EP0389815A1 - Sealing for a container closure - Google Patents

Abstract

The invention relates to a container closure with a wall and a bottom wall and a sealing device which has an axial seal cooperating with an end face of the container and a sealing lip interacting radially with a lateral surface of the container, which lip is associated with an actuating arm. For an optimal sealing effect with a simple design, it is proposed that the actuating arm (5) and sealing lip (3) form a rigid rocker (18) which, for decoupling, is assigned a weakening zone (17) of the wall of the container closure which facilitates a pivoting movement, the Actuating arm (5) forms the axial seal (13) and coincides with the bottom (15).

Description

The invention relates to a seal for a container closure according to the preamble of claim 1.

Various container resolutions, in particular screw, twist-off and bayonet closures made of plastic or metal, are known. The closures have a seal made of paper, plastic or rubber, which is to ensure a secure closure of the container. However, it has been shown that, particularly in the case of an overpressure in the interior of the container to be closed, a tight seal of the container is not always ensured. This is particularly the case if the container to be closed has damage in the contact area of the seal.

From US Pat. No. 4,276,989, a container closure of the type mentioned at the outset is known, in which a radially acting sealing lip is acted upon by means of an actuating arm extending from the bottom of the container closure. On the inside of the bottom, an axial seal is also provided, which with a End face of the container cooperates. Deformations of the overall contour of the known container closure - be it by screwing it onto the container appropriately or by a high internal pressure in the container - lead to the deflection of the actuating arm, which thereby acts radially on the sealing lip, thereby improving the sealing effect. Viewed in cross section, this known container closure has a very jagged and undercut contour, so that the structure is complicated and can only be produced with correspondingly complex plastic injection molds. The container closure can therefore only be removed from the mold with a correspondingly large outlay during production.

It is an object of the invention to provide a container closure with a sealing device which always ensures a perfect sealing effect, in particular even if the mouth region of the container is damaged. In this case, a particularly simple structure should be present and, in particular, simple production and demoldability during production as a plastic injection-molded part should also be provided.

This object is achieved in a seal of the type mentioned with the help of the features mentioned in claim 1. The actuating arm pivoting the sealing lip ensures that when the sealing force of the axial seal is increased, the sealing lip lies firmly against the container to be closed in the radial direction, thereby ensuring an optimal sealing effect. Since the actuating arm and the sealing lip form a rigid rocker, which is a pivoting movement for decoupling relieving weakening zone of the wall of the container closure is assigned, the required optimal sealing effect is achieved by shifting the rocker without the shape of the remaining contour of the container closure being changed. The rigidity of the rocker leads to an immediate transmission of force, which has a favorable and particularly high intensity on the sealing function. Since the actuating arm forms the axial seal and also coincides with the base, there is a particularly simple construction which, viewed in cross section, results in a corresponding contour without undercuts occurring, which are complicated and costly injection molds in the manufacture of the container closure or whose sealing device requires plastic. The force acting on the actuating arm, which causes the associated sealing lip to pivot, also brings about an improved sealing of the container in the region of the actuating arm. The actuating arm therefore has a double function, in which it on the one hand shifts the sealing lip as part of the rocker and on the other hand itself takes over the sealing function (axial seal) mentioned. The axial seal can also be designed as a sealing lip. In particular, if the closure consists of one part and is made of plastic, a particularly simple and inexpensive configuration can be achieved by the actuating arm collapsing with the bottom of the container closure, which can be easily produced in large quantities. Due to the weakening zone, the sealing lip attaches particularly well to the container to be closed and seals it optimally. This good sealing effect is already achieved when the container closure is screwed onto a container thread with only a small tightening torque; extreme tightening forces are therefore not absolutely necessary, which may lead to deformations of the container closure (cap contour).

Further configurations and advantages result from the subclaims.

• Figur 1 ein erstes Ausführungsbeispiel einer Dichtung im Schnitt;
• Figur 2 ein weiteres Ausführungsbeispiel einer Dich­tung im Schnitt;
• Figur 3 ein weiteres Ausführungsbeispiel einer Dich­tung im Schnitt;
• Figur 4 ein weiteres Ausführungsbeispiel einer Dich­tung im Schnitt;
• Figur 5 ein weiteres Ausführungsbeispiel einer Dich­tung im Schnitt und
• Figur 6 ein weiteres Ausführungsbeispiel einer Dich­tung im Schnitt, die als Teil einer Dichtungsscheibe ausgebildet ist.

The invention is explained in more detail below with reference to the drawing. Show it:

• Figure 1 shows a first embodiment of a seal in section;
• Figure 2 shows another embodiment of a seal in section;
• Figure 3 shows another embodiment of a seal in section;
• Figure 4 shows another embodiment of a seal in section;
• Figure 5 shows another embodiment of a seal in section and
• Figure 6 shows another embodiment of a seal in section, which is designed as part of a sealing washer.

Figure 1 shows a partial section through a container closure 1 made of plastic. The closure is made, for example, by plastic injection molding, so that the seal and the closure consist of one piece.

The seal has a sealing lip 3 and an actuating arm 5. The sealing lip has an essentially triangular cross section, with a contact surface 7 lying concentrically to the central axis of the container closure being formed.

The outer boundary wall 9 of the sealing lip 3 can enclose an angle of approximately 15 ° to 85 °, preferably of 30 ° to 60 °, with the contact surface 7. In the embodiment shown here, an angle of 45 ° has been selected.

The outer boundary surface 9 merges into the side wall 11 of the container closure 1.

The actuating arm 5 has a downward-facing end surface towards the container to be closed, which encloses an angle of approximately 90 ° with the contact surface 7 of the sealing lip 3. The angle can also be smaller if the sealing lip or the contact surface 7 is not arranged parallel to the central axis of the container closure 1 but is pivoted inwards.

The side wall 11 of the container closure 1 merges into a floor 15.

In the embodiment shown here, a weakening zone 17 is provided in the area of the seal formed by the sealing lip 3 and the actuating arm 5, which forms a rigid rocker 18, which is concentric with the central axis of the container in the end, preferably forcefully decoupling, preferably external gutter. The weakened zone is designed so that the actuating arm 5 can be pivoted upwards, in the direction of the floor 15. The fulcrum of such a pivoting movement lies in the region of the intersection of the contact surface 7 and the end surface 13. Because the actuating arm 5 is pivoted counterclockwise, there is also a pivoting movement of the sealing lip 3 also counterclockwise.

When the container closure 1 is placed on a container, its mouth region, or its upper outer surface, on the one hand abuts the contact surface 7 of the sealing lip 3 and, on the other hand, on the end surface 13 of the actuating arm 5.

Figure 2 shows a further embodiment of a seal consisting of a sealing lip and actuating arm, which is also part of a container closure made of plastic. In Figure 2, again only a partial section of a container closure is shown.

The container closure 20 in turn has a seal which has a sealing lip 23 and an actuating arm 25. The sealing lip 23 has an essentially triangular cross section, with a contact surface 27 arranged concentrically to the central axis of the container closure 20 being formed. This can enclose an angle of approximately 10 ° to 85 ° with an outer boundary surface 29 of the sealing lip 23. The angle is preferably in Range between 15 ° and 40 °. In the embodiment as shown, the contact surface 27 and the outer boundary surface 29 enclose an angle of approximately 20 °.

The outer boundary surface 29 of the sealing lip 23 merges into the side wall 31 of the container closure 21.

Here, too, the actuating arm 25 has an end surface 33 directed towards the container to be closed, which encloses an angle of approximately 90 ° with the contact surface 27.

The side wall 31 of the container closure 21 merges into a floor 35. In this exemplary embodiment, the actuating arm 25 is part of the bottom 35, as in the case of the one shown in FIG is trained. The cross section of the gutter that decouples from the remaining areas of the container closure can be selected as desired. While a channel with an approximately semicircular cross section was selected in the exemplary embodiment according to FIG. 1, the channel here has a trapezoidal cross section.

When the container 21 is placed on a container, its upper edge presses against the end surface 33. Because of the weakening zone 37, the actuating arm 25 can deflect at such a force, as a result of which a pivoting movement takes place. The The pivot point of this pivoting movement lies approximately in the region of the intersection between the contact surface 27 and the firing surface 33. When placed on a container, the actuating arm is pivoted counterclockwise. As a result of the mechanical coupling between the sealing lip 23 and the actuating arm 25, which leads to the formation of a rocker 36, a pivoting movement of the sealing lip 23 also takes place counterclockwise. The pivoting movement of the sealing lip 23 is indirectly facilitated by the weakening zone 37.

Figure 3 shows a partial section through a container closure 41 made of plastic with a seal consisting of a sealing lip 43 and an actuating arm 45.

The sealing lip has a triangular cross section. It shows a contact surface 47 running parallel to the central axis of the container closure and an outer boundary surface 49. The contact surface and the boundary surface can enclose an angle of 10 ° to 85 °. In the illustrated embodiment, an angle of approximately 20 ° is selected. The outer boundary surface 49 merges into the side wall 51 of the container closure 41.

The actuating arm 45 has a closing surface 53 directed downwards onto the container to be closed.

The embodiment shown in Figure 3 is characterized in that the actuating arm 45 completely in the bottom 55 of the container closure 41 is integrated. That is, the operating arm 45 continues in the bottom 55 of the container closure.

The end surface 53 of the actuating arm 45 and the contact surface 47 of the sealing lip 43 enclose an angle of approximately 90 °. An angle smaller than 90 ° can also be provided.

The side wall 51 of the container closure 41 merges into the bottom 55 via a hump or edge bead 57. As a result, the bottom 55 is arranged sunk relative to the highest point of the edge bead 57. A central depression 59 thus arises in the upper end region of the container closure 41.

The actuating arm 45 is so rigidly connected to the sealing lip 43 that when the actuating arm is pivoted, the sealing lip 43 is moved in the manner of a rigid rocker 56. If, for example, the actuating arm is pivoted counterclockwise by the axial force on the upper edge of the container, the sealing lip 43 is also displaced counterclockwise.

FIG. 4 shows a partial section through a further exemplary embodiment of a seal which is part of a container closure 61. The seal has a sealing lip 63 and an actuating arm 65 assigned to it. The sealing lip is triangular in cross-section, a contact surface 67 arranged concentrically to the central axis of the container closure 61 and an outer boundary surface 69 being formed. The two surfaces can form an angle include from 10 ° to about 85 °. In the embodiment shown here, an angle of approximately 45 ° has been selected.

The outer boundary surface 69 merges into a side wall 71 of the container closure 61. This is also arranged concentrically to the central axis of the container closure. The actuating arm 65 has a lower end surface 73 directed in the direction of the container to be closed, which encloses an angle of approximately 90 ° with the contact surface 67 of the sealing lip 63. The angle can also be chosen larger or smaller.

The side wall 71 of the container closure 61 merges into a floor 75. The operating arm 65 arises from the inner surface of the floor.

In the area of the actuating arm 65, a circumferential notch 77, which brings about decoupling, is provided, which is arranged in the transition area between the side wall 71 and the floor 75. This notch facilitates a pivoting movement of the actuating arm 65, which occurs when, for example, a force is exerted on the end surface 73 by the container to be closed. The actuating arm 65 and the sealing lip 63 are so rigidly connected to one another as a rocker 76 that a pivoting movement of the sealing lip is produced when the actuating arm is pivoted, the pivot point of the two pivoting movements being approximately in the intersection of the contact surface 67 and the end surface 73.

The weakened zone designed as a notch 77 can be arranged in the region of the base, the side wall or in the transition region between the side wall and the base. This also applies to the weakening zones of the exemplary embodiments shown in FIGS. 1 and 2.

Figure 5 shows a section through a seal which is part of a container closure 61 '. The same parts are provided with the same reference numerals, so that their detailed designation can be dispensed with.

As in the exemplary embodiment according to FIG. 4, the seal has a sealing lip 63 and an actuating arm 65.

Here too, the sealing lip 63 is triangular in cross section, a contact surface 67 arranged concentrically to the central axis of the container closure and an outer boundary surface 69 of the sealing lip 63 being formed. The outer boundary surface merges into the side wall 71 of the container closure.

The actuating arm is provided with an end surface 73 which points to the container to be closed.

The side wall 73 of the container closure 61 continues in a bottom 75.

In contrast to the exemplary embodiment shown in FIG. 4, the circumferential notch 77 is dispensed with here.

By the choice of plastic for the container closure 61 'it is nevertheless ensured that a pivoting movement of both the actuating arm 65 and the sealing lip 63 is possible with a force acting on the end surface 73 of the actuating arm 65. There is an elastic deformation of the base 75 with respect to the actuating arm 65 and the sealing lip 63 with respect to the side wall 71, so that weakening zones are formed there by the appropriate choice of plastic.

The function of the seal can easily be derived from the above. In the event of a force acting from below on the end face of the actuating arm, the latter is pivoted counterclockwise. Due to the relatively rigid coupling with the sealing lip, this is also pivoted so that it is pressed against the outer boundary surface of the container to be closed. If, therefore, the rocker-shaped seal consisting of the sealing lip and the actuating arm is pressed onto a container, on the one hand the end surface of the actuating arm serves as a sealing surface and on the other hand also the sealing lip which is pressed against the outer, concentric to the central axis of the closure outer wall of the container. Because the sealing lip is pressed against the outer wall of the container, the container is optimally sealed even if there is damage in the mouth region, that is to say in the region between the horizontal and vertical boundary surface of the container.

With the described seal, various overpressures in the container can be safely closed. Depending on the choice of the length of the sealing lip, the overpressure to be sealed by the seal can be varied. The longer the sealing lip, the wider the area spanned on the outside of the container, the higher the overpressure in the container.

It is clear that the actuating arm of the seal is not only pivoted by the force acting on the end face when the container is closed. By coupling to the bottom of the container closure, the actuating arm can be pivoted due to an overpressure in the container. If the bottom of the closure is arched upwards by overpressure, this arching causes the actuating arm to pivot in a counterclockwise direction. This also causes the sealing lip to be pivoted counterclockwise and pressed against the outside of the container to be closed. An overpressure in the container increases the sealing effect of the seal.

It should be particularly emphasized that if the pressure in the container is excessive, the seal can be lifted off the mouth area of the container, so that the excess pressure escapes. As the overpressure drops, the seal rests on the container and closes it optimally.

Blowing off excess pressure can be initiated by designing the seal. The shorter the sealing lip, the less it is Covered outside wall of the container, the lower the overpressure at which the overpressure is blown off.

On the basis of the partial section in FIG. 6, it is shown that the seal, which consists of a sealing lip and an actuating arm, can also be part of a sealing washer, which is inserted here, for example, into a metal container closure.

FIG. 6 shows a further exemplary embodiment of a container closure 101. In the illustration, a closure made of thermoformable material, for example made of aluminum or steel, is shown.

The closure is combined with a seal consisting of a sealing lip 103 and an actuating arm 105. The seal is part of a sealing washer 107 inserted into the container closure 101. A radius is provided in the region of the transition between the side wall 109 and the bottom 111 of the closure cap of the container 101. The seal also has a radius on its outside facing the container closure, so that practically a rolling movement of the seal on the inner surface of the container closure is made possible. The actuating arm 105 of the seal continues in the sealing washer 107, the sealing washer being designed thinner than the actuating arm in this exemplary embodiment. This forms a weakening zone 108 which facilitates the pivoting movement of the actuating arm when a container 113 is closed by the container closure 101. When the container 113 is against the bottom 15 of the operating arm 105 presses, it is pivoted counterclockwise. There is an elastic deformation in the transition area between the actuating arm and the sealing washer 107. Due to the relatively rigid coupling leading to a rocker 106 between the actuating arm and the sealing lip 103, this is also pivoted counterclockwise when the actuating arm is pivoted. As a result, the sealing lip bears against the outside of the container 133. A sealing surface is therefore formed not only between the underside 115 of the actuating arm 105 and the container 113 but also between the outside thereof and the inside surface of the sealing lip 103.

It is also possible to design the coupling between the sealing washer 107 and the actuating arm 105 so rigid that, when the sealing washer is curved, the actuating arm 105 pivots counterclockwise with an internal pressure inside the container 113.

The seal shown in Figure 6 can be combined with a plastic container closure.

The container closure can be designed as a screw, twist-off or bayonet closure. This does not change the function of the seal consisting of the sealing lip and the actuating arm.

Claims (18)

1.Container closure with a wall and a bottom wall and a sealing device which has an axial seal which cooperates with an end face of the container and a sealing lip which cooperates radially with an outer surface of the container and which is assigned an actuating arm, characterized in that actuating arm (5 , 25, 45, 65, 105) and sealing lip (3, 23, 43, 63, 103) form a rigid rocker (18, 36, 56, 76, 106) which, for decoupling, has a weakening zone (17 , 37, 77, 59, 108) is assigned to the wall of the container closure, the actuating arm (5, 25, 45, 65, 105) forming the axial seal (13, 33, 53, 73, 115) and with the bottom (15 , 35, 55, 75, 107) coincides. 2. Container closure according to claim 1, characterized in that the side wall (11, 31, 51, 71), the bottom (15, 35, 55, 75, 107) and / or the transition region between the side wall and bottom in the region of the sealing device Weakening zone (17, 37, 77, 59, 108). 3. Container closure according to one of the preceding claims, characterized in that the sealing lip (3, 23, 43, 63, 103) and the actuating arm (5, 25, 45, 65, 105) an angle of 30 ° to 150 °, preferably from 70 ° to 110 °, in particular from 90 °. 4. Container closure according to one of the preceding claims, characterized in that the contact surface (7, 27, 47, 67) of the sealing lip (3, 23, 43, 63, 103) is arranged substantially parallel to the outer surface of the container to be closed. 5. Container closure according to one of the preceding claims, characterized in that the sealing lip (3, 23, 43, 63) has a substantially triangular cross-section. 6. Container closure according to one of the preceding claims, characterized in that the sealing device is formed in one piece with the container closure or is part of a sealing washer (107) of the container closure. 7. Container closure according to one of the preceding claims, characterized in that the pivoting movement of the rocker (18, 36, 56, 76) takes place about a pivot point which in the region of the intersection of a contact surface (7, 27, 47, 67) of the sealing lip ( 3, 23, 43, 63) and an end face (13, 33, 53, 73) of the axial seal. 8. Container closure according to one of the preceding claims, characterized in that the system surface (7, 27, 47, 67) concentric to the central axis of the container closure. 9. Container closure according to one of the preceding claims, characterized in that the end face (13, 33, 53, 73) and contact surface (7, 27, 47, 67) enclose an angle of 90 °. 10. Container closure according to one of the preceding claims, characterized in that the end face (13, 33, 53, 73,) and contact surface (7, 27, 47, 67) directly adjoin one another. 11. Container closure according to one of the preceding claims, characterized in that the weakening zone (17, 37, 59, 77, 108) is arranged in the region of the actuating arm (5, 25, 45, 65, 105). 12. Container closure according to one of the preceding claims, characterized in that the weakening zone (17, 37, 77) is designed as a groove which runs concentrically to the central axis of the container closure. 13. Container closure according to one of the preceding claims, characterized in that the channel has an approximately semicircular cross section. 14. Container closure according to one of the preceding claims, characterized in that the channel has a trapezoidal cross section. 15. Container closure according to one of the preceding claims, characterized in that in the area the actuating arm (65) has a circumferential notch (77) which forms the weakened zone and lies in the transition region between the side wall (71) and the bottom (75). 16. Container closure according to one of the preceding claims, characterized in that it consists of plastic. 17. Container closure according to one of the preceding claims, characterized in that it consists of thermoformable material, in particular aluminum or steel, and has a sealing device (107) made of plastic. 18. Container closure according to one of the preceding claims, characterized by a rolling surface of the sealing device which facilitates the pivoting movement of the sealing lip (103) and has a radius, a radius being provided in the region of the transition between the side wall (109) and the base (111), that interacts with the rolling surface.

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