JP6721782B2 - Aluminum alloy and aluminum alloy strip for pedestrian collision protection - Google Patents

Description

The present invention relates to a vehicle aluminum alloy, an aluminum alloy strip manufactured from an aluminum alloy, and a sheet metal body component for an automobile manufactured from the aluminum alloy strip according to the present invention.

Aluminum alloys of the AA6xxx type are used in automotive engineering because of their advantageous combination of good formability and their ability to increase strength by hardening after heat treatment. In contrast to the commonly used aluminum alloy sheet metals, which consist of AA6xxx aluminum alloys, which can obtain particularly high yield strengths by hardening, in the case of sheet metals associated with pedestrian collision protection, for example after heat treatment for painted surfaces , It is necessary to do minimal curing. On the other hand, the pedestrian collision protection sheet metal must have a sufficient energy absorption capability and convert impact energy into deformation energy as intended, and therefore must have an appropriate yield strength. On the other hand, the properties of the sheet metal associated with pedestrian crash protection should not change over time or should be negligible over time. Use of AA6xxx type aluminum alloys with a very low Mg and/or Si content in addition to AA6xxx type higher alloyed aluminum alloys whose hardening properties are degraded by certain manufacturing methods You can also do it. However, in the case of the more highly alloyed aluminum alloys, the production process, and here in particular the control of the solution annealing conditions, is extremely complex and expensive. Furthermore, aluminum alloys with a very low magnesium content of about 0.2% by weight exhibit very low yield strength and tensile strength. Therefore, they are too soft to be used in automobiles. A third possibility is to use soft AA5xxx aluminum alloy. However, they are somewhat susceptible to flow patterns and cannot be used in the visible body area. Moreover, they hinder the uniform alloy concept, for example based on the AA6xxx aluminum alloy, thus making the recycling idea more difficult.

From US Pat. No. 6,037,049, a bodywork component is known which is able to absorb most of its kinetic energy by plastic deformation in the event of a collision and is therefore suitable for pedestrian collision protection. According to the suggestion of US Pat. No. 6,037,037, the elemental magnesium and silicone required for solid solution are present in the form of precipitated Mg ₂ Si and/or Si particles, which hinders artificial aging, and this therefore leads to, for example, painted surfaces. After drying, it has a low hardening effect after further heat treatment. In order to obtain a precipitation state, US Pat. No. 5,968,078 does not carry out homogenization annealing of the cast ingot, but partial solution annealing at lower temperatures, or partial final thickness of rolled sheet metal in coils in a batch furnace. It is proposed to perform only heterogeneous annealing (Germany: partielle Heterogenisierungsgluehung, English: partial heterogenization annealing). These measures add significantly to the cost during manufacture of aluminum alloy strips or adversely affect their processability. Homogenization that has not been performed can affect, for example, the quality of the sheet metal produced.

European Patent Application Publication No. 1 533 394 (A1)

On this basis, the present invention provides that the produced strips have a moderate strength, exhibit only a very low tendency to cure from T4 conditions, and can be used in the area of pedestrian collision protection. It has the object of providing a vehicle aluminum alloy which can be processed into strips using the method steps. Furthermore, the corresponding aluminum alloy strips and sheet metal body parts for automobiles are proposed.

According to the first teaching, the above object of an aluminum alloy strip containing a vehicle aluminum alloy is achieved in that the aluminum alloy contains the following alloying components in weight percent.
0.40 wt% ≤ Si ≤ 0.55 wt%,
0.15 wt% ≤ Fe ≤ 0.25 wt%,
Cu≦0.06% by weight,
0.15 wt% ≤ Mn ≤ 0.40 wt%,
0.33% by weight≦Mg≦0.40% by weight,
Cr≦0.03% by weight,
0.005% by weight≦Ti≦0.10% by weight,
The balance is Al and an unavoidable impurity of up to 0.05% by weight, individually, and up to 0.15% by weight in total.

The aluminum alloy strip according to the invention, in addition to the tensile strength level of at least 130 MPa required for fields of application in automotive engineering, has a markedly weakened hardening and an increased yield strength R _P0.2 compared to known AA6xxx aluminum alloys. Was found to be low. Especially when the aluminum alloy strip is applied in the thermal stress zone, the aluminum alloy strip according to the invention has a significantly lower tendency to harden than aluminum alloy strips made of similar alloys. The proportion of silicone and magnesium in the aluminum alloy is generally responsible for the hardening of the aluminum alloy that constitutes the aluminum alloy strip according to the present invention. A strictly balanced content of silicone and magnesium, here 0.40% to 0.55% by weight of silicone and 0.33% to 0.40% by weight of magnesium, on the other hand, Ensure sufficient strength level of such aluminum alloy strip. On the other hand, a manganese content of 0.15% to 0.40% by weight combined with an iron content of 0.15% to 0.25% by weight, preferably 0.2% to 0.4% by weight or 0%. 20% to 0.30% by weight, excess silicone is bound by the formation of Al-Fe-Mn-Si phases, resulting in less available silicone for curing by precipitation of the silicone-containing particles. .. As a result, the hardening of the aluminum alloy of the aluminum alloy strip according to the present invention may be reduced. Preferably, the silicone content can also be limited to a maximum of 0.50% by weight to prevent cure. Copper is commonly added to increase the strength of aluminum alloys. However, due to the balanced content of silicone, iron, manganese and magnesium, this is not necessary according to the invention. Copper can also impair corrosivity. The aluminum alloy of the aluminum alloy strip according to the invention is therefore substantially copper-free and has a maximum of 0.06% by weight of copper. Copper is also often an undesirable impurity in the case of recycling, so that not only is the corrosion resistance of the aluminum alloy strip improved, but also the recycling of the aluminum alloy strip is facilitated. To improve the formability of aluminum alloy strips, the chromium content is limited to a maximum of 0.03% by weight and the titanium content is limited to 0.005% to 0.10% by weight. Titanium improves atomization during casting of the aluminum alloy strip and is therefore included in the aluminum alloy constituting the aluminum alloy strip according to the invention in at least 0.005% by weight. Due to atomization, a maximum of 0.10% by weight titanium is generally included. The use of up to 0.03% by weight of titanium can minimize the titanium content in the case of good atomization. In the narrow and limited range of alloy compositions, the special hardening properties of the aluminum alloys constituting the aluminum alloy strip according to the invention are exhibited, which is characterized by a low long-term hardening, especially in the case of thermal stress. Was found. The aluminum alloy strip according to the invention is therefore very suitable for use in sheet metal used in pedestrian collision protection in motor vehicle engineering due to its distinct energy absorption capacity, due to its low hardening.

According to the present invention, the aluminum alloy strip according to the first embodiment has a manganese content of 0.25% by weight to 0.35% by weight. This manganese content is an aluminum alloy that constitutes the aluminum alloy strip according to the present invention, since a larger amount of manganese is available to bind excess silicone by forming an Al-Fe-Mn-Si phase. Can be further reduced. At the same time, the further limitation of manganese offsets the increased strength in the T4 condition.

According to a further embodiment, the corrosion behavior of the aluminum alloy strip according to the invention can be improved by reducing the copper content to below 0.05% by weight, preferably up to 0.01% by weight. ..

According to a further embodiment of the aluminum alloy strip according to the invention, the aluminum alloy has a silicone content of 0.40% by weight to 0.48% by weight. This particular reduction in the upper limit of the silicone content can further reduce the hardening of the aluminum alloy by reducing the silicone atoms available for precipitation.

According to a next embodiment of the aluminum alloy strip according to the invention, the aluminum alloy has a magnesium content of 0.35% by weight to 0.40% by weight. This magnesium content allows the aluminum alloy to have slightly higher tensile strength and improved formability due to the higher Mg content while having the same hardening properties.

According to a preferred embodiment of the aluminum alloy strip, it has a yield strength R _p0.2 of 55 MPa to 70 MPa and a tensile strength R _{m of} 130 MPa to 160 MPa measured transversely to the rolling direction at T4 conditions. Have. The preferred combination of yield strength and tensile strength values of this embodiment of the aluminum alloy strip can be preferably used in the manufacture of body parts suitable for pedestrian crash protection. Due to a modest increase in strength or a reduction in hardening, the corresponding sheet metal retains good properties for pedestrian crash protection both after long-term use and with long-term thermal stress.

According to a further embodiment of the aluminum alloy strip according to the invention, it has a yield strength R _{p0.2 of} less than 100 MPa, measured transversely to the rolling direction at T6x conditions. As T6x conditions, a particularly practical heat treatment is specified in this patent application. This includes solution annealing at 530°C for 5 minutes, followed by quenching to room temperature, natural aging at room temperature for 7 days, heating at 205°C for 30 minutes, and heating at 80°C for 500 hours. The first heat treatment step that realizes the T6x condition corresponds to the T4 condition, the usual condition used to realize the known series of heat treatments consisting of solution annealing, quenching and natural aging. Heating to 205° C. for 30 minutes is followed, which is assumed to simulate the heat treatment of sheet metal in the case of painting and paint drying (paint baking). Subsequently, the continuous use of the aluminum alloy sheet metal at high temperature, eg when used near an engine, is simulated by a further heat treatment. For this, the sheet metal is heated at 80° C. for 500 hours. Thermal stress generally accelerates the hardening of aluminum alloys. However, the aluminum alloy strip according to the present invention is significantly less hardened despite high thermal stress and can give a yield strength R _{p0.2 of} less than 100 MPa.

The above objective is accomplished according to a further teaching of the present invention by a method of manufacturing an aluminum alloy strip according to the present invention from an aluminum alloy. The method comprises the steps of casting a rolled ingot, or casting a cast strip, homogenizing the rolled ingot, hot rolling the rolled ingot or cast strip, and, optionally, intermediate annealing. Or without, including cold rolling to final thickness. Contrary to the teaching of US Pat. No. 6,037,048, the method according to the invention comprises conventional method steps, due to the narrowly specified aluminum alloys, especially in the case of long-term thermal stresses, for example in automobile hoods. In some cases, also ensure a sufficient level of tensile strength and less hardening. Using the method according to the invention, aluminum alloy strips for the production of metal sheets for pedestrian collision protection can be produced cost-effectively and of high quality.

The rolled ingot is preferably homogenized for 1 hour or more at a temperature of 450°C to 580°C, preferably 500°C to 570°C. The hot rolling is preferably performed at a temperature of 280°C to 550°C. Hot strip production is also possible by quenching the aluminum alloy strip at the end of hot rolling, the hot strip temperature is reduced to a maximum of 230° C. in the final hot rolling pass and the strip is subsequently wound. Hot strips can be economically produced by these hot rolling methods. In some cases, the hot strip is subjected to cold rolling, in which case the cold rolling is carried out with or without intermediate annealing, depending on the starting thickness of the hot strip and the final thickness of the resulting strip. Be seen. Preferably, strips for the production of sheet metal body parts with a thickness of 0.8 mm to 2.5 mm are produced with or without intermediate annealing. The intermediate anneal can be performed at a temperature of 280°C to 430°C for at least 30 minutes in a batch furnace or in a continuous furnace. Subsequently, solution annealing is carried out in a continuous furnace, followed by quenching, for example to room temperature, followed by natural aging for about 3 to 7 days, the sheet metal and strip in T4 conditions for further processing. Can be made available in a stable condition. At T4 conditions, T4 conditions constitute the preferred starting conditions for sheet metal as maximum formability can be made generally available in AA6xxx alloys. The aluminum strip according to the invention can be produced cost-effectively due to its conventional production and still has a low hardening.

The temperature of the aluminum strip during solution annealing is preferably at least 480°C, preferably at least 500°C for at least 20 seconds. At these solution annealing temperatures, the strips according to the present invention are insensitive to variations or changes in temperature and duration during solution annealing and provide aluminum alloy strips prepared in constant solution. You can

According to a further teaching of the invention, the above object is achieved by a sheet metal body part of an automobile manufactured from the aluminum alloy strip according to the invention. Sheet metal body parts are particularly cost-effective because, with the alloy composition, the conventional method steps of producing aluminum alloy strips have a low tendency to harden and are sufficient to provide sheet metal with moderate strength properties. Can be made available. Since the sheet metal body part has a low hardening tendency, the yield strength R _p0.2 during continuous use increases only slightly. In addition, the corresponding aluminum alloy strips allow for a uniform alloy concept made of AA6xxx alloy with alloy components that are positive in terms of recycling. For this reason, the low proportions of copper, chromium and titanium of the aluminum alloy according to the invention are particularly mentioned.

Preferably, the sheet metal body component is a sheet metal provided for pedestrian crash protection, preferably part of a wing, part of a hood, or a vehicle roof, roof frame or rear door. The sheet metal body part provided for pedestrian collision protection absorbs impact energy by deformation in case of a collision, and sustains a moderate yield strength R _p0.2 in order to absorb the impact of the collision. Must have The hardening properties of the aluminum alloy according to the invention are advantageous here, since the increase in the yield strength R _p0.2 remains moderate over the service life of the sheet metal body part. In addition, sufficient strength levels of sheet metal are also provided to allow easy handling of sheet metal components for wings, bonnets, rear doors, vehicle roofs or roof frames.

According to a further teaching, the above object of a vehicular aluminum alloy is achieved in that the aluminum alloy contains the following alloying components in weight percent.
0.40 wt% ≤ Si ≤ 0.55 wt%,
0.15 wt% ≤ Fe ≤ 0.25 wt%,
Cu≦0.06% by weight,
0.20% by weight≦Mn≦0.40% by weight, preferably 0.25% by weight≦Mn≦0.40% by weight,
0.33% by weight≦Mg≦0.40% by weight,
Cr≦0.03% by weight,
0.005% by weight≦Ti≦0.10% by weight,
The balance is Al and an unavoidable impurity of up to 0.05% by weight, individually, and up to 0.15% by weight in total.

In addition to the tensile strength level of at least 130 MPa required for automotive engineering applications, the aluminum alloy according to the invention has a markedly weakened hardening and an increased yield strength R _p0.2 compared to known AA6xxx aluminum alloys. It was found to be few. Especially when the aluminum alloy is applied in the thermal stress region, the aluminum alloy according to the present invention has a significantly lower tendency to harden than similar alloys. The proportion of silicone and magnesium in the aluminum alloy is generally responsible for the hardening of the aluminum alloy according to the invention. The strictly balanced contents of silicone and magnesium according to the invention, here 0.40% to 0.55% by weight of silicone and 0.33% to 0.40% by weight of magnesium, on the other hand , To ensure a sufficient strength level of the aluminum alloy according to the present invention. On the other hand, a manganese content of 0.2% to 0.40%, 0.25% to 0.4% or 0.20 combined with an iron content of 0.15% to 0.25% by weight. By weight percent to 0.30 weight percent, excess silicone is bound by the formation of Al-Fe-Mn-Si phases, resulting in less available silicone for curing by precipitation of the silicone-containing particles. As a result, unlike known aluminum alloys, the hardening of the aluminum alloy according to the invention may be reduced. Preferably, the silicone content can also be limited to a maximum of 0.50% by weight to prevent cure. Copper is commonly added to increase the strength of aluminum alloys. However, due to the balanced content of silicone, iron, manganese and magnesium, this is not necessary according to the invention. Copper can also impair corrosivity. The aluminum alloy according to the invention is therefore substantially copper-free and has a maximum of 0.06% by weight of copper. Copper is also often an undesirable impurity in the case of recycling, so that not only the corrosion resistance of the aluminum alloy is improved, but also the recycling of the aluminum alloy is facilitated. In order to improve the formability of aluminum alloys, the chromium content is limited to a maximum of 0.03% by weight and the titanium content is limited to 0.005% to 0.10% by weight. Titanium improves atomization during casting of the aluminum alloy and is therefore included in the aluminum alloy in at least 0.005% by weight. Due to atomization, a maximum of 0.10% by weight titanium is generally included. The use of up to 0.03% by weight of titanium can minimize the titanium content in the case of good atomization. It has been found that, within a narrow and limited range of alloy composition, the particular hardening properties of aluminum alloys are exhibited, which is characterized by low long-term hardening, especially in the case of thermal stress. The aluminum alloy according to the invention is therefore less suitable for use in sheet metal used for pedestrian crash protection in motor vehicle engineering due to its distinct energy absorption capacity.

According to the present invention, the aluminum alloy according to the first embodiment has a manganese content of 0.25% by weight to 0.35% by weight. This manganese content can further reduce the hardening of the aluminum alloy as more manganese is available to bind the excess silicone by forming the Al-Fe-Mn-Si phase. At the same time, the further limitation of manganese offsets the increased strength in the T4 condition.

According to a further embodiment, the corrosion behavior of the aluminum alloy according to the invention can be improved by reducing the copper content to below 0.05% by weight, preferably up to 0.01% by weight.

According to a further embodiment of the aluminum alloy according to the invention, the aluminum alloy has a silicone content of 0.40% to 0.48% by weight. This particular reduction in the upper limit of the silicone content can further reduce the hardening of the aluminum alloy by reducing the silicone atoms available for precipitation.

According to the following embodiment of the aluminum alloy according to the present invention, the aluminum alloy has a magnesium content of 0.35% by weight to 0.40% by weight. This magnesium content allows the aluminum alloy to have slightly higher tensile strength and improved formability due to the higher Mg content while having the same hardening properties.

Furthermore, the invention will be explained in more detail on the basis of exemplary embodiments in connection with the drawings.

FIG. 6 shows process steps for manufacturing an aluminum alloy strip according to the present invention. It is a figure which shows the change of the yield strength value after different heat processing which starts from T4 condition. 1 is a schematic perspective view of an automobile having a sheet metal body part related to pedestrian collision protection.

FIG. 1 shows, in a highly schematic view, a method sequence for an exemplary embodiment of a method for manufacturing an aluminum alloy strip according to the invention.

In step 1, a rolled ingot is first cast from an aluminum alloy according to the present invention containing the following alloying components in weight percent.
0.40 wt% ≤ Si ≤ 0.55 wt%, preferably ≤ 0.50 wt%, more preferably ≤ 0.48 wt%,
0.15 wt% ≤ Fe ≤ 0.25 wt%,
Cu≦0.06% by weight,
0.15 wt% ≤ Mn ≤ 0.40 wt%,
0.33% by weight≦Mg≦0.40% by weight,
Cr≦0.03% by weight,
0.005% by weight≦Ti≦0.10% by weight,
The balance is Al and an unavoidable impurity of up to 0.05% by weight, individually, and up to 0.15% by weight in total.

Subsequently, the aluminum alloy ingot is homogenized according to step 2 at a temperature of 450°C to 580°C. Homogenize for at least 1 hour. Instead of producing a rolled ingot according to step 1, according to step 3, the cast strip can also be cast directly from the aluminum alloy according to the invention.

Hot roll the rolled ingot or cast strip according to step 4. Hot rolling is performed at a temperature of 280°C to 550°C. The hot strip is then rolled up. However, the hot strip can also be manufactured, for example, by quenching to temperatures below 230° C. in the last two hot rolling passes and then winding. The hot strips thus produced can also be subjected to solution annealing, quenching and subsequent natural aging according to step 5 in order to provide the hot strips of the aluminum alloy according to the invention in T4 conditions.

The hot strip can have a thickness of about 2 mm to 12 mm. According to step 5, the hot strip is transferred to the T4 condition in order to give maximum formability in the production of sheet metal parts from the strip. The T4 condition can be achieved, for example, by solution annealing at 530° C. for 5 minutes, quenching to room temperature, followed by 7 days of natural aging at room temperature. In this case, because of the relatively low Mg and Si contents, the aluminum alloy strips according to the invention have a solution annealing parameter, in particular a solution annealing temperature, when the temperature is at least 480° C., preferably at least 500° C. It was shown to be relatively insensitive.

In some cases, the hot strip can be first subjected to cold rolling 6 followed by intermediate annealing 7, which is preferably coiled in a batch furnace in a temperature range of 300°C to 450°C for at least 30 minutes. It is done against. However, the intermediate annealing can also be performed in a continuous furnace. As long as an intermediate anneal is required, then follow step 8 to cold roll to final thickness. Otherwise, immediately after cold rolling 6, the strip can be fed according to step 9 for solution annealing, quenching to room temperature, and natural aging. The aluminum alloy strips thus produced under T4 conditions generally have a final thickness of 0.8 mm to 2.5 mm and are preferably used in car body construction.

Six different aluminum alloys were now processed by the method according to FIG. Rolled ingots were cast from these 6 different aluminum alloys according to step 1 in a continuous casting process, followed by homogenization at a temperature of 550° C. for 2 hours according to step 2. The homogenized rolled ingot was then hot rolled according to step 4 at a temperature of 280° C. to 550° C. to a hot strip thickness of 8 mm, followed by cooling to room temperature. The resulting hot strip was intermediate annealed with an intermediate thickness of 3.5 mm and cold rolled to a final thickness of 1.0-1.5 mm according to steps 6, 7 and 8. Intermediate annealing was performed in a batch furnace at a maximum temperature of 350°C for 1 hour.

Table 1 shows various aluminum alloys containing these alloy components. Values are given in weight% for all alloys in Table 1. The following applies to all alloys. The balance is Al and 0.05% by weight at the maximum, and 0.15% by weight at the maximum, inevitable impurities in total.

All comparative alloys A, B, C, E and F have an excessively low Mn content compared to the alloy according to the invention. It is believed that only the Mn content according to the invention in combination with the Si, Fe and Mg contents reduces the hardening of the aluminum alloy at T6 or T6x conditions. Alloy A also has an excessively low proportion of magnesium. Alloy F contains excess silicone at 0.59% by weight. The produced aluminum alloy strip was first subjected to solution annealing at 530° C. for 5 minutes, and then transferred to T4 condition by natural aging for 1 week at room temperature to _obtain both the yield strength R _p0.2 and the tensile strength R _m internationally. It was measured transversely to the rolling direction according to standard ISO 6892-1:2009. Notably, overly low measurements of yield strength R _p0.2 and tensile strength R _m were obtained with comparative alloy A. The corresponding aluminum sheet metal is considered too soft to absorb pedestrian impact energy. In contrast, comparative alloy F already has a significantly too high yield strength value R _p0.2 at T4 conditions and is therefore not optimal for sheet metal used in the area of pedestrian crash protection.

An exemplary embodiment according to the invention of an aluminum alloy D, together with comparative alloy B and comparative alloy C, has a yield strength R _p0.2 measured transversely to the rolling direction of about 55 MPa to 70 MPa and a tensile strength. It is _{R m} is in the preferred intensity range in T4 condition 130MPa～160MPa. Comparative alloy E is slightly inferior to alloys B, C and D in terms of tensile strength R _m and yield strength R _p0.2 . Table 2 shows measured values of the exemplary embodiment of the present invention and the comparative example under the T4 condition. The overly high yield strength and tensile strength measurements of Comparative Example F result from the high Si content and significantly lower manganese content as compared to the exemplary embodiments of the present invention. The overall too low level for yield strength or tensile strength of Comparative Example A is due to the low magnesium content of 0.25% by weight.

The measured values for comparative examples and exemplary embodiments of the invention are now shown in Table 3 for heat treated state T6. The T6 heat treatment simulates the effects of solution annealing, quenching and coating after natural aging and paint baking by heating to 205°C for 30 minutes. As Table 3 actually shows, in terms of absolute and relative increases in yield strength and tensile strength, the exemplary embodiments according to the invention show these values, especially in comparison with the comparative example of alloy C. Although not the least, the increase in tensile strength R _m and yield strength R _p0.2 of the exemplary embodiment of the aluminum alloy D according to the invention remains small, in particular below 10 MPa.

Example embodiment D of the present invention shows a significant reduction in cure as far as heat treatment is examined, indicating long term thermal stress of the part. Long-term behavior was measured by T6x heat treatment conditions. The T6x condition is achieved by starting from the T6 condition, followed by artificial aging at 80° C. for 500 hours, as described above. The artificial aging at 80° C. for 500 hours simulates the practical use of aluminum alloy sheet metal in applications such as automobiles in the case of thermal stress. Since heat enhances the hardening effect in AA6xxx alloys, the yield strength values generally increase relatively rapidly.

Unlike other comparative alloys, the exemplary embodiment D of the present invention has a significantly reduced increase in yield strength after aging at 80° C. for 500 hours. Not only is the absolute increase in yield strength significantly lower by 19.5 MPa, but the relative increase in yield strength of only 34 wt% is significantly lower than the relative or absolute increase in yield strength of all other aluminum alloys. .. With respect to the long-term behavior of aluminum alloys, an unexpected decrease in hardening is observed, which is due to the formation of Al-Fe-Mn-Si phases. It is believed that these Al-Fe-Mn-Si phases do not contribute to the precipitation hardening of the aluminum alloy and thus reduce the effect of silicone precipitation.

In Tables 5 and 6, aluminum alloy strips were measured at T6 conditions including 2% cold forming or 5% cold forming. The T6 condition (2%) and T6 condition (5%) are believed to simulate deformation of sheet metal parts and subsequent coating. For this, the sheet metal is subjected to a heat treatment at a temperature of 185° C. for a duration of 20 minutes.

An exemplary embodiment of an aluminum alloy D according to the invention was also measured in the case of these heat treatments simulating a processing directed towards the application of sheet metal in the area of automotive engineering, likewise 2% cold forming. Or, it was the minimum value with respect to the absolute or relative increase of the yield strength R _{p0.2 in} the T6 condition including 5% cold forming.

The measured relative increase in yield strength starting from the T4 condition is again shown in the graph of FIG. The positive hardening behavior of the aluminum alloy according to the invention can be read based on the exemplary embodiment D in comparison with the remaining variants, in particular from a comparison under T6x conditions.

FIG. 3 schematically shows in perspective view a sheet metal body part of an automobile provided for pedestrian collision protection. The vehicle hood 10, wings 11, vehicle roof or roof frame 12 and rear door 13 shown are, in principle, sheet metal body parts that must be designed for pedestrian crash protection. Therefore, they must have a particular energy absorption behavior that is still present, especially under long-term thermal stress. If these sheet metal parts provided for pedestrian crash protection are manufactured from the aluminum alloy according to the invention, long-term hardening of the sheet metal can be reduced even in the thermal stress region. As will be appreciated on the basis of the exemplary embodiment according to the invention of alloy D, it is advantageous to produce a corresponding sheet metal body part of a vehicle from an aluminum alloy according to the invention. This is because they have a particularly advantageous hardening behavior and have moderate yield strength and tensile strength values.

Claims (14)

The following alloying components in weight% units, namely:
0.40 wt% ≤ Si ≤ 0.55 wt%,
0.15 wt% ≤ Fe ≤ 0.25 wt%,
Cu≦0.06% by weight,
0.15 wt% ≤ Mn ≤ 0.40 wt%,
0.33% by weight≦Mg≦0.40% by weight,
Cr≦0.03% by weight,
0.005% by weight≦Ti≦0.10% by weight,
Including
The balance is Al and 0.05% by weight of each, and 0.15% by weight in total of inevitable impurities.
Aluminum alloy strip with a vehicle aluminum alloy. The aluminum alloy strip according to claim 1, wherein the Mn content of the aluminum alloy is 0.25% by weight ≦Mn≦0.35% by weight. Aluminum alloy strip according to claim 1 or 2, characterized in that the Cu content of the aluminum alloy is Cu <0.05 wt% in wt% units. The aluminum alloy strip according to any one of claims 1 to 3, wherein the Si content of the aluminum alloy is 0.40% by weight ≤ Si ≤ 0.48% by weight. The aluminum alloy strip according to claim 1, wherein the Mg content of the aluminum alloy is 0.35% by weight≦Mg<0.40% by weight. 6. The aluminum alloy strip according to claim 1, wherein the aluminum alloy strip has a yield strength of 55 MPa to 70 MPa and a tensile strength of 130 MPa to 160 MPa measured in the transverse direction with respect to the rolling direction under T4 conditions. The aluminum alloy strip as described in 1 above. The aluminum alloy strip, 5 30 ° C. for 5 minutes solution annealing, quenching to room temperature followed by natural aging for 7 days at room temperature, for 30 minutes at 205 ° C. heating, and after heating of 500 hours at 80 ° C. Aluminum alloy strip according to any one of claims 1 to 6, characterized in that it has a yield strength of less than 100 MPa measured transversely to the rolling direction. A method for producing the aluminum alloy strip according to any one of claims 1 to 7, wherein a method step of casting a rolled ingot or a cast strip, a method step of homogenizing the rolled ingot, the rolled ingot or casting. A method comprising the method steps of hot rolling a strip and, optionally, cold rolling to a final thickness, with or without intermediate annealing. Sheet metal body parts of a motor vehicle which is manufactured from an aluminum alloy strip according to any one of claims 1-7. Said sheet metal body parts are part of an automobile wing (11), part of an engine bonnet (10), roof frame or roof (12) or rear door (13) provided for pedestrian collision protection. there, the sheet metal body part according to claim 9. The following alloying components in weight percent, namely:
0.40 wt% ≤ Si ≤ 0.55 wt%,
0.15 wt% ≤ Fe ≤ 0.25 wt%,
Cu≦0.06% by weight,
0.20% by weight≦Mn≦0.40% by weight,
0.33% by weight≦Mg≦0.40% by weight,
Cr≦0.03% by weight,
0.005% by weight≦Ti≦0.10% by weight,
Only including,
The balance is Al and 0.05% by weight of each, and 0.15% by weight in total of inevitable impurities.
Aluminum alloy for vehicles. The aluminum alloy according to claim 11 , wherein the Mn content of the aluminum alloy is 0.25% by weight ≤Mn ≤0.35% by weight. The aluminum alloy according to claim 11 or 12 , characterized in that the Cu content of the aluminum alloy is Cu <0.05% by weight in units of% by weight. The Si content of the aluminum alloy is 0.40 wt%≦Si≦0.48 wt %, and/or the Mg content is 0.35 wt%≦Mg<0.40 wt%. wherein the percentages by weight of aluminum alloy according to any one of claims 11 to 13.

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