EP2888383A1 - Highly malleable and igc-resistant almg strip - Google Patents

Abstract

The invention relates to a cold-rolled aluminum alloy strip made of an AlMg aluminum alloy as well as a method for producing the same. Furthermore, adequate components made from said aluminum alloy strips are also disclosed. The aim of the invention is to design a single-layer aluminum alloy strip that is sufficiently resistant to intergranular corrosion and is nevertheless very easily malleable so that even large-area deep-drawn parts, e.g. interior parts of motor vehicle doors, can be made with sufficient strength. Said aim is achieved by an aluminum alloy strip made of an AlMg aluminum alloy which has the following alloying components: Si ≤ 0.2 wt.%, Fe ≤ 0.35 wt.%, Cu ≤ 0.15 wt.%, 0.2 wt.% ≤ Mn < 0.35 wt.%, 4.1 wt.% ≤ Mg ≤ 4.5 wt.%, Cr ≤ 0.1 wt.%, Zn ≤ 0.25 wt.%, Ti ≤ 0.1 wt.%, the remainder consisting of Al and inevitable impurities, each of which amounts to no more than 0.05 wt.% and the total amount of which amounts to no more than 0.15 wt.%. The aluminum alloy strip has a recrystallized structure, the average grain size of the structure ranges from 15 μm to 30 μm, preferably from 15μm to 25 μm, and the final soft annealing of the aluminum alloy strip is performed in a continuous furnace.

Description

 Highly formable and IK-resistant AlMg tape

The invention relates to a cold-rolled aluminum alloy strip consisting of an AlMg-aluminum alloy and a process for its preparation. Furthermore, even corresponding components are made from the

Aluminum alloy strips are proposed.

Aluminum magnesium (AlMg) alloys of type AA 5xxx are used in the form of sheets or plates or strips for the construction of welded or joined structures in shipbuilding, automotive and aircraft construction. They are characterized in particular by a high strength, which increases with increasing

 Magnesium content increases. AlMg alloys of the type AA 5xxx with Mg contents of more than 3%, in particular more than 4%, are increasingly prone to intercrystalline corrosion when exposed to elevated temperatures. At temperatures of 70 - 200 ° C, β-A15Mg3 phases separate out along the grain boundaries, which are called β-particles and can be selectively dissolved in the presence of a corrosive medium. As a result, especially the very good

Strength properties and a very good formability having

Aluminum alloy of type AA 5182 (AI 4.5% Mg 0.4% Mnj not in

heat-stressed areas is used, provided that the presence of a corrosive medium, such as water in the form of moisture, must be expected. This concerns in particular the components of a motor vehicle, which are usually subjected to cathodic dip painting (KTL) and

Subsequently, they are dried in a baking process, since sensitization with respect to intercrystalline corrosion can already be caused by this baking process in conventional aluminum alloy tapes. In addition, for use in the automotive sector, the forming during the production of a component and the subsequent operating load of the component must be taken into account. The susceptibility to intergranular corrosion is usually in a

Standard test (NAMLT test) according to ASTM G67, in which the samples are exposed to nitric acid and the mass loss due to the

intercrystalline corrosion is measured. According to ASTM G67 is the

Mass loss in materials that are not resistant to intercrystalline

Corrosion are more than 15 mg / cm ² .

Automotive sheets require very good formability, as in the case of interior door parts, for example. The requirements are essentially determined by the rigidity of the respective component, where the strength of the material plays only a minor role. The components often go through multi-stage

Forming processes, such as door interiors with integrated

Joinery areas. In addition to the corrosion properties, the formability of the AlMg

Aluminum alloy has a great influence on the possibilities of using these materials. For example, the previously known materials have meant that the side walls of a motor vehicle could not be pulled deep from a single sheet, which not only a redesign of the side wall, but also additional process steps to provide the side wall part of a

Motor vehicle required.

The forming behavior can, for example, in stretch-stretching by a

Camber test according to Erichsen (DIN EN ISO 20482) are measured, in which a test piece is pressed against the sheet, so that it comes to a cold deformation. During cold working, the force as well as the punch away from the specimen is measured until there is a load drop which causes the formation of a crack. The SZ32 stretch drawing measurements mentioned in the application were made with a punch head diameter of 32 mm and a

Diameter of 35.4 mm with the help of a Teflon drawing film to reduce friction performed. Further measurements of the thermoformability were made by the so-called plane-strain-depression experiment with a Nakajima Geometry according to DIN EN ISO 12004 with a punch diameter of 100 mm. These are samples with a specified geometry

Camber tests until the formation of cracks, the depression during the tearing is then used as a measure of the formability of the material.

Composite solutions consisting of high Mg-containing AA5xxx

Aluminum alloys with corrosion protective outer

Aluminum alloy layers have the disadvantages that the production is complex and also at joints where the aluminum composite is connected to other parts, for example, cut edges, holes and breakthroughs continue to be given an increased risk of corrosion.

The present invention therefore deals with single-layered

Aluminum materials. Proceeding from this, the object of the present invention is to provide a single-layered aluminum alloy strip which has sufficient resistance to intergranular corrosion and is nevertheless very easy to form, so that deep-drawn parts of large dimensions, for example door parts of motor vehicles, can be provided with sufficient strength , In addition, a method is to be specified with which single-layer aluminum alloy strips can be produced. Finally, components produced from the aluminum alloy strips according to the invention are to be specified.

According to a first teaching of the present invention, the object is achieved by a cold-rolled aluminum alloy strip consisting of an AlMg aluminum alloy, the aluminum alloy comprising the following

Alloy components comprising:

Si <0.2 wt .-%.

 Fe <0.35 wt%,

 Cu <0.15 wt.%,

0.2% by weight <Mn <0.35% by weight, 4.1% by weight <Mg <4.5% by weight,

 Cr <0.1 wt%,

 Zn <0.25 wt.%,

 Ti <0.1 wt.%,

Rest AI and unavoidable impurities individually max. 0.05% by weight, in total max. 0.15 wt .-%, wherein the aluminum alloy strip has a recrystallized structure, the mean grain size of the structure between 15 μιτι and 30 microns,

preferably between 15 μπι and 25 μηι and the final soft annealing of the aluminum alloy strip has been carried out in a continuous furnace.

Within the specification of the AA5182 aluminum alloy, it has been found that there is a specified, narrowly limited alloying range which, on the one hand, has sufficient resistance to intergranular corrosion and, at the same time, taking into account certain secondary conditions, such as average grain size and the type of final soft annealing, also has an excellent forming behavior. In particular, the combination of the mean grain size with the claimed alloying components of

Aluminum alloy of the aluminum alloy strip make it possible to achieve degrees of deformation, which allow sufficient strength, the production of large-scale, deep-drawn aluminum sheet metal parts. In particular, it has been shown that the use of a continuous furnace instead of a conventionally carried out Coilglühung in a chamber furnace significantly increases the formability again.

According to a first embodiment of the aluminum alloy strip has the

Aluminum alloy in addition to one or more of the following alloy contents content limits: 0.03 wt% Si <0.10 wt%,

Cu <0.1%, preferably 0.04% <Cu <0.08%, Cr <0.05% by weight, Zn <0.05% by weight,

0.01% by weight <Ti <0.05% by weight

The limited alloying content of copper to at most 0.1% by weight leads to an improvement in the corrosion resistance of the aluminum alloy strip. With a Cu content of 0.04 wt .-% to 0.08 wt .-% is achieved that copper participates in an increase in strength, but still does not reduce the corrosion resistance too strong. Higher levels of silicon, chromium, zinc and titanium than the

given values lead to a reduced formability of the

Aluminum alloy. The silicon content in the alloy of 0.03 to 0.1% by weight, in combination with the iron and manganese fractions in the stated amounts, leads in particular to relatively uniformly distributed, compact particles of the quaternary a-Al (Fe, Mn) Si Phase, which increase the strength of the aluminum alloy without adversely affecting other properties such as formability or corrosion behavior.

Titanium is commonly used in continuous casting of the aluminum alloy

Grain refining agent added, for example, in the form of Ti-boride wire or rods. Therefore, the aluminum alloy in another

Embodiment a Ti-content of at least 0.01 wt .-% on.

A further improvement of the corrosion behavior and the formability of the aluminum alloy strip can be achieved in that the

Aluminum alloy additionally has one or more of the following restrictions on the contents of alloy constituents:

Cr <0.02 wt.%,

 Zn <0.02 wt .-% It has been found that chromium is clearly in content below the

Pollution threshold of 0.05 wt%, the formability of the

Al uminiumlegierungsbandes influenced and thus in the lowest possible proportions in the aluminum alloy of the aluminum alloy strip according to the invention may be included. The zinc content is set below the impurity threshold of 0.05% by weight to reduce the overall corrosion behavior of the

Aluminum alloy strip not to deteriorate.

In addition, it has been found that iron within the according to the

Type AA5182 aluminum alloy values in conjunction with the silicon and manganese levels as described above have an effect on the

Formability has. Iron, in combination with silicon and manganese, contributes to the performance of the aluminum alloy strip so that, preferably, the Fe content of the aluminum alloy strip is 0.1 wt.% To 0.25 wt. 10 wt .-% to 0.20 wt .-% is.

The same also applies to the Mn content according to a further embodiment of the aluminum alloy strip, which should preferably be limited to 0.20 wt .-% to 0.30 wt .-%, in order to optimize the formability of

To reach aluminum alloy strip.

A particularly good compromise between the provision of high strength, good corrosion resistance to intergranular corrosion and improved forming properties can according to a further embodiment of the

Aluminum alloy ribbon having a Mg content of 4.2 wt .-% to 4.4 wt .-% can be achieved. In order to provide the necessary strength for the applications, the aluminum alloy strip according to a next embodiment has a thickness of 0.5 mm to 4 mm. Preferably, the thickness is 1 mm to 2.5 mm, as in this area are the most applications of the aluminum alloy strip. Finally, in particular areas of application in the automotive sector for the aluminum alloy strip according to the invention are made possible by the fact that the

Aluminum alloy strip in the soft state a yield strength R _p o, 2 of min. 110 MPa and a tensile strength R _m of min. 255 MPa. It has

In particular, aluminum alloy tapes with appropriate yield strengths and tensile strengths are particularly well suited for use in the

Automotive sector are suitable.

According to a second teaching of the present invention, the above-described object is achieved by a method for producing an aluminum alloy strip according to the above-described embodiments in that the method comprises the following method steps:

Casting a rolling bar, preferably in DC continuous casting,

 Homogenizing the rolling ingot at 480 ° C - 550 ° C for min. 0.5 hours,

 Hot rolling of the rolling ingot at a temperature of 280 ° C to 500 ° C, cold rolling of the aluminum alloy strip to final thickness with a

 Abwalzgrad of 40% to 70% or 50% to 60% and

 Annealing of the finished rolled aluminum alloy strip at 300 ° C - 500 ° C in a continuous furnace

It has been found that with the specified parameters in conjunction with the abovementioned aluminum alloy constituents, an aluminum alloy strip with mean particle sizes of 15 μm-30 μm can be produced, which is sufficient

Has resistance to intergranular corrosion, sufficient

Provides strength and also has very good forming properties, so that large-area, deep-drawn sheet metal parts can be produced. The

Homogenizing the rolling billet ensures a homogenous structure and a homogeneous distribution of the alloy components in the hot rolling billet to be rolled. Hot rolling at temperatures of 280 ° C - 500 ° C allows a

continuous recrystallization during hot rolling, wherein the hot rolling is typically carried out to a thickness of 2.8 mm - 8 mm. The final cold rolling step is limited to a degree of rolling of 40% to 70% or 50% to 60%, to provide in both cases in the soft annealing for a continuous recrystallization of the aluminum alloy strip. The bigger the Abwalzgrad the aluminum alloy strip, the smaller the average grain sizes, it has been found that above 70% degree of reduction in the final annealing can result in a too small average grain size. Below 40% Abwalzgrad be in the soft annealing, the middle

Again, grain sizes too large, so that although the resistance to intergranular corrosion increases, but the formability is reduced. The soft annealing of the finished rolled aluminum alloy strip takes place in the continuous furnace, which usually heating rates of 1 - 10 ° C / sec. and thus, in contrast to chamber furnaces, in which an entire coil is heated, due to the rapid heating have a significant influence on the subsequent properties of the structure of the aluminum alloy strip. In particular, it has been found that in soft annealing in a continuous furnace improved formability of the strip is achieved in comparison to variants annealed in the chamber furnace. Alternatively, according to another embodiment of the method, the

 Aluminum alloy strip can also be produced with an intermediate annealing.

According to this alternative variant, the following process steps are alternatively carried out after hot rolling: Cold rolling of the hot-rolled aluminum alloy strip to a

 Intermediate thickness, which is determined such that the final

 Cold rolling at final thickness 40% to 70% or 50% to 60%

 Intermediate annealing of the aluminum alloy strip at 300 ° C to 500 ° C, cold rolling of the aluminum alloy strip to final thickness with a

 Rolling degree from 40% to 70% or 50% to 60%,

 Annealing of the finished rolled aluminum alloy strip at 300 ° C to 500 ° C in a continuous furnace

The intermediate annealing of the aluminum alloy strip can take place both in the chamber furnace and in the continuous furnace. An influence on the formability could not be determined. The decisive factor is which degree of rolling is achieved during cold rolling to final thickness and whether the soft annealing of the strip takes place in the continuous furnace. As a result, regardless of the type of intermediate annealing, the formability and the corrosion resistance are determined in connection with the alloy composition. In order to prevent a further change in the structural state in the wound state after the soft annealing, the aluminum alloy strip according to a further embodiment of the method after annealing to a temperature of max. 100 ° C, preferably to max. Cooled to 70 ° C and then

coiled.

As already stated above, according to another embodiment of the method, the intermediate annealing can be carried out in a batch furnace or in a continuous furnace. If the aluminum alloy strip cold rolled to a final thickness of 0.5 mm - 4 mm, preferably to a final thickness of 1 mm - 2.5 mm, the typical application areas, especially in automotive very well convertible sheets are available, which can be deep-drawn extensively and simultaneously high strength combined with sufficient

Provide corrosion resistance to intergranular corrosion.

Preferably, the soft annealing is carried out in a continuous furnace at a metal temperature of 350 ° C - 550 ° C, preferably at 400 ° C - 450 ° C for 10 sec. - 5 min., Preferably 20 sec - 1 min. This ensures that the cold strip recrystallized sufficiently by and the corresponding properties in relation to the very good formability and the average grain size with high process reliability and

Economic efficiency can be achieved.

Finally, the object shown above is achieved by a component for a motor vehicle which has been produced from the aluminum alloy strip according to the invention. The components are characterized by the fact that they, as already stated, can be deep-drawn over a large area and thus, for example, large-area components can be made available for the automotive industry. In addition, these have due to the provided strength and the necessary

Rigidity and corrosion resistance, which are suitable for use in

Motor vehicle construction are required.

It is conceivable, for example, that the component is according to a further embodiment, a body part or a body part of a motor vehicle, which is loaded in addition to high strength requirements and temperature. Preferably, the "body-in-white parts", for example, a door inner part or a

Tailgate inner part, made from the aluminum alloy strip according to the invention.

In addition, the invention will be explained in more detail with reference to embodiments in conjunction with the drawings. The drawing shows in

Fig. 1 is a schematic flow diagram of an embodiment of the

 Production method of the aluminum alloy strip,

2a is a plan view of the sample geometry for the tarpaulin strain measurement according to DIN EN ISO 12004,

2b shows in a sectional view the schematic experimental setup of the plan

Strain-Tiefungsmessung according to DIN EN ISO 12004, Fig. 3 in a sectional view of the test arrangement for Tiefungsmessung

 SZ32 in the Erichsen creep test according to DIN EN ISO 20482 and

Fig. 4 shows a typical embodiment of a large, deep-related

 Sheet metal part according to the present invention.

Fig. 1 shows the sequence of embodiments for the production of

Aluminum strips. The flowchart of Fig. 1 shows schematically the various process steps of the manufacturing process of the aluminum alloy strip according to the invention.

In step 1, a billet of an AlMg aluminum alloy is cast with the following alloying constituents, for example in DC continuous casting:

Si <0.2 wt.%,

 Fe <0.35 wt%,

 Cu <0.15 wt.%,

 0.2% by weight <Mn <0.35% by weight,

 4.1% by weight <Mg <4.5% by weight,

 Cr <0.1 wt%,

 Zn <0.25 wt.%,

 Ti <0.1 wt.%,

Each of the remaining AI and unavoidable impurities at a maximum of 0.05% by weight,

Total not more than 0.15 wt .-%.

Subsequently, the rolling ingot in procedural step 2 is subjected to homogenization, which can be carried out in one or more stages. In a homogenization temperatures of the rolling ingot are reached from 480 to 550 ° C for at least 0.5 h. In process step 3, the rolling ingot is then hot rolled, with typical temperatures of 280 ° C to 500 ° C can be achieved. The final thicknesses of the hot strip are, for example, 2.8 to 8 mm. The

Hot strip thickness can be selected so that after hot rolling only a cold rolling step 4 takes place, in which the hot strip with a rolling degree of 40% to 70%, preferably 50% to 60% in its thickness is reduced to the final thickness.

Subsequently, the aluminum alloy strip cold rolled to final thickness is subjected to soft annealing. The soft annealing is carried out according to the invention in a continuous furnace. In the embodiments shown in Table 1 the second way was used with an intermediate glow. For this purpose, the hot strip after hot rolling according to process step 3 is fed to a cold rolling 4a, which cold rolled the aluminum alloy strip to an intermediate thickness, which is determined such that the final cold rolling degree of final thickness 40% to 70% or 50% to 60%. In a subsequent intermediate annealing, the aluminum alloy ribbon is preferably recrystallized throughout. The

Intermediate annealing was carried out in the embodiments either in a continuous furnace at 400 ° C to 450 ° C or in the chamber furnace at 330 ° C to 380 ° C. The intermediate annealing is shown in FIG. 1 with method step 4b. in the

Process step 4c of FIG. 1 is the intermediate annealed

Finally, aluminum alloy strip is fed to a cold rolling to final thickness, wherein the degree of rolling in step 4c is between 40% and 70%, preferably between 50% and 60%. Subsequently, the aluminum alloy ribbon is returned to the soft state by a soft annealing, wherein the

 Soft annealing is carried out according to the invention in a continuous furnace at 400 ° C to 450 ° C. The anneals of Comparative Examples in Table 4 were carried out in the chamber furnace (KO) at 330 ° C to 380 ° C. In the various tests, different degrees of rolling were set after intermediate annealing in addition to different aluminum alloys. The values for the degree of rolling after the intermediate annealing are also given in Tables 1 and 4. In addition, the mean grain diameter of the soft-annealed aluminum alloy strip was determined. For this purpose, longitudinal slices were anodized according to the Barker method and then measured under the microscope in accordance with ASTM E1382 and the mean grain size determined by the mean grain diameter.

On the correspondingly produced aluminum alloy strips were

mechanical properties, in particular the yield strength R _p o, 2, tensile strength R _m , the uniform elongation A _g and the elongation Aeomm determined, Table 2, 5. In addition to the measured according to EN 10002-1 or ISO 6892 mechanical characteristics of the aluminum alloy strips are also the mean particle sizes according to ASTM E1382 in μιη indicated. In addition, the corrosion resistance was against Intercrystalline corrosion measured according to ASTM G67, without additional heat treatment in the initial state (output Oh). To use in the

In addition, before the corrosion test, the aluminum alloy ribbons were subjected to different heat treatments. A first heat treatment consisted of storing the aluminum strips for 20 minutes at 185 ° C to image the KTL cycle.

In a further series of measurements, the aluminum alloy strips were additionally stored for 200 hours or 500 hours at 80 ° C. and then subjected to the corrosion test. Since transformations of aluminum alloy strips or sheets can additionally affect the corrosion resistance, the

Aluminum alloy tapes were stretched by about 15% in a further test, subjected to a heat treatment or storage at elevated temperature, and then subjected to an intergranular corrosion test according to ASTM G67 in which mass loss was measured.

In Table 1, the alloy contents are four different

Aluminum alloys, which are within the specification of the aluminum alloy of type AA5182 specified. The reference alloy represents the material used hitherto and is given in comparison to variants 1, 2 and 3. In addition, in Table 1, an indication of the type of final annealing, the final rolling and the measured average grain size (grain diameter) in μιτί. The variants 1 and 2 differed only in the final rolling, which leads to the formation of a different grain size. Thus variant 2 of variant 1, apart from almost identical alloy constituents, essentially differs by a final rolling degree of 57% for identical ones

Belt furnace conditions. The result was that variant 2 had a mean particle size of 18 μιη compared to 33 μηι variant 1 had. The tapes in Table 1 were brought to a temperature of 400 ° C - 450 ° C in a continuous belt oven for 20 sec. - 1 min., Then cooled and wound up at less than 100 ° C. The samples taken were then measured according to the corresponding DIN EN ISO standards as indicated in Table 2. It can be seen from Table 2 that variant 1 does not reach the value of 110 MPa with respect to the yield strength and that it does not reach the diagonal measurement,

marked with the symbol D, has a value of less than 110 MPa. The measurement in the rolling direction L and transverse to the rolling direction Q, however, showed that variant 1 just reached a yield strength R _p o, 2 of 1 0 MPa. The reference and variants 2 and 3 were well above this lower limit for the

Stretch limit. The embodiment variant 2 according to the invention certainly reached the yield strength values of at least 110 M Pa in all tensile directions. It can be clearly seen that variant 3 with the highest Mg content of 4.95% by weight achieves the highest yield strength and tensile strength values. In addition, it can be seen that the varying degree of rolling between variants 1 and 2 not only significantly affects the grain size, but in particular raises the yield strength to a value of significantly more than 110 MPa.

In particular, the inventive alloy variant 2 has a lower anisotropy compared to the reference, which is reflected in low values of the planar anisotropy Ar. The planar anisotropy Ar is defined as V2- (n + rq-2 rD), where rL, rQ and r »are the r-values in longitudinal, transverse and

Diagonal direction correspond. The mean r-value f, calculated from l / 4- (rL + rQ + 2ro), does not differ significantly from that of the reference material.

Table 3 now shows the measured values taken with respect to intergranular corrosion resistance. It has been found that variant 2 according to the invention has comparable values with respect to the measured values of the reference, in particular with regard to the long-term loading, both in the stretched state and in the unstretched state. Here the variant 2 and the reference are nearly identical. Variant 3, which indeed has the highest yield strength and tensile strength values, showed in the corrosion test, however, that the excessive Mg content would lead to excessive mass loss, especially in the long-term tests, which, in addition to a short tempering cycle of 20 min. At 185 ° C. In addition, a long-term load of 200 hours at 80 ° C have gone through, the result. With regard to the measurements in Table 3 with respect to the formability, it was found that, in particular, variant 2 was superior to the reference alloy in the stretch-drawing properties in the SZ32 deepening test as well as in the plane-strain creep test. The significantly improved forming behavior of the aluminum alloy strip according to Variant 2 over the reference aluminum alloy strip shows that even with a reduced Mg content, equivalent yield strengths and tensile strengths can be achieved with the reference alloy without sacrificing resistance to intergranular corrosion. This was demonstrated in particular by the mass loss measurement according to ASTM G67 in the NAML test. Significantly could with the variant 2 an improvement of thermoforming behavior in

Camber test according to Erichsen by 7% and in Plane-Strain-Tiefungsversuch be determined by about 10%, which the additional reshaping potential of

Aluminum alloy ribbons according to the invention shows. This additional

Forming potential can be used to produce deep-drawn, large-area sheet-metal shaped parts, for example, door inner parts of a car.

In the following, the experimental setup for the test "SZ32 Sumping" according to DIN EN ISO 20482 as well as the Plane-Strain Seaming Test according to Nakajima geometry according to DIN EN ISO 12004 shall be briefly explained.

In Fig. 2a, the geometry of the sample body 1 is shown. From a

Circular sheet metal blank, the waisted specimen 1 is cut so that the web 4 has a width of 100 mm and the radii 2 at the waistings 20 mm. With the measure 3, which is 100 mm, the punch diameter is shown. Fig. 2b now shows the sample 1 clamped between two

Hold-downs 5, 6. The test piece 1, which was placed on a receptacle 8 and was pressed against the support via the hold-downs 5, 6, is pulled in the direction of the arrow with a punch 7, which has a hemispherical tip with a radius of 100 mm Service. The hold-downs have additional

Einlaufradien of 5 or 10 mm on its side facing the support 8 side. The force with which the tilling test is performed becomes during deformation measured and a sudden load drop, which signals the formation of a crack, leading to the measurement of the corresponding Ziehstempeltiefe.

However, no waisted samples are used here, but only a test piece 9 is held between a hold-down 10 and a receptacle 11 and pulled with a punch 12, until a load drop in the pulling force is also achieved The opening of the die in Fig. 3 was 35.4 mm, the

Punch head diameter 32 mm, d. H. the punch radius was 16 mm. In addition, a Teflon drawing film was used to reduce friction in SZ32.

In Tables 4 and 5, further embodiments and

Comparative examples were prepared and measured in terms of their mechanical properties and resistance to intergranular corrosion. It has been found that the combination of the use of the continuous furnace in conjunction with a specifically selected particle size of 15 μηι - 30 μπι, preferably 15μηι - 25 μηι leads to a good compromise between corrosion resistance and mechanical measurements. For example, the invention

Embodiments Nos. 3, 4, 7, 11 and 15 are equipped with a sufficient resistance to intergranular corrosion and also have the mechanical measurements R _p o, 2 and R _m necessary for use in the automotive sector, so that they are ideal for the provision of large-area, deep-drawn components are suitable.

In Fig. 4, for example, a corresponding "body-in-white part, shown in the form of a door inner part, which is using the

Aluminum alloy strip of the present invention can be made from a single, deep-drawn sheet metal. The sheet thickness is thereby

preferably 1.0-2.5 mm. In addition, other parts of a motor vehicle in sheet metal shell design are conceivable, such as the inner parts of the boot lid, hood, as well as components in the vehicle structure, which have high demands on formability and intergranular corrosion.

Table 1

Table 2

Table 3

IK mass loss formability

Variant not thermal 20 min. 185 ° C 20 min 185 ° C 17h 15% 15% stretched SZ 2 tarpaulin treated plus 200 h 80 ° C 130 ° C stretched 20 min. 185 ° C plus 200 hours of subsidence

 20 min. 80 ° C [mm]

 185 ° C [mm]

Limit 2.0 4.0 35.0 50.0 15.0 45.0

 Reference 1.2 2.1 29.8 48.8 10.4 42.1 14.2 27.9

Var. 1 (Comp.) 1.2 1.7 10.4 21.3 4.4 12.9 14.5 30.3

Var. 2 (Inventive) 1.2 2.4 33.7 42.2 13.5 40.1 14.6 30.7

Var. 3 (Comp.) 1.3 5.3 41.7 55.0 30.4 53.5 14.6 31.6

Table 4

Table 5

Claims

claims

1. Cold-rolled aluminum alloy strip consisting of an AlMg aluminum alloy,

 characterized in that

 the aluminum alloy has the following alloy constituents:

 Si <0.2 wt.%,

 Fe <0.35 wt%,

 Cu <0.15 wt.%,

 0.2% by weight <Mn <0.35% by weight,

 4.1% by weight <Mg <4.5% by weight,

 Cr <0.1 wt%,

 Zn <0.25 wt.%,

 Ti <0.1 wt.%,

 Rest AI and unavoidable impurities individually a maximum of 0.05 wt .-%, in total not more than 0.15 wt .-%, wherein the aluminum alloy strip has a recrystallized structure, the grain size of the structure between 15μηι and 30 μιη and the final soft annealing of the aluminum alloy strip in a continuous furnace has been performed.

2. aluminum alloy strip according to claim 1,

 characterized in that

 the aluminum alloy additionally one or more of the following

 Limits on the contents of alloying constituents include:

 0.03% by weight <Si <0.10% by weight,

 Cu <0.1%,

 Cr <0.05% by weight,

 Zn <0.05% by weight,

0.01% by weight <Ti <0.05% by weight. Aluminum alloy strip according to claim 1 or 2,

characterized by the fact that

the aluminum alloy additionally one or more of the following

Limits on the contents of alloying constituents include:

 Cr <0.02 wt.%,

 Zn <0.02 wt .-%.

Aluminum alloy strip according to one of claims 1 to 3,

characterized in that

Fe content is 0.10 wt% to 0.25 wt% or 0.10 wt% to 0.2 wt%.

Aluminum alloy strip according to one of claims 1 to 4,

characterized in that

the Mn content is 0.20 wt% to 0.30 wt%.

Aluminum alloy strip according to one of claims 1 to 5,

characterized in that

the Mg content is 4.2% by weight to 4.4% by weight.

AI u m i n i u m 1 egi ed r e ngsba n d according to one of claims 1 to 6,

characterized in that

the aluminum alloy strip has a thickness of 0.5 mm to 4 mm.

Aluminum alloy strip according to one of claims 1 to 7,

characterized in that

the aluminum alloy strip in the soft state has a yield strength R _p o, 2 of at least 110 MPa and a tensile strength R _m of at least 255 MPa.

9. A process for producing an aluminum alloy strip according to any one of claims 1 to 8, comprising the following process steps:

 Casting a rolled bar,

 Homogenizing the rolling ingot at 480 ° C to 550 ° C for at least 0.5 h,

Hot rolling of the rolling ingot at a temperature of 280 ° C to 500 ° C,

- Cold rolling of the aluminum alloy strip to final thickness with a

 Abwalzgrad of 40% to 70% or 50% to 60% and

 - Annealing the finished rolled aluminum alloy strip at 300 ° C to 500 ° C in a continuous furnace.

10. The method of claim 9, wherein na h the hot rolling alternatively the

 the following process steps are carried out:

 - Cold rolling of the hot rolled aluminum alloy strip on a

 Intermediate thickness, which is determined such that the final degree of final cold rolling is 40% to 70% or 50% to 60%,

 Intermediate annealing of the aluminum alloy strip at 300 ° C to 500 ° C,

- Cold rolling of the aluminum alloy strip to final thickness with a

 Abwalzgrad from 40% to 70% or 50% to 60%

 - Annealing the finished rolled aluminum alloy strip at 300 ° C to 500 ° C in a continuous furnace.

11. The method according to claim 9 or 10,

 characterized in that

 After annealing, the aluminum alloy strip is cooled to a maximum temperature of 100 ° C. and wound up.

12. The method according to any one of claims 10 or 11,

 characterized in that

the intermediate annealing is carried out in a batch furnace or in a continuous furnace. Method according to one of claims 9 to 12,

characterized _» that

the aluminum strip is cold rolled to a final thickness of 0.5 mm to 4 mm.

Method according to one of claims 9 to 13,

characterized in that

soft annealing in a continuous furnace at a metal temperature of 350 ° C to

550 ° C for 10 seconds to 5 minutes.

Component for a motor vehicle produced from an aluminum alloy strip according to one of claims 1 to 8.

Component according to claim 15,

characterized in that

the component is a body component or a body component of a

Motor vehicle is.