WO2012092989A1 - Closure device for a container, and associated method for closing a container - Google Patents

Abstract

The present invention relates to a reclosable closure device for a container (10), as are used, above all, in consumer goods products, in particular in product dispensers in the cosmetics and detergent sectors. A closure device of this type for a container (10) usually has a cylindrical container neck (11), which surrounds a container opening (12) to the container interior, and a cover-like closure element (30) which is fastened releasably to the container neck (11) by means of a screw/latching connection, in order to close the container opening (12). In order to realize a user-friendly embodiment which is improved in terms of production technology, the closure device comprises at least one slotted guide (13) which is formed integrally on the container neck (11) and has an axial inlet opening (12) which interacts with an associated projection (33) on the closure element (30), at least one stop (18) which is formed integrally on the container neck (11) in the circumferential direction and interacts with an associated corresponding stop (34) on the closure element (30), and at least one ramp (20) which is formed integrally on the container neck (11) and has an axial undercut (21) which interacts with an associated, radially elastically deformable latching projection (33) on the closure element (30).

Description

 Closure device for a container and associated method for closing a container

The present invention relates to a resealable closure device for a container, as they are used mainly in consumer products, especially in product dispensers in the detergent and in the cosmetics sector, are used.

As a mass-produced article, such consumer goods are subject to immense cost pressure and, in addition to the requirements for general practicability in the application, must therefore meet the requirements for cost-effective production. For product dispensers in the cosmetics and in the detergent sector, for reasons of general sustainability, there is also a steadily growing trend towards packaging formats with reusable product dispensers, which can be refilled with product after a first product emptying using a separate refill pack and thus reused. These reusable product dispensers should be easy to open and safe to reseal.

For example, WO 2008 / 0822DE describes a generic trigger dispenser, which is used, inter alia, for liquid detergents. The local bottle-shaped product container is closed by means of a dispensing head in trigger construction. Specifically, the dispensing head is attached via a snap connection to the neck of the bottle-shaped container, wherein three locking projections on the dispensing head cooperate with three associated recesses on the container neck accordingly. This opens up the possibility of manufacturing the dispensing head advantageously solely by axial movement on the container neck. In addition, the dispensing head is fixed in the latched state in the circumferential direction, characterized in that at least two locking projections are enclosed on both sides by cams on the container neck. This results in addition to a bayonet-type connection between the container neck and dispensing head, so that it can be solved by overcoming a resistance caused by the cam by a superimposed rotating and pulling movement of the container. In general handling, however, this arrangement has deficits such that damage to the locking projections or cams can not be effectively prevented during repeated assembly and disassembly of the dispensing head. In addition, the arrangement does not consistently prevent unwanted incorrect assembly of the dispensing head on the container neck. From EP 1982770 A2 an alternative bayonet-type closure device for a bottle-shaped container is known, wherein the container neck is closable with a trigger dispenser. The trigger dispenser is on the one hand via lateral elastic tongues axially latched to associated ramp projections of the container neck and, on the other hand, positioned in the circumferential direction with respect to the container by means of projections which interact with associated stop cams on the container neck. However, the lateral arrangement of the snap elements on the container neck or on the trigger dispenser, based on the predetermined by the trigger dispenser dispensing direction, proves to be not consistently advantageous. The action of force on the trigger dispenser in the event of actuation can thus lead to leakage at the junction between the container neck and the trigger dispenser or, in the worst case, even to release the trigger dispenser from the container.

Based on this, the object of the invention is to provide a closure device for a container, which overcomes the above-mentioned disadvantages of the use and also has a simple manufacturing technology.

The object is achieved by a closure device for a container according to claim 1. Thereafter, the closure device comprises a container, a cylindrical container neck which surrounds a container opening to the container interior and a lid-like closure element which is releasably secured by means of a screw-locking connection to the container neck to close the container opening. In detail, the screw-locking connection of the closure device has at least one integrally formed on the container neck slotted guide with an axial inlet opening, which cooperates with an associated projection on the closure element, at least one integrally formed on the container neck stop in the circumferential direction, which cooperates with an associated counter-stop on the closure element and at least an integrally formed on the container neck ramp with an axial undercut, which cooperates with an associated, radially elastically deformable latching projection on the closure element. The combination of said closure device elements advantageously allows a particularly simple assembly and disassembly of the closure element both by purely axial movement, relative to the container axis, as well as in superposition of a rotational and axial movement. Thus, the closure device can be mounted or dismantled as often as desired. In addition, a defined positioning of the closure element on the container is effectively achieved by the slide guide and the stop elements.

According to an advantageous embodiment of the closure device, the container neck on at least one cam-like elevation with circumferentially lateral bevels, which cooperates as Losdrehsicherung with an associated projection on the closure element. The cam-like elevation thus holds in the assembled state, the closure element in the, relative to the circumferential direction, correct position on the container. In addition, the cam-like elevation advertising in conjunction with the zughörigen projection on the closure element unwanted release of the closure element from the container. At the same time, however, the cam-like elevation allows for assembly or disassembly of the closure element by means of rotational movement due to the side slopes in the circumferential direction. In this case, a certain rotational resistance caused by the cam-like elevation must be overcome. The lateral slopes on the cam-like elevation can in particular be made differently steep, in order to influence the rotational resistance occurring as a function of the direction of rotation.

To simplify the structural design of the radially elastic latching projection on the closure element also forms the projection for cooperation with the associated link guide. In this respect, the latching projection is both the axial snap or latching element, which axially fixes the closure element by axially engaging behind the ramp on the container neck and the guide element which positions the closure element in the circumferential direction of the container by cooperation with the slotted guide. According to a further developed variant of the closure device, the radially elastic latching projection on the closure element also simultaneously also has the counterstop, which is intended to cooperate with the associated stop on the container neck in the circumferential direction. In this respect, a particularly simple design results, in which the latching projection on the closure element fulfills several functions.

In order to ensure a clear positioning in the circumferential direction of the closure element on the container, three ramps distributed unevenly over the container neck circumference are preferably provided on the container neck, the associated latching projections being arranged on the closure element corresponding thereto. Due to the uneven distribution of the ramps, which at the same time allow the axial locking of the closure element by the respective formation of an undercut, incorrect assembly of the closure element due to incorrect positioning is effectively excluded. In this case, each ramp preferably has an opening angle α of 30-40 °, in particular approximately 35 °, in the circumferential direction. Fittingly, the respectively corresponding latching projection on the closure element has a somewhat smaller opening angle in the circumferential direction. A particularly useful arrangement of the ramps on the container neck circumference results from the fact that the ramps are positioned at the container neck circumference at 320-0 °, 90-130 ° and 190-230 °, wherein the associated latching projections are arranged correspondingly on the mounted closure element. Such a distribution of the ramps and thus the axial Verrastungsstellen on the container neck circumference proves to be particularly advantageous if the container is substantially bottle-shaped and the closure element is designed as a dispensing device for a product delivery from the container interior, in particular as a trigger dispenser. In this case, the angular position 0 ° in the circumferential direction denotes the product discharge direction of the dispensing device, for. B. the orientation of the Triggeraustrittsdüse in the ready state of the container with trigger dispenser. Such an uneven Dividing the ramps or axial Verrastungsstellen also takes into account the specific balance of power, as they occur in a container with dispensing device, in particular trigger dispenser. Thus, the inventive arrangement of the ramps or axial Verrastungsstellen ensures a secure hold of the dispenser on the container.

A further advantageous embodiment of the closure device results from the fact that each locking projection is formed radially elastically deflectable on the closure element. This can be achieved constructively in different ways, for example by selective choice of material of the latching projection or of the closure element or corresponding shape design, in particular material thickness of the sleeve-shaped closure element section, on which the latching projection is formed. This results in a deformation of the sleeve-shaped closure element portion, which causes a desired elastic deflection of the locking projection in the radial direction under force.

Basically, it should be noted that all provided on the container neck or closure element closure means of the screw-locking connection, d. H. For example, the locking projections, the slotted guides, the ramps with undercut, the stops / counterstops or the cam-like elevations, in the sense of Wrkungsumkehr also on each other component, d. H. on the closure element or on the container neck, may be formed. The does not change the above-described interaction of the individual closure means.

A further useful embodiment of the device is achieved in that an integrated sealing collar is formed on the closure element, which protrudes into the container opening in the mounted state of the closure element. In this case, the sealing collar is in particular formed directly on the closure element, so that no additional seal is required. At the same time, the sealing collar extending into the container opening ensures reliable sealing of the container with closure element.

In general, the specific container shape has no influence on the closure device according to the invention, so that the closure device is suitable for different container shapes. Preferably, however, the closure device may find application in substantially bottle-shaped containers.

In addition, the invention describes a first possible method sequence for mounting a generic closure device, according to which the closure element is initially positioned exactly on the container neck, especially in the circumferential direction, all radially resilient latching projections abut each of the associated ramps of the container neck. Due to the smaller opening angle of the locking projections relative to those of the ramps, the locking projections can be particularly easy to insert into the respectively associated ramps. Furthermore If a plurality of unevenly distributed over the container neck circumference ramps and correspondingly arranged locking projections a desired unique positioning of the closure element is guaranteed at the container neck. Thus, a possible incorrect assembly of the closure element on the container neck is effectively prevented. Subsequently, the axial bouncing of the closure element under axial force, so that each locking projection slides under radial elastic deformation along the associated ramp along and then axially locked at the undercut. Such an assembly method requires only translational movement steps and does not require any rotational movements and can therefore be implemented particularly simply as a cost-effective mechanical assembly process.

A second alternative mounting method of the closure device includes both translational and rotational movement steps and provides, initially the closure element axially to the container neck attach so that all radially resilient locking projections in each case abut the associated inlet openings of the slotted guides of the container neck. The respective position of the latching projections is thus oriented on the respectively associated A lassöffnung. Thereafter, the closure element is connected to the container neck and indeed by superimposed axial and rotational movement of the closure element relative to the container neck, each locking projection within the associated slide guide follows their course and is guided by this. Upon further rotation of the closure element relative to the container neck, each locking projection overcomes due to radially elastic deformation an associated cam-like elevation, wherein a defined rotational resistance is exceeded. Finally, the closure element is rotated so far with respect to the container neck until at least one counter-stop on the closure element comes into contact with the associated stop on the container neck in the circumferential direction. By abutment of the closure element counter-stop on the container neck stop, the end position of the closure element on the container in which the container is sealed by the closure element is defined in the circumferential direction. Unintentional release of the closure element from the container neck is advantageously prevented by the cam-like elevation. A release of the closure element is only possible if the caused by the cam-like survey or the corresponding locking projection rotational resistance is deliberately overcome. In general, the dismantling of the closure element is carried out analogously to the second alternative assembly method, but with the reverse sequence of the individual process steps.

Further inventive features will be explained below with reference to the embodiment shown in FIGS.

It shows: FIG. 1 shows a closure element designed as a dispensing device with closure means in a perspective view; FIG.

FIG. 2 shows a container neck with closure means for fastening an associated closure element in the form of a dispensing device according to FIG. 1 in a perspective partial view; FIG.

Fig. 3 is a bottom view of the dispensing device of Fig. 1;

Fig. 4 is a partial view of the container neck of FIG. 2 from above in a sectional view.

FIGS. 1-4 illustrate a closure device according to the invention for a bottle-shaped container 10, as used in particular for consumer goods in the detergent or cosmetics sector. In this case, the container 10 is intended in particular for receiving a corresponding cleaning or cosmetic preparation but can of course also absorb other comparable substances within the meaning of the invention. For this purpose, the bottle-shaped container 10 has a container opening 12 which is bounded by the cylindrical container neck 11 and which communicates with the container interior. The not completely shown bottle-shaped container thereby extends substantially along a longitudinal axis X. For sealing closure of this container opening 12, a cover-like closure element 30 is provided, which is designed in the present embodiment as a dispenser 30, on the one hand to reliably store the recorded in the container 10 preparation and, on the other hand, to dispense the preparation via the dispenser 30 as needed. In the present embodiment, the dispensing device 30 is designed as a trigger dispenser, which causes a pump delivery of the preparation from the container interior due to manual operation by a user. In principle, however, different types of closure elements 30 or dispensing devices are also possible within the meaning of the invention.

In order to provide for the container 10 a manufacturing technology favorable and almost resealable closure device, a plurality of closure means are accordingly provided which form a releasable screw-locking connection between dispensing device 30 and container neck 1 1. Specifically, three groove-like slide guides 13 are formed on the container neck 1 1, each extending substantially in the circumferential direction of the container neck 1 1 and having an axially directed inlet opening 14. The slide guides 13 are generally used to receive corresponding locking projections 33, which are each formed on a closure sleeve 31 of the dispensing device 30. The insertion of the latching projections 33 is facilitated by integrally formed on the latching projections 33 wedge portions 35, which additionally run obliquely in the circumferential direction. Thus, the locking projections 33 can be easily positioned at the inlet openings 14, then inserted into the respective slotted guides 13 and by a superimposed axial, translational and rotational movement follow the further course of the slide guide 13. Towards the end, each link guide 13 terminates in the circumferential direction with a stop 18, which cooperates with a counter-stop 34 of the corresponding latching projection 33 in order to form a rotational limit in the circumferential direction during assembly of the dispensing device 30. This is achieved by the stop 18 and the associated counter-stop 34 defined in the circumferential direction positioning of the dispensing device 30 on the container neck 1 1 in the ready state. This leads to a desired alignment, in particular of the dispensing device of the dispensing device 30 with respect to the often ergonomic, and thus not rotationally symmetrical designed container. Particularly advantageously, the three slide guides 13 as well as the three associated locking projections 33 are unevenly distributed over the circumference of the container neck 1 1 and the closure sleeve 31. As a result, a clearly aligned in the circumferential direction positioning of the dispensing device 30 is ensured on the container neck 1 1, so that incorrect assembly is effectively prevented. Within the slotted guide 13, a cam-like elevation 15 is further provided with lateral slopes 16, 17. This survey 15, in conjunction with the associated latching projection 33 a Losdrehsicherung that prevents unwanted loosening of the dispensing device 30 from the container neck 1 1. For this purpose, the elevation 15 with the lateral slopes 16, 17 in a slide along the associated radially elastic latching projection 33 as a result of rotation of the dispensing device 30 relative to the container neck 1 1 causes a corresponding rotational resistance. This rotational resistance must be deliberately overcome in order to detach the dispensing device 30 from the container neck, but reliably prevents unintentional release. The size of the required to overcome the cam-shaped elevation 15 rotational resistance is influenced as a function of the respective direction of rotation characterized in that the lateral slopes 16, 17 are formed differently steep. In particular, the slope 17 facing the inlet opening 14 is less steep than the slope 16 facing the stop 18. This results in a lesser rotational resistance to be overcome in the closing direction than in the loosening direction.

In addition, at the container neck 1 1 three unevenly distributed over the neck circumference ramps 20 are provided, which are inclined relative to the container axis x, preferably at an angle of 10-20 °, more preferably 15-16 °. Each ramp 20 terminates at the side facing away from the container opening 12 with an undercut 21, which can be axially engaged behind by a corresponding latching projection 33 of the dispensing device 30. Due to the coordinated distribution of the ramps 20 and slotted guides 13 on the container neck circumference, each undercut 21 axially limits the end portion of the respective slotted guide 13. Insofar, each ramp 20 acts on the container neck 1 1 during assembly and in the assembled state of the dispenser 30 with a corresponding locking projection 33 together. By the cooperation of locking projections 33 and ramps 20 and in particular the axial engagement behind the undercuts 21 by the locking projections 33 thus a reliable axial locking of the dispensing device 30 is ensured at the container neck 1 1. Each ramp 20 has an opening angle α of 30-40 °, preferably about 35 °, not least to allow a clear positioning of the locking projections 33 at the respective ramps. In this context, the latching projections 33 have a smaller opening angle relative to the ramps 20, so that they can easily be attached to the ramps 20. According to a preferred embodiment with a commonly used bottle-shaped container having a capacity of about 500 ml, a conventional container opening inner diameter of about 25 mm. In such dimensions of the container neck 1 1, the ramps 20 are each between 1 -3.1 mm, preferably 2.9 mm, wider than the associated locking projections 33 and wedge portions 35 executed. This guarantees easy attachment of the locking projections 33 to the ramps 20th

As can be seen in particular from FIGS. 3-4, the individual closure means, in particular the ramps 20 and the corresponding latching projections 33, are distributed unevenly over the circumference of the container neck 11 or the dispensing device 30. For a clear description of the respective angular positions β, the dispensing direction Y of the dispensing device 30 is defined as the reference point. Starting from the delivery direction Y, the relevant angles β can thus be given unequivocally, with reference being made to the direction of the angle measurement according to arrow direction β in FIGS. 3 and 4. In detail, the ramps 20 and the corresponding latching projections 33 are preferably provided in ranges β = 90-130 °, 190-230 °, 320-0 °, where β = 0 ° in the assembled state of the dispenser 30 describes the dispensing direction Y. Such a distribution of the ramps 20 and locking projections 33 over the circumference not only guarantees a clear positioning of the dispensing device 30 but also their secure axial attachment to the container neck 1 1. Above all, the two locking connections between locking projection 33 and associated undercut 21 on the side facing away from the dispensing direction Y, d. H. ß = 90-130 °, 190-230 °, thereby also take into account the specific balance of power in the application of a generic dispensing device 30, in particular a trigger dispenser invoice. Such dispensing devices 30 are usually operated via an actuating lever, not shown, in the vicinity of the dispensing device, which leads to corresponding axial force effects in the release direction on the opposite dispensing direction Y. The axial snap-in connections at ß = 90-130 °, 190-230 ° ensure that even with these dispensing devices for a secure fit. Analogously, the other closure means of the entire closure device, d. H. the stops 18, counter-stops 34, inlet openings 14, correspondingly distributed unevenly over the circumference, wherein the Wnkelposition the individual closure means is of course coordinated with each other.

In addition, the tightness of the connection of dispensing device 30 and container neck 1 1 is ensured by a sealing collar 32 which is formed directly on the dispensing device 30, and extends axially into the associated container opening 12. Due to the integrated sealing collar 32, an additional separate sealing element can also advantageously be dispensed with. The reclosable closure device according to the invention with the above-described closure means offers the decisive advantage of a production-technically favorable assembly or disassembly of the dispensing device 30 or of the closure element.

According to a first variant of the method for assembling the dispensing device 30, the dispensing device 30 is initially positioned in the circumferential direction with exact position on the container neck 1 1, wherein all radially elastic locking projections 33 respectively abut the associated ramps 20 of the container neck 1 1. The wedge sections 35 with side slopes make it easier to position this position accurately. Following the dispensing device 30 is axially aufsprellt under axial force on the container neck, so that each locking projection 33 in each case under radial elastic deformation of the associated ramp 20 slides along and then axially locked at the undercut 21. In the axially latched state, the cam-shaped projections 15 prevent unintentional loosening of the dispensing device 30.

According to a second variant of the assembly method, the dispensing device 30 can also be mounted on the container neck 1 1 by means of the slotted guides 13 and latching projections 33, wherein the dispensing device 30 performs a combined axial translational and rotational movement relative to the container neck 1 1. Specifically, the dispensing device 30 is first attached to the container neck 1 1, wherein all radially resilient locking projections 33 each initially abut the associated inlet openings 14 of the slotted guides 13. Thereafter, we the dispenser 30 to the container neck 1 1 connected by superimposed axial and rotational movement, each locking projection 33 within the associated slide guide 13 whose course follows until the locking projection 33 with the cam-like elevation 15 comes into contact. By further rotation of the dispensing device 30 relative to the container neck 1 1 each locking projection 33 as a result of radially elastic deformation overcomes an associated cam-like elevation 15 with lateral slopes 16, 17 and that under a defined rotational resistance. Finally, there is a further rotation of the dispensing device 30 relative to the container neck 1 1 until at least one counter-stop 34 of the dispensing device with the associated stop 18 on the container neck 1 1 in the circumferential direction in contact and thus defines the final assembly position.

Both types of installation can be used alternatively, with the first variant being preferred in machine initial assembly due to the purely translatory mounting direction.

A disassembly of the dispenser 30 from the container neck 1 1 is analogous to the second assembly process variant, albeit in reverse order of the individual process steps. Here, the dispensing device 30 is released by superimposed turning and axial pulling from the container neck 1 1, wherein the individual locking projections 33, overcoming the cam-shaped elevations 15 of the respective slotted guide 13 to the inlet opening 14 follow.

Claims

claims

1 . Closure device for a container (10), with a cylindrical container neck (1 1) surrounding a container opening (12) to the container interior and with a cover-like closure element (30) which is releasably secured by means of a screw-locking connection to the container neck (1 1) to close the container opening (12), the closure device comprising the following elements

 - At least one on the container neck (1 1) integrally formed link guide (13) having an axial inlet opening (12) which cooperates with an associated projection (33) on the closure element (30),

 - At least one on the container neck (1 1) integrally formed stop (18) in the circumferential direction, which cooperates with an associated counter-stop (34) on the closure element (30),

- At least one on the container neck (1 1) integrally formed ramp (20) having an axial undercut (21) which cooperates with an associated, radially elastically deformable latching projection (33) on the closure element (30).

2. Closure device according to claim 1, characterized in that the container neck (1 1) at least one cam-like elevation (15) with circumferentially lateral bevels (16, 17) which as Losdrehsicherung with an associated projection (33) on the closure element (30 ) cooperates.

3. Closure device according to one of the preceding claims, characterized in that the radially elastic latching projection (33) on the closure element (30) at the same time also the projection (33) for cooperation with the associated slotted guide (13).

4. Closure device according to one of the preceding claims, characterized in that the radially elastic latching projection (33) on the closure element (30) at the same time also the counter-stop (34).

5. Closure device according to one of the preceding claims, characterized in that on the container neck (1 1) three unevenly distributed over the container neck circumference ramps (20) are provided.

6. Closure device according to one of the preceding claims, characterized in that each ramp (20) in the circumferential direction has an opening angle α of 30-40 °, in particular about 35 °.

7. Closure device according to claim 5, characterized in that the ramps (20) are positioned at the container neck circumference at β = 320-0 °, 90-130 ° and 190-230 °.

8. Closure device according to one of the preceding claims, characterized in that each latching projection (33) is formed radially elastically deflectable on the closure element (30), in particular by means of a material weakening between closure element (30) and latching projection (33).

9. Closure device according to one of the preceding claims, characterized in that on the closure element (30) an integrated sealing collar (32) is formed, which protrudes in the mounted state in the container opening (12).

10. Closure device according to one of the preceding claims, characterized in that the container (1 1) bottle-shaped and the closure element (30) as a dispensing device (30), in particular as a trigger dispenser is formed

1 1. Method for mounting a closure device according to one of the preceding claims, characterized by the following method steps:

 - Positionally accurate attachment of the closure element (30) on the container neck (1 1), wherein all radially resilient latching projections (33) respectively at the associated ramps (20) of the container neck (1 1) lie,

 - Axial bouncing of the closure element (30) under the action of axial force, so that each locking projection (33) in each case under radial elastic deformation of the associated ramp (20) slides along and then axially locked at the undercut (21).

12. A method for assembling a closure device according to one of the preceding claims, characterized by the following method steps:

 - Attachment of the closure element (30) on the container neck (1 1), wherein all radially resilient latching projections (33) respectively at the associated inlet openings (14) of the slotted guides (13) of the container neck (1 1) lie,

 - Connecting the closure element (30) with the container neck (1 1) by superimposed a- axial and rotational movement of the closure element (30) relative to the container neck (1 1), each locking projection (33) within the associated slide guide (13) whose course follows

 - Further rotation of the closure element (30) relative to the container neck (1 1), wherein each locking projection (33) as a result of radially elastic deformation overcomes an associated cam-like projection (15) under rotational resistance,

- further rotation of the closure element (30) relative to the container neck (1 1), up to At least one counter-stop (34) on the closure element (30) with the associated stop (18) on the container neck (1 1) in the circumferential direction in contact.