DE19926229C1 - Process for in-process heat treatment - Google Patents

Abstract

Production of cold-formed components made of a hardenable aluminum material comprises producing an aluminum strip or sheet, positioning the strip or sheet, heat treating, and cold forming. Cold forming is carried out shortly after heat treatment. Preferred Process: The heat treatment is carried out by calcining and quenching the aluminum strip or sheet. The aluminum strip or sheet has a width of up to 1000 mm.

Description

The invention relates to a method for producing cold-formed components from a hardenable Aluminum material, in which a process integrated Heat treatment is carried out. Curable Aluminum materials, such as Al-Mg-Cu, Al-Mg-Si, Al-Zn-Mg, Al-Cu-Mg or comparable alloys are preferred for Manufacture of cold-formed, especially deep-drawn Components used. Alloys have hardenable alloys with regard to the strengths achievable by the influence of heat special advantages. For example, in the area automotive components such as bonnets, doors etc., proven, that of an Al-Cu-Mg or Al-Mg-Si alloy have been produced. The firmness of these Components made of alloys can, for example due to the effect of a stove enamel finish Increase heat ("bake hardening").

Usually is used for the production of cold-formed Aluminum components used an aluminum band, which by successive hot and cold rolling of a cast Aluminum slab has been produced. Depending on the End user desired condition of the aluminum strip is the Followed by a heat treatment, which comprises annealing the strip in the continuous furnace.  

Such a method is, for example, in German Published patent application DE 196 19 034 A1. At this known method, the aluminum strip before its Forming into a component annealed to ensure formability to improve the aluminum material. The person in question Heat treatment is preferably by means of an inductive one working heating device performed. With a such facility can be large in a relatively short time Apply heat to the material to be annealed.

In connection with the processing of non-curable It is aluminum alloys from the German layout DE AS 10 87 815 also known from the subject Aluminum strip cut blanks to soft anneal before closing Shaped bodies are formed.

The different delivery conditions of aluminum strips are for example in aluminum headquarters: aluminum paperback, Aluminum-Verlag Düsseldorf, 1974, p. 989 ff.

The procedure for carrying out generic production of components made of hardenable aluminum alloys Continuous furnaces used must be designed so that in strips of various widths and thicknesses are annealed to them can be. On the one hand, this brings high investment costs in the construction and operation of such stoves. On the other hand, the problem arises in practice, not only wide, thin ribbons to glow, but also with narrow ribbons a greater thickness. This makes it difficult to find one Continuous furnace considering the desired Capacity utilization to be interpreted so that everyone Heating task.

The production of the aluminum strip explained takes place in the Usually held in a rolling mill. The processor from which Aluminum material by cold forming the component to be manufactured  is manufactured, obtains aluminum strips or - from the rolling mill sheets. This material is then processed at the processor usually stored a certain time before it Cold forming is fed. The camp has the function a buffer that ensures that there is always a sufficient amount of material available for processing stands.

A problem with the storage of curable materials of the above-described type of aluminum strips produced consists of the fact that in the case of tapes which change when leaving the Rolling mill is in the annealed and quenched state, this condition is not stable. So immediately after the End heat treatment as "cold curing" designated process, in the course of which increasing Form lots of fine, metastable material phases, through which the deformability of the material is impaired. Therefore aluminum straps must be delivered within certain deadlines, for example after three months at the latest, but ideally within 14 days after the production of the Cold forming can be supplied. Harden after this time the tapes so strong that their trouble-free Further processing is no longer guaranteed. The limited Durability of the aluminum strips brings for the processor logistical problems and the danger that in the case of a Malfunction larger quantities of those kept in stock Aluminum strips become unusable.

The invention has for its object a method for Manufacture of cold-formed components from curable Specify aluminum materials where the workability of the aluminum strip used regardless of the storage time is.  

This object is achieved according to the invention by a method for producing cold-formed components from a hardenable aluminum material, which comprises the following steps:

• - production of an aluminum strip or sheet,
• - intermediate storage of the aluminum strip or sheet,
• - heat treating the aluminum strip or sheet,
• - cold forming of the aluminum strip or sheet,

whereby the heat treatment occurs immediately before the cold forming he follows. The heat treatment usually involves annealing and quenching the aluminum strip or sheet.

In contrast to the conventional approach, the Invention before, the heat treatment of the aluminum strips or Aluminum sheets only after storage shortly before cold forming perform. Since according to the invention between the Heat treatment and cold forming are only minor Period of time, the process of cold curing can no longer use to a significant extent. The aluminum band or - This is how sheet metal is when it enters the Cold forming device in an optimal one for the deformation Structural state, in which there is a low yield strength, a has a favorable yield ratio and high elongation values.

Another significant advantage of the invention is that that, it is no longer necessary, the rolled aluminum strip or sheet before it is stored in the processor's warehouse undergo an extensive annealing treatment. So can those required by the conventional approach Significant investments in the construction and the Operation of the continuous furnaces used for annealing saved become. Instead, small, compact and therefore inexpensive devices for heat treatment at Processors are set up. These devices can without any problems with regard to the respective heating task  be optimized. The processor is doing this regardless of shelf life and can do so required aluminum strip or sheet at any time according to the consume actual demand. Capacity bottlenecks or insufficient utilization of the aluminum strip processing Devices or plates used can be avoided become.

At the same time stands for the production of the end products Starting material available, which is regarding its processability is in optimal condition. In this way, by the method according to the invention the processing of aluminum strips or aluminum sheets not only reduces investment and operating costs and Utilization efficiency significantly improved, but also that Quality of the products manufactured.

The method according to the invention is particularly suitable for Manufacture of components from aluminum strip or sheet, the a small width and a larger one in relation to the width Has thickness. Such tapes can be inexpensive manufacturable and operable devices effectively be heat treated, the respective Heating devices in contrast to conventional used continuous furnaces in a simple way to the special Task can be adapted. This leads to the fact that Procedure according to the invention in particular in the Processing of narrow, thick strips or sheets in particular significant cost advantages over the conventional Manufacture of such aluminum strips or sheets. So can be preferred with the inventive method Tapes with a width up to 1000 mm and a thickness over Process 3 mm.

Another particular advantage of the invention is Connection with processing thicker, narrower  Aluminum strips or sheets in that for heating of these strips or sheets used without facilities special effort can be designed so that a safe Warming of the respectively heated aluminum strip or sheet is guaranteed. This leads to a further improvement the quality of the thick strips or sheets manufactured end products.

A particularly advantageous embodiment of the invention is characterized in that the heating during the annealing done inductively. Facilities where exposure of an electromagnetic field an inductive heating of the processed goods are carried out, enable the tape to be heated to the within a short time heat the required annealing temperature. Both the Duration and temperature development are precisely controlled be so that an optimal treatment result is achieved. For this reason, working inductively Heating devices especially for the heat treatment of narrow and thick bands or from such bands manufactured blanks where a proper Warming of the material is required, which in conventionally used continuous furnaces only under Difficulties to be guaranteed.

Of course, it is also conceivable to put the tapes in front of the Cold forming, for example in gas or other To heat energy-operated furnaces. This is displayed, for example, when the structural conditions an assembly of the necessary for inductive heating Components, such as coils, converters, etc., makes difficult.

In many applications it is advisable to close the aluminum strip Cut to size before it is cold formed is fed. In such a case, it is beneficial if the Ready-made at a central point from which the  Cuts to the cold forming equipment be forwarded and if the heat treatment of the Aluminum strip immediately before entering the Assembly facility is carried out. Through this Measure can reduce the effort for heat treatment become. At the same time it is between cutting and cutting Cold forming time so short that in that time unwanted cold curing that occurs only a small amount Extent reached and on the result of the cold forming none has significant influence.

The difference between heat treatment and cold forming To minimize passing time, it is according to another Embodiment of the invention favorable when the heat treatment in the catchment area of those used for cold forming Setup is done. With this procedure is ensures that the aluminum strip or from it manufactured blank in for further processing in the best possible condition into cold forming. Especially are suitable for the implementation of these measures due to their small size working inductively Heating devices.

The invention is based on two Exemplary drawing illustrating explained in more detail. In a schematic representation:

Figure 1 shows a process flow in the manufacture of a deep-drawn component.

Fig. 2 shows a process flow while producing several deep-drawn components on different multi-stage presses.

An aluminum strip 1 produced from a hardenable alloy with a small width and a large thickness is produced in a rolling mill 2 in a conventional manner by rolling from a slab. The aluminum strip 1 coiled into coils 3 leaves the rolling mill 2 without having undergone a final heat treatment, such as solution annealing and quenching in a continuous furnace.

The coils 3 are delivered to a processor 4 , who can be, for example, a plant for the production of body components, and stored in the warehouse 5 thereof. If necessary, the coils 3 are removed from the store 5 and transferred to a production line 6 .

The production line 6 comprises a decoiler 7 , a heat treatment device 8 , a blanking press 9 and a multi-stage press 10 . In addition to multi-stage presses, ie forming presses, z. B. also roll profiling systems in question. The heat treatment device 8 is arranged in the feed area 9 a of the blanking press 9 . It comprises a device 8 a for inductive heating, not shown here in detail, and a quenching device 8 b, also not shown in detail. In the heating device 8 a is arranged over the width of the material to be heated, not shown, induction coil is arranged, which generates an electro-magnetic field that causes the heating of the goods located in the effective range of the coil.

The coils 3 removed from the store 5 are placed in the uncoiler 7 . The unwound aluminum strip 1 is fed from this to the heat treatment device 8 . The section of the aluminum strip 1 located in the heat treatment device 8 is first brought to the solution annealing temperature for a short time, for example 2 to 3 seconds, by the induction heating device 8 a. Subsequently, the question, heated to the annealing temperature portion of the aluminum strip 1 is quenched in the quenching b. 8 The section of the aluminum strip 1 which has been heat-treated in this way then passes into the blanking press 9 which stamps blanks 11 from the strip. The blanks 11 are then fed to the multi-stage press 10 .

In the multi-stage press 10 , the annealed and quenched blanks 11 are cold-formed into body components 12 . Due to the small spatial distance between the heat treatment device 8 , the blanking press 9 and the multi-stage press 10 , the time between the heat treatment and the cold forming in the multi-stage press 10 is short. Therefore, the blanks 11 have an optimal structural condition with regard to their formability when they enter the multi-stage press 10 .

In the process sequence shown in FIG. 2, a production line 20 includes a decoiler 21 , a heat treatment device 22 , a blanking press 23 and a plurality of multi-stage presses 24 , 25 , 26 , 27 , 28 , 29 .

The heat treatment device 22 is arranged in the feed region 23 a of the blanking press 23 . Like the heat treatment device 9 shown in FIG. 1, it includes a device 22 a for inductive heating, not shown here in detail, and a quenching device 22 b, also not shown in detail.

In the decoiler 21 , an aluminum strip 31 is wound into a coil 30 and made of a hardenable alloy, which was previously produced in a rolling mill as in the exemplary embodiment according to FIG. 1 and was stored in a warehouse by the processor. From the decoiler 21 , the aluminum strip 31 is fed into the heat treatment device 22 , in which it is briefly heated by the heating device 22 a to solution annealing temperature and then quenched by the quenching device 22 b. The aluminum strip 31 which has been heat-treated in this way and has an optimum state for cold forming then passes into the blanking press 23 in which blanks 33 are punched out of the aluminum strip 31 . The blanks 33 go from the blanking press 23 to the multi-stage presses 24-29 , in which they are cold-formed into multi-stage body components.

REFERENCE SIGN LIST

1

Aluminum strap

2nd

Rolling mill

3rd

Coils

4

Processor

5

camp

6

Production line

7

Decoiler

8th

Heat treatment facility

8th

a Induction heating device

8th

b quenching device

9

Blanking press

10th

Multi-stage press

10th

a Feed area of the multi-stage press

10th

11

Blanks

12th

Body component

20th

Production line

21

Decoiler

22

Heat treatment facility

22

a Induction heating device

22

b quenching device

23

Blanking press

23

a Feeding area of the blanking press

23

24th

,

25th

,

26

,

27

,

28

,

29

Multi-stage presses

30th

Coil

31

Aluminum strap

33

Blanks

Claims (9)

1. A method for producing cold-formed components ( 12 ) from a hardenable aluminum material, comprising the following steps:

• - producing an aluminum strip ( 1 ) or sheet,
• - intermediate storage of the aluminum strip ( 1 ) or sheet,
• - heat treatment of the aluminum strip ( 1 ) or sheet,
• - cold forming of the aluminum strip ( 1 ) or sheet,

whereby the heat treatment takes place immediately before the cold forming. 2. The method according to claim 1, characterized in that the heat treatment comprises annealing and quenching the aluminum strip ( 1 ) or sheet. 3. The method according to claim 2, characterized characterized in that the warming during of the glow takes place inductively. 4. Method according to one of the preceding claims, characterized in that the aluminum strip ( 1 ) or sheet is cut to size ( 11 ) before it is fed to the cold forming. 5. The method according to claim 4, characterized in that the cutting of the blanks ( 11 ) takes place before the heat treatment. 6. The method according to claim 4, characterized in that the assembly takes place at a central point from which the blanks ( 11 ) are forwarded to the cold-forming devices, and that the heat treatment of the aluminum strip ( 1 ) or sheet immediately before entry is carried out in the assembly device ( 8 ). 7. The method according to any one of claims 1 to 5, characterized in that the heat treatment takes place in the feed area of the device ( 10 ) used for cold forming. 8. The method according to any one of the preceding claims, characterized in that the aluminum strip ( 1 ) or sheet has a width of up to 1000 mm. 9. The method according to any one of the preceding claims, characterized in that the aluminum strip ( 1 ) or sheet has a thickness of over 3 mm.