DE2100053C2 - One-piece molded metal can for goods under overpressure - Google Patents

Description

21 OO 053

The outer ring surface also forms the base of the container. If the container were to be filled with products with overpressure, the floor could easily be around the ring-shaped footprint Bend axially outwards as a bending line, whereby the central, curved bottom section under the Stand area and restricts the stability of the container Apart from that, the conditions are in the case of containers made of thermoplastic material made of a tube are made by blow molding, significantly different from one-piece metal cans, due to the different material properties and the different shaping processes.

In the case of the one-piece molded metal can according to the Invention, the floor area receives significantly more favorable strength properties, above all through the special formation of the bottom edge area. The relatively small cone angle of the truncated cone Bottom ring section gives this bottom ring section increased internal pressures in the can high dimensional stability This is increased by the fact that the lower, wider end of the bottom ring section An axial merges into the cylindrical fuselage wall over a comparatively small radius of curvature Outward bending of the bottom ring section under the effect of the overpressure inside the can furthermore prevented that at the inner, narrowed end of the bottom ring section tangentially into the outwardly open ring bead passes over a semicircular cross-section with a radius of curvature which is much larger than the radius of curvature with which the wide end of the bottom ring section merges into the cylindrical wall. This ring bead, the diameter of which is significantly smaller than that The diameter of the can has a high degree of dimensional stability, even with a thin wall, and forms on the Another transition from the bottom ring section and the central, outwardly convex bottom section Stiffening that increases the cone angle of the bottom ring section under the action of the This effectively counteracts pressure forces inside the can. This creates a particularly stiff bottom edge area obtained, which surrounds the outwardly convex bottom portion This is relatively flexible. Because he however, is held by the stiff bottom edge area, its migration in the axial direction outwards under the effect of the overpressure in the can, limits are set by the material properties of the sheet itself are determined and are sufficient to prevent that even with high internal pressures in the Can the curved bottom section reach into the level of the standing surface or beyond this ·. Which Standing surface is formed by the small radius of curvature with which the wide end of the bottom ring section adjoins the cylindrical body.

The new shape of the bottom also takes into account the desire to make the cans as thin as possible To be able to produce sheet metal in order to achieve high material savings in the mass product, and at the same time to design the soil profile in such a way that it has little space of the theoretical total volume the can without affecting the dimensional stability of the bottom area against even higher pressures.

It is advantageous if you consider the diameter portion of the relatively flexible, convexly curved bottom portion limited to the diameter of the can by advantageously the mean diameter of the ring bead is greater than 0.6 times and smaller than 0.8 times the outside diameter of the fuselage is selected

The invention is illustrated below with reference to schematic drawings of an exemplary embodiment explained it shows

Fi g. 1 in detail a side view of the Bodenbe rich, partially axially cut, eicss extruded Can body before the deformation step for the rotationally symmetrical profiling of the concrete.

F i g. 2 in the same representation as FIG. 1 the can body after the change in shape of the bottom area. In Fig. 1 is shown an intermediate product in the form of doses of the blank 5 is prepared by extruding smooth-walled It comprises a cylindrical trunk wall 10 with the outer diameter D 1 of the finished box, and a dome-shaped convex outwardly curved bottom portion 12. The edge of the bottom section merges into the fuselage section 10 via the edge 14. The bottom section 12 has a radius of curvature R 1 and a varying wall thickness, which increases from the thickness T 1 in the area of the can axis CL to the thickness T2 at the transition 14 to the can body 10, which itself has a thickness Γ3 chosen so that after the change in shape in the bottom area 12 'according to FIG. 2 the wall thickness over the entire base area essentially uniformly corresponds to the value Ti , which is equal to the wall thickness Γ3 of the can body 10.

In the example shown, the change in shape results in a deformation factor of approximately 3: 8.
The rotationally symmetrically profiled floor 12 'according to FIG. 2 has a wall area that is profiled in a special way. This consists initially of a frustoconical bottom ring section 16, which opens axially outward with a cone angle of about 80 °. In FIG. 2 is not the cone angle, but the complementary angle A to half the cone angle. The angle A is about 40 °. The upper, narrower end of the bottom ring section 16 merges tangentially into an axially outwardly open ring bead 18. This has a semicircular cross section with the radius of curvature R 3. The mean diameter of the ring bead 18 is indicated by D 2. The outer, further end of the frustoconical bottom ring section 16 merges into the fuselage 10 via a radius of curvature R 2 which is smaller than the radius of curvature R 3 of the ring bead 18. The proportion of the bottom ring section in the diameter D 1 of the can corresponds to half of the difference between the can diameter and the mean diameter of the ring bead. The actual wall length of the bottom ring section 16 is indicated with L and the wall thickness in this area with Γ 4.

The central, outwardly convex bottom section 20 adjoins the inner edge of the ring bead 18 via a radius of curvature R 5 . The bottom section 20 itself has a radius of curvature R 6 which is greater than the original radius of curvature R 1 of the convexly curved bottom 12 according to FIG. 1 is.

It can be seen that the transition radius of curvature R 2 "between the bottom ring section 16 and the body wall 10 forms a relatively sharp edge 17, which at the same time defines the standing surface of the can. The base has the maximum possible diameter. so that the box has an excellent stability

21 OO

owns.

The actual length L of the bottom ring section 16 is determined by the following equation:

(Di-Dl) 2 Cos A

The dimensional rigidity of the bottom edge area is essentially determined by the radius of curvature R 3 of the bead 18, the mean diameter D 2 of the bead 18 and the actual length L of the bottom ring section 16. The ring bead 18 is due to its ring shape and the semicircular cross-section and the limited radius of curvature, the lies between 1.5 times and 3 times the sheet metal thickness 7 "! of the bottom, highly resistant to deformations under the action of high pressures inside the can and the central arched floor section 20. The behavior of the individual floor sections under the effect of an internal overpressure can be more easily understood with the aid of the right half of FIG is only aimed at the curvature reduce the radius of the bead. The compressive force, which tries to move the bead 18 axially outward, is absorbed by the frustoconical bottom ring section 16, which is stressed by compression. The length L of the bottom ring section 16 is sufficient, however, to rule out any bulging of the bottom ring section itself under the forces to be expected. The forces acting on the bottom ring section try to enlarge the cone angle of this section and thereby reduce the diameter of the ring bead 18. The high resistance to deformation of the ring bead 18 successfully counteracts the tendency to reduce the diameter of the ring bead. The ring bead therefore effectively supports the base ring section against the tendency to bend this section outwards. This is favored by the inherent rigidity of the bottom ring section, in particular by its relatively small cone angle of about 80 °. The compressive forces acting on the central base section 20 attempt to bulge this section further outwards and to roll the ring bead 18 downwards along the base ring section 16. The rigidity of the Ringsikke successfully counteracts this rolling process, while the material properties of the sheet counteract the enlargement of the state of curvature of the central base section. In addition, outward bending of the arched bottom section 20 is permissible within limits, as long as the arch does not reach the level of the base of the can

If only limited excess pressures are to be expected in the filling goods, the radii of curvature R 2 and R 3 can be increased somewhat, which makes it easier to change the shape of the base area during the manufacture of the can. The design of the bottom is particularly advantageous when producing cans from aluminum, but this bottom design is also suitable for cans made of other metal. In the practical example, the following values were provided for a can made of aluminum. The angle A is 40 °, the mean diameter D 2 of the ring bead 18 is 0.7 times the can diameter D 1, the radius of curvature R 6 for the curved bottom section 20 is 1.1 times the can diameter D 1 and the radius of curvature R 3 is Ring bead 18 equal to twice the sheet metal thickness 7Ί for the blank according to FIG. 1, this means the following values: The radius of curvature R 1 for the base 12 was 0.7 times the can diameter D 1 and the thickness T2 in the edge area of the base was 1.5 times the thickness Tl in the central floor area.

The value for the angle A can vary depending on the degree of stiffness that is to be achieved for the bottom edge area. The mean diameter D 2 for the ring bead can vary between 0.6 times and 0.8 times the can diameter D 1 and the radius of curvature for the central base section between OJ times and 1.5 times the can diameter.

The figures show the preferred configuration and dimensions for an extruded aluminum smooth-walled can.

1 sheet of drawings

Claims (2)

21 OO 053 1 2 It is therefore known, in the case of one-piece metal claims: tall cans have a central, uniformly curved base section and a frustoconical and geometric 1. One-piece molded metal can for filling goods that are inclined at an angle to the container axis, in which the cylindrical 5 ring section is to be provided so that without the need for additional stiffening ribs in the body of the can bottom, which passes over the central one to give uniform greater rigidity without the arched bottom section and a frustoconical cone needing to have a greater wall thickness than the body of the metal cones and inclined relative to the container axis DE-OS 15 27 947 known In this is characterized in that the frustoconical central, uniformly arched bottom portion to the bottom ring portion (16) is convexly curved with a cone angle inside the can and goes with an axially outward of about 80 ° and opens with the almost cylindrical edge directly into the ring-shaped, outwardly convex bottom section (20) ge base of the metal box, which is formed by a relatively small radius of curvature connected via an outwardly open ring bead (18), which is connected to the semicircular cross-section with the bottom ring section, which has a two-step radius of curvature (R 3) between 1.5 times of different inclination to the can axis and 3 times the thickness (T1) of the base of the metal can from above and towards the bottom, and that the bottom ring section (16) on the outside frustoconical except for the diameter which is extended to the cylindrical body (10) via a curved metal can and connected to the body of the can overmoving radius (R 2), which is smaller than that of these cans central, uniform radius of curvature of the ring bead (18) is arched bottom section because of the desired, 2. Metal can according to claim 1, characterized in that the wall thickness as thin as possible is relatively flexible. It was noted that the mean diameter (D 2) of these cans was perceived as a disadvantage, that when the inner pressure is greater than 0.6 times and less than 25 times the inner pressure of the ring bead (D 1 ) and can bend radially outward so that the trunk is. Fahr consists that the central, uniformly curved Floor section too easily out of its original opposite above the inside of the container convex position into a convex 30 kave layer and thus protrudes under the base of the can and its stability and thus also The invention relates to a one-piece molded medial whose sales value is impaired, Tall box for goods under overpressure, in which it is the object of the invention to change the shape the cylindrical body in the rotationally symmetrical tion of this box has more favorable strength properties The profiled floor passes over to give a central, evenly in the floor area. shaped arched bottom section and a conical This object is achieved according to the invention, frustoconical and opposite to the container axis that the frustoconical bottom ring section Has inclined bottom ring section with a cone angle of about 80 ° axially outward There are one-piece formed metal containers made of aluminum and with the outwardly convex bominium. Aluminum alloy, stainless steel or the like. 40 denabschnitt over an outwardly open ring bead known, which is connected smooth-walled by drawing, extrusion which has a semicircular cross-section and / or ironing are made and one piece with a radius of curvature between l ^ times Have kig molded profiled bottom. Has one and 3 times the sheet metal thickness of the bottom such a container in the form of a metal bottle shows both and that the bottom ring section with the cylindrical For example, US-PS 21 57 896. Here, the Bo- 45 fuselage is connected via a radius of curvature which is a much greater thickness than the body of which is smaller than the radius of curvature of the ring bead Container on. The domför to the interior of the container It is in itself of one-piece art The mig convex bottom goes into the body wall of the material container known to provide this with a rotationally symmetrical container via a metrically profiled bottom open to the interior of the container (see. Bead over, which has a semicircular cross-section of 50 US-PS 34 34 626). A has nders than the integrally molded relatively large radius of curvature. The dome metal cans are this one-piece shaped artificially profiled bottom section occupies the far material container by blow molding a larger part of the cross section of the container by extrusion and is sen formed tubular blank made of additional thermally extending, elongated, plastic ribs embossed in a corresponding blow mold stiffened. Such a floor design 55 is formed. To increase the strength this requires an alignment for sufficient strength against plastic material in the drainage area, filling goods with overpressure a relatively large sheet metal thickness which, however, is missing in the bottom area due to the area of the bottom, since the bottom edge bead is formed by squeezing and shaping the hose end over a large area on the dome-shaped bottom section. In order to improve the bursting strength of the base, the internal pressure that has an outward tendency is to bend uniformly, so that the base as a whole is convex from its original and from an annular, initially convex position to a The inside of the shoulder is made of non-oriented plastic, the container can wrap around in a concave position when viewed. which in a frustoconical section over-in addition that one goes largely over the whole, which at a cone angle of about 90 ° cross-section of the container reaching inwardly convex 65 opens axially outward and at its wide end over arched bottom profile a relatively high Share occupies a bending line in an internal volume of the container perpendicular to the axis of the container, which merges for the ters extending annular surface, which in turn is lost via the filling material. a bending line directly in the cylindrical body