines 39 and thus hang down four segment-shaped tabs, press in the edge region in the middle of the circumferential line of these four circle segments 22, that is to say at the pressure points 23 shown. onto the same, and the circular segments 22 are subsequently pivoted downwards along one secant each and held in this position.

FIG. 6 shows a closure disk 3 with an alternative arrangement of the weakening lines 30, 31 in the form of thin spots or slots. In addition to the star-shaped course with three radial lines, there are circumferential lines at their outer ends 30 also weakened, leaving three areas left as later pressure points 23. The spreading legs 8 with their feet 26 are then pressed onto these free areas or pressure points 23 and the respective 120 ° circle segments are pivoted downward. FIG. 7 on the right shows the arrangement of the three spreading legs 8 with the central punch 7. However, the spreading legs 8 are not shown correctly here, in fact they are bent outwards and their end regions can be elastically bent as feet 26. This closure cap together with the sealed closure disc 3 is shown in FIG.

FIG. 9 shows a diametrical section through a closure cap in order to provide further information about how the punch 7 and the spreading legs 8 act. In the snapshot shown, the stamp 7 already presses on the closure disk 3 and stretches it, thus placing it under a certain pretension. FIG. 10 shows the subsequent state after the further depressed punch 7 caused the closure disk 3 to burst or burst along its weakening lines 39, that is to say along thin points or slits. Three 120 ° circle segments now project loosely downwards. When the pushbutton 2 is depressed further, they are pivoted downward by the spreading legs 8, each by one secant at the location of the spreading leg ends 26. The spreading legs 8 are then curved outwards in the radial direction and their feet or ends 26 lie at the edge area of the closure disk 3 on the respective circular segments.

A particular challenge for such caps is bottles with degassing drinks in them, so if they contain carbonated drinks. In such a bottle, the gas pressure increases after filling until it reaches a level that avoids further outgassing. Under the increased pressure, however, the gas presses on the closure disc 3 from below, so that its inner or upper side is pressed against the stamp 7 in the closure cap 1. In individual cases, this can lead to the closure disc 3 breaking under the load acting on it and the contents in the capsule 18 falling prematurely and unintentionally into the bottle. In the following, a version of the closure cap is presented, which is suitable even for bottles with degassing beverages, and which ensures that the closure disc withstands this pressure even after a complete outgassing and as a result of it being pressed firmly against the stamp from below Capsule can still be opened safely at the push of a button. To this end, a special design of the stamp 3 is important. In Figure 1 1, a closure cap 1 is shown seen from below, which has a central stamp 3 in the capsule 18, which here forms a star in cross section, with three radially outwardly extending wings 27. The stamp 3 thus not only acts in the Center on the locking disc. Rather, if a closure disc is pressed onto the stamp from below due to the pressure in the bottle, the closure disc is supported over the entire end surface 28 of the stamp 3 visible here, that is to say over a surface, and because the If wing 27 extends radially outward from the center, the closure disk is also supported over these radial wings 27, which can reliably avoid bursting along its lines of weakness, which are in the form of thin spots or slots. Between the wings 27, the spreading legs 8 are arranged here, which after the bursting or breaking of the closure disk take over the function of reliably folding down the disk parts detached from the disk assembly.

For an overall reliable and safe function of the opening of the closure disk 3 and after the closing of the closure disk parts, a specially designed closure disk proves to be necessary. Such a closure disc 3 is shown in Figure 12. It consists of a plastic disc with continuous slots 29-31. A first slot 29 extends diametrically over almost the entire diameter of the closure disk 3 and leaves the disk intact in the edge region. Two further continuous slots 30, 31 extend here in an arc along the circumference in the edge region of the closure disk 3, one at a distance following the other, so that the closure disk is intact between them, that is to say between the opposite ends of the two arches remains and material bridges are formed there, each of which acts as a hinge 32, 33, as will become clear. The diametrically extending slot 29 is arranged such that it ends with its two ends in the middle of the two arcuate slots 30, 31. Two semicircular circle segments 34, 35 are thus formed. Such a closure disc 3 is provided on its one, lower side with a barrier layer 36, so that a barrier against water vapor or oxygen or against various flavors is formed. Such a barrier layer consists, for example, of an aluminum layer of approx. 0.2 mm thickness which is glued on by means of a contact foil, an adhesive or by means of PE outside is also provided with a thin protective layer of plastic, which protective layer can be vapor-deposited or sprayed on. Ultimately, this coating is a coated aluminum foil which is intended to act as a barrier foil. The finished sealing washer is finally sealed into a flanged edge on the sealing cap using an induction welding process (torsional welding).

From a functional point of view, this closure cap acts as follows: First, the closure disc 3 is prestressed when it is pressed against the stamp 3 of the closure cap 1 as a result of the internal pressure acting in a bottle. However, it continues to seal the capsule securely, even if the internal pressure in the bottle rises to a maximum as a result of the outgassing of the carbonated beverage, which prevents further outgassing. To open the capsule 18 integrated in the closure cap 1 in a targeted manner, the capsule 18 is pressed downwards by pressing the pushbutton 2 it forms. This causes the stamp 7 inside the capsule 18 to be pressed down and finally this causes the sealing disk or its oxygen-tight coating or protective film to rupture along the diametrical slot 29. Immediately the coating also tears along the arcuate slots 30, 31 and when the pushbutton 2 and the stamp 7 are pressed further down, the latter presses the two semicircular circular segments 34, 35 of the closure disc 3 downwards, so that they are hinges 32, 33 Swing acting material bridges down. The capsule content thus falls down into the bottle.

Figure 13 shows a further possible design of the stamp 7. This also has radially projecting wings 27, namely five wings 27, each with an equal angle of 72 ° (5 x 72 ° = 360 °). Two of these wings 27, which enclose an angle of 144 ° on one side and subsequently an angle of 216 ° on the other (144 ° + 216 ° = 360 °), are recessed from below over their almost entire height 37 provided, so that one spreading leg 8 is formed in its outer area. This configuration also works because a flat stamp end is formed for the flat support of a pressed-on closure disc, and the stamp is nevertheless able to break open the coating of a closure disc as described by pressing it down and is able to pivot the closure disc segments, at the end of which the two Ensure the spreading legs 8 by swiveling outwards the complete swiveling of the circle segments of the locking disc.

FIG. 14 shows one half of the closure disk along a diametrical section. One looks here at the underside of the closure disc 3, which faces the contents of the bottle, that is to say at the coating 36, which acts as an oxygen-tight barrier. On the top you can see the plastic disc with its circumferential slots 30, 31, which open into the diametral here. FIG. 15 shows this closure disk 3 viewed obliquely from above. The edges of the closure disk 3, regardless of whether the outer circular edge or the edges of the slots 29-31 run out in a wedge shape and in the middle into an edge 38.

So which features prove to be particularly important in order to achieve the aim of the invention and to ensure the good functioning of such a closure cap?

1 . A concave finger rest with sharp edges 14 is required which intuitively provokes a finger rest lying in the central axis 21 of the closure.

2. The push button 2 must be designed as shown and described so that it ensures a straight, vertical or axial downward pressing.

 3. The push button 2 is held by its socket in the center of concentric adjoining shafts and can therefore be depressed in two phases, so that the forces for the bursting of the closure disk 3 and the subsequent folding down of the same do not produce a single high force peak along the circumferential region of the detached segments.

 4. The wall thickness of the first corrugated area 10 from the center of the capsule cover 6 is designed to be thinner than that of the corrugated area 1 1 adjoining the outside, so that initially only the first capsule cover area is tumbled for the first phase of depression.

 5. The wall thickness of the adjoining second area 1 1 is thicker and thus provides more resistance when the push button 2 is depressed.

6. The spreading legs 8 acting on the locking disc 3 can be moved laterally, that is to say radially outwards, so that the rounded ends 26 of the spreading legs 8 slide radially outwards when they strike the locking disc 3 and, finally, the pressure force downwards as close as possible to the circumferential Apply the edge area of the sealing disc 3. The weakening notches or weakening lines 39 in the form of thin spots or slits ensure that the closure disk 3 bursts and opens at the desired locations due to the pressure of the stamp 7 and the spreading legs 8, namely along the deliberately running weakening lines 39.

For an oxygen-tight capsule, the closure disk 3 is designed with slots and the closure disk 3 is completely provided with a coating 36 which covers the slots. To swivel the closure disk parts away, the coating 36 must first burst.

Numerical index

1 cap

 2 push buttons

 3 locking disc

 4 trough outer area 11

 5 Wellenberg outer area 11

 6 capsule lids

 7 stamps

 8 spreading legs

 9 Cup-shaped connection to push button 2

 10 Inner area of the corrugated capsule lid

 11 Outer area of the corrugated capsule cover

 12 Inner trough in the inner area 10

 13 Wave crest adjacent to 12 in the inner area 10

14 Sharp edge of the handle surface

 15 recesses in the cup

 16 internal thread sealing cap

 17 Inner pipe socket directed downwards

 18 capsule

 19 Notch on the sealing disc

 20 sealing caps

 21 axis of rotation of the closure cap

 22 circle segment

 23 pressure points

 24 pusher surface

 25 capsule wall

 26 end of the spreading legs 8

 27 radial wings on stamp 7

 28 Flat end face of the stamp

 29 Diametrical slot in the locking disc

 30 arched slits in the locking disc

 31 radial slots in the locking disc

32 First material bridge to act as a hinge Second material bridge acting as a hinge First semicircular circle segment Second semicircular circle segment Coating - oxygen-tight barrier recess in the radial wing

Protruding edge 38 on the slit wall line of weakness

Claims

Claims

1.Fillable, screw-on or attachable closure cap (1) with a push button (2) for triggering the emptying of a capsule (4) shaped under this push button (2), open at the bottom and closable with a closure disk (3) encircling capsule wall (5) and capsule cover (6), for receiving a substance that can be emptied into a container equipped with this sealing cap (1), a central push button (2) on the outside of the capsule cover (6) for depressing the capsule cover ( 6) is formed under its deformation, characterized in that a central, axially downwardly projecting stamp (7) is formed on the inside of the capsule (18) below the push button (2), and that around the circumference of this stamp (7) distributed around at least two spreading legs (8) which are pivotable downwards and outwardly towards the closure axis of rotation (21) and which extend over their end region into one run out elastically bendable taper as feet (26), further that the capsule cover (6) around the punch (7) is designed corrugated in the radial direction, this capsule cover (6) in the first, inner corrugated area (10) of its radius Thinner wall thickness than in the second, outer corrugated area (11), so that the cover wall can be walked in two phases by pressure from above on the push button (2) by first walking the inner cover area (10) while axially depressing the push button (2) until the plunger (7) pressurizes the sealing disc (3) at pressure points (23) and thereby prestresses it and the spreader legs (8) touch the sealing disc (3), afterwards the outer corrugated area (11) with further depression of the push button (2) is walkable and thus the end regions of the spreading legs (8), while the punch (7) breaks through the sealing disc (3), the resulting loose sealing disc segments sc down Swivel so that the opening of the capsule (4) is exposed.

2. A fillable closure cap (1) which can be screwed or fitted onto a threaded connector of a container, according to claim 1, characterized in that the stamp (7) is of star-shaped cross section and forms radially projecting wings (27) so that it forms a flat end, which is intended to act as a support for a closure disc (3) pressed on from the bottom by gas outgassing, the closure disc (3) being a plastic disc which is covered over its entire extent with a barrier coating (36 ), the plastic disc being provided by means of at least one diametrical slot (29) and at least two arcuate slots (30, 31) bordering the ends of this slot (29) with their center, each of which has a material bridge (32, 33) leave as a hinge, two otherwise free semicircular circle segments (34, 35) are formed, which are pressed by pressure from the stamp (7) from above to Bers th of the coating (36) on its underside can be pivoted in a hinged manner around the material bridges (32, 33).

3. Fillable, screwed onto a threaded connector of a container or attachable closure cap (1) according to claim 1, characterized in that the spreader legs (8) touch the closure disc (3) and when pressing the push button (2) the end regions (26) of the spreader legs (8) bend elastically outwards and slide radially on the closure disc (3) outwards close to the slots (30, 31) and there create a shear effect and a break, and their ends (26), while the punch (7 ) the sealing disc (3) breaks through, swivel the resulting loose sealing disc segments down so that the opening of the capsule (4) is exposed.

4. Fillable, screwed onto a threaded connector of a container or attachable closure cap (1) according to one of claims 1 to 3, characterized in that the capsule cover (6) around the stamp (7) is designed corrugated in the radial direction, the Capsule lid (6) forms a waveform with a thinner wall thickness with at least one wave trough (12) and a wave crest (13) in the first, inner area (10) of its radius, and then the area (11) of its radius with thicker wall thickness also forms a waveform forms at least one wave trough (4) and one wave crest (5), so that the capsule cover (6) is pressed from above onto the push button (2) can be walked in two phases, with the pushbutton (2) moving axially downwards.

5. Fillable, screwed onto a threaded connector of a container or attachable closure cap (1) according to one of the preceding claims, characterized in that the capsule cover (6) around the stamp (7) is designed corrugated in the radial direction, the capsule cover ( 6) in the first, inner area (10) of its radius with a thinner wall thickness than in the outer area (11), and this capsule cover (6) to the push button (2) then seen in the radial direction first a wave trough (12) and then forms a wave crest (13), and then the second region (11) forms a wave trough (4) and then a wave crest (5), which is transferred into the capsule wall (25), which is again of larger dimensions.

6. Fillable, screwable or attachable closure cap (1) to a threaded connector of a container according to one of claims 1 or 3 to 5, characterized in that the push button (2) in the capsule lid (6) as an inverted, conically widening cup ( 9) is formed, with the central punch (7) on the inside, and that the spreading legs (8) are produced and shaped by recesses (15) from the cup wall (9).

7. Fillable, screwable or attachable closure cap (1) to a threaded connector of a container according to one of the preceding claims, characterized in that the push button (2) forms a concave pusher surface (24) on its outer, upper side, with a circumferential upward facing Edge (14) tapering at an acute angle, for centering and axially guiding a finger pressing the push button (2).

8. Fillable, screwable or attachable closure cap (1) to a threaded connector of a container according to one of claims 1 or 3 to 6, characterized in that the closure disc (3) with three radial and arcuate lines of weakness arranged around the circumference (39 ) in the form of thin spots or slots (30, 31) is divided into three segments (22) and three spreading legs (8) on the center of a circle segment circumference are intended to be pivoted, when the push button (2) and the stamp (7) are swung down, around an area of this segment of the circle which acts as pressure points (23) at the edge of the sealing disc (3).

9. Fillable, screwable or attachable closure cap (1) to a threaded connector of a container according to one of claims 1 and 3 to 6, characterized in that the closure disc (3) with four arcuate lines of weakness (39) distributed around the circumference and radial lines of weakness (29) are each divided into four segments (22) in the form of thin spots or slits and four spreading legs (8) are intended to strike the center of each segment of a circle, for pivoting the same when the push button (2) and stamp (7 ) around four areas acting as pressure points (23) on the edge of the sealing disc (3) of these circular segments (22).

10. Fillable, screwable or attachable closure cap (1) to a threaded connector of a container according to one of the preceding claims, characterized in that the spreading legs (8) are widened at their ends (26), so that the torn circular segments (22) of the After swiveling downwards, the closure disc (3) is held in this open position in order to completely empty the capsule (18) into the container below.