Method for protecting a container, and container protected in this way

The invention relates to a method of protecting a container (1) against impacts, the container presenting a body (2) that is terminated at one end by a bottom and at the other end by a transition portion (4) leading to a neck (3), the method comprising the steps of:

The invention relates to a method of protecting a container against impacts, and to a container protected in this way.

BACKGROUND OF THE INVENTION

In certain fields, in particular in pharmacy, use is made of liquid-containing glass bottles.

Dropping such a bottle or allowing it to strike an obstacle often ends in the bottle breaking. Furthermore, transporting such bottles requires certain precautions to be taken and often imposes the use of individual packages.

Various solutions have been proposed for protecting such a bottle from risks associated with impacts or being dropped. For example, document WO 2011/006089 describes a bottle that is completely covered in a sleeve of elastomer material. Document US 2010/0072162 shows a glass bottle covered in protection comprising two half-shells fitted around the bottle. Document CN 201912469 shows a baby's bottle fitted with a bottom cup engaged on the bottom of the bottle and with a ring that is positioned on the screw thread that receives the bushing carrying the teat.

OBJECT OF THE INVENTION

The invention seeks to provide an alternative to known methods of protecting containers.

SUMMARY OF THE INVENTION

In order to achieve this object, the invention provides a method of protecting a container against impacts, the container presenting a body that is terminated at one end by a bottom and at the other end by a transition portion leading to a neck, the method comprising the steps of:putting a bottom cup into place on the container to cover the bottom of the container and to project laterally from the body of the container;putting a top cup into place on the container pressing against the transition portion of the container in order to project laterally from the body of the container;covering the assembly with the help of a sleeve of heat-shrink material; andheat-shrinking the sleeve.

Thus, the cups are secured to the bottle by a sleeve that has been subjected to heat-shrinking, and they constitute bumpers that contribute to protecting the bottle and that limit the risk of the bottle breaking. The cups are held firmly on the bottle by the sleeve, which may also contribute to damping impacts, where appropriate. Furthermore, in the event of the bottle breaking, the sleeve serves to prevent pieces of glass from being dispersed.

Furthermore, the cups are held securely and cannot escape from the container.

In addition, the cups change the shape of the container, making it easier to hold in the hand. A user can thus manipulate the container more easily, thereby implicitly reducing any risk of said container being dropped. This is particularly true when the body of the container is in the form of a circular cylinder, where the cups “break” the line of said body.

The cups are preferably made of deformable material that is suitable for providing effective protection. Also preferably, the cups co-operate with the container to define respective annular volumes full of air.

In a particular embodiment, the body of the container is in the shape of a circular cylinder.

As a result, the body of the container is simple in shape, thereby making it easier to clean.

DETAILED DESCRIPTION OF IMPLEMENTATIONS OF THE INVENTION

With reference toFIG. 1, the method of the invention consists in preparing a container, in this example a glass bottle1comprising a body2that is substantially circularly cylindrical and terminated at its bottom end by a bottom, together with a neck3connected to the body1by a transition portion4.

The bottle1is thus provided with a bottom cup5that is engaged on the bottom end of the bottle in order to cover its bottom, and a top cup6that is engaged on the bottle so as to bear against the transition zone of the bottle. It can be seen that the cups project from the side wall of the body2so as to form dampers for protecting the bottle1in the event of impacts thereagainst.

With reference toFIGS. 2aand 2b, the top cup6is generally rounded in shape and presents a top opening (of square shape in this example) for passing the neck3of the bottle1. The top cup6has a first peripheral stiffener8in the form of a circular bead that projects from the inside face of the top cup6so as to bear against the wall of the bottle1, and a second peripheral stiffener in the form of a skirt10that terminates the top cup6and that defines a terminal lip that comes into contact with the wall of the bottle1. The top cup6is generally rounded in shape, projecting considerably from the side wall of the body of the container and presenting an outwardly convex surface to the outside that is suitable for coming into contact with any obstacle that the bottle might strike.

With reference toFIGS. 3ato 3c, the bottom cup5has a bottom11with three bosses12to enable the bottom11of the bottom cup to come into abutment against the bottom of the bottle1. The bottom11is associated with a collar13terminated by a skirt14that defines a terminal lip coming into contact with the wall of the bottle1. In this example, the bottom11is precut to allow a tab15to be released and folded, which tab may be used for example for hanging up the bottle1. The bottom cup5is generally rounded in shape, projecting considerably from the side wall of the body of the container and presenting an outwardly convex surface to the outside that is suitable for coming into contact with any obstacle that the bottle might strike.

As can be seen inFIG. 4, the cups5and6are of shapes that co-operate with the wall of the bottle1to define annular volumes16that are full of air and that participate in absorbing impacts.

After the cups have been fitted on the container, the assembly is covered in a sleeve20of thermoformable material by engaging the sleeve20over the assembly (vertical arrows). In this respect, it should be observed that the outside shapes of the cups facilitate passing and guiding the sleeve20around the bottle. The thickness of the sleeve20is exaggerated in the figures, and in reality it is no more than a few micrometers.

Thereafter the sleeve is heated so as to cause it to shrink. As shown inFIG. 5, the sleeve20then fits closely around the outside shape of the assembly and holds the cups firmly against the bottle. It is ensured that the sleeve covers the flanks of the cups5and6to a substantial extent. Optionally, the sleeve may also cover the neck fitted with its stopper, in order to provide protection against opening. The sleeve should then preferably be provided with circumferential precutting substantially at the base of the neck so as to allow the stopper to be released, while retaining the remainder of the sleeve around the assembly.

The sleeve then performs several roles. In addition to its role of providing cohesion for the assembly constituted by the bottle and the cups, the sleeve also serves, in the event of the bottle breaking, to prevent the pieces of glass from dispersing. In addition, the sleeve is pressed tightly against the cups, thereby ensuring that the assembly is leaktight, even if the bottle leaks. Finally, the sleeve may itself be made of a material that is flexible so as to participate in absorbing impacts.

A bottle that has been prepared in this way can be stored with other bottles in a common package, it being possible for the cups of the bottles to touch one another and strike against one another without risk.

By way of example, the sleeve may be made using an oriented film based on styrene, e.g. the film referenced OPS TF/095 XB from the supplier Sleever International. This film is highly transparent (which makes it possible to monitor the level of liquid in the bottle, providing the bottle is itself transparent), and it is also a good medium for printing. Its maximum shrinkage ratio exceeds 75%.

Also by way of example, the cups are made by injection-molding a resin, e.g. a low density polyethylene resin. The cups are preferably made of deformable material.

Naturally, the invention may be subjected to numerous variants. In particular,FIG. 6shows a bottle fitted with a top cup60presenting tongues61that extend towards the neck and enable the cup to be clipped under the rim of the neck of the bottle, such that the top cup is held prisoner on the bottle, even before the bottle is covered by the thermoformable sleeve. In this example, the top cup presents longitudinal stiffeners62(one of them being visible in this figure by transparency) that bear against the wall of the bottle in order to ensure that there is a volume of air between the cup and the bottle.

The invention is not limited to the above description, but on the contrary covers any variant coming within the ambit defined by the claims.

In addition, although the cups are circular in outline, it is possible for at least one of the cups to be given an outline that is polygonal in order to make it easier to wedge containers that have been prepared in this way when they are in a common package, or in order to prevent any turning of the container.

Although the invention is particularly intended for protecting containers made of glass, the method of the invention could naturally be applied to other containers, whenever it is important to give them increased ability to withstand impacts.