EP0675773A1

EP0675773A1 - Process and apparatus for further treating a closure end made of sheet.

Info

Publication number: EP0675773A1
Application number: EP93921809A
Authority: EP
Inventors: Lutz Strube; Peter Hoeft; Heinz Heinecke
Original assignee: Schmalback Lubeca AG
Current assignee: Ardagh Metal Packaging Germany GmbH
Priority date: 1993-10-08
Filing date: 1993-10-08
Publication date: 1995-10-11
Anticipated expiration: 2013-10-08
Also published as: JPH09503443A; BG100481A; ES2082660T3; WO1995010373A1; GR3018362T3; NO312018B1; RU2111820C1; AU5106693A; DE59300795D1; KR100274401B1; FI961527A0; BG62278B1; FI961527A; NO961358D0; AU686571B2; DK0675773T3; ATE129173T1; EP0675773B1; NO961358L; US5832770A

Abstract

PCT No. PCT/DE93/00958 Sec. 371 Date May 17, 1996 Sec. 102(e) Date May 17, 1996 PCT Filed Oct. 8, 1993 PCT Pub. No. WO95/10373 PCT Pub. Date Apr. 20, 1995A process for further treating a closure end made of sheet material is provided, particularly for beverage cans, in which an annular fringe region is radially coupled between the central panel portion and a radius of curvature coupled to a core groove with an inner leg. The central panel portion is squeezed such that material is displaced (flows) from the fringe region in a substantially radial outward direction towards the radius of curvature. The squeezing is accomplished by a coining tool having a coining surface operable to contact the closure end. The closure surface is pressed against the closure end causing the thickness of the sheet material of the closure end to be reduced in the annular fringe region. The reduction in thickness gradually decreasing in the direction of the radius of curvature. The material displaced by the squeezing flowing towards the radius of curvature. A ring tool which is finger like in cross section can be used to exert pressure on the core groove during or after the squeezing thereby causing the inner leg of the core groove to move towards a more vertical orientation.

Description

Process for the further treatment of a metal cover

The invention relates to a method for further treatment of a closure lid made of sheet metal, in particular a folded lid for beverage cans or the like, with the features of

The preamble of claim 1 and claim 2. The tool for executing the method is also affected.

Such a cover is known from US Pat. No. 3,441,170, in which the radius of curvature is reduced in thickness even from the inside of the cover, with the formation of a “coined bead”. As a result, a kind of joint is created between the inner leg of the groove and the cover mirror in order to restrict the bulging of the cover to the cover mirror, so that the tensile forces acting radially inward on the core wall of the cover are reduced. At this joint (embossed bead), the lid mirror, which bulges more strongly under greater internal pressure, is articulated to the core wall in such a way that the latter is not or only slightly touched in its vertical orientation by the bulging.

A similar measure is known from EP 88 968 A1, in which the cover plate is deformed from the outside by a pressing pressure starting from the radially inner edge of the radius of curvature over a region of the radius of curvature, so that from this

Radius of curvature area Material of the lid flows radially inwards and outwards. The deformation area forms a flat on the outside of the radius of curvature, the major part of the flat coming to lie in a plane perpendicular to the axis of the cover or in a conical plane inclined outwards and downwards. This also improves the resistance of the cover to bulging. Due to the flow of material radially inward, the outwardly arched cover mirror is placed under compressive stress to form a free doming of the "free doming of central panel", while the radially outward flowing material removes the inner leg of the U-shaped cross section from its original inclined position in a more cylindrical or permanently pivoted to the axis of the cover ("permanent deflection of inner leg"). In both known measures, the area deformed by coining is hardened at the same time by cold working (work hardened). Both solutions of the prior art therefore strive for an enlarged curvature of the lid mirror ("doming"). If, however, a can provided with such a strongly domed lid and filled is pasteurized, for example (whereby it is upside down), the resulting bulging leads to the cans tipping and falling over.

It is an object of the invention to change a lid with a method with the features of the preamble of claim 1 so that the bulging of the lid center can be largely reduced and yet to increase the

Compressive strength Material can be displaced from the lid edge area in a controlled manner.

This object is achieved by the teaching of claim 1 or 2 or by the teaching of claim 8.

The ring-shaped strip area, which is formed during the further treatment with a reduction in thickness, lies clearly radially within the actual radius of curvature. This means that almost no material is displaced into the cover mirror, but from its edge area over the radius of curvature (almost only) into the radially inner leg of the U-shaped core groove. This displacement process is achieved primarily by the angle which is formed and determined by the embossing surfaces acting on the strip-shaped area. This angle is determined between the embossing surfaces of the embossing tool or stamp that acts on the lid from the outside and a plane running perpendicular to the axis of the lid. The embossing surface of the lower embossing tool or stamp is preferably parallel to this plane running perpendicular to the lid axis, that is to say that the angle mentioned is also present between the two embossing surfaces. This angle should be significantly larger than 0 ° be, but in any case less than 90 °.

This angle is preferably between 2 ° and 15 °.

Lids reshaped in such a way are also increased

Internal pressure is stable in its overhead stability, although you do not have to miss the advantage of the more precise vertical alignment of the inner leg.

For precise centering of the cover, a U-shaped groove with a finger-shaped ring holder can be centered in the U-shaped groove during the embossing process, without exerting forces on the core groove.

However, you can also use a finger-shaped ring tool to apply a controlled stretching pressure parallel to the axis of the cover to the bottom of the core groove at the same time or during the last phase of the embossing process, which displaces the material outward, so that the material flow radially decreases beyond the radius of curvature supported on the outside and at the same time the inner leg of the U-shaped groove is tightened and brought more precisely into the desired vertical position.

According to the invention, the material of the cover plate in

The area of the annular strip is pressed together in such a way that in this annular strip area the reduction in sheet thickness decreases steadily from a point of smallest residual thickness in the direction radially outward. In the deformed area, the remaining thickness changes radially outward, for example in the form of a straight wedge, the underside lying in a plane perpendicular to the lid axis and the top in a straight conical surface.

It has proven to be particularly advantageous if a second treatment step follows the first treatment step described. During the second treatment step, the lid material is - in the first Crushed and deformed step - strip-shaped area slightly leveled, but without making noticeable material displacements, but only in a partial area, namely a radially outer area of the strip adjacent to the radius of curvature. This leads to another

Reduction of the radius of curvature, which contributes significantly to increasing the nose strength of the lid. If, due to the first embossing, an insignificant part of the displaced material has been shifted radially inward, the second treatment step levels out the slight "doming" of the cover mirror that may have arisen and essentially creates the precise contact of the radially inner wall of the core groove with the lower mold. The radially inner "lock", which has already been cold-hardened due to the wedge effect, and the planar action of the tool prevent, during leveling, that material is again displaced from a local area or even shifted inward (past the cold-hardened "lock").

The leveling step therefore does purely geometric design work, which relates to the improved alignment of the inner leg of the core groove.

The invention is explained in more detail in several exemplary embodiments according to the following hand-schematic drawings.

Show it:

Figure 1 in a detail and in a vertical section containing the axis 16 of the lid, the tools required to carry out the method at the end of the further treatment of a corresponding sheet metal lid;

FIG. 2 shows the sheet metal cover treated according to the invention in a similar representation as FIG. 1;

Figure 3 shows a modified embodiment of the tool for a modified method example.

FIG. 4 shows the tools for a further processing step following the further processing step of FIG. 1 or FIG. 3;

Figure 5 in a similar representation as Figure 2, a cover that has been treated with both process steps according to Figure 1 and Figure 4.

The cover 1 is shaped as usual from a sheet metal blank so that it has a slightly curved central cover mirror 10, which over a radius of curvature 11, Rl in the straight inner leg 13 of a cross-sectionally U-shaped groove 12, the outer leg 14, the Forms the core wall of the lid, to which (not shown) the lid edge connects. The edge can be of any design and typically be a folded edge.

The lid preformed in this way is placed between the embossing tools 2 and 4. The embossing tool 2 has an embossing surface 3 running approximately perpendicular to the lid axis 16. The embossing tool 4, which can be moved relative to the embossing tool 2 in accordance with the arrow 15, has on its underside in the outer area an annular rib formed by a step 5, the effective bottom 6 of which forms a predetermined angle 25 with respect to the embossing surface 3 of the tool 2, which angle is noticeably greater than 0 ° and less than 90 ° and preferably approximately between 2 ° and 15 ° lies. The embossing tool 4, 5 is supported on a stamp 7, on which, in the example shown, a ring-shaped hold-down device 8 is supported via a spring 9, which is finger-shaped in cross-section and engages centering in the U-shaped groove 12 of the cover.

Figure 1 shows the embossing tools in a position which they assume at the end of the squeezing or embossing process.

As a result of this further treatment of the cover, the material of the cover mirror 10 of the sheet metal cover is squeezed in an annular strip region 20 which adjoins the Rl curvature 11 radially on the inside. The curvature 11 itself is largely spared from the squeezing process, but not from its effects with regard to the material moved outwards. The material displaced during the squeezing flows in a controlled manner radially outward and via the curvature 11 into the inner leg 13 of the groove 12 to be aligned.

Because of this training results in one

Strip width 24 distance from the curvature 11, the smallest remaining thickness, which is indicated at 28 in the tool position according to FIG. For example, it can be 65%. The reduction in thickness decreases in the radial direction towards the outside, preferably along 22 evenly and steadily, so that radially outside the remaining thickness 29 merges into the normal thickness of the sheet in the region of the curvature 11 essentially without steps. The flow process is further favored if the holding-down device 8 is rigidly supported on the punch 7 via the part 8a, the axial length 27 of the centering finger 8 being dimensioned such that at the end of the embossing process, a predetermined pressure is exerted on the bottom 12 of the finger Nut is exercised. As a result, the flow of material from the strip area 20 is still significantly favored by the curvature 11, and at the same time the radially inner straight leg 13 of the U-shaped groove 12 is held and aligned under tensile stress.

The resistance to deformation of the edge profile can be significantly increased and the nose strength increased if the treatment step (stamping) according to FIG. 1 or 3 described above is followed by a treatment step (leveling) according to FIG. 4. Tools similar to those used in the first treatment step are used here, but the upper die 31 has an embossing rib, the effective leveling surface of which runs essentially perpendicular to the lid axis 16, so that the material runs between two planes and perpendicular to the lid axis 16 during pianing

Is shaped geometrically. However, this leveling is limited to only a part of the strip that has been squeezed beforehand, and that part that is adjacent to the curvature and has the greatest remaining thickness (for example between 100% and 70%). The embossing tool 31 is supported on the punch 30, on which the centering tool 34, which is finger-shaped in cross section, can also be supported directly via part 33, as shown in FIG. 4. The stretching effect of the tool 34 is the same as the effect of the tool 8 according to FIG. 3.

With this leveling, the radius R2 of the curvature 11 is reduced compared to the radius Rl according to FIG. 2. The reduction in the radius of curvature and the geometrical reforming of the squeezing area lead to an increase in the nose strength through clean contouring of the edge profile without additional material hardening. The original residual thickness of the sheet in the radially outer region of the strip, as indicated at 29 in FIG. 3, is only slightly reduced at 40, but is geometrically shaped. The outer surface, which originally runs conically over the entire width 24 of the strip 20, is deformed by the deformation in a surface region 35 which is narrower than the width of the strip 24 and is perpendicular to the cover axis 16. The remaining part of the strip 24 maintains its inclination according to the angle 25 from the first page. The centering during the second step according to FIG. 5 can take place according to FIG. 1, that is to say with a spring-loaded centering tool. However, a centering tool according to FIG. 4 is preferred, with which the leg 13 of the U-shaped groove 12 can be placed under yield stress.

Claims

Expectations

1. A method for the further treatment of a closure lid made of sheet metal, in particular a folding lid for beverage cans or the like, in which the lid is punched out of a flat sheet and molded between molds, with a central lid mirror (10) which has a radius of curvature (R1, R2) merges into the radially inner wall (13) of a core groove (12) which has the edge of the cover, and in which for further treatment the material of the cover plate is caused to flow in the region of the radius of curvature by pressing pressure while reducing the plate thickness, characterized in that Further treatment, the material of the cover plate is caused to flow in an annular strip region (20, 24) of the cover mirror (10) that is essentially radially inward and adjacent to the radius of curvature (R1, R2) and for this purpose between an orientation perpendicular to the cover axis (16) ( 3) and a radially outward wedge-shaped (25) diverging (6) F or mold surface is pressed together.

2. Process for the further treatment of a closure lid made of sheet metal, in particular a folded lid for beverage cans or the like, in which the lid is punched out of a flat sheet and molded between molds, with a central lid mirror (10) which has a

Radius of curvature (R1, R2) merges into the radially inner wall (13) of a core groove (12) which has the edge of the cover, and in which the material of the cover mirror is caused to flow in the region of radius of curvature ¹ by pressing pressure while reducing the sheet thickness, for further treatment, characterized in that, for further treatment, the material of the cover plate is caused to flow in an annular strip region (20, 24) of the cover mirror (10) which is essentially radially inward and adjacent to the radius of curvature (R1, R2), in such a way that in the annular Strip area of the lid mirror

Sheet thickness reduction (28, 29) decreases steadily (21, 22, 25) from a point of minimal residual thickness (21) in the direction radially outward.

3. The method according to claim 1 or 2, characterized in that - at the same time with the sheet thickness reduction of the annular strip region (20) of the cover mirror (10) - on the bottom of the groove (12) a radially inner groove wall (13) under tension in the direction the pressure displacing the cover axis (16) is exerted in such a way that a material flow from the annular strip area over the radius of curvature (R1, R2) and a tightening and alignment of the radially inner wall (13) of the groove are favored.

5. The method according to any one of the preceding claims, characterized in that after the material of the lid has been made to flow in the annular strip area of the lid mirror, the radius of curvature (R1, R2) by leveling (35, 40) - or a part of - annular strip area (20, 24) is reduced (Figure 4).

6. The method according to claim 5, characterized in that during the leveling only the area of the ring-shaped strip which is close to the radius of curvature (R2) and which has the greater residual thickness (29) is pressed (35, 40). 7. The method according to claim 1 or 2, characterized in that the pressurization of the bottom of the groove (claim 5, claim 6) takes place only or additionally during the pianing.

8. Machining device, in particular tool set with a contour and counter-contour course (28, 29) to maintain the effects of the characterizing part of claim 2.