HUP0900705A2 - Curveable flexible bottle - Google Patents

Description

((Species of frog

704671/JA

Bendable flexible bottle

The invention relates to a bendable flexible bottle, which has a self-closed, flexible side wall defining an internal space, forming a body of rotation, a neck connected to the side wall of the bottle, provided with a spout, and a base closing the bottle. At least one pleat is formed on the side wall perpendicular to the axis of rotation of the bottle. Each pleat is formed by two shells forming an obtuse angle with each other, where the surface of the shells is of different size, and the shells meet each other along the edge. Each pleat is connected to the other pleat or to the side wall by hinge edges made of its own material.

More and more plastic or plastic-coated containers or bottles are becoming known for storing various liquids, especially soft drinks. So-called PET bottles made of polyethylene terephthalate are particularly widespread. More and more of these PET bottles are produced every year, and their reuse or recycling after use is very difficult. The reuse of deposit-based or so-called returnable PET bottles is a costly and often unprofitable activity due to strict food laws, and is therefore increasingly being pushed into the background. Single-use, disposable bottles must be collected selectively or sorted for recycling. Due to the large volume of used bottles, their storage and disposal also cause problems, so it is advisable to collect and store them compressed or flattened.

Devices are known from the prior art that compress or shrink the bottle mechanically or by heat. These solutions have only been used to a limited extent in practice due to their equipment requirements, cost, and sometimes difficulty in use.

Plastic bottles which can be folded after use are also known from the prior art. This is described, for example, in EP 0 408 929 B1. The volume of these bottles can only be reduced to a relatively small extent and they are generally not suitable for storing carbonated drinks.

The side walls of plastic bottles can also be provided with a concertina-like ribbing consisting of adjacent folds in a known manner. In these bottles, each fold consists of two opposing surfaces. By applying relatively slight axial pressure to the bottles, the surfaces of the folds can be pressed into each other, which can reduce the volume of the bottles. By compressing the bottle, the internal volume of the bottle can be reduced in accordance with the consumption of the beverage inside, and after the bottle is completely emptied, the empty bottle can be compressed to a very small volume.

US Patent No. 4,492,313 discloses a collapsible bottle. The side wall of a plastic bottle suitable for storing food and soft drinks is pleated like an accordion. The pleated wall is made of folds having a larger and a smaller surface connected to each other. The pleated side wall can be semi- or even completely compressed without external means. In order to prevent the compressed side wall from springing back to its original, uncompressed state, a smooth-walled cup is fitted to the bottom of the bottle, the inner diameter of which is substantially the same as the largest diameter of the pleated side wall in the uncompressed state of the bottle. When the bottle is compressed, the diameter of the compressed folds of the pleated wall increases somewhat, the folds lie on the wall of the cup, and the friction between them prevents the folds from springing back to their original state.

US Patent No. 5,584,413 describes a plastic, pleated-walled bottle that can be compressed into a small volume for storage and transport. The bottle has a pleated side wall like an accordion, a neck connected to the side wall, and a base. The base has a rim formed on the inner surface into which a groove formed on the neck can be snapped when the bottle is compressed.

US Patent No. 5,002,193 relates to a collapsible bottle equipped with a gripping device. The neck and base of the bottle are connected by a side wall folded in an accordion-like manner. The pleats are formed by conical shells of smaller and larger surfaces which, when compressed axially, press into each other with a decrease in the volume of the bottle. A groove is formed between each pleat, the diameter of which is smaller than the diameter of the meeting edge of the pleats. Rings of a gripping device are inserted into two non-adjacent grooves of the bottle, where the rings are connected by a tab. The gripping device prevents the side wall of the bottle from being compressed in the area between the rings, while also preventing the compressed side wall from springing back to its original state below and above the gripping device.

US Patent No. 6,598,755 relates to a disposable, collapsible bottle. The bottle has a side wall formed in an accordion-like manner with a plurality of adjacent pleats. The pleats have two surfaces of different sizes, which are located opposite each other. Of the surfaces forming the pleat, the smaller surface is curved and the convexity of this surface is directed towards the larger surface adjacent to it, opposite the direction of compression. In order to maintain the stable position of the compressed pleats, the edges of the pleats in contact with each other and the edges in contact with the side wall are reinforced with a cylindrical ring portion.

A collapsible container is disclosed in US Patent No. 3,301,293. The container has a flexible, accordion-like ribbed wall. The container can be partially or completely compressed by compressing some or all of the ribs, where protrusions and recesses formed on adjacent ribs snap together to hold the ribs together and the container in their compressed position.

The disadvantage of the solutions cited is that the compressed folds are not able to maintain their compressed state, i.e. the folds have only one equilibrium state. After compression, the bottles spring back to their original state after a shorter or longer period of time. The solutions known from the prior art, detailed above, aim to use additional elements or structures that prevent the springs back of folds or folds that have already been compressed.

The aim of our invention is to develop a bendable flexible bottle that overcomes the disadvantages detailed above. The bottle according to our invention maintains its compressed or bent position without any additional device.

The aim is achieved by designing the flexible bottle presented in the introductory part in such a way that the force-locking self-retaining fold has two stable equilibrium positions, and the fold can be brought from one equilibrium position to the other equilibrium position by bending the neck and/or base of the bottle perpendicular to the axis of rotation and by pressing or pulling it in the direction of the axis of rotation, thereby snapping one of the smaller surface areas under or out of the other larger surface area area along at least a part of the rim.

The invention is applicable to plastic bottles, primarily PET bottles. According to their usual use, such bottles are suitable for storing soft drinks, including carbonated soft drinks. The bottle has a side wall forming a self-closed body of rotation, which can be closed with a neck at the top and a base at the bottom. The body of rotation is in the most preferred embodiment circular in cross-section, but it can also be oval, polygonal with rounded corners or other similar cross-sections.

According to a preferred design of the bottle, the side wall is connected to the neck and the base by a transition that does not form a stress accumulation area. The neck of the bottle may have a truncated cone, a spherical slice or even a flat surface, as is known in practice, which ends in a spout concentric with the side wall. The spout has a threaded end suitable for receiving and fixing the closure cap. The design of the neck and the spout may also be different. A closure cap or other similar closure device may also be used to close the spout. The base of the bottle may be flat or a convex surface starting from a flat circular ring.

The side wall of the bottle is pleated in an accordion-like manner, perpendicular to the axis of rotation. The term perpendicular here means not only a pleated shape at exactly 90° to the axis of rotation, but also minor deviations resulting from manufacturing inaccuracies, i.e. the pleats must be substantially perpendicular to the axis of rotation. The pleats are formed by two facing shells. According to a preferred embodiment of the invention, the first shell closer to the neck has a larger surface area than the second shell opposite it. The first shell and the second shell form an obtuse angle with each other. According to a preferred embodiment, the obtuse angle is between 91 and 125 degrees. The pleat formed by the shells is connected to the other pleat or to the side wall of the bottle by forming a hinge edge, and the shells are connected to each other by forming a rim. The hinge edge or rim is formed by an angular bending or curved transition of the pleat material along which the casings can turn. According to a preferred embodiment of the invention, the hinge edge has the same wall thickness as the side wall or the pleats. According to another preferred embodiment, a groove is formed in the hinge edge by easing the side wall, which groove facilitates the bending of the pleats.

According to a preferred embodiment of the invention, the first and second shells meet along a sharp edge. According to a further preferred embodiment of the invention, the first and second shells meet along a rounded edge.

At least one pleat is formed on the side wall of the bottle. In order to optimally achieve the intended purpose, it is advisable to form several pleats on the side wall. An embodiment in which at least two-thirds of the side wall is pleated is preferred. This embodiment makes it possible to significantly reduce the volume of the bottle by compressing it to a large extent. Pleats of the same size and shape can be formed along the side wall of the bottle, but the scope of the invention also includes embodiments in which the size and/or shape of the pleats varies along the axis of rotation. By choosing the size and location of the pleats, the shape and external appearance of the bottle can be changed to a wide extent.

According to a preferred embodiment of the invention, both sides of the pleat are frustoconical, i.e., they are bounded by a straight line in their cross-section. The sides may also take on other shapes, such as a barrel shape. In a further preferred embodiment of the invention, at least one of the sides is bounded by a curved line in its cross-section.

The flexible plastic material of the bottle and the inventive design of the pleats allow for compression and snapping along the edge of the pleats. In the traditional accordion shape, the volume of the bottle is changed only by compressing or bending the flexible material of the pleats. In our invention, the pleats are self-supporting and have two stable equilibrium positions. Under the influence of tensile or compressive or bending stress, the pleats not only bend along their edges, but also snap from one extreme position to another extreme position and remain stable there. If the pressure in the direction of the axis of rotation is also accompanied by bending or tilting in a direction perpendicular to it, then the smaller surface area of the pleat completely or partially snaps under the larger surface area. When snapping occurs, a temporary deformation or stretching occurs in the material, which the flexible material of the bottle is suitable for without any permanent deformation. The snapping can occur along a part of the rim or along the entire circumference. Depending on the degree of snapping, the bottle bends along its axis of rotation or compresses, changing its size. Since each pleat has two stable equilibrium positions, the bottle can assume different shapes between the smallest volume, fully compressed pleat, straight axis of rotation, and the largest volume, fully stretched pleat, straight axis of rotation. Pleats that are adjacent to each other or are further apart can bend and snap in different directions, so the bottle can assume several curvatures in different directions.

To change the shape and/or volume of the bottle, it is therefore necessary to bend and simultaneously pull or press the bottle. By bending the neck and/or the base of the bottle perpendicular to the axis of rotation and pressing in the direction of the axis of rotation, the folds can snap from the stretched equilibrium position to the compressed equilibrium position, and the bottle can be bent or compressed. In the fully compressed state, the folds lie on top of each other and the bottle takes up minimal volume. By bending and pulling in the opposite direction, the volume of the bottle can be increased, or the bottle can be stretched and/or straightened.

The size, number of pleats, and the angle formed by the pleats should be selected according to the size, material, and design ideas of the bottle. The bottle resists lateral external impact and internal pressure well due to the pleated side surface.

The compressed, empty bottle can be bent and stretched to its original shape and volume, and the bottle can be refilled a few times. The reusability is limited by the material of the bottle, meaning that it can be refilled until the material cracks or breaks under the strain.

The invention will be described in more detail below with the aid of drawings. In the drawings,

Figure 1 is a diagram of a bottle according to the invention in its largest volume state, the

Figure 2 is a schematic diagram of a bottle according to the invention in a bent state, the

Figure 3 is a diagram of a bottle according to the invention in its smallest volume state,

Figure 4 is an enlarged sketch of the side wall of the bottle,

Figure 5. is an enlarged diagram of two equilibrium states of a fold, the

Figure 6. An enlarged sketch of two equilibrium states of three folds.

Figure 1 shows a bottle 1 according to the invention in its largest volume, Figure 2 in the bent state, and Figure 3 in the fully compressed state. The bottle 1 is made of PET and has a side wall 2 closed by a neck 3 and a base 4 in a conventional design. A pouring spout 5 is arranged rotationally symmetrically on the neck 3, which is closed by a threaded closure cap in a known manner. The side wall 2 of the bottle 1 is formed with pleats 7 arranged in an accordion-like manner.

Figure 4 shows a detail of the side wall 2 of the bottle 1, only the part provided with the pleats 7. Each pleat 7 meets the non-pleated part of the side wall 2 and each other along the hinge edges 10. The hinge edges 10 are located in the smallest diameter of the bottle 1. Each pleat 7 has two conical edges 8, 9, which meet each other in the largest diameter of the pleats 7, along the edge 11. The pleats 7 and correspondingly the edges 11 are perpendicular to the axis of rotation 6 of the bottle 1. The surfaces of the edges 8, 9 are of different sizes, the first edge 8 has a larger surface area than the second edge 9. The edges 8, 9 make an angle of a= 130° with each other in this embodiment.

The bottle 1 can be brought from its maximum volume, fully extended state to a bent or compressed state by bending the bottle 1 in the direction of arrow “B”, perpendicular to the axis of rotation 6, and then pressing it in the direction of arrow “A”. Depending on the degree of bending or pressure, according to the kinematics detailed later, the second layer 9 of each pleat 7 snaps partially or completely under the first layer 8, and the bottle 1 is brought into a bent state corresponding to Figure 2 or a compressed state corresponding to Figure 3. By snapping the second layer 9 under the first layer 8, the pleat 7 moves from one stable equilibrium position to the other stable equilibrium position. The pleat 7 maintains this equilibrium position as long as the bottle 1 is not subjected to further bending and stretching. The envelope 8, 9 of the pleats 7 is of a force-locking self-supporting design, i.e. the shape and size of the pleats are chosen so that their stable equilibrium position is changed only under the influence of a certain external force or bending moment. If this certain external force or moment is greater than the internal load acting on the side wall or the pleats during normal use of the bottle, then we can avoid the pleats 7 from bouncing back from their compressed equilibrium position to their other equilibrium position during normal use of the bottle - even in the case of a carbonated soft drink.

The bottle 1 can be bent or compressed to different degrees depending on the degree of bending and compression. Since each pleat 7 has two stable equilibrium states, by snapping in one selected pleat or group of pleats 7 while keeping others in an uncompressed position, different spectacular shapes of the bottle 1 can be created. By pulling the bottle 1 in the direction opposite to the arrow “A” or by bending it back perpendicular to the axis of rotation 6, the second layer 9 of the pleats 7 can be snapped out from under the first layer 8 and the bottle 1 can be brought into the larger or largest volume state.

Figure 5 shows a detail of the side wall 2 of a bottle 1 containing two folds 7. The figure shows the kinematics of the snapping of one fold 7 from one stable position to the other stable position in more detail, i.e. in which the uppermost fold 7 of the bottle 1 has snapped into its second stable position, while the next fold 7 has remained in its original stable position. One equilibrium position of the envelopes 8, 9 of the folds 7 is shown with a continuous line, while the other equilibrium position is shown with a dashed line. The angle enclosed by the first envelope 8 and the second envelope 9 in this case is a’ = 120°. Under the influence of bending and compression, the elastic material of the bottle 1 deforms without permanent deformation so that the hinge edge 10 slides along the axis of rotation 6 to the position 10’, while the rim 11 snaps along a circular arc 12 to the position 11’.

Figure 6 shows the side wall 2 of a bottle 1 in which the angle between the first 8 and the second 9 is a” = 95°. The figure shows two stable equilibrium positions of three pleats 7, with one stable equilibrium position indicated here by a continuous line and the other by a dashed line. In the first stable equilibrium position, the 8, 9, and 10 shells are connected to each other and to the side wall 2 along the hinge edges and edges 11. After bending and compressing the bottle 1, the hinge edges 10 slide into position 10”, while the edges 11 turn into position 11 along a circular arc 12, and the 9 shells snap into position 8. The figure clearly shows the reduction in size of the bottle 1 in the direction of the axis of rotation 6.

Under the influence of opposite stress, one, another or even all 7 folds can be reset from their snapped equilibrium position to the other equilibrium position. The reduction or increase of the volume of the bottle 1 and the corresponding snapping of the folds 7 from one equilibrium position to the other equilibrium position can be carried out a limited number of times depending on the properties of the material. In other words, the bottle according to the invention can be refilled a limited number of times. After too much bending or compression, the bottle can crack or break along the hinge edges or the edges. In this case, the bottle can be selectively collected and discarded after being compressed to its smallest volume.

The bendable flexible bottle, while retaining the positive properties of previously known bottles, offers several possibilities for storage and reuse. On the one hand, its volume can be reduced to a size corresponding to the level of the liquid stored in it. In addition to restoring the original volume after emptying,

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refillable in a limited number of cases. If refilling is not desired, the bottle can be easily compressed to a small size and, remaining in this state, can be collected and stored. A further advantage of the bottle according to the invention is that, in addition to its simple design, it can take on many different, varied shapes.

Claims (9)

Patent claims 1. A bendable flexible bottle with - it has a self-closed, flexible side wall defining an internal space and forming a body of rotation, - it has a neck connected to the side wall of the bottle, equipped with at least one pouring spout, and a base closing the bottle, - at least one pleat is formed on the side wall perpendicular to the axis of rotation of the bottle, - each fold is formed by two sheets forming an obtuse angle with each other, where the surface of the sheets is of different size and the sheets meet each other along the edge, and each fold is connected to the other fold and the side wall by hinge edges made of its own material, characterized in that - the force-locking self-holding fold (7) has two stable equilibrium positions, and the fold (7) can be brought from one equilibrium position to the other equilibrium position by bending the neck (3) and/or base (4) of the bottle (1) perpendicular to the axis of rotation (6), and by pressing or pulling it in the direction of the axis of rotation (6), thereby snapping the smaller surface area (9) under the larger surface area (8) along at least a part of the rim (11, 11', 11"). 2. Bottle according to claim 1, characterized in that the bottle (1) is designed as a body of revolution with a circular, oval, polygonal cross-section with rounded corners. 3. Bottle according to claim 1, characterized in that the folds (7) are formed on at least two-thirds of the side wall (2) of the bottle (1). 4. Bottle according to claim 1, characterized in that the folds (7) on the side wall (2) of the bottle (1) are of the same size and shape. 5. Bottle according to claim 1, characterized in that the folds (7) on the side wall (2) of the bottle (1) are formed in different sizes and/or shapes in the direction of the axis of rotation (6). 6. Bottle according to claim 1, characterized in that both sides (8, 9) of the fold (7) are delimited by a straight line in cross-section. 7. Bottle according to claim 1, characterized in that at least one of the sleeves (8, 9) forming the fold (7) is delimited by a curved line in its cross-section. 8. Bottle according to claim 1, characterized in that the surface of the first shell (8) closer to the neck (3) of the bottle (1) among the shells (8, 9) forming the fold (7) is larger than the surface of the second shell (9). 9. A bottle according to claim 1, characterized in that the angle (a) enclosed by the sleeves (8, 9) forming the pleats (7) is between 91 and 125 degrees.