The present invention relates to a closure cap for a container, wherein the container typically receives loosely stored products such as pills or tablets, in particular effervescent tablets. The closure cap comprises a top part connected to a container body via a hinge, wherein the top part includes a sealing skirt to sealingly engage with an opening of the container body, and the top part includes a desiccant chamber for accommodating a desiccant, according to the preamble of claim 1.
Closure caps for containers of the above-mentioned type are known and common to the skilled persons.
WO 2005/012131 A2 relates to a container for packaging products which are sensitive to a moist environment. The container comprises a closure cap including a desiccant chamber.
Closure caps for containers of the above-mentioned type are typically manufactured or molded separately from the container body. The closure caps are then connected to the container body after the products to be stored, in particular pills or tablets, have been introduced into the container body. The container body is typically a cylindrical tube having one opening at one end face and which is closed at the opposite end face. Effervescent tablets, which are particularly sensitive to moisture, are typically contained in containers of this type.
After the tablets have been introduced into the respective container body, the closure cap is attached to the container body, conventionally by positive locking.
The closure cap of this type may comprise a ring part which snaps over a bead around the opening of the container body and which connects the top part firmly to the container body by positive locking.
In order to sealingly close the container, the top part may include a sealing skirt which fits with its outer wall surface snugly into the inner wall surface of the opening of the container body.
In particular, in the case of effervescent tablets, the products are very sensitive to moisture. In order to increase the shelf life, a desiccant chamber may be included in the closure cap. Furthermore, as soon as the container is opened by a customer for the first time, moisture enters into the inside of the container body. Into the desiccant chamber, a desiccant such as silica gel, a molecular sieve or any other drying agent is provided in order to ensure that the quality of the products within the container can be maintained over a long period of time and over repeated opening and closing cycles.
It is an objective of the present invention to provide a closure cap for a container which has an improved storage performance and which can be manufactured in a cost efficient manner.
This object is achieved by a closure cap with the features of claim 1. Advantageous improvements are claimed in the dependent claims.
According to the preamble of claim 1, a closure cap for a container comprises a top part connected to a container body via a hinge, the top part being pivotable about the hinge and the top part including a sealing skirt to sealingly engage an opening of the container body. Furthermore, the top part includes a desiccant chamber for accommodating a desiccant; and a spring element for pre-tensioning products received in the container body is provided.
According to the invention the spring element extends from the top part in a single loop. In this disclosure, the term “single loop” is to be understood in the sense that the spring element does neither branch off nor has more than one single band of material. In particular, the term “single loop” is intended to mean that the spring element extends from the top part and ends at the top part, not showing more than one single winding. The term “loop” does, however, not necessarily mean that the loop is closed and open loops are also contemplated. In particular, an open loop having at least one gap is also understood to be included in the definition of “single loop”.
By the provision of the spring element in this form, in particular in the form of a single loop that extends from the top part, the spring element can be provided in a cost efficient manner. Furthermore, it improves the storage characteristics of the closure cap as the spring element pre-tensions the products received in the container body, in particular the tablets or pills, such that they do not move around during transport and, thus, do not break or dust.
Further, according to the invention, the single loop of the spring element has a diameter larger than the diameter of the desiccant chamber and/or a diameter larger than the sealing skirt. This enables an easy access to the desiccant chamber such that the desiccant can be easily introduced into the desiccant chamber without being hindered by the spring element.
Furthermore, the desiccant, once introduced into the desiccant chamber, needs to be closed in, typically by using a piece of paperboard. This piece of paperboard is conventionally attached to the walls of the desiccant chamber by means of heat welding. The spring according to the invention has the advantage that a welding gun can be easily introduced through the spring in order to heat weld the paperboard to the desiccant chamber.
Furthermore, a specific embodiment enables that the spring element is made in one piece with the closure cap, as there is no need to remove the spring element for inserting a desiccant into the desiccant chamber.
In a preferred embodiment, the spring element extends from the end face of the desiccant chamber or from the end face of the sealing skirt. In a further preferred embodiment, the walls of the desiccant chamber are identical with the walls of the sealing skirt such that the outer wall surface of the sealing skirt adopts the function of sealingly engaging with the inner surface of the container body, and the inner wall surface of the sealing skirt defines the desiccant chamber. In such an embodiment, it is appropriate that the spring extends from the end face of the sealing skirt.
Preferably, the spring element is made in one piece, or integrally, with the closure cap. This embodiment reduces the number of parts, reduces the assembly cost and the overall cost of the closure cap. It furthermore improves the handling of the closure cap as there is one piece less to be assembled when filling the container body and the desiccant chamber.
In a preferred embodiment, the spring element extending in a single loop, extends from the top part and ends at the top part such that the two base portions are situated in a sector of a circle of less than 90 degrees of the top part. Preferably, the sector is situated opposite to the sector in which the hinge is situated. This embodiment enables that the spring element can be shaped in a form such that it makes maximum use of a length extending from the top part.
In particular, the spring element can be shaped such that the single loop is bent substantially about the hinge axis, in particular in a plane perpendicular to the hinge axis, such that the spring element is basically bent backwards towards the hinge. In particular, the spring element describes some sort of radius about the hinge axis.
This shape of the spring element enables the provision of a comparatively long spring element that makes maximum use of the opening in the container body. In other words, by shaping the spring element in a bent form, substantially bent about the hinge axis, it is possible to provide a spring element that is long, yet the top part can be opened without the spring element touching the inner surface of the container body.
The length of the spring element according to this embodiment has the advantage that the spring element has an increased travel, resulting in a situation in which tolerances in the products, e.g. tolerances in the thickness of the tablets, can be easier accommodated for and the closure cap can be used for a larger range of different products, e.g. different thicknesses of tablets. This has the advantage that a reduced number of different lengths for the container bodies can be used in order to accommodate different products, or that a larger range of products can be accommodated in a given range of lengths of container bodies.
In a preferred embodiment, the spring element is shaped in the form of a single band, extending from a position substantially opposite the position of the hinge, looping around the outside of the desiccant chamber and extending back to the top part in a position likewise substantially opposite to the hinge, wherein the single loop also extends beyond the extension orthogonal to the surface of the top part, and in particular substantially beyond the end face of the desiccant chamber.
Further advantages, details and characteristics can be derived from the following description of embodiments of the invention by means of exemplary drawings.
The invention will be explained below in more detail with reference to the Figures.
In the drawings:
In the following description, like elements are indicated by identical reference numerals and repeated description of the respective elements is omitted.
The closure cap 3 includes a ring part 30 which is fixedly connected to the container body 2, and a top part 32 which is connected to the ring part 30 via a hinge 34 and which is pivotable about the hinge 34. The hinge 34 can be a foil hinge, such that the top part 32, the ring part 30 and the hinge 34 can be made in one piece.
The top part 32 includes a sealing skirt 36 which has an outer diameter which is dimensioned to sealingly engage with the opening 20 of the container body.
A desiccant chamber 38 is integral with the top part 32 and extends perpendicular to the general extension of the top part 32, which is schematically shown as the top surface 320. In particular, the desiccant chamber 38 extends in the same direction as the sealing skirt 36. The desiccant chamber 38 serves to accommodate a desiccant, for example a silica gel, calcium chloride, a molecular sieve, other drying agents or any mixtures thereof.
The drying agents that are to be received in the desiccant chamber 38 serve to remove moisture from the inside of the container body 2 in order to keep the products inside the container body 2 dry. This is of relevance in order to increase the shelf life of the products and in order to preserve the products even if the container or the closure cap were slightly moisture permeable and/or if some moisture was introduced during the filling of the container. The provision of the desiccant chamber is also of relevance when a consumer opens the container 1 in order to remove a product and then recloses the container. Repeated opening and closing of the container may introduce substantial amounts of moisture into the inside of the container.
A spring element 4 for pre-tensioning products received in the container body 2 extends from the top part 3 in a single loop. In particular, the spring element 4 is made in the form of a single leg or single band extending from the top part 32 in a single loop, basically around the desiccant chamber 38 and back to the top part 32. At the same time, the spring element extends in a direction perpendicular to the general plane of the top part 32, i.e. in the same direction as the desiccant chamber 38 as well as the sealing skirt 36. However, the spring element 4 extends substantially beyond the end face 380 of the desiccant chamber 38.
The spring element 4 comprises a first base portion 40 and a second base portion 42 which are both situated at the top part 32. Both base portions 40, 42 are situated between the outer diameter of the desiccant chamber 38 and the inner diameter of the sealing skirt 36. The first base portion 40 and the second base portion 42 are both situated in a single sector of a circle that has a radial extension of less than 90 degrees. The two base portions 40, 42 are situated in a sector opposite to the sector of the top part 32 in which the hinge 34 is situated.
In a further embodiment, which is not shown, it is contemplated that the base portions 40, 42 are situated on the end face 380 of the desiccant chamber 38, or on the end face 360 of the sealing skirt 36. It is even contemplated integrating the sealing skirt 36 and the desiccant chamber 38 such that the outer wall surface of the sealing skirt 36 has the function of sealingly engaging with the inner wall of the container body 2 and the inner wall surface of the sealing skirt 36 defines the desiccant chamber.
The spring element 4 has, thus, as it also extends around the desiccant chamber 38, a shape in which it is basically bent backwards towards the hinge 34. In particular, the spring element 4 is substantially bent about the hinge axis.
Due to this bending of the spring element 4 about the hinge axis, as can be seen in
In other words, the extension between the general extension of the top part 32 and the lowest tip 44 of the spring element 4 can be increased due to the asymmetric position of the lowest tip 44. Compared to the common arrangements in which the spring elements are e.g. concentric or conic, a substantially longer spring element can be provided.
Accordingly, the desiccant chamber 38 can also be made longer and, thus, includes a larger volume than in conventional arrangements.
The substantially longer spring element results in increased travel of the spring element such that different products or larger tolerances can be accommodated for using the same configuration of closure cap 3 and container body 2. In other words, the number of different lengths for container bodies used for a selected number of products can be lowered, or the number of different products that can be accommodated in the container can be increased when using the closure cap according to the embodiment described.
As the spring element 4 extends, in an axis perpendicular to the top surface 320 of the top part 32 and concentric to it, substantially around the desiccant chamber 38, the desiccant chamber is easily accessible even if the spring element 4 is present.
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Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2008/055994 | 5/15/2008 | WO | 00 | 11/15/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2009/138128 | 11/19/2009 | WO | A |
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