This is a U.S. National Phase of PCT/EP2013/054551, filed Mar. 7, 2013, which claims the benefit of priority to French Patent Application No. 1253002, filed Apr. 2, 2012, which is incorporated herein by reference.
The present invention relates to a plug for closing the neck of a container.
The invention in particular addresses the case of containers consisting of a carboy of liquid, capable of containing at least about ten liters of liquid, notably water, typically water carboys of three, four or five gallons, which are used in the upside down position in dispensing fountains or similar devices. The neck of these carboys, which is therefore turned downwards when the carboy is installed on a water dispenser, is closed by a plug generally described as a <<snapped-on>> plug, i.e. a plug for which the tubular skirt is able to be interiorly clipped or more generally coaxially blocked around the neck, unlike screwed plugs for example. This skirt extends axially from a cap of the plug, which obturates the neck and which is designed so as to be crossed right through by a driving-in member belonging to the dispenser.
In order to facilitate the placement of this driving-in member through the cap of the plug, it is known, for example from U.S. Pat. No. 5,687,865 on which the preamble of appended claim 1 is based, how to provide the cap with a central cavity, which is dimensioned so as to receive the driving-in member, by guiding it until the free end of this member will abut against a breakable part, with the shape of a smooth cone frustum with a convex central bottom, of the wall of the cavity: a weakening line, which runs as a straight line on a lateral side of the conical wall of this breakable part to the other lateral side, while passing through the central bottom, then breaks under the action of driving in the member, the progression of the latter through the cap may then be continued until a liquid circulation is established between the inside and the outside of the plug, via the driving-in member generally provided as a hollow member for this purpose. U.S. Pat. No. 5,687,865 makes provision for having the end of the driving-in member bear axially against a rib protruding from the central bottom of the breakable part of the cap, this rib extending in length from the weakening line and perpendicularly thereto. Considering this perpendicular layout between the rib and the weakening line, the effect of this rib on the breaking of the weakening line is limited: this is only an initiation of this breakage, localized at the center of the weakening line. The benefit of this initiation is therefore small, or even insignificant as regards the global force which has to be produced for having the driving-in member pass right through the cap. Further, it is understood that the relevance of this rib is greatly dependent on the shape of the free end of the driving-in member: indeed, if the driving-in member actually used has a less convex end than the one envisioned in U.S. Pat. No. 5,687,865, it is not excluded, or even it is probable that the weakening line begins to break under the action of the driving-in member even before the end of the latter comes into contact with the rib. Now, in practice, very many different shapes are found on the market as regards the driving-in member of water dispensers.
The object of the present invention is to improve the plugs of the type mentioned above, by significantly limiting the force required for driving them in, and this for a large diversity of shapes of the free end of the driving-in member used.
For this purpose, the object of the invention is a plug for closing the neck of a container as defined in claim 1.
One of the ideas at the basis of the invention is to seek, regardless of the specific shape of the free end of the driving-in member, to concentrate on the breaking lines the bearing stresses of this end on the breakable part of the cap. According to the invention, provision is made on the side wall which is notably at least partly frustoconical, of the breakable part, for raised portions protruding from the face of this wall turned towards the cavity, in other words turned towards the free end of the driving-in member, so that this end essentially bears, or even exclusively bears on these raised portions or protrusions, in particular the furthest end comes into contact with the bottom wall of the breakable part. Each of these protrusions thus allows a contact interface to be established with the driving-in member, which, according to the invention has an elongated global shape, globally extending along one of the breaking lines, with which the side wall of the breakable part is provided: to do this, each of these protrusions runs over one of the two longitudinal sides of one of the breaking lines, globally following this longitudinal side. In this way, at the moment when the end of the driving-in member begins to bear on this protrusion, it induces a concentration of stresses on the line, notably tensile and/or torsional stresses, which facilitates breakage of the line and then as the driving in of the member is gradually continued, the end of the driving-in member continues to act on the protrusion by displacing its bearing area along the protrusion, which efficiently causes progression of the breakage of the line along the latter. The force required for complete breakage of the line thus proves to be significantly reduced, and this all the more so since the resistant frictional effects between the driving-in member and the side wall of the breakable part are limited by the small extent of their frictional contact. Advantageously, with the invention, it is thus possible to cause the tearing of the breaking lines essentially or even exclusively under the effect of the weight of the container when the latter is full, typically at the moment when the latter is installed in the upside down position on a dispenser, with upward engagement of the driving-in member of the latter into the inside of the cavity of the cap of the plug for closing this container. The performances of the invention are such that, while guaranteeing breakage of the breakable part of the cap under the effect of the weight of the container, as explained above, the breaking lines may be reinforced, which thus facilitates handling of the plug in order to put it initially in place on the neck of the container, and which limits the risks of leaks through these breaking lines.
Additional advantageous features of the plug according to the invention are specified in the dependent claims.
The invention will be better understood upon reading the description which follows, only given as an example and made with reference to the drawings wherein:
In
Generally, the neck 3 is either made in the same material with the remainder of the container 2, notably when the latter is a glass or plastic container, or adapted so as to be permanently secured on a wall of the container 2, at an aperture crossing this wall. As discussed in the introductory portion of the present document, the container 2 is preferentially a carboy containing at least about ten liters of liquid, notably a water carboy having a capacity of three, four or five gallons.
The neck 3 has a globally tubular shape, the central longitudinal axis of which is referenced as X-X. By convenience, the following of the description of the plug 1 is oriented relatively to the axis X-X, by considering that the terms of <<lower>> and <<bottom>> describe a portion of the plug which is directed axially towards the main body of the container 2 when the plug 1 obturates the neck 3 of this container and while the latter lies on a horizontal plane, such as table, with its neck 3 directed upwards, as in
The neck 3 includes a globally tubular body 4, with a circular base and centered on the axis X-X. The top axial end 5 of the body 4 is free, while being open on the outside, while, at its opposite axial end, the body 4 opens into the main body (not shown) of the container 2. The free end 5 of the body 4 connects with each other the inner and outer faces of this body. The outer face of the body 4 is provided with an upper peripheral heel 6 protruding outwards.
As this is well visible in
At the outer periphery of the cap 10, a globally tubular skirt 12 extends downwards, centered on the axis X-X and with a circular base, having been made with the cap in the same material.
As this is well visible in
The skirt 12 is moreover provided with a weakening line 16 designed so as to be broken under the action of the user, in order to separate the portions of the skirt 12 from each other, which were initially connected with each other through this weakening line 16. In practice, it is understood that the weakening line 16 is broken by a user when the latter wishes to free the plug 1 in totality relatively to the neck 3 of the container 2, notably for purposes of reusing this container. As an exemplary embodiment, this weakening line 16 includes a first portion, which is located at a substantially constant axial level of the skirt 12 and which runs over a portion of the periphery of this skirt along the bulging line 14 on the one hand and a second portion which connects the first portion of the weakening line to the free lower end of the skirt 12 on the other hand. Advantageously, the lower end of the skirt 12 is provided with a tab 18 protruding downwards, in close proximity to the second portion of the weakening line 16: in a way known per se, this tab 18 is provided so as to be grasped by the fingers of the user in order to be moved away from the neck 3 of the container 2, which induces initiation of tearing at the free end of the second portion of the weakening lines 16.
Now returning to the description of the cap 10 of the plug 1,
The inner peripheral portion 22 of the cap 10, as for it, has a hollow shape relatively to the upper face 20A of the outer peripheral portion 20: the cap 10 thus defines, by its inner peripheral portion 22, a cavity 24, which is globally centered on the axis X-X and which, as this will be detailed later on with reference to
As this is well visible in
The inner portion 22 of the cap 10 also comprises a lower portion 28, which extends downwards from the lower end of the tubular wall 26 and which delimits the bottom axial portion of the cavity 24 by closing the latter downwards, which amounts to stating that this lower portion 28 of the cap 10 delimits the bottom region of this cavity 24.
As this is well visible in
In the exemplary embodiment considered in the figures, the side wall 32 includes a main frustoconical part 34, which is substantially centered on the axis X-X and converges towards the bottom wall 30, and the lower end of which is joined with the outer periphery of the bottom wall 30 while the upper end of this frustoconical part 34 is connected to the lower end of the tubular wall 26 through a globally annular connecting portion 36, centered on the axis X-X and slightly tilted downwards upon moving away from the tubular wall 26.
The lower portion 28 of the lower peripheral portion 22 of the cap 10 is breakable, in the sense that this lower portion 28 is provided with weakening lines 38 which are three in number in the exemplary embodiment considered in the figures and which are designed for breaking so as to separate portions of the part 28 from each other which were initially connected with each other through these weakening lines 38. In practice, as explained in more detail in the following, these lines 38 are broken under the action of the driving-in member 7 when the latter is engaged through the cap 10. Advantageously, as this is well visible in
As an advantageous option, the outer end of each breaking line 38 forms an arc centered on the axis X-X, which extends on either side of the breaking line, and this at the junction between the lower portion 28 and the tubular wall 26. As an alternative not shown, the upper end of the breaking line 38 is without the aforementioned arc, and only has a point-like profile, located in the rectilinear extension of the remainder of the breaking line.
Also as this is well visible in
In all the cases, according to an advantageous arrangement, each rib 40 is orthoradially distant from the breaking line 38 with which this rib is associated, and this over the whole length of this rib. This amounts to stating that each rib 40 is in totality laid out at a distance from its associated breaking line, notably without this rib 40 intersecting its associated breaking line or being joined up with it. In other words, the orthoradial spacing between each rib 40 and the associated breaking line 38 is advantageously non-zero in every point of this rib. One of the benefits of this advantageous arrangement is avoiding that the presence of the ribs 40 perturbs the propagation of a tear along the breaking line 38, notably for avoiding the breaking or the dispersion of the propagation of this tear.
In practice, notably for reasons of manufacturing, notably molding of a plastic material forming the plug 1 when the latter is made in one piece, and/or for reasons of mechanical behavior, both ribs 40 associated with a same breaking line 38 are laid out symmetrically with respect to this breaking line.
The benefit of the ribs 40 will now be explained, essentially with reference to
In a first phase which is illustrated by
By continuing the axial engagement of the driving-in member 7 into the cavity 24, its free end 7A moves closer to the breakable part 28 of the cap 10, until it comes into contact with this portion 28, as shown in
More generally, by means of the ribs 40, the force required for breaking the lines 38 is comparatively reduced as compared with the situation where these ribs 40 would be absent, and this by at least 10%, or even more. As explained above, this is because the ribs 40, which are the first areas of the plug 1 against which the driving-in member 7 bears, concentrate the bearing stresses to which they are subject, onto the breaking lines 38. This is also because the global pressing contact interface between the driving-in member 7 and the plug 1 is then restricted to the six ribs 40, which significantly limits the frictional resistances between the driving-in member 7 and the plug 1, in particular comparatively with the situation where the ribs 40 would be absent.
According to an advantageous arrangement illustrating the performances of the invention, it is possible to reinforce the resistance to breakage of the breaking lines 38, typically by limiting their weakening, which reinforces the mechanical strength of the plug 1 before its opening and consequently its leakproof performances, while guaranteeing that the force required for tearing these lines 38 under the action of the driving-in member 7 remains less than what would have been required to apply in the absence of the ribs 40, notably remains less than the force resulting from the weight of the container 2 when the latter has to be placed in an upside down position on the aforementioned dispenser. More generally, the possibility, which the invention provides, of somewhat allowing overdimensioning of the breakage resistance of the lines 38, facilitates the manufacturing of the plug, notably by limiting the molding stresses of these breaking lines.
Of course, what has just been described with reference to
Various arrangements and alternatives to the plug 1 described up to now may moreover be contemplated. As examples:
Number | Date | Country | Kind |
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12 53002 | Apr 2012 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/054551 | 3/7/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2013/149783 | 10/10/2013 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3392862 | Faulstich | Jul 1968 | A |
4303167 | Martinez | Dec 1981 | A |
4545497 | Martha, Jr. | Oct 1985 | A |
4577771 | Martinez | Mar 1986 | A |
5687865 | Adams et al. | Nov 1997 | A |
Entry |
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International Search Report in PCT/EP2013/054551, mailed May 21, 2013 (3 pages). |
Number | Date | Country | |
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20150060388 A1 | Mar 2015 | US |