DE202007015564U1 - Cup-shaped container - Google Patents

Abstract

Bowl-shaped container (1) preferred for Food, with a preferably sealable upper edge (6) around a substantially rectangular, preferably square opening (5) with rounded corners (7) and an oval or circular base (2), which is produced by deep drawing, preferably of aluminum, the transition between the stand area (2) and the side walls (8) arcuate is formed and in the region of the container corners (7) has a smaller curvature as in the area of the side walls, characterized in that in the meridian section through the corner (7) the transition from the stand area (2) to the conical surface of the rounded corner (7) substantially the shape of a circular arc section having a grinding angle (α) between 5 ° and 25 ° in the footprint (2) opens its radius (RM) is between 0.75 and 1.2 times the Radius of corner rounding (RE) is and its transition in the conical corner area tangential.

Description

The Innovation concerns a cup-shaped Container, especially for Food, with a preferably sealable upper edge around an im Essentially rectangular, preferably square opening with rounded edges Corners made by deep drawing, preferably of aluminum becomes, its footprint oval or circular, with the transition between the stand area and the side walls arched is and in the area of container corners a smaller curvature than in the area of the side walls, according to the preamble of claim 1.

Such a container is from the EP 0 694 478 A known. The radius in the region of the side walls is 1/5 to 1/10 of the container height, in the corner but 1/2 to 1/3 of this height, the transitions both in the circumferential direction and in the respective Meridianschnittssebene done steadily. By this known embodiment, the load in the corners can be reduced and thus a thinner starting film can be used, but the creation of a Bodenwulstes that is favorable for stability, not provided and not well possible.

Thermoformed container are generally for known in portions packaged foods for animals and humans and have essentially proven themselves. In order to be stackable when empty, on delivery to the filling station, but also to facilitate molding after manufacture, have such containers slope faces on. The floor area is to stiffen the container slightly retracted at a distance from the edge, so that the container with a kind of Bodenwulst rests on the ground. In the area everyone Corner thus forms near the ground or in the area of Bodenwulstes from an area in the manufacture by that mentioned Deep drawing is particularly stressed. It is necessary, the container material (Strength, structure) to adjust to the stress in these small areas, thereby the container is significantly heavier than it seems necessary because he yes over his entire surface which needed only in the corners Strength having. It also gets more expensive, not just because of the waste of material, but also because of the stronger Materials the tools more massive and therefore more expensive than without them solitary Peak loads must be trained.

It The object and purpose of the innovation, a container of the initially defined To indicate type, the mentioned Disadvantages not and therefore allows it, compared to the container EP-A with the same strength from a lighter or thinner or made of cheaper materials molded foil with lighter and therefore to be manufactured cheaper tools.

To be new Achieves these goals, that in the meridian section through the Corner of the container the transition from the stand area to the conical surface the rounded corner substantially the shape of a circular arc section having, with a Einschleifwinkel between 5 ° and 25 ° opens into the base, whose Radius between 0.75 and 1.2 times the radius of the Corner rounding is and its transition in the conical corner area tangential. The position of the center of the arc section above the floor area results from the respective grinding angle; the height of the transition between the circular arc and that in the meridian section at least in Essentially rectilinear generatrix of the corner rounding is affected by their inclination the stand area Are defined. The transition from this meridian section to the adjoining side surfaces preferably fluently and will be explained below with reference to exemplary embodiments.

On this way you avoid the hitherto always occurring corners small radius of curvature, the because of its double curvature in contrast to edge-like deformations with a small radius of curvature normal to the stretched edge (simple curvature) difficult and uncomfortable are in production.

The Innovation is explained in more detail below with reference to the drawing. there shows

the 1 a meridian section through a shell along the line II of 2 .

the 2 a top view of the shell of 1 .

the 3 to 6 show meridian sections at different angles,

the 7 and 8th show views similar to those of 1 and 2 but with horizontal sections at different heights.

In 1 and 2 is a renewal according shell 1 shown. It has an annular base 2 on, in the embodiment by a down from the bottom surface 3 protruding annular bead is formed. The upper edge 4 the Bowl 1 has essentially square shape with rounded corners 7 with a "corner radius" RE, in particular from 2 evident. Parallel to the floor surface 3 one passes around the opening 5 the shell circumferential sealing surface 6 whose outer contour is of little significance for the innovation. The inner contour of the sealing surface 6 , according to the shape of the opening 5 and the top of the sidewalls 8th the shell, thus the upper edge 4 , Runs in the illustrated embodiment so that the width of the sealing surface 6 remains essentially constant, which can be chosen differently.

Out 1 is the relatively strong curved transition 10 between the side wall 8th and the stand area 2 in the lower part of the shell, but because of the essentially unidirectional deformation of the material during deep drawing, it does not cause any problems in the production. The 3 shows the same situation in the corner, thus in section IV-IV of the 2 , at 45 ° to the side walls 8th , It can be seen that in this region of the shell surface with double curvature the radius of curvature RM is significantly greater than in the region of the simple curvature in FIG 1 , In this way, the corner areas during deep drawing are not claimed as much as in the prior art and it can be reduced accordingly the material thickness. The 4 . 5 and 6 each show meridian sections with the angles 30 °, 35 ° and 40 °.

Of the radius of curvature RM is preferably between 0.75 and 1.2 times the Radius RE of the corner rounding of the opening of the shell. The angle α, with the the circular arc runs into the footprint and only with a technical needs, not extra rounding with a small radius, is in the illustrated embodiment 18.42 ° and is preferably between 5 ° and 25 °.

In a preferred embodiment, the center of curvature KM of the circular arc section lies in the meridian section through the corner 7 at a midpoint height h which is between 50 and 75%, preferably between 55 and 56% of the shell height H.

In a further preferred embodiment, the horizontal sections, which are above 33% of the shell height H, extend at least substantially parallel to the opening 5 ,

As in particular from 7 and 8th As can be seen, the critical formation of the transition between the bottom and the side walls of the shell is completely defused by the circular formation of the bottom and the manner in which the corner is rounded. These two figures show the location of sections F, g and H, where F is just below the opening 5 or the sealing surface 6 lies. These two elements are in 8th not drawn because they are above each of the three cuts. The cutting line G, which is already in the lower part of the shell, is like out 8th can be seen, still largely parallel to the section line F and thus lying parallel to the edge. From the 8th Thus, it can be seen that the shell is formed in the region of the cuts G and F and above as a truncated pyramid with rounded corners, and that the rounding of the corner takes place only near the circular base surface. This brings with it that the shell is excellent fillable, as in particular from the top view and the 45 ° side view of the 3 evident.

Only just above the floor area 3 lying section H shows the rounding of the corners and the course of this rounding in the horizontal. In this way, the originally flat shell material is significantly weaker curved during deformation in these areas, in which it covers the longest paths from the initial state, for example, in the corner region 9 the side walls and therefore requires no more training in the original state.

• * In diesem Winkelbereich werden zwei aufeinander folgende Bogenabschnitte verwendet.

An embodiment of a shell according to the invention shows the following characteristics in the individual meridian sections, including vertical sections through the shell vertical axis, a square shell with an outer contour of 87.90 mm edge length, a height H of 24.56 mm and a diameter of the base 2 of 64 mm, with the circumferential angle of 0 ° for a cut normal to the side wall and center cutting and 45 ° for the cut through the corner: Cutting angle: Radius of curvature (mm): Height of the center (mm): A-grinding angle: Upper end of the bow (mm): ° 30 15,12 13.05 ° 30 8.45 35 ° * 15.92 / 14.28 14.47 / 14.38 35 / 23.16 ° 8.10 / 2.3 40 ° 15.28 14.54 21.2 ° 7.82 45 ° 14.62 14.17 18.42 ° 12.12

• * In this angular range, two consecutive arc sections are used.

The radius of curvature of the radius of curvature of the arc (short arc) in each meridian section, the height of its center is from the footprint 2 measured from, the Einschleifwinkel is the measured in meridian section angle between the base and the end tangent of the circular arc, the upper end of the arc is measured from the footprint. It should be noted that all meridian sections are near the circular bottom surface 3 or the stand area 2 actually run along a meridian, with the exception of the 0 ° and the 45 ° cut but with increasing distance from the bottom surface obliquely to the rounding of the corner in the upper shell area, since this rounding does not have its center in the center of the shell.

you realizes that the height the upper end of the circular arc used to round the corner at 45 ° significant maximum (12.12 mm), indicating the in the corner area especially big to be bridged "gap" between the floor space and is due to the conical or pyramidal section in the lid area. The fluctuations around remaining area go on in the further Changing corner area Cutting lines between the upper, conical area and the arch area according to the increasing grinding angle of the bow area and its location on the circular footprint back. The height The centers of the circular arc also varies slightly.

Of the 35 ° cut shows as an embodiment two arc sections, the lower of Grinding angle of approx. 23 ° to to the transition angle of 35 °, the next after that up to the side wall at a height of 8.10 mm with a slight rounding at the transition. It is of course possible this two sections through a continuous circle section or a circle-like Replace curve.

The Innovation is not on the illustrated or described embodiment limited, but can be modified variously.

Claims (3)

Cup-shaped container ( 1 ) preferred for foodstuffs, with a preferably sealable upper edge ( 6 ) around a substantially rectangular, preferably square opening ( 5 ) with rounded corners ( 7 ) and an oval or circular base ( 2 ), which is produced by deep drawing, preferably made of aluminum, wherein the transition between the footprint ( 2 ) and the side walls ( 8th ) is arcuate and in the area of the container corners ( 7 ) has a smaller curvature than in the region of the side walls, characterized in that in the meridian section through the corner ( 7 ) the transition from the footprint ( 2 ) to the conical surface of the rounded corner ( 7 ) substantially in the form of a circular arc portion, with a Einschleifwinkel (α) between 5 ° and 25 ° in the footprint ( 2 ) whose radius (RM) is between 0.75 and 1.2 times the radius of the corner rounding (RE) and whose transition into the conical corner surface is tangential. Container according to claim 1, characterized in that the center of curvature (KM) of the circular arc section in the meridian section through the corner ( 7 ) is at a midpoint height (h) that is between 50 and 75%, preferably between 55 and 56% of the shell height (H). Container according to claim 1 or 2, characterized in that the horizontal sections lying above 33% of the shell height (H), at least substantially parallel to the outline of the opening ( 5 ).