DE1813192A1 - Aluminum alloy sheet - Google Patents

Description

COMPAIIY OP AMERICA, Pittsburgh, Pa / USA

In recent years aluminum alloy sheets have gained increasing acceptance, for example, they are used as book lids or the like for beverages, food and other goods US _{Pat. No. 3,191,797 0} This type of use is one of the main reasons for the increasing and widespread use of aluminum sheet in book covers, but it poses certain problems in the selection of a suitable material it encloses the material in the beech bioreactor, and this strength must be maintained at the stoving temperatures that are applied to the coverings during the hardening process. Second, since mufl · Material sufficiently workable eein, eo that it can be deformed easily Xn a öffnungebaren Büoheeldeckel with integral out-worked rivet. For example, goes

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from the aforementioned U.S. Patent 3,191,797 directly show that a can end is subjected to quite a considerable amount of deformation in the machining of the integral rivet which is used to secure the pull tab to the end of the can. Many different aluminum alloy sheet compositions have one before and after baking sufficient strength, but they lack the desired deformability. Conversely, some have the required Deformability, but they often show such a low level Strength, so that economically high strengths have to be used in order to obtain a sufficiently strong can end to manufacture. It is generally desirable to have a scrap rate of no more than 5 manufacturing failures of 10,000 easy-to-open liner-end rivets «This is a pretty strict rule for that Sleeve cover! Material, which must also be strong enough, like this that it can be thin enough to compete economically with other materials.

According to the invention, an aluminum alloy sheet is proposed which contains 4 to 6.5% magnesium, 0.2 to 0.7% Manganese, where the manganese content has the following relationship with the magnesium content:

% Mn * 1.700-0.9 (In% Mg) +. 0.15%,

and the rest of aluminum and not more than 0.2% copper, 0.4% iron, 0.3% silicon, 0.1% titanium, 0.2% chromium, 0.05% other individual components, and not more than 0.15% all of the other components consist of

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it is preferred that the total amount of all impurities not exceed 0.5%. The preferred range for magnesium is 4.2 to 4.8 % and for hangan 0.25 to 0.5 %. The percentages are expressed in weight at least 85 # is present in the recrystallized state i (in order to create a particularly hard tooth structure bu) tensile strengths and yield stresses of 3,990 kg / cm bev · 3 710 kg / cm ² , an elongation, in 50.4 an, of 3 pounds or more e as well a Olsen Cupping value Bew of 3.56 mm "After a '20 minute heating at a furnace temperature of 204.4 ⁰ C, the sheet has a tensile strength and a yield stress of 3710 kg / cm ^2, Figure 3 150 kg / cm ² , an elongation of 8 Ji and an Olsen cupping value of 3.81 mm «,

The invention is explained in more detail in the accompanying drawing which is a graph showing the increased strength and machinability of the improved alloy.

The aggregate values set out in the previous paragraph must be strictly adhered to so that the combination of strength and machinability is achieved, which characterizes the improved sheet metal

If the manganese content exceeds the value given by the equation, then the ductility falls below the Value, with the easily opening can lid with a

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integral rivets consistently well in a commercial Scale can be manufactured. If he's under the by If the value given in the equation falls, then the strength decreases below a value according to the present invention was fixed »

The specified alloy composition can be produced as a continuously cast blook. The block can be homogenized by heating it to a temperature of at least 426 ^° C. but below the melting point for 24 hours Heat to approximately 315 G for a time sufficient to allow the internal structure to recrystallize. Next, this material is cold rolled to effect a reduction in thickness of at least 85 %, and preferably 90 % or more, to produce a sheet having a thickness of 0.20 to 0.38 mm It is preferred that the temperature of the sheet metal when it leaves the rollers does not exceed 93.3 ° C. The use of lubricants on water toaaie is nutslioh if this temperature limit is adhered to. This cold reduction in thickness gives the sheet an extremely hard tempering o The sheet is characterized by high strength in this tempering state and also has a very good degree of deformability, so that integral rivets can be worked out, as is specified, for example, in the ÜS patent 3 191 797 . It is also

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highly significant »that sufficient strength is retained after the thermal treatment» which can be compared with that which is encountered in the manufacture of office covers when a coating is applied to the sheet metal and baked. A thermal treatment at 204 ⁰ C for 20 minutes corresponds to a stronger baking treatment, as it is normally used in the production of book endocards «

As already indicated, a combination of strength and deformability both before and after the thermal treatment, for 20 minutes at 204 ⁰ C for a liner cover material, is desirable alloy sheets with a similar composition and tempering do not have the combination of machinability and strength of the improved sheet .

To explain the strength of the improved sheet, it is compared to a sheet product of similar composition. The individual compositions are indicated in Table I, in which A is a sheet metal plate according to the invention., The sheet B is the product that is currently dae of the can industry in the production of leioht disclose Buchsendeokeln used "

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Table I.

Sheet metal Mg Mn Fg Si Cu Cr Ti Zn A 4.54 0.37 0.21 0.10 0.01 0.02 0.02 0.01 B 4.45 0.01 0.19 0.08 0.02 0.00 0.01 0.01

Each alloy was continuously cast to produce an ^{ingot which was homogenized by heating to a temperature of 482 °} C. for 24 hours, after which it was brought to a temperature of approximately 399 ^° C. and then hot rolled to form a plate approximately in thickness 3.80 mm. ”The plate was then tempered at 315 ° C in order to

to recrystallize the corostructure, whereupon it was cold rolled into a sheet of 0.33 mm thickness without any interfering ". This cold reduction in thickness of over 90 % gave the sheet an extremely hard cold temper. Tensile strength samples were separated from the sheet. In the test, the average tensile strength data given in Table II were obtained . The table also includes an Olsen cupping value, which is a measure of the ductility of the sheet metal. Part II, page 398, 1920

Table II BIe oh tensile strength flow stressing extensibility * Olsen-

A. 3 990 3 710 4 * 3, 56 B. 3 640 3 360 4 # 3, 82 009887/0682

From Table II it can be seen that the improved Bleqh shows a considerably improved resistance of about 10 96 across the sheet B, although the latter a higher Olsen Cupping value has "Additional sheet samples A and B were added 20 minutes to a temperature of 204.4 ⁰ C exposed, which means an approximation of the conditions that are encountered when an organic coating is applied to the sheet metal and baked in a baking oven. »After this baking, the properties are de? Sleclhs are of great importance as these are the properties that the sheet metal exhibits when it is used as a socket cover. The average properties, strength and Olsen cupping value for panels A and B after the thermal treatment are given in Table III =.

tensile strenght
kg / cm Table III in 50.4 ma t Olsen
Cupping
Value (ran) sheet 3 710 Yield stress]
kg / cm ² 8th* 4.06 A. 3 360 3 150 8th% 4.57 B. 2,800

From Table III it can be seen that the improved panel, Panel A, still has about 10 5 »higher strength than the sheet B shows »The Olsen cupping value is lower for sheet A than for sheet B, but it is sufficient for the production of integral rivets proven on book covers «.

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The combination of both better strength and better formability of the improved sheet metal works best from Pig. 1, in which the tensile strength is plotted against the Olsen cupping word for sheets A and B. From Fig. 1 it is immediately apparent that for any given strength value, the improved sheet, sheet A, by a * Significantly higher Olsen cupping value than is marked on tray B.

In addition to the standard tensile strength tests, another measure of the strength of a sheet metal that is to serve as a liner cover is the bending behavior under pressure. This behavior is determined by the fact that a beverage can is produced, the lid of which is formed from the metal sheet to be tested. Within the box a pressure is applied and gradually increased until the can lid auebeult and plastically deformed "The pressure at which the can lid is bulges then as Ausbeuldruck designated at W a comparison of the sheets A and B with the Auebeultests has been found that a 0.343 mm thick can end made from sheet A withstands the same pressure as a 0.368 mm thick book cover made from sheet B, which is the sheet currently widely used in the manufacture of easy open beer can covers. This means a considerable saving in material »

From the above it appears that the improved sheet metal is a useful new material for easy-open beech cover with an integral rivet, so it becomes clear

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Improvement in the combination of workability and Strength demonstrated, so that socket cover can now be made from a considerably thinner sheet metal "

PATQiTANSPHUCHS:

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Claims (1)

- to - .PATMIUM CLAIMS: 1 ο AluminiumlegierungablecK, characterized in that it contains: 4 to 5.5 f 'magnesium, 0.2 0.7 bit is ^v / o manganese, the manganese content to the magnesium content as follows in context:% Mn = 1,700 - 0.9 (in i » Mg) % i 0.15 ⁰ A ₉ and the rest of aluminum and not more than 0.2% copper, 0.4 1 * iron, 0.3 % silicon, Ο, Ί % titanium , 0.2% chromium and 0.05 ° is i other individual components and not more than 0.15 $ entire other components, which alloy has a tensile strength of 3990 kg / cm, a yield stress of 3710 kg / cm and a Dshnfähigkeit , in 50.4 mm, of 3 i> and an Olsen cupping value of 3.56 mm if it has obtained a thickness reduction of at least 85 7 & to a thickness of 0.203 to 0.432 mm by cold rolling » 2ο aluminum alloy sheet according to claim 1, characterized in "that the magnesium in an amount from 4.2 to 4.8 i" and the manganese in an amount of 0.25 to 0.5 ⁰ A present lato 3ο aluminum alloy sheet according to claim 1 or 2, characterized in that the cold reduction in thickness amounts to at least 90 Ά of the thickness before cold rolling -!:. 4 «aluminum alloy sheet according to any one of claims% to 3, characterized in that it has a tensile strength of 3 710 kg / cm _{ a pinning stress of 3 150 kg / cm, a 009887/0682 - 11 - Having elongation of 8 $ »and a Oleen-cupping value of 4.06 when it has been heated for 20 minutes at a temperature up to 204 ⁰ C. 5. aluminum alloy cup according to claim 4, characterized characterized in that ee has the state that results from a Heat treatment results. 6ο Process for the production of an aluminum regulator, characterized in that nan produces a body which consists of 4 to 5.5 # magnesium, 0.2 to 0.7 % manganese, the manganese content being related to the magnesium content as follows : 1 » Mn = 1.700 - 0.9 (In # Mg) + 0.15 % and also consists of aluminum and no more than the following impurities: 0.2 » copper, 0.4 # iron, 0.5 # Silicon, 0.1 % titanium, 0.2 % chromium, others individually 0.0 £ #, the others not exceeding 0.15% in total, whereupon the body is cold-rolled to a thickness of 0.203-0.432 mm, with the cold gauge reduction is at least 85 # the pre-cold rolling body thickness and where the cold rolled sheet has a tensile strength of 2 2 3,990 kg / cm, a yield stress of 3 710 kg / cm and a Extensibility, in 50.4 mm, of 3% and an Olsen cup »value of 3.56 mm. 7. The method according to claim 6, characterized in that that the body is 4.2 to 4.8 pounds of magnesium and 0.25 to 0.5 pounds Contains manganese 009887/0682. - 12 - 8. The method according to claim 6 or 7, characterized in that the cold reduction in thickness makes up at least 90 i »of the body thickness before cold rolling. 9. The method according to any one of claims 6 to 8, characterized marked! that the body after cold rolling to a temperature of up to 20 minutes for a period of time 204 ⁰ C is heated, whereupon the body has a tensile strength of 2 2 3710 kg / cm, a yield stress of 3150 kg / pm, an elongation of 8 » and an Olsen cupping value of 4.06 mm 0Θ9887 / Θ682