DE10218144B4 - Textured container - Google Patents

Abstract

Container, in particular Cans or bottles whose walls are shaped analogous to the Beulstrukturierung are over by Beulfalten or Faltstege connected regular surfaces, the quadrangular, rectangular or crest-shaped could be, as a trough-shaped Bumps are formed, and wherein the Beulstrukturierung means of internal support element is done, characterized in that the curves of Beulfalten or folding bars run a little flatter than they are through would give the Beulstrukturierung.

Description

The Invention relates to containers with structured wall, in particular beulstrukturierte container, such as Bottles and cans, in particular of plastic or thin sheet, where the container obtains a high dimensional stability and the structural folds, such as buckling folds or creases, under local pressure loading from the outside are dimensionally stable against permanent buckling and the structure troughs the bumps or vault structures dimensionally stable are internal pressure load.

such structured containers For the purpose of saving materials in many areas Technology, such as packaging and drums needed. With these products is a high strength or stiffness at stacking load and Implosionsbelastung despite thinner Wall thickness desired to Save material, transport weight and waste, and further the performance characteristics, such as a high grip stiffness and stability to internal pressure to ensure.

Methods are known for buckling deformation of webs of material and films in which webs or foils obtain a uniform, offset buckling structure preferably based on self-organization by supporting curved walls on the inside by support rings or support spirals and subjecting them to external overpressure or internal negative pressure ( DE 43 11 978 C1 . DE 44 01 974 A1 ). The processes occurring here are complex and are therefore explained in more detail below: self-organization of the Beulfalten is a process to be understood in which the material folds multidimensional almost independently such that its dimensional stability improves. This shaping process of the Beulstrukturierens takes place for example in such a way that the curved, thin-walled material, the inside by spaced-apart, rigid support rings or by a helical, rigid support spiral ( DE 25 57 215 A1 ) becomes unstable due to external pressure. The instability triggers a multi-dimensional folding, and this results in staggered, square Beulstrukturen. If instead of the rigid support elements flexible support elements, for example made of rubber, which can move during the Beulstrukturierens in the axial direction on a core used, arise about hexagonal Beulstrukturen. These hexagonal Beulstrukturen can also be produced by hexagonal, rigid support elements. A minimum of plastic deformation of the web then occurs; if the material can deform in free self-adjustment. For this purpose, in the deformation of the material web, by means of a hydraulic or elastic pressure transmission, the Beulstruktur only specified by means of support elements, so that these support elements yield in the course of structuring that the structural folds take over the function of the support elements themselves, and that the Beulfalten and Beulmulden in free Self-adjustment take such an optimal shape that they can withstand the prevailing deformation pressure with minimal plasticization ( EP 0 888 208 B1 ). In this case, for example, crest-shaped structures arise, in which approximately s-shaped Beulfalten each include a Beulmulde, and created in this way a coat of arms figure.

The staggered buckling structure can be produced in plastic bottles by making models for molded parts for extrusion blow molding of plastics ( DE 43 11 978 C1 ).

in the The difference to self-structuring is forced structuring seen. In doing so, the material is e.g. by pressing or deep drawing in wide limits imposed on any structures that are not can adjust freely.

Furthermore It is also known with presses or similar tools structures into the material, which also by mere suggestion form after the process of self-structuring.

It is also known a method in which material webs from both sides ( DE 196 34 244 A1 ) or in which larger bumps are provided with small bumps ( DE 196 51 937 A1 ).

Finally, a large-volume industrial packaging container is known in which, for example, a sheet drum or lidded drum made of sheet steel or plastic is provided with roll beads and vault structure elements in order to achieve a higher rigidity against underpressure formation ( DE 100 21 117 A1 ). However, the advantages of this large-volume packaging container are limited in particular to the case of safety barrels, which experience a considerable internal negative pressure during filling with hot products. The roll beads contribute more to the dimensional stability than the arch structures.

They are from the EP 0 888 208 B1 Methods are known in which hexagonal or offset quadrangular or crest-shaped supporting elements are used in Beulstrukturieren example, for cans whose geometry corresponds to the geometry of freely adjusting Beulfalten. In the free setting a bulge must be stimulated only to develop independently. The self-adjusting structures are known as self-structuring and are considered as a bionics example. These buckling structures already impart a high isotropic stiffness to the structured material. The return behavior of this bulge However structured container was still felt to be in need of improvement. Therefore, it is an object of the present invention to improve the Behälterwandausformung such that the resilience of such containers shows a significant improvement.

Is solved this task in that the curves of Beulfalten or Faltstege a bit flatter become as they would result from the Beulstrukturierung.

Surprisingly has been shown by these shallower curves of the Faltstege or the hollows of Beulstrukturen a permanent kinking stability of the convex Faltstege also with external local Can achieve pressure load.

The so structured hollows and Faltstege remain at internal overpressure so dimensionally stable or form-elastic that they do so at elevated internal pressure can shape something, but at pressure relief, as when opening the container again in their original one Return shape. Furthermore, one can optionally achieve that the convex folding webs of Structures under local external pressure, as if gripping, while briefly something can buckle, however after releasing the container, the external pressure load is lifted again, immediately back to its original Situation to jump back and therefore do not bother. The cause of this lies in the improved elastic behavior of the beulstrukturierten Through the wall of the container slightly gentler curves of the folding bars and hollows of the structures.

A Another embodiment of the structured container according to the invention is that the hull of the container get a slight waist, so that there the cross-section is slightly reduced. In this way The elastic restoring forces can be additionally improved.

in the The following are examples of some embodiments of the structured container according to the invention shown.

1 shows the top view of a 0.5 liter bottle of PET plastic in the scale 1: 1.

2 shows the partial section AA of the PET bottle 1 in the scale 2: 1.

3 shows the partial section BB of the PET bottle 1 in the scale 2: 1.

4 shows the sub-step AA of the PET bottle 1 in the scale 2: 1, whereby the curves of the hollows are gentler.

5 shows the sub-step BB of the PET bottle 1 in the scale 2: 1, with the curves of the folding bars are made gentler.

6 shows the perspective top view of a tin of high-strength, very thin tinplate.

7 shows a section of the structure field 6 with the partial step AA and the partial section BB.

8th indicates a step out of the structure field 6 with the partial section AA and the sub-step BB, wherein the curves of the folding bars (partial section AA) and the troughs (partial section BB) are made gentler.

The exemplary embodiments are explained in greater detail below by way of example:
The bottle body ( 1 ) of the 0.5 liter PET (polyethylene terephthalate) drinking bottle ( 2 ) with a diameter of 65 mm and a height of about 203 mm contains a buckling structure that contains eight hexagonal structures on the circumference and four rows of structures with bulge widths (SW) of 25 mm in the vertical direction. This structural arrangement corresponds to the buckling structures resulting from self-assembly. But there are also six to ten Beulstrukturen on the circumference and also in the vertical direction different structure rows conceivable. The upper and the lower zig-zag course of the structure folds adjoins directly to the smooth body part and thus increases the stiffness and further the elastic restoring forces, although here the curves can be pronounced.

The sub-step AA in 2 gives for example dimensionally stable hollows with a radius ( 3 ) R of 34 mm in the vertical direction.

In 3 is the radius ( 4 ) The trough in the circumferential direction almost infinitely, ie here the wall is almost straight, so that the blown bottle can be easily removed without so-called undercut from the two-part blow molds again. The radius ( 5 ) of the folding bars here is 3 mm.

These 0.5 liter PET bottle is very dimensionally stable; she can, however in the case of unintentional firm gripping or strong impacting of the open bottle at the folding bars in the middle area of the structured Fold the hull so that this Kink does not disappear again.

In the event that these conceivable undesirable kinks are to be avoided in any case, are in step AA in 4 the lowering right curves of the hollows ( 6 ) with a radius of 50 mm. At the same time in 5 also the radius of the folding web ( 7 ) with R of 4 mm gentler. However, the stiffness of the bottle is slightly reduced by the gentler curves.

The selected radii for the stiff 0.5 liter PET bottle after 2 and 3 and for the more gentle rounded 0.5 liter PET bottle 4 and 5 are exemplary. The optimal radii result depending on the material properties, the wall thickness, the size and depth of the Beulstrukturen and the geometric dimensions of the bottle itself.

In 6 is a tin can ( 8th ) with a diameter of 99 mm and a height of 119 mm. It contains 14 hexagonal buckling structures of key width SW of 22.25 mm on the circumference and 5 structural rows in the vertical direction. With a wall thickness of 0.13 mm by way of example, this structural arrangement corresponds to the buckling structures resulting from self-assembly. However, even with the same wall thickness, ten to seventeen buckling structures on the circumference and also different rows of structures in the vertical direction are conceivable. With larger wall thickness, the number of buckling structures on the circumference reduces to eight to sixteen structures.

In 7 are exemplary the radii of the folding bars ( 9 ) R of 1.5 mm in the section AA and the vertical radii ( 10 ) of the hollows R of 36 mm. These radii result in a high implosion resistance and a high stacking strength for a high-strength tinplate of thickness 0.13 mm from Hoesch Rasselstein with a tensile strength of about 900 N / mm ² .

These Tin can is very dimensionally stable; However, it can be unintentional firm gripping or very strong abutment of the box on the folding bars buckle in the area of the structured hull so that this Kink does not disappear again.

In the event that these conceivable undesirable kinks are to be avoided in any case, are exemplified in 8th in sub-step AA the radius ( 11 ) of the folding webs R of 2.0 mm and in the sub-step BB, the vertical curves of the wells ( 12 ) with the radius of 50 mm. However, the form-rigidity of the can is somewhat reduced by these gentler curves.

The selected radii for this can after 7 and 8th are exemplary. The optimal radii are obtained at other doses depending on the material properties (hardness and flow curve), the wall thickness, the size and depth of the Beulstrukturen and the geometric dimensions of the box itself.

The forms according to the invention can be produced in different ways:
When pressing and pulling various devices can be used. All devices have in common that there is a shape that includes an image of the desired contour. The material is pressed and / or pulled into the mold.

The Pressing and drawing involve step-by-step procedures.

Also continuous processes are possible. To the continuous Forming heard the rolling. In structure-forming rolls, two rolls are used as a pair of rolls provided, the corresponding surfaces are indeed round, but otherwise the corresponding tool surfaces correspond in a press.

The Pressing and pulling can for the production of a flat Starting material to be used, which then to a bottle, can or a container is processed. The Pressing and pulling can also be used to work in one step already a hollow body to produce that forms part of a bottle, can or container. The rolling allowed, in contrast to pressing and pulling only the Production of a flat Starting material for Flanges, cans or containers.

On This way can not only sheet metal but also processed plastic become. Compared to sheet metal, however, the plastic has a very big one elastic deformation, which is very cold processing difficult. Therefore, such deformation occurs mainly in Plastic, often even with sheet metal, in the heated Status.

Of the Plastic can be by heating so soften that he by blowing into the desired shape depressed can be. Then one speaks of the form bubbles.

Plastic also opens up another processing option:
The plastic can be brought into the mold in the molten state. In the mold, the plastic adapts easily under pressure to the predetermined contact surfaces. Upon subsequent cooling, the plastic retains its shape.

The plastic melt is usually produced with an extruder. The extruder can also ge be used to produce the required melt pressure for the process.

Of the Melt pressure can also be generated differently.

Similarly the melt can be generated differently.

Otherwise there there are metals, such as aluminum, which are alike how to process plastic as a melt.

Claims (6)

Container, in particular cans or bottles whose walls are formed analogous to the Beulstrukturierung by connected via Beulfalten or folding webs regular areas that may be quadrangular, rectangular or crested, are formed as trough-shaped bulges, and wherein the Beulstrukturierung is done by means of internal support element, characterized characterized in that the curves of the Beulfalten or folding bars are made somewhat flatter than they would result from the Beulstrukturierung. container according to claim 1, characterized in that the curves the Beulfalten or Faltstege be formed so shallow that the Beulfalten be generated with an inner radius, the between 5% and at least 20% larger, than the inner radius that results in self-structuring. container according to claim 1 and 2, characterized in that at the same time Bumps with a curvature radius (R), which is between 5% and at least 20% larger as the curvature radius (R), which results in self-structuring. container according to claim 1, characterized in that it is made of plastic is produced by blow molding. container according to claim 4, characterized in that the diameter about 65mm, wherein there are 8 bumps on the circumference and in the longitudinal direction 4 bump rows on top of each other are located. container according to one of the preceding claims, characterized by a Sidecut.