EP0510291B2 - Method of and device for manufacture of threaded cans made of aluminium - Google Patents

Abstract

Deep-drawn, deep-drawn and stretched or extruded, cylindrical aluminium cans are coated inside and outside, provided with a two-stage neck (10, 20) by drawing-in, onto which neck a thread (30) is rolled, and then cut to length, the drawing-in of the neck, the thread-rolling and the cutting-to-length being carried out in the same clamping operation on the can. The coating used is mixed with a catalyst, plasticiser and/or lubricant to increase its flexibility, to increase its adhesiveness and to improve its sliding properties. The thread is rolled by the can neck being supported from inside by a virtually stationary thread template (40) while a thread roller (50) is rolled over the surface of the neck from outside, the said roller pressing the thread inwards into the neck. Thread template and thread roller are positively controlled in such a way that a slipping is produced between them and the material of the neck. As a result, the coating remains intact even in the region of the thread.

Description

The invention relates to a method and a device according to the preambles of the corresponding independent claims for the production of Aluminum cans with threads, especially deep-drawn, deep-drawn and stretched or extruded, aluminum cans painted inside and out with bottle thread.

Such is known.

It corresponds to the state of the art through flat, round pieces of aluminum Pull into cylindrical tins to shape them inside and out paint and then narrow the can opening by pulling and flanging and get ready for the attachment of a clasp. Such cans are further processed into aerosol monoblock cans, for example. The Painting and especially the printing of lettering or decorative patterns before pulling in is advantageous because only on cylindrical Cans the paints can be rolled up. Even inside where the paint is is sprayed on, this is easier on the still cylindrical can.

Painting the inside of aluminum containers is necessary for everyone those applications in which a bare aluminum surface from Contents of the can would be attacked. Wherever during use and Storage of the can contents in contact with the inner surface of the can in such cases, it is important that the interior paint cover the aluminum surface covers absolutely without interruption.

For the processes for the production of painted aluminum cans according to In the prior art, coatings have been developed that are so adhesive, Are elastic and slippery that cylindrical, painted aluminum cans Allow to be drawn in bottle-shaped without the paint being damaged.

Since aluminum is a good and cheap recyclable packaging material, would be it makes sense and desirable if made from aluminum containers could be on the like on plastic or glass bottles for example screwed on a hand pump with a riser pipe or a screw cap could be. The aluminum container could be filled with, for example the screw cap come on the market. The consumer the pump, which would be designed for multiple use, could simply be Screw the aluminum container on and off and the container without Recycle or refill foreign material. To this Purposes would be aluminum cans with appropriate threads, advantageously standardized threads necessary.

The task is therefore to demonstrate a method and a device to create with those on the inside and externally painted aluminum cans thread, especially standardized thread, can be attached. It is particularly important that the paint, especially the inner varnish is not injured by attaching the thread will, because in the above-described task of such a can Internal threads are in contact with the contents of the can. Procedure and Device are said to be in known production lines for the manufacture of deep-drawn, deep-drawn and ironed or extruded, lacquered Aluminum cans can be integrated, i.e. the thread must be made can be in the same setup in which the other work steps like pulling in the neck, cutting the can to length, etc. in a cycle time of approx. 0.3 to 0.6 sec and an effective one Processing time from 0.035 to 0.07 sec. The cans should be after the application the thread does not need to be cleaned, that is, process and device must do without the addition of lubricant or that a lubricant is used that does not contain the contents of the can or Appearance of the can impaired.

This object is achieved by the method and the device according to the independent claims. In the dependent claims design variants are shown.

The most important features of the method according to the invention are the following: The thread is made by a rolling on the outer neck side Tool and a quasi stationary one that supports the can material from the inside Tool created on the inside of the neck. The two tools work so positively controlled that there is slippage between the neck and the tool arises. This can largely prevent the neck material dammed up in front of the tools and in the direction of movement of the tools is shifted, which lead to oval threads and the paint in would claim and damage to a great extent.

Figur 1

eine schematische Übersicht über die einzelnen Verfahrensschritte des erfindungsgemässen Verfahrens;

Figur 2 a und b

eine detaillierte Darstellung für den Verfahrensschritt des Gewinderollens als Draufsicht auf die Dose und die verwendeten Werkzeuge vor (Fig. 2a) und während (Fig 2b) dem Gewinderollen;

Figur 3 a und b

wie Figuren 2a und 2b, aber als Schnitt entlang der Rotationsachse der Dose;

Figur 4

eine schematische Darstellung einer beispielhaften Ausführungsform der erfindungsgemässen Vorrichtung, geschnitten entlang der Rotationsachse der zu bearbeitenden Dose;

Figur 5

eine nach dem erfindungsgemässen Verfahren hergestellte Aluminiumdose entlang ihrer Rotationsachse geschnitten.

The method according to the invention, the device according to the invention and the aluminum can produced by the method according to the invention will now be described in detail with reference to the following figures. Show:

Figure 1

a schematic overview of the individual process steps of the inventive method;

Figure 2a and b

a detailed representation of the process step of thread rolling as a top view of the can and the tools used before (Fig. 2a) and during (Fig 2b) the thread rolling;

Figure 3 a and b

like FIGS. 2a and 2b, but as a section along the axis of rotation of the can;

Figure 4

a schematic representation of an exemplary embodiment of the device according to the invention, cut along the axis of rotation of the can to be processed;

Figure 5

cut an aluminum can manufactured according to the inventive method along its axis of rotation.

Figure 1 shows the basic method steps of the inventive method. The process is shown as a process block diagram and below it schematically the shape changes produced by the individual process steps on the can, namely as a top view and as a longitudinal section through the neck part of the can.

From flat, mostly round pieces of a deep-drawable or extrudable Aluminum alloys are made in a known manner by deep drawing Deep drawing and additional drawing or cylindrical extrusion Cans made. The wall thickness of the can should not exceed 20% of the Measure the pitch of the thread intended for the can.

After pulling, pulling and stretching or extrusion, the Cans cleaned to remove the lubricant necessary for drawing. Then in a first step of the method according to the invention A (paint) painted inside and out and possibly printed, as long as it have a cylindrical shape. The paints used are, for example Polyester or epoxy phenolic lacquers. You are going for increased flexibility, for increased adhesion and for better sliding properties with one or several additives that the expert as plasticizers, and Lubricants are known. The devices used for painting correspond to known such devices with which the Spraying the interior paint, the exterior paint with a corresponding roller is applied. After painting, the paints are dried accordingly and polymerized.

For the following process steps, the cans are placed on a turntable stretched, by gradually turning them into the area of successive Tools are guided, which are mounted on a tool plate are. A corresponding device is for example in the CH patent 394'998 / 65 (Lechner) and is assumed to be known.

In two subsequent process steps B and C, each can is drawn in in stages, the two process steps depending on the diameter of the can, depending on the desired can shape and depending on the material, consisting of different numbers of effective drawing-in steps with different tools. The first time B is pulled in, the can has a narrowing shoulder and a substantially cylindrical first neck piece 10, the second time it is pulled in C, a second, narrower, essentially cylindrical neck piece 20 is connected to the first neck piece 10. The outside diameter d _{1 of} the first neck piece 10 essentially corresponds to the outside diameter of the thread to be created, the outside diameter d _{2 of} the second narrower neck piece 20 is slightly smaller than the core diameter d _{3 of} the thread to be created.

The shape of the retracted shoulder is for the inventive method Not relevant.

Procedures and tools for pulling in aluminum cans are the same Known specialist. He can also use it for feeding to the one described Adapt the neck shape so that it is not described here Need to become.

In a subsequent method step D, a thread 30 is rolled up on the first neck piece 10 or on the part of the first neck piece 10 facing the second neck piece 20. The thread is produced by a thread roll rolling around the outer circumference of the first neck piece 10, which is pressed against a quasi-stationary thread template in the interior of the neck. The thread is therefore pressed inwards from the outside of the neck so that the outside diameter of the finished rolled thread corresponds to the original neck diameter d ₁ . Its core diameter d ₃ is a little larger than the outer diameter d _{2 of} the second neck piece 20.

The thread runs against the second neck piece 20, that is, it extends not to the edge of the neck. This prevents the neck edge deformed by the thread rolling from their exactly circular cylindrical shape becomes.

The device according to the invention used for method step D is described in more detail in connection with Figures 2, 3 and 4.

In a subsequent process step E, the can neck is cut to length, for example immediately above the upper outlet of the thread. Should the Can be used in connection with a hand pump, the The connection between the neck edge and the pump connection must be tight. Depending on The type of seal used can be advantageous to the face of the can neck straight or slightly crooked. Methods and devices to cut can necks are known and must therefore not be described here.

To ensure continuous, fast and economical production, it is necessary to carry out process steps B, C, D and E at the same Can be clamped. But that also means that the procedural steps a basic cycle that is characterized by a corresponding production machine is given, must submit. Should the thread be in one such a cycle is rolled at a production speed that is common today from between 100 and 200 doses per minute that for the thread rolling has a cycle time of between 0.6 and 0.3 seconds Is available in which the can is moved to the appropriate location Tools are brought into the working position and the thread is rolled.

A working time of stands for the effective process of thread rolling between 0.035 and 0.07 sec.

Figures 2a and b now show a top view in detail of the method and the tools that are used to roll the thread. Figure 2a shows the tools before the thread rolling process, Figure 2b during the thread rolling process.

Of the can, only the annular end face 21 of the second neck piece 20 with the outside diameter d ₂ and the first neck piece 10 with the outside diameter d ₁ are shown. For the thread rolling process, an essentially cylindrical or slightly frustoconical thread template 40 is inserted into the doser neck. The largest diameter of the template is such that it can be inserted through the second neck piece 20 without difficulty. On its side surface, the template carries a slightly distorted, negative image 41 of the thread to be rolled, which is indicated by dashed lines in this top view. During the insertion process, the can neck and the template are arranged coaxially, that is, their axes of rotation S and T coincide.

Advantageously simultaneously with the insertion of the thread template in a thread roll 50 is positioned outside the can neck, that with a thread form (formed as spiral around the roll pulling bead 51) is designed such that it moves without being axially to be able to roll the whole thread. During the insertion process it is Thread roll spaced from the neck so that it does not touch it.

For the effective thread rolling process, the template 40 and the Thread roll 50 by shifting their axes T and U against each other moves that the template 40 where the thread roll 50 outside is positioned, touches the inner surface of the first neck piece and the Thread form 51 of the thread roll 50 around the thread depth of the roll Thread is pressed into the neck material. At the same time, the thread roll 50 rolled on the neck and thus coordinates the axis of rotation the template rotated about the axis of rotation of the can so that the template always rests against the neck and supports the neck material where the thread roll just rolls.

In this closed state, the two tools are at least moved once around the can neck and created the thread.

When the thread is rolled, the template 40 and thread roll 50 brought back into the position described for the insertion (Fig. 2a) and axially away from the can.

When the thread rolls, the thread roll 50 is positively controlled in this way unrolled that the circumferential distance rolled on the roll is greater than that circumferential stretch rolled on the neck. Between thread roll and neck This creates a slip, so that the thread roll is in one Direction rolls over the neck circumference, but always in the opposite direction Direction slips on the neck surface. Through this Slip through which a force counteracts the direction of movement of the thread roll 50 arises on the neck material, the role is prevented Neck material in front of it and shifted in the unwinding direction.

Since the circumference of the thread template 40 is smaller than the inner circumference of the first neck piece 10, which they support during the thread rolling process has also arises between the template 40 and the inner surface of the first neck 10 a slip, such that the template 40 on the inner surface of the neck slides in the direction of movement of the thread roll 50.

This double-sided slip results in the particularly advantageous ones Procedural circumstances that lead to the fact that the thread runs true and that the paint on the can is not damaged. The Slipping of the thread roll and the template leaves traces on the paint, which as slight surface changes of the paint in the area of Thread are recognizable.

FIGS. 3a and 3b show, corresponding to FIGS . 2a and 2b, the tools used for the thread rolling process before (FIG. 3a) and during (FIG. 3b) the thread rolling process, namely as a section along the axis of rotation of the can, with only one side of the can neck is shown. In these figures, the configurations of the thread template 40 and the thread shape 51 of the thread roll 50 are clearly visible. The threads 41 of the thread template need only correspond to the shape of the finished thread in depth and pitch, but should not have any sharp edges where they come into contact with the deformed inner surface. The thread shape 51 of the thread roll 50, however, must correspond in shape to the shape of the thread to be created. The thread template 40 is advantageously designed such that it not only supports the inner surface of the first neck piece 10, but also at least partially the inner surface of the second neck piece 20, although no thread is rolled thereon.

FIG. 4 schematically shows the parts of a device for thread rolling on cans relevant to the invention in an exemplary embodiment. The figure is a section along the axis of rotation S of the can. The two neck pieces 10 and 20 are visible from the can. The thread template 40 and the thread roller 50 are in a position which corresponds to their position in FIGS. 2b and 3b. The axis T of the template 40 is not on the axis of rotation S of the can, the thread roller 50 presses into the neck material.

Above all, the means 60 are shown, by means of which the slip between the thread roll 50 and the can neck is produced. These are around a ring gear 61 which is attached to the shaft 42 of the template 40, and a second ring gear 62 running in this ring gear 61, which the thread roll 50 is attached. Now the axis U of the thread roll 50 moves about the axis T of the template 40, the thread roll rolls by the toothed drive 60 from the can neck under positive control. Since the Rolling radius r of the thread roll 50 on the can neck is smaller than that Rolling radius R of the ring gear 61 arises between the thread roll 50 and Can slip in such a way that the thread roll 50 on the Neck material slips against its direction of drainage.

It has proven to be advantageous to increase the two radii r and R in this way choose that R: r ≧ 1.1.

The drives for the axial movement of the are not shown in the figure Device parts before and after the effective thread rolling process and for the rotational movement of the thread roll 50 around the can neck and with it coupled circular movement of the axis T. For the axial movement advantageously the clocked movement of the tool plate, on the too the tools for the other process steps are assembled, used.

The circular movement of the thread roll is, for example, with a belt drive driven.

The coupling of the movement of the thread roll 50 and the axis T of the Template 40 and the control of the relative movement of the two axes T and U before and after the effective thread rolling process can be done by appropriate asymmetrical wedge arrangements can be realized, the relative movement of the two axes by a relative movement in the axial Direction of these wedge arrangements is realized.

The movement of the axis T about the axis S can be realized in such a way that the axis T describes a cylinder jacket around the axis S, or that the axis T describes a cone about the axis S. In the event of cylinder movement the template 40 must be cylindrical, in the event of taper movement the template 40 must be frustoconical, with in the Can pointing tapered end be designed.

FIG. 5 shows a can closed with a hand pump 70, to which a thread was attached using the method according to the invention. The thread can correspond to any standard for such threads, for example the Euronorm. It can be seen that threads which are produced by the method according to the invention have an accuracy of approximately ± 0.1 mm, an accuracy which far exceeds the accuracy of corresponding plastic or glass threads. For this reason, it is also not necessary, as shown in FIG. 5, to improve the centering of the screwed-on pump by means of a corresponding recess on the end of the can neck facing the shoulder. The shape of the can base is not relevant for the method according to the invention. The can shown has, for example, an inwardly curved base.

Claims (8)

1. Method for the manufacture of aluminium cans having a thread and being varnished on the inside and outside, by producing a cylindrical can by means of deep drawing, deep drawing and ironing or extruding, by varnishing the cylindrical can and subsequent drawing in, thread rolling with the aid of an inside screw pitch gauge (40) and an outside thread roll and cutting to length, wherein the method steps drawing in, thread rolling and cutting to length are all performed with the same fixing of the can, characterized in that during thread rolling the tools (40, 50) are guided in such a way that through slipping of the tools (40, 50) on the can material a predetermined slip is produced between the tools and the can material, wherein the inside tool (40) slips on the can material in the moving direction of the tools (40, 50) and the outside tool (50) slips on the can material in a direction opposed to the moving direction of the tools.
2. Method according to claim 1, characterized in that for varnishing of the cans use is made of varnishes modified by additives in such a way that they have an increased adhesiveness, an increased flexibility and improved sliding characteristics.
3. Method according to claim 2, characterized in that the additives are catalysts, softeners and/or lubricants.
4. Method according to any one of the preceding claims, characterized in that prior to the tread rolling the can is drawn in to at least one, substantially cylindrical neck portion (20) and that the external diameter of this neck portion essentially corresponds to the minor diameter of the thread to be rolled.
5. Apparatus for rolling threads on varnished aluminium cans according to the method of any one of the claims 1 to 4, which apparatus comprises a screw pitch gauge (40) for supporting the neck from the inside and a thread roll (50) for rolling the thread from the outside, characterized in that it further comprises control means coordinating the movement of the screw pitch gauge (40) and the thread roll (50) and allowing the movements of the tools to take place in such a way that the required slip occurs.
6. Apparatus according to claim 5, characterized in that the control means for producing the slip comprise a gear rim (61) on the shaft (42) of the gauge (40) and a gear rim (62) on the thread roll (50) and that the rolling circle of the gear rim (61) on the shaft (42) of the gauge (40) is larger than the rolling circle of the thread roll (50) on the can neck.
7. Apparatus according to claim 6, characterized in that the radius (R) of the rolling circle of the gear rim (61) is chosen relative to the rolling radius (r) of the thread roll (50) on the can neck in such a way that R:≧1.1.
8. Apparatus according to any one of the claims 5 to 7, characterized in that the control means for coordinating the radial movement of the gauge (40) and the thread roll (50) comprise wedge systems and means for producing a relative axial movement of said wedge systems against one another.

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