Patent Application
20170121087
The invention relates to a container, such as those that can commonly be found for liquids or food products, the method of capping a container, and its use.
Generally, the invention relates to the field of the capping of containers, particularly bottles and cartons, of the type of those that comprise a neck, the neck forming a constriction on the container.
In fact, a container in general comprises a body, defining a volume for filling, closed by a bottom at a lower end. The body is topped by an open neck, having a cross-section that is smaller than that of the body and therefore forming a constriction, so as to facilitate the flow of the product out of the container. The body is, for example, obtained by blow molding or stretch blow molding of a preform made of thermoplastic material, the neck being previously attached to, or more commonly an integral part of, the preform. The body can also be a carton, for example made of paperboard, on which a plastic neck is mounted. Once the body is filled, a capping system is added to the neck to close the container.
Two categories of capping systems are commonly found on the market.
A first category consists in forming, on the neck, temporary mounting means with a cap. The cap appears in the form of a rigid part, for example made of plastic, whose dimensions allow it to cover the neck and the opening. The temporary mounting means are, for example, of the snap-on type, or else of the threading-on-the-neck type working with a counter-thread of the cap.
The document EP 0 941 938 illustrates an example of a capping system of this first category.
Such caps have, in particular, the advantage of offering a secure, even fluidtight, closing, and of making it possible to remove the cap to open the container and to put the cap back in place to reclose the container in a fluidtight manner repeatedly, without degrading the quality of the closing.
However, such rigid caps are expensive to manufacture. Further, they require the putting in place of mounting means that are exclusive to their placement on the neck, complying with the dimensions that are adapted to the cap, making the shape of the neck complex, and therefore again increasing the manufacturing costs.
The second category consists in applying a sheet made of a flexible material, typically of aluminum, over the the opening and covering the neck. The sheet is then mounted onto the neck for example by adhesion or by heat-sealing. To open the container, the mounting of the sheet on the neck must be broken. In this second category, the sheet can be accompanied by an overcap, i.e., an additional cap, added above the sheet.
One advantage of this second category of capping systems is that, when the sheet is not accompanied by an overcap, the costs are reduced relative to the caps of the first category. In fact, the amount of material constituting the sheet is less than that of the caps of the first category. In addition, the mounting of the sheet on the neck does not require forming additional means on the neck, simplifying the design and the manufacture of the neck. This is why this second category of capping systems is generally placed on bottles whose necks are not long enough to make possible the formation of such additional means.
Nevertheless, once the mounting between the sheet and the neck is broken, the sheet is not able to reclose the container. In fact, even if the sheet can be placed over the opening of the neck, there are no longer mounting means. The container can no longer be closed in a fluidtight manner. The contents can then inadvertently spill out of the container, or foreign bodies can enter into the container.
Therefore, a need exists for a container equipped with a new capping system that solves in particular the previously-cited drawbacks.
For this purpose, the invention, according to a first aspect, proposes a method of capping a hollow container. The container comprises a body that extends between an upper end and a lower end, the upper end being topped by a neck forming a narrowing on the container and defining an opening to the interior of the container, and the lower end comprising a bottom that closes the container. The capping method comprises the following steps:
The capping method according to the invention makes it possible in particular to form a cap from a sheet in a simple and economic manner. The sheet shaped during the deep drawing operation has a shape that is suitable for a subsequent recapping.
According to the invention, the method can have the following characteristics:
According to a second aspect, the invention proposes a capped container obtained by the method as presented above, in which the neck lacks threading or in which the neck lacks snap-on means.
According to a third aspect, the invention proposes a use of the container that is capped according to the method presented above, comprising an opening step in which the mounting between the sheet and the container is broken, detaching the sheet from the body of the container to allow it to be opened, and a closing step in which the collar of the sheet is placed on the edge of the opening, the central area capping the opening.
To be able to be implemented, the invention is set forth in a sufficiently clear and complete way in the following description that is, in addition, accompanied by drawings in which:
The container 1 comprises a body 2, extending between an upper end 3 and a lower end 4.
In the following description, the terms “lower,” “upper,” “top,” “bottom,” etc., are used in reference to the drawings for greater ease of understanding. They must not be understood as being limitations of the scope of the invention.
The upper end 3 is topped, in the direction of the main axis X, by a neck 5, with a cross-section that is smaller than the cross-section of the body 2. A shoulder 6 connects the neck 5 to the upper end 3 of the body 2. The neck 5 thus forms a narrowing on the container 1. The neck 5 has a free, open end 7 that forms the edge of an opening 8 (as referenced in
In what follows, the terms “interior,” “exterior,” “inside,” within,” etc., are used with reference to the container 1, which delimits an interior volume.
The lower end 4 of the body 2 of the container 1 is closed by a bottom 9.
The container 1 can have, as illustrated in
The container 1 can be made of thermoplastic material, such as PET, and is formed by, for example, a method of molding, blow molding or stretch blow molding, from a preform. As a variant, the body 2 of the container is made of paperboard; the neck 5, made of thermoplastic material, is rigidly mounted on the body 2. The neck 5 can have a collar 5′ projecting transversely, serving as a support during different manufacturing steps of the container.
The opening 8 of the neck 5 is capped by means of a sheet 10 shaped in the form of a cap, according to a capping method that will now be described.
Shaping is defined here as making a permanent deformation.
The sheet 10 initially appears in the form of a disk of thin material, whose thickness is on the order of a millimeter or less. The sheet 10 is made of ductile material, i.e., it is intended to be deformed plastically under the action of minimal stress without breaking. For example, it is made of thermoformable material, i.e., it can be deformed plastically without breaking after having undergone a temperature increase.
In a first step, the sheet 10 is applied over the entire edge 7 of the opening 8 of the container 1. The sheet 10, in the form of a disk, is centered on the longitudinal axis X so as to cover the opening 8 completely.
In a second deep drawing step, the sheet 10 is deep drawn in the opening 8. For this purpose, a die 11 comprises an impression 12 corresponding to the opening 8 and to its edge 7. The die 11 can be moved in translation along the longitudinal axis X. As a variant, it is the container 1 that can be moved in translation along the longitudinal axis X. More specifically, the impression 12 of the die 11 is formed by two portions. A first portion 12a extends along the longitudinal axis X over a distance on the order of a centimeter and has a cross-section corresponding approximately to the interior cross-section of the neck 5. The second portion 12b also extends along the longitudinal axis X and has a cross-section whose dimensions are greater than those of the cross-section of the opening 8. During the deep drawing step, the first portion 12a of the impression 12 of the die 11 enters into contact with the sheet 10 and penetrates to the interior of the neck 5 through the opening 8 until the second portion 12b strikes against the edge 7 of the opening 8 while crushing the sheet 10 against the edge 7.
So as to facilitate the deep drawing step, the sheet 10, then made of thermoformable material, can be heated. The heating can take place just before, or during, the deep drawing, the die 11 then comprising heating means for this purpose.
The die 11, optionally associated with a heating step, thus exerts a sufficient stress on the sheet 10 to deform it plastically.
The sheet 10 shaped in the form of a cap by deep drawing, optionally cooled, then has a central area 13 that penetrates to the interior of the container through the opening 8 over a distance on the order of a centimeter. The central area 13 is surrounded by a collar 14, pressing on the edge 7 of the opening 8. The central area 13 and the collar 14 of the sheet 10 are offset along the longitudinal axis X in relation to one another (in other words, the collar 14 and the central area 13 are in offset planes). Thus, during the deformation, a junction area 15 is created between the central area 13 and the collar 14 of the sheet 10. The junction area constitutes a riser 15 between the collar 14 and the central area 13 and is advantageously in contact with the interior wall of the neck 5. The central area 13 has a circular cross-section, adapted to the opening 8. The collar 14 of the sheet 10 is also circular, limiting in particular the bulk beyond the edge 7 of the opening 8.
In a third step, known as mounting, the deep drawn sheet 10 is mounted on the neck 5, thus ensuring the interlocking of the sheet 10 on the body 2 of the container 1.
According to one embodiment, the mounting is performed by sealing between the collar 14 of the sheet 10 and the edge 7 of the opening 8. As a variant, or in combination, the sealing is performed between the riser 15 and the interior wall of the neck 5.
The sealing step can take place at the same time as the deep drawing step. For this purpose, the die 11 is equipped with heating means bringing the sheet 10, and optionally the neck 5, to a temperature that is sufficient to bring about the sealing.
As a variant, the mounting is performed by adhesion. For this purpose, for example, prior to the step of applying the sheet 10, the edge 7 of the opening 8 of the neck 5 is, coated with a layer of sealant, preferably an edible sealant. The pressure exerted by the die 11 on the sheet 10 against the edge 7 ensures the setting of the sealant on the sheet 10.
The mounting step ensures a fluidtight contact between the collar 14 of the sheet 10 and the edge 7 and/or between the riser 15 and the interior wall of the neck 5.
When the die is moved along the longitudinal axis X in order to move away from the sheet 10, the sheet 10 remains mounted rigidly on the neck 5.
The sheet 10 thus forms a cap, preventing the liquid from escaping out of the container, and preventing outside bodies from penetrating into the container.
So as to facilitate the opening of the container by pulling out the sheet 10, it can comprise a portion projecting transversely, from the collar 14 of the sheet 10, and forming the gripping area 16, as can be seen in
As a variant, the collar 14 can have a square shape in which the opening 8 lies. The corners of the collar 14 extending beyond the edge 7 of the opening 8 then form gripping areas.
It is understood that the collar 14, and the sheet 10 in general, can be of any shape, covering the opening 8.
To open the container, a user grasps the gripping area 16 and exerts a force to break the mounting between the sheet 10 and the neck 5. The sheet 10 is thus detached from the container 1. However, the sheet 10 maintains it cap shape, i.e., the central area 13, the collar 14, and the riser 15. The choice of material and of the thickness of the sheet 10 makes it possible to prevent the sheet 10 from tearing during the breaking of the mounting.
To reclose the container, the sheet 10 can be placed again over the opening 8, while inserting the central area 13 into the opening 8 to cap it, the collar 14 of the sheet 10 pressing against the edge 7. Although the mounting is broken, the shape of the cap-shaped sheet 10 makes possible an interlocking between the sheet 10 and the container 1, limiting the risks that the contents of the container escape out of the container or that foreign bodies penetrate into the container 1.
The sheet 10 can be made of flexible or rigid material.
Flexible is defined here as the property of the sheet 10 to be deformed elastically under the effect of a specified maximum stress under normal conditions of use of the container 1.
Rigid is defined here as the property of the sheet 10 to maintain its shape under the action of a specified maximum stress under normal conditions of use of the container 1.
For example, the sheet 10 is made of thermoplastic material, or of metal such as aluminum.
The neck 5 no longer requires specific means for receiving a cap, such as a threading or snap-on means. The neck 5 in fact lacks such means.
The sheet 10 thus provides a cap at low cost, making it possible, moreover, to reclose the opening 8 of the container 1.
| Number | Date | Country | Kind |
|---|---|---|---|
| 14 52934 | Apr 2014 | FR | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/FR2015/050720 | 3/23/2015 | WO | 00 |
