EP0037132A1 - Process for the manufacture of semi-finished products, and finished articles from an Al-Mn-Si alloy - Google Patents

Abstract

In a process for the manufacture of semi-finished products and finished articles of an AlMnSi alloy, which have a tensile strength of at least 120 N/mm<2> and an electrical conductivity of at least 29 m/ OMEGA mm<2> and in which these minimum values are reversibly preserved in the application range up to 450 DEG C, the object of the invention is to provide an aluminium material which is comparable with the known materials with respect to the tensile strength and electrical conductivity, but in which these properties are reversibly preserved up to a substantially higher application temperature. To achieve this object, it is proposed according to the invention to produce a cast block of the following composition: 0.2 to 2 % of manganese 0.6 to 3 % of silicon 0.2 to 1 % of iron 0 to 0.2 % of copper 0 to 0.2 % of magnesium the remainder being aluminium, including a total of at most 0.2 % of unavoidable, production-related impurities. After conventional annealing of the cast block at 400 to 620 DEG C, the desired semifinished products or finished articles are obtained by hot- and/or cold-forming. These are finally subjected at 300 to 450 DEG C to annealing up to complete recrystallisation. In Figure 1, the curves of the tensile strength and electrical conductivity are plotted as a function of the temperature in the recrystallisation annealing. <IMAGE>

Description

The invention relates to a process for the production of semi-finished and finished parts made of an AlMnSi alloy, which have a tensile strength of at least 120 N / mm ² and an electrical conductivity of at least 29 m / Ω mm ² at room temperature and in which these minimum values in Range of application reversibly maintained up to 450 ° C.

The standardized E-Al and E-Al-Mg-Si standard materials are used in Germany for guiding purposes. In state F 16 according to DIN 40 501, E-Al has a very high electrical conductivity of at least 34.5 m / Ω mm ² for aluminum materials, but on the other hand only a very low strength. Due to strong work hardening, tensile strength values of approx. 180 N / mm ² (in state F 17 according to DIN 40 501) can be achieved with this material, but this strength can only really be used in a temperature range up to a maximum of 80 ° C, since at higher Depending on the duration of exposure, softening must be expected until it is completely soft. For this For this reason, the area of application for E-Al for overhead lines is limited, for example, to a maximum temperature of 80 ° C.

In the case of the second common material, E-Al-Mg-Si, minimum tensile strength values of 215 N / mm ² can be achieved by curing, but at the same time the electrical conductivity is reduced to a minimum value of 30 m / llmm2. But even with this material there is a risk of gradual softening due to aging if the material is heated to temperatures above 80 ° C for a prolonged period, whereby the tensile strength in the completely soft state can drop to 100 N / mm ² .

It should also be borne in mind that an application temperature limit for a material also means that care must be taken during the manufacture and further processing of objects made therefrom that the temperature limit is not exceeded. For example, for materials with a limit temperature of 80 ° C, it is not possible to apply plastic insulation, the processing of which requires higher temperatures. Furthermore, it is not possible to enamel or solder such materials.

This resulted in the task of providing an aluminum material which is comparable to the known materials in terms of tensile strength and electrical conductivity, but in which these properties are reversibly retained up to a substantially higher application temperature. So the primary goal is not to improve the train strength values or the electrical conductivity as such, but the provision of an aluminum material with comparable minimum values, the processing and application area of which, however, is not restricted to temperatures of up to 80 ° C. as in the known materials.

Rest Aluminium, einschließlich insgesamt höchstens 0,2 % nichtvermeidbare, herstellungsbedingte Verunreinigungen
nach der üblichen Glühung des Gußblocks bei 400 bis 620⁰C durch Warm- und/oder Kaltumformung die gewünschten Halbzeuge oder Fertigteile hergestellt werden und daß diese abschließend bei 300 bis 450°C einer Glühung bis zur vollständigen Rekristallisation unterworfen werden.This object is achieved in that the following composition from a casting block

Rest of aluminum, including a total of at most 0.2% unavoidable, manufacturing-related impurities
After the usual annealing of the casting block at 400 to 620 ⁰ C by hot and / or cold forming, the desired semi-finished or finished parts are produced and that these are finally subjected to annealing at 300 to 450 ° C until complete recrystallization.

The semi-finished or finished parts produced by this process have the advantage that they are in a thermodynamically stable state and that the set strength and conductivity values are therefore reversible with certainty even at a temperature stress above 80 ° C at least up to the temperature of the recrystallization annealing used remain.

The method has the further advantage that it allows the setting of optimal conductivity values or optimal strength values. For optimal. Conductivity values, the recrystallization annealing is preferably carried out at 300 ° C. or just above, while for the setting of optimal strength values, the recrystallization annealing is preferably carried out at 450 ° C. or just below.

Further details and advantages are explained in more detail with reference to the diagram shown in FIG. 1. The values for the tensile strength and the conductivity of a semifinished product produced according to the invention, measured at room temperature, are plotted as a function of the temperature used in each case for two hours of recrystallization annealing. In the work hardened state, the material has a tensile strength of approximately 250 N / mm ² with an electrical conductivity of almost 30 m / Ωmm ² . With these values, the material treated according to the invention is quite comparable to E-Al-Mg-Si in the hardened state. After recrystallization annealing at 300 ^° C., the tensile strength drops to the specified minimum value of 120 N / mm ² , while the electrical conductivity increases to 30.7 m / Ω mm ² . With recrystallization annealing from 300 to 500 ° C, the tensile strength increases approximately steadily to over 160 N / mm ² , while the electrical conductivity also drops almost continuously to below 28 m / Ωmm ² . The temperature range which can be used under the given conditions for the recrystallization annealing is therefore expediently limited to 450 ° C. in order to avoid an excessive decrease in the electrical conductivity. At this annealing temperature, the capability at just under 29 m / nmm2, while the tensile strength has already risen to over 140 N / mm ² . The diagram shows that an optimum combination of tensile strength and electrical conductivity can be set for the respective application by varying the temperature of the recrystallization annealing. It should be repeated once again that the properties set in this way are reversibly maintained regardless of the temperature at which the semifinished or finished parts are used, because the material structure is in a thermodynamically stable state.

The diagram also shows that the material can of course also be used without prior recrystallization if a particularly high tensile strength is important and the room temperature is certainly not significantly exceeded during use. To this extent, however, the material would be subject to the same restrictive conditions as the known materials mentioned at the beginning.

In the case of semi-finished and finished parts that were produced by the method according to the invention, one is always on the safe side; The minimum values for strength and electrical conductivity that arise after complete recrystallization are still guaranteed if higher temperatures have to be used when processing such as applying insulation, enamelling, soldering, etc.

Claims (3)

1. Process for the production of semi-finished products and finished parts from an AlMnSi alloy which have a tensile strength of at least 120 N / mm ² and an electrical conductivity of at least 29 m / Ωmm ² at room temperature and in which these minimum values in the application range up to 450 ° C reversibly preserved, characterized in that the following composition from a casting block

Rest of aluminum, including a total of at most 0.2% unavoidable, manufacturing-related impurities
After the usual annealing of the casting block at 400 to 620 ⁰ C by hot and / or cold forming, the desired semi-finished or finished parts are produced and that these are finally subjected to annealing at 300 to 450 ° C until complete recrystallization. 2. The method according to claim 1, characterized in that the recrystallization annealing is carried out at about 300 ⁰ C to achieve optimum conductivity values. 3. The method according to claim 1, characterized in that the recrystallization annealing to achieve optimal strength values is carried out at about 450 ° C.

Images