DE1085336B - Process for the production of texture-free sheets from aluminum and iron-nickel - Google Patents

Description

Process for the production of texture-free sheets from aluminum and iron-nickel The invention relates to a method for producing textureless metal sheets from aluminum -and iron-nickel, especially for deep-drawing purposes, in which the material is warm and / or cold rolled and then annealed to recrystallize.

When deep drawing sheet metal from face-centered cubic metals are formed as a result of the previous cold and hot forming Textures often have tips that lead to noticeable material losses and therefore very are desired.

Mainly two textures are the cause of significant earing. On the one hand, this is the rolling texture, which is caused by hot or cold deformation and due to which four lobes are formed during the drawing process, which are less than 45 'to the original rolling direction. On the other hand, this is a texture that occurs after high degrees of cold rolling and subsequent recrystallization annealing and is referred to as a cube position, in which one cube edge of the face-centered cubic crystallizing grains lies parallel to the rolling, transverse and normal direction of the sheet. The latter texture results in particularly strong tips that are below 0 and 90 ' to the original rolling direction.

When manufacturing deep-drawn sheets from pure aluminum, the block material is usually first hot-rolled, then cold-rolled, then annealed to recrystallize, and the blanks are removed from this material. Attempts have been made in various ways to avoid or reduce the extent of ear formation by appropriate pretreatment of the sheet. It is therefore possible, through special management of the rolling and annealing processes, to produce a material that has an M # .is, h texture from the rolled and cube layers, as described in the above-mentioned process Then the 0 ' or 900 lobes of the cube layer are superimposed with the 45' lobes of the rolled layer, so that instead of four lobes eight are obtained, the height of which is less.

A completely texture-free material, in which a 7ipitl '£ # formation does not occur at all, results e.g. For example, if the sheet is twisted by a certain angle after each pass during rolling, i.e. the rolling is ir 'h, ung #t: #ndig iLwiert, such a process fails because of its practical feasibility, since inclined or transverse rolling is only possible with very small metal sheets corresponding to the roll width and is therefore completely uneconomical.

Furthermore, certain conditions have been determined purely empirically, under which suffer from the undesirable formation of ears when deep-drawing hollow bodies made of copper sheet can be significantly restricted or even avoided. Basic knowledge for the deeper causes of these phenomena that would have made such conditions possible Up to now, however, it has not been possible to transfer them to other cubic, surface-centered metals not before. A simple transfer of the conditions known for sheet copper is in no case possible, since the conditions of the rolling and annealing treatments that are required to achieve the most perfect cube texture possible, z. B. for aluminum and iron-nickel, differ considerably from those for copper.

According to the invention, texture-free sheets are produced by that the rolling degrees and temperatures as well as the annealing temperature are set so that a cube texture is achieved. and that then another cold rolling is carried out with subsequent recrystallization annealing.

When the sheet with the cube texture is cold rolled again, a cross-section decrease of 10 to 60, preferably 40 to 50 %, is carried out.

This makes it possible to produce a practically texture-free sheet made of aluminum or to produce iron-nickel without changing the rolling direction, which is free of lobes Can be deep drawn, which is particularly important for thin sheet metal.

The invention is based on the fundamental knowledge that a sheet metal, that has a cube texture that is as complete as possible, in this state for Deep-drawing purposes would be particularly unsuitable after renewed cold forming and subsequent recrystallization annealing is largely randomly oriented and thereby enabling deep-drawing without any lugs.

According to the invention , a sheet is first produced with a cube texture that is as perfect as possible, this is cold-rolled again and then re-annealed in a recrystallizing manner. The conditions under which a perfect cube texture is obtained are largely dependent on the material and the impurities it contains. In the case of aluminum, this is known to be achieved by cold rolling amounting to more than 80% or by hot rolling at low temperatures (below 450 ° C), subsequent cold rolling and subsequent recrystallization (400 to 600 ° C), with iron-nickel the cube layer is obtained over 90 % cold rolling and subsequent recrystallization at 800 to 1000 ° C. The sheet with cube texture obtained in this way is now, according to the invention, again cold rolled by 10 to 60%, preferably 40 to 50%, and then recrystallized. Less or more rolling no longer leads to a texture-free structure. Possible annealing temperatures are 400 to 600 ° C for aluminum and 600 to 1000 ° C for iron-nickel. The material obtained after this treatment is substantially free of texture, and therefore ideally suited as a starting material for overall Tiefziehblecbe.

Claims (2)

PATENT CLAIMS: 1 .-. Process for the production of texture-free sheet metal Made of aluminum and iron-nickel for deep-drawing purposes, in which the material is warm and / or cold-rolled and then annealed in a recrystallizing manner, characterized in that that the rolling degrees and temperatures as well as the annealing temperature are set so that a cube texture is obtained, and that then another cold rolling is carried out with subsequent recrystallization annealing. 2. The method according to claim 1, characterized in that the re-cold rolling of the sheet with a cube texture is carried out by 10 to 60, preferably 40 to 501 / o cross-section reduction. Publications considered: Zeitschrift für Metallkunde, 19/1927, pp. 435 to 437-