EP2025426A1 - Production of a container by means of internal high pressure moulds and container produced thereby - Google Patents

Abstract

A longitudinal completely seamless seam-welded aluminum tube (10) is inserted into a molding tool (12). A completely seamless aluminum tube can be used, e.g. if the tube has been extruded or cast from a molten mass of aluminum. The die (14) for the molding tool has a cylindrical shape, which it uses to define the shape of a pressure vessel/tank to be produced. An independent claim is also included for a pressure vessel/tank.

Description

The invention relates to a method for producing a container. Furthermore, the invention relates to a use of the container produced by the method as a pressure vessel. In addition, the invention relates to a container having two end face regions and with a container jacket arranged between the end face regions.

Containers of the aforementioned type are already known. Usually, the container casing and the two end-side regions are produced separately. In order to produce a container casing, for example, a rectangular blank of a metal strip is formed into a hollow cylindrical body and longitudinally welded. In order to produce the end face regions, circular blanks, for example, are preferably deep-drawn from the same metal strip. The container shell is then welded at both ends with the hollow bodies formed by deep drawing. The container thus produced can then optionally be further processed. A disadvantage of this type of container manufacture is that the shape of the container to be produced can not be chosen arbitrarily. Furthermore, the number of process steps to be carried out is essentially predetermined by the container parts to be preformed separately. Thus, the production with high financial, human resources as well connected device technical effort. The separately preformed container parts, such as front side areas and container shell, must also be connected by a joining process such as welding. This sets the container parts in particular a thermal load, which can have a negative effect on the material properties or by delay on the geometry thereof.

The present invention is therefore based on the object to propose an improved method for producing a container, which requires less joining steps for the production of the container and at the same time increases the flexibility in the shape of the container. Furthermore, the present invention is based on the object to provide an improved container.

According to a first teaching of the present invention, the object is achieved by a method for producing a container, in which the container is formed by hydroforming a hollow body, wherein the end face regions of the container are formed during the hydroforming.

To carry out hydroforming, a hollow body is introduced as a blank into the die of a molding tool. The die of the mold has a shape corresponding to the desired shape of the container to be manufactured. Subsequently, an active medium is introduced into the hollow body. Under the influence of pressure, the hollow body is molded into the die of the molding tool. The shaping by hydroforming is not limited to the container shell. According to the invention, the front side regions of the container to be produced are also produced. The container shell as well as the front side areas are thus formed from the same hollow body. A separate provision of frontal areas and container shell is no longer necessary. Complex Preformverfahrens steps such as the deep drawing of the front side areas are therefore superfluous. The welding or other types of joining the front side areas with the container shell can thus be omitted. Rather, the front side areas are mitgeformt by the hydroforming of the hollow body and are therefore seamlessly connected to the container shell. A material entry heat input during a welding operation to connect the end faces with the container shell can be avoided. The container thus produced therefore has a very good stability. Further, the shape that the container is to take after the hydroforming can be freely selected by a corresponding configuration of the mold.

In a preferred embodiment of the method is used as a hollow body, a tubular hollow body. Tubular hollow bodies are particularly suitable for hydroforming into a container because they have an annular cross-sectional profile. The shape of the container to be produced is therefore least restricted by a tubular hollow body. But of course, other shaped hollow body suitable for the process.

Preferably, a seamless hollow body, for example an extruded profile or a longitudinally welded pipe, is used as the hollow body. As a seamless hollow body, for example, hollow bodies of metal may be used, which have been extruded or cast from a molten metal. However, it is also possible to use a hollow body, for example a pipe, which has a weld seam, in particular a longitudinal weld seam. The welding process can preferably be carried out without additional materials. As a result, the container consists only of a metal alloy with a uniform composition, which has an advantageous effect on the resistance and strength of the weld or the container.

Preferably, the hollow body is formed of aluminum or of an aluminum alloy. On the one hand, aluminum or aluminum alloys are particularly suitable for hydroforming because of their advantageous forming properties. On the other hand, they have considerable weight advantages over steel containers. In addition, the containers made of aluminum or aluminum alloy by hydroforming can be used for a variety of applications. However, it is also conceivable to manufacture the container from steel or stainless steel.

In a further preferred embodiment of the method, the hollow body is cold-formed high-pressure. This means that no targeted heat input to the hollow body before hydroforming or during hydroforming. Thus, the energy required for hydroforming is kept low.

However, it is also possible to reshape the hollow body warm hydroforming. In this case, the hollow body is heated specifically before hydroforming or during hydroforming. The heat can be transmitted to the hollow body via the active medium, the molding tool and / or via separate heat transfer means. The effect of heat on the hollow body improves its forming properties for the hydroforming process.

According to a further advantageous embodiment of the method, the hollow body is reduced before the hydroforming at least one end. Thus, in particular the hydroforming of the end face regions can be supported and / or optionally supplemented. Thus, it is possible, for example, to provide by the reduction of points on the end face areas, where a later to be carried out further processing of the container produced by hydroforming can begin.

It can, for example, after the hydroforming at least one end face portion of the container, a thread be incorporated. The type of thread is basically not limited to specific embodiments. Threads are particularly suitable for creating or making available connection points so that the container can be connected to other components.

Preferably, the container is provided on at least one end face area with a closure, with a connecting piece and / or with lines.

It is particularly advantageous if a pressure vessel or a tank is produced by the method. In a pressure vessel gaseous and / or liquid media are stored under pressure. The pressure difference to the environment can be positive or negative. Positive pressure difference means that the pressure in the interior of the container is greater than in the environment of the container. Accordingly, negative pressure difference means that the pressure in the interior of the container is smaller than in the vicinity of the container. The hydroforming containers have no welds between the face areas and the container shell. This reduces the points at which shortcomings, for example insufficient tightness or breakage due to embrittlement of the welded material, can occur in the case of pressure vessels under a pressure load. Thus, containers produced by hydroforming are particularly suitable for use as pressure vessels. Pressure vessels are used, for example, as so-called pressurized gas containers for the storage of liquid oxygen, liquid nitrogen, liquid helium or the like, but are not limited to this particular application. Tanks, in particular tanks for motor vehicles, can not only be produced more cheaply with the method according to the invention, but also have less potential vulnerabilities due to the small number of welds in the event of an accident.

The object according to the invention is achieved according to a further teaching of the present invention by a container with two end-side regions and with a container casing arranged between the end-side regions in that the container has been shaped by hydroforming a hollow body so that the end-side regions of the container are seamlessly connected to the container casing are. With regard to the advantages of the container according to the invention, reference is made to the comments on the method according to the invention.

Preferably, the container has a longitudinal weld, in particular a high-frequency welded longitudinal seam or is completely seamless. The starting material of the longitudinally welded containers are usually longitudinally welded tubes, which have an improved forming behavior. In completely seamless containers, for example, made of an extruded tube, no joining method such as welding is used, so that on the one hand saves steps and weak points on the container body can be avoided.

Furthermore, it is advantageous for the container casing to have an annular, rectangular, square or polygonal cross section. This allows the container shape to be adapted to the application. The cross-sectional profile is but not limited to the above forms.

In a preferred embodiment of the container, the container is made of aluminum or of an aluminum alloy, so that it has an optimized weight with high strength.

Furthermore, a thread is preferably incorporated on at least one end face region of the container in order to easily create a connection point or to simplify the closing of the container.

If the container is provided with a closure, with a connection piece and / or with lines at at least one end area, the connection and the use of the container can be simplified.

The wall thickness of the container is preferably 0.5 mm to 15 mm. This wall thickness ensures the necessary strength, especially when used as a pressure vessel or tank with low weight. At the same time, the forming properties of, for example, an aluminum alloy at these wall thicknesses are still sufficient for carrying out the hydroforming process.

If the container is a pressure vessel or a tank, they can be provided with reduced weight with simple production with a few process steps.

Fig. 1a

zwei Stirnseitenbereiche und einen Behältermantel als separate Behälterteile, wie sie aus dem Stand der Technik bekannt sind, in einem Seitenquerschnitt, bevor sie zu einem Behälter verschweißt werden,

Fig. 1b

die Behälterteile aus Fig. 1a in einem Seitenquerschnitt, nachdem sie zu einem Behälter verschweißt wurden,

Fig. 2 und 3

ein Ausführungsbeispiel des Verfahrens gemäß der vorliegenden Erfindung in einer schematischen Darstellung und

Fig. 4

eine beispielhafte Ausgestaltung eines Behälters, wie er durch das erfindungsgemäße Verfahren herstellbar ist.

In the following the invention will be explained in more detail with reference to an embodiment, reference being made to the accompanying drawings. In the drawing shows

Fig. 1a

two end face regions and a container shell as separate container parts, as known from the prior art, in a side cross-section, before they are welded into a container,

Fig. 1b

the container parts Fig. 1a in a side cross-section, after being welded into a container,

FIGS. 2 and 3

an embodiment of the method according to the present invention in a schematic representation and

Fig. 4

an exemplary embodiment of a container as it can be produced by the method according to the invention.

Fig. 1a shows a container shell 2 and two end portions 4a, 4b in a side cross-section, which are to be joined together to form a container 6, as is common in the prior art. The container shell 2 was preformed from a rectangular blank of an aluminum strip into a hollow cylindrical shape and then longitudinally welded. The end face portions 4a, 4b were formed by deep drawing, respectively preformed from a circular blank of the same aluminum strip and after this transformation have a cup-shaped design. The cross-sectional profiles of both the preformed container casing 2 and the preformed end-face regions 4a, 4b have been adapted such that one preformed end-face region 4a, 4b can be brought from one side to the front sides of the preformed container casing 2 (arrows), in order to be welded flush there become.

The finished container 6 after welding is in Fig. 1b to see. In addition to the longitudinal weld seam (not shown) on the container jacket 2, two annular welds 8a, 8b are visible, which substantially circulate the container. In addition to the high number of welds, welding also brought about a heat input into the aluminum, which in principle reduces the strength of the aluminum alloy at this point.

Fig. 2 shows according to an embodiment of the method according to the invention in a schematic side cross-section how a longitudinally welded aluminum tube 10 has been introduced into a mold 12. Of course, it is also possible to use a completely seamless aluminum tube 10, for example when the tube has been extruded or cast from an aluminum melt. The die of the molding tool 14 has a cylindrical shape and thus defines the shape of the container 6 to be produced.

Fig. 3 shows in the continuation of the example Fig. 2 like the aluminum tube 10 with an active medium 16, for example, a water-oil emulsion has been filled. The, for example, by a punch, not shown, pressure exerted by the two end faces (arrows) causes the aluminum tube 10 is formed in the mold 12 internal high pressure and formed in the die of the mold 14. Before hydroforming or during hydroforming, the aluminum tube 10 may be heated to improve its forming properties

After the hydroforming has taken place, the protruding aluminum pipe sections at the end face regions 4a, 4b of the molded container 6 can be cut or completely removed, for example by sawing. The front side portions 4a, 4b of the container 6 can now be provided with a thread 18, which can serve in particular as a connection for closures, lines or the like, as in Fig. 4 is shown.

In the in Fig. 4 shown exemplary embodiment of the container 6, the container casing 2 has a circular cross-section. But it is also possible to provide the container casing 2 with a rectangular, in particular square, polygonal or other different cross-section. Polygonal cross sections, which include as special cases, the rectangular and square cross-sections, for example, offer the advantage of allowing a higher packing density of adjacent, similar containers 6.

The container produced according to the example described above can be used in particular as a pressure vessel. Since no joining process had to be used to connect the end faces of the container with the container shell, the number of joining zones on the finished container is minimized compared to containers known from the prior art. Due to the lack of joining, the heat input into the container material in the region of the container jacket could also be avoided, which leads to an improved strength of the container.

Claims (15)

A method of manufacturing a container in which the container is formed by hydroforming a one-piece hollow body, wherein the end-face portions of the container are co-formed during hydroforming,
characterized in that
after the hydroforming at least one end face portion of the container a thread is incorporated. Method according to claim 1,
characterized in that
the hollow body is formed of aluminum or of an aluminum alloy. Method according to claim 1 or 2,
characterized in that
the hollow body is cold-formed to hydroforming. Method according to one of claims 1 to 3,
characterized in that
the hollow body is converted to warm hydroforming. Method according to one of claims 1 to 4,
characterized in that
the hollow body is reduced before hydroforming at least one end. Method according to one of claims 1 to 5,
characterized in that
the container is provided on at least one end face region with a closure, with a connecting piece and / or with lines. Method according to one of claims 1 to 6,
characterized in that
a pressure vessel or a tank is made. Use of a container produced according to one of claims 1 to 7 as a pressure vessel. Container, in particular produced according to a method described in claims 1 to 8,
with two end face regions (4a, 4b) and with a container shell (2) arranged between the end face regions (4a, 4b),
the container (6) has been formed by hydroforming a hollow body (10) so that the end-side regions (4a, 4b) of the container (6) are connected seamlessly to the container jacket (2),
characterized in that
at least one end face region (4a, 4b) of the container (6) a thread (18) is incorporated .. Container according to claim 9,
characterized in that
the container (6) has a longitudinal seam or is completely seamless. Container according to claim 9 or 10,
characterized in that
the container casing (2) has an annular, rectangular, square or polygonal cross-section. Container according to one of claims 9 to 11,
characterized in that
the container (6) is made of aluminum or of an aluminum alloy. Container according to one of claims 9 to 12,
characterized in that
the container (6) is provided on at least one end face region (4a, 4b) with a closure, with a connecting piece and / or with lines. Container according to one of claims 9 to 13,
characterized in that
the wall thickness of the container (6) is 0.5 mm to 15 mm. Container according to one of claims 9 to 14,
characterized in that
the container (6) is a pressure vessel or tank.

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