The invention relates to a container which comprises a cylindrical pouring nozzle having an outer thread and a cap having an inner thread for screwing onto the pouring nozzle. In the process, the cap can be screwed as far as an end position in which the cap abuts a stop of the pouring nozzle in the direction of rotation. In the end position, the cap assumes a desired orientation with respect to a front face of the container, for example.
A container in the form of a washing agent bottle is known from the prior art, in which container an annular seal is provided for sealing between the cap, in the form of a screw closure, and the pouring nozzle. In this case, the seal is made of a material that is softer than a material of the cap and than a material of the pouring nozzle. The seal is arranged between an end edge of the pouring nozzle and an end contact surface of the cap in the axial direction. When the cap is screwed onto the pouring nozzle, the soft seal is compressed in the axial direction.
If the bottle having the pouring nozzle closed by means of the screw closure is also distributed by means of electronic commerce (e-commerce), it cannot be precluded that the bottle is in any position for a long period of time in the event of delivery by means of a parcel service, for example, and is upside down, for example. This imposes high requirements for sealing between the screw closure and pouring nozzle which the above-described axial seal does not always meet. More stringent requirements arise when the bottle is filled with a liquid washing agent which typically contains surfactants. The lower surface tension of the liquid increases the risk of leakage. Due to production tolerances, it cannot be precluded that although the desired end position is achieved when the cap is screwed on, the axial seal is not compressed to the extent required in order to be able to seal satisfactorily.
The object of the invention is therefore to provide a container having a pouring nozzle and a cap, which container meets high requirements with regard to sealing between the pouring nozzle and the cap.
The object of the invention is achieved by the combination of features according to the claims. Embodiments of the invention can be found in the claims.
According to the invention, the seal comprises a first sealing element which is arranged between the cap and the pouring nozzle in the radial direction when the cap is screwed on and abuts a lateral surface portion of the pouring nozzle. The first sealing element can therefore also be referred to as a radial sealing element, as it is arranged in the radial direction between the components to be sealed. The first sealing element can be designed as a peripheral sealing lip, for example, it being possible for the sealing lip to have a thickness of less than 0.5 mm in profile in the radial direction. For example, the thickness of the first sealing element may be 0.2 to 0.4 mm in the radial direction.
The cap for the pouring nozzle can be designed as a closure cap, for example, in order to close the pouring nozzle. In another embodiment, the cap is designed as a pouring aid. The pouring aid may comprise a specific pouring spout which is intended to make it easier to pour liquid out of the container through the pouring nozzle. Owing to the stop of the pouring nozzle, it can be ensured that the pouring aid having the pouring spout is properly oriented with respect to the front face and/or to a handle of the container.
Preferably, the pouring aid comprises an outer thread onto which the inner thread of an additional cap can be screwed. This additional cap may be the above-described closure cap, for example. The closure cap can therefore be screwed onto the pouring nozzle both directly and indirectly via the pouring aid. In the latter case, the pouring aid is screwed onto the pouring nozzle and the closure cap is screwed in turn onto said pouring aid. In order to define an end position of the closure cap with respect to the pouring aid, the pouring aid can comprise a stop beyond which the closure cap cannot be screwed onto the pouring aid.
The cap may comprise a substantially cylindrical outer wall and a substantially cylindrical inner wall which define a receiving space, in the form of an annular cylinder, for the pouring nozzle. The cylindrical outer wall and/or the cylindrical inner wall may comprise shoulders, conical portions, threads etc., due to which the outer wall and/or the inner wall deviate from a mathematically exact cylindrical lateral surface. Correspondingly, the receiving space is not a mathematically exact annular cylinder.
The seal may be arranged in the receiving space at a front end of the receiving space. Preferably, this front end is a closed end of the receiving space. The receiving space is open at the opposite side so that the pouring nozzle can be moved in the receiving space when the cap is screwed on. When the cap is screwed on in the end position, only an upper end of the pouring nozzle can project into the receiving space.
In one embodiment, the seal and the cap are rigidly interconnected. Preferably, the rigid connection between the seal and the cap is established only when the cap and seal are produced, it being possible for both components to be produced by injection molding and one component to be injected onto the other. In the process, the seal is first injection-molded onto or around which seal the cap is injected.
The seal may comprise a first leg and a base, the first sealing element being arranged on the first leg and possibly comprising a bulge facing the receiving space. A rear face of the first leg can abut a lateral surface portion of the inner wall of the cap and can be rigidly connected thereto. The first leg extends in the axial direction along the lateral surface portion of the inner wall of the cap.
When the cap is mounted, the first sealing element closes the gap produced between the lateral surface portion of the inner wall of the cap and the lateral surface portion of the pouring nozzle. The two lateral surface portions are radially opposite one another. The bulge, which is convex in cross-section, abuts the lateral surface portion of the pouring nozzle. Due to the bulge, there is an undercut in the axial direction. This undercut can, as described in more detail below, be used to hold the seal in a fixed position inside an injection mold for the cap when the cap is produced.
In one embodiment, the seal comprises a second sealing element on the base, which sealing element is arranged between the cap and the pouring nozzle in the radial direction when the cap is screwed on and abuts an end edge of the pouring nozzle. The seal therefore provides two-fold sealing: firstly by means of the first sealing element, which is arranged between two surfaces to be sealed in the radial direction, and secondly by means of the second sealing element, which is arranged between two surfaces to be sealed in the axial direction. The thickness of the second sealing element in the axial direction is preferably greater than 0.5 mm. In one embodiment, this thickness is 0.7 to 1.7 mm. The thickness of the second sealing element in the axial direction is therefore greater than the thickness of the first sealing element in the radial direction.
A rear face of the base can abut a radial web of the cap. In the above-mentioned embodiments, which comprise an annularly cylindrical receiving space, the preferably peripheral radial web interconnects the inner wall and the outer wall of the cap.
In one embodiment, front faces of the seal facing the receiving space are free of production-related surface structures. Surface structures of this kind may be, for example, injection points which can be produced in the event of injection molding. The front faces of the seal can therefore be particularly smooth, which is conducive to their sealing effect.
The preferably integral cap may be made of plastics material, preferably of polypropylene (PP). A plastics material is preferably also used for the material of the seal; in this case, thermoplastic elastomers (TPE) have proven particularly favorable. Although the material of the seal is softer, according to the invention, than the material of the cap and the material of the pouring nozzle, the material of the seal should not be too soft. Efficient sealing is achieved when the material of the seal has Shore A hardness of 30 to 90 or 60 to 80 ShA at 23° C.
A groove that is open to the receiving space and has groove side walls may be provided on the base of the seal, which groove side walls diverge towards a groove floor. In other words, the groove is an (additional) undercut which is used to hold the seal securely in place by means of a holding element while the cap is produced.
In one embodiment, the seal is substantially U-shaped and comprises a second leg which is connected to the first leg via the base. The second leg also extends in the axial direction. A rear face of the second leg is rigidly connected to a wall portion of the cap (for example the outer wall).
A protrusion oriented towards the receiving space may be provided on the second leg, which protrusion produces an (additional) undercut in the axial direction.
The above-described undercuts ensure a rigid connection between the seal and a holding device for the seal. The holding device is used when the seal is produced and when the cap is produced preferably at a later point. The holding device is used as part of an injection mold for the seal in this case. After injection molding has taken place, the seal is placed into the injection mold of the cap by means of the holding device. The various undercuts and the U shape of the seal ensure that the seal is securely placed on the holding device, which makes it easier to produce the cap and the seal. In this case, the holding device may specify the inner contour of the receiving space of the cap at least in part. The holding device may be in several parts, so that said device can be pulled out of the receiving space after the cap has been injection molded. A specific design of the seal, which is also unrelated to other features of the invention such as the stop, is therefore disclosed here, which design is used for rigid connection between the seal and the holding element in order to, for example, hold the seal in position in an additional production step, in particular when another material is injected around the seal.
The invention is described in more detail with reference to the embodiments shown in the drawings, in which:
The container 1 further comprises a cap 8, which has a cylindrical basic form in the shape of an upside-down pot or cup and is mounted on the pouring nozzle 7. The cap 8 comprises a cylindrical outer wall 9 and a cylindrical inner wall 10, which define a receiving space 11. Owing to the cylindrical walls 9, 10, the receiving space 11 assumes the shape of an annular cylinder.
An annular seal 12 is arranged in the receiving chamber 11, which seal, proceeding from the central axis 4, is arranged between the inner wall 10 and an upper end of the pouring nozzle 7 in the radial direction. The seal 12 therefore seals an annular gap 13 between the inner wall 10 of the cap 8 and the pouring nozzle 7. A typical gap size for the gap 13 (radial distance between the pouring nozzle 7 and the inner wall 10) is 0.2 to 1.5 mm, preferably 0.2 to 1 mm, more preferably 0.2 to 0.5 mm, in the region of the seal. Correspondingly, the seal 12 is also 0.2 to 1.5 mm, preferably 0.2 to 1 mm, more preferably 0.2 to 0.5 mm, it being possible for said seal to be compressed when in the position shown. The non-compressed seal 12 may have a thickness of 0.2 to 1.5 mm, preferably 0.2 to 1 mm, more preferably 0.2 to 0.5 mm, in the radial direction.
The receiving space 11 is delimited by a peripheral radial web or connecting ring 14 at an upper end. The radial web 14 connects the outer wall 9 and the inner wall 10 in this case. The upper end of the receiving space 11 is closed by the radial web 14.
In order to remove the washing agent 3 from the container 1, the cap 8 is detached from the pouring nozzle 7.
In the embodiment in
In one embodiment, the volume of the main body is 0.5 to 51. An inner diameter of the cylindrical pouring nozzle is preferably between 30 and 50 mm. It should be emphasized at this point that
Components or features that are identical or similar to components and features denoted in
An inner thread 20 is provided on an inner face 19 of the outer wall 9 facing the receiving space 11, by means of which inner thread the closure cap 15 of
The seal 12 is mounted in the upper end of the receiving space 11, in a specific design in this case.
A first sealing element 26 is arranged on the first or radially inner leg 21, which element comprises a convex bulge 27 which is formed in the direction of the inner face 19 of the outer wall 11. In the illustration in
A second sealing element 29 having a groove or recess 30 is provided on the base 23. The groove 30 comprises two groove side walls 32, 33 which diverge towards a groove floor 31, so that the groove 30 is also undercut in the axial direction. A protrusion 34 oriented in the direction of the first leg 21 is provided on the second or radially outer leg 22, which is shorter than the first leg 21, by means of which protrusion an undercut 35 is also provided on the second leg 22 in the axial direction.
Owing to the specific design of the seal 12 having the opposing legs 21, 22 and the undercuts 28, 35 and the undercut groove 30 on the base 23, the seal 12 is positioned securely on a part of the injection mold that is necessary for injection molding the seal, after injection molding has taken place. This part is also referred to in the following as a holding element. When the seal 12 is injection molded, the holding element defines the inner contour of the seal 12. For subsequent production of the cap 8, the seal 12 and the holding element protrude into the injection mold for the cap 8. The material for the cap 8 is injected onto the seal 12. Owing to the secure position of the seal 12 on the holding element, the seal 12 remains in the desired position while the cap 8 is injection molded.
A nozzle portion 37 having an outer thread 38 is arranged above the radial web 14. The dimensions of the nozzle portion 37 and the outer thread 38 are selected such that the closure cap 15 can be screwed onto the pouring aid 36.
A significant feature of the pouring aid 36 is the pouring spout denoted by the numeral 39. The pouring spout 39 extends from a lower end, which is formed on an end of the inner wall 10, in the axial direction beyond an upper end edge 40 of the nozzle portion 37.
In one embodiment of the invention, a lateral surface portion 41 of the nozzle portion 37 abuts the bulge 27 at a specific pressure, such that a first sealing is thus produced between the closure cap 15 bearing the seal 12 and the pouring aid 36. The first sealing is independent of the end position of the screw movement in this case. The first sealing element 26 already demonstrates its (total) effect when the bulge 27 presses against the nozzle portion 37 or the pouring nozzle 7 in the radial direction.
A second sealing takes place due to the interaction of the second sealing element 29 and the upper end edge 40 of the nozzle portion 37. However, the second sealing element 29 acting in the axial direction demonstrates its effect only when the closure cap 15 has been completely screwed onto the pouring aid 36 as far as the end position. However, due to production tolerances, the second sealing element may be compressed insufficiently, which impairs the sealing function of the second sealing element 29.
The embodiment according to the invention therefore achieves two-stage sealing, the sealing induced by the first sealing element 26 acting in the radial direction and the sealing induced by the second sealing element 29 acting in the axial direction. The material of the seal is softer than the material of the cap 8 and softer than the material of the pouring nozzle 7.
In one embodiment of the invention, the end position of the screw movement is configured such that a total sealing effect is already achieved before the end position has been reached by the first sealing element 26. Preferably, there is a gap of greater than or equal to 0.15 mm between the closure cap 15 securely screwed onto the pouring aid 36 and the end edge 40 of the nozzle portion 37 at the end position in the axial direction. This produces an optimal radial seal over an increased dimensional tolerance, which seal also has an increased resistance to congestion.
The interaction described here between the nozzle portion 37 of the pouring aid 36 and the seal 12 relates to the connection of the pouring aid 36 and the closure cap 15. The above-mentioned embodiment applies by analogy to the possible connection between the pouring nozzle 7 and the closure cap 15 and to the possible connection between the pouring nozzle 7 and the pouring aid 36.
The sealing by means of the first sealing element 26, which acts in the radial direction, is therefore essential to the invention. The provision of the second sealing element 29, which acts in the axial direction, is therefore merely one embodiment of the invention. Correspondingly, the seal 12 may deviate from the specific design as shown in detail in
Number | Date | Country | Kind |
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102016223043.3 | Nov 2016 | DE | national |
Number | Date | Country | |
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Parent | 16419442 | May 2019 | US |
Child | 17373744 | US |