Aluminium–magnesium alloys (AlMg) – standardised in the 5000 series – are aluminium alloys that are mainly made of aluminium and contain magnesium as the main alloy element. Most standardised alloys also contain small additives of manganese (AlMg(Mn)). Pure AlMg alloys and the AlMg(Mn) alloys belong to the medium-strength, natural (not hardened by heat treatment) alloys. Other AlMg alloys are aluminium–magnesium–copper alloys (AlMgCu) and aluminium–magnesium–silicon alloys (AlMgSi, 6000 series).
Discovery of aluminium–magnesium alloys dates back to late 19th century.[1] AlMg alloys are among the most important aluminium alloys for construction materials. They get cold dwell transform, i.e., by rolling and forging and are easily weldable at Mg levels of at least 3%. AlMg is rarely processed through extrusion presses, as subsequent strength changes in extrusion profiles must be avoided. The majority of AlMg alloys are processed into rolled products as well as pipes, rods, wires and free-form or drop-forged parts. Parts are also processed into extrusion profiles with simple cross-sections.[2]
Due to the good corrosion resistance and high strength at low temperatures, AlMg is used in shipbuilding, in the construction of chemical apparatus and pipelines, and for refrigeration technology and automobiles. The good weldability is crucial for use in the aircraft construction, there also with additions of scandium and zirconium for better weldability.[3]
The solubility of magnesium is very high in aluminium and reaches a maximum at 450 °C with 14% to 17% depending on the literature reference. At 34.5%, there is a Eutectic with Al8Mg5 (sometimes referred to as Al3Mg2), an intermetallic phase (
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The elimination of the
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In the case of technical alloys, the excretion differs from this for the following reasons:[5]
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The diffusion of magnesium in aluminium is very low. The reason is the high size difference between the radius of the aluminium atoms and that of the magnesium atoms (
rAl:rMg=1.43:1.6
Excess magnesium is excreted mainly at the grain boundaries as well as on dispersion particles in the grain. The speed of the process depends on the Mg content and the temperature and increases with both. At the grain boundaries, so-called plaques are initially excreted, thin plates that are not connected, i.e. do not yet form a continuous layer around the grain. At 70 °C, they form after 3 months, at 100 °C after 3 days and at 150 °C after one to nine hours. If further time passes at elevated temperature, the plaques grow together to form a contiguous film. This has a negative effect on corrosion resistance, but can be dissolved by heat treatment. Annealing at 420 °C for one hour followed by slow cooling of 20 °C/h or starting annealing at 200 °C to 240 °C is suitable. The plaques of the
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The compositions of some standardised varieties are contained in the following table. Proportions of alloying elements in mass percent. Of the available varieties, there are fine gradations of Mg and Mn levels. Mn-free are very rare. Standard alloys are AlMg3Mn, AlMg4.5Mn0.7, as well as for bodywork AlMg4.5Mn0.4. Magnesium levels of up to 5% and manganese content up to 1% are used for wrought alloys.[8] [9]
Mg contents up to 10% are also possible for cast alloys; however, contents of 7% and more are considered heavypourable.[10]
| Numerically | abbreviations | Si | Fe | Cu | Mn | Mg | Cr | Zn | |
|---|---|---|---|---|---|---|---|---|---|
| EN AW-5005 | – | 0.3 | 0.7 | 0.2 | 0.2 | 0.5–1.1 | 0.1 | 0.25 | |
| EN AW-5052 | AlMg2.5 | 0.25 | 0.4 | 0.1 | 0.1 | 2.2–2.8 | 0.15–0.35 | 0.1 | |
| EN AW-5083 | AlMg4.5Mn0.7 | 0.4 | 0.4 | 0.1 | 0.4–1.0 | 4.0–4.9 | 0.05–0.25 | 0.25 | |
| EN AW-5454 | AlMg3Mn | 0.25 | 0.4 | 0.1 | 0.5–1.0 | 2.4–3.0 | 0.05–0.2 | 0.25 |
5000 series are alloyed with magnesium. 5083 alloy has the highest strength of non-heat-treated alloys. Most 5000 series alloys include manganese as well.
| 5005 & 5657 | 99.2 | Mg 0.8 | Sheet, plate, rod | |
| 5010 | 99.3 | Mg 0.5; Mn 0.2; | ||
| 5019 | 94.7 | Mg 5.0; Mn 0.25; | ||
| 5024 | 94.5 | Mg 4.6; Mn 0.6; Zr 0.1; Sc 0.2 | Extrusions, aerospace[11] | |
| 5026 | 93.9 | Mg 4.5; Mn 1; Si 0.9; Fe 0.4; Cu 0.3 | ||
| 5050 | 98.6 | Mg 1.4 | Universal | |
| 5052 & 5652 | 97.2 | Mg 2.5; Cr 0.25 | Universal, aerospace, marine | |
| 5056 | 94.8 | Mg 5.0; Mn 0.12; Cr 0.12 | Foil, rod, rivets | |
| 5059 | 93.5 | Mg 5.0; Mn 0.8; Zn 0.6; Zr 0.12 | rocket cryogenic tanks | |
| 5083 | 94.8 | Mg 4.4; Mn 0.7; Cr 0.15 | Universal, welding, marine | |
| 5086 | 95.4 | Mg 4.0; Mn 0.4; Cr 0.15 | Universal, welding, marine | |
| 5154 & 5254 | 96.2 | Mg 3.5; Cr 0.25; | Universal, rivets[12] | |
| 5182 | 95.2 | Mg 4.5; Mn 0.35; | Sheet | |
| 5252 | 97.5 | Mg 2.5; | Sheet | |
| 5356 | 94.6 | Mg 5.0; Mn 0.12; Cr 0.12; Ti 0.13 | Rod, MIG wire | |
| 5454 | 96.4 | Mg 2.7; Mn 0.8; Cr 0.12 | Universal | |
| 5456 | 94 | Mg 5.1; Mn 0.8; Cr 0.12 | Universal | |
| 5457 | 98.7 | Mg 1.0; Mn 0.2; Cu 0.1 | Sheet, automobile trim[13] | |
| 5557 | 99.1 | Mg 0.6; Mn 0.2; Cu 0.1 | Sheet, automobile trim[14] | |
| 5754 | 95.8 | Mg 3.1; Mn 0.5; Cr 0.3 | Sheet, Rod |
Aluminium-magnesium alloys are considered to be very corrosion-resistant, making them suitable for marine applications, but this is only true if the
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The
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Alloys in states susceptible to intergranular corrosion are annealed at temperatures of 200 °C to 250 °C with slow cooling (heterogeneisation annealing). This changes the
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| Numerical[18] | abbreviations | Condition | Elongation limit[N/mm<sup>2</sup>] | Tensile strength[N/mm<sup>2</sup>] | Elongation at break[%] | Brinell hardness | Vickers hardness | Bending strength [N/mm<sup>2</sup>] | Young's modulus[N/mm<sup>2</sup>] | |
|---|---|---|---|---|---|---|---|---|---|---|
| 5005 | AlMg1(B) |
|
|
|
|
|
|
| 69500 | |
| 5052 | AlMg2.5 |
|
|
|
|
|
|
| 70,000 | |
| 5083 | AlMg4.5Mn0.7 |
|
|
|
|
|
|
| 71,000 | |
| 5454 | AlMg3Mn |
|
|
|
|
|
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| 70,500 |
The strength is increased by alloying magnesium. At low Mg levels, the increase in strength is relatively strong with higher levels, it is getting weaker and weaker. However, magnesium increases strength very efficiently compared to other elements; per % Mg, so it is stronger than with alternative elements. Even with medium Mg content, the increase in strength by alloying manganese is higher than by additional magnesium, which is also one reason why most AlMg alloys still contain manganese. As a reason for the high increase in strength of magnesium, the high binding energy of vacancies at Mg atoms. These spaces are then no longer available as free spaces. However, these are favourable for plastic deformation.[19]
The yield strength increases linearly with increasing Mg content from about 45 N/mm2 at 1% Mg to about 120 N/mm2 at 4% Mg. The tensile strength also increases linearly, but with a steeper gradient. With 1% Mg it is about 60 N/mm2, with 4% Mg 240 N/mm2.[20] There are different statements for the elongation at break : Research on alloys based on the purest shows an increasing elongation at break from about 20% elongation at 1% to 30% at 5% Mg Elongation at break: First it drops sharply from 38% elongation and 1% Mg to 34% elongation and about 1.8% Mg, reaches a minimum at 3% Mg with only 32% elongation and then rises again to about 35% Elongation at 5% Mg.[21] [22]
The flow curves for AlMg show the behaviour typical of metallic materials of increasing the flow voltage with the true elongation or forming degree. For all alloys, the increase is relatively strong at low elongations and lower at higher elongations. However, the curves for higher alloy varieties are always above the low-dried. For example, with a true elongation of 0.2, AlMg0.5 has a flow voltage of about 100 N/mm2, AlMg one of 150 N/mm2, AlMg3 of 230 N/mm2 and AlMg4.5Mn0.4 of about 300 N/mm2. The higher the alloy content and the greater the elongation, the greater the resulting PLC effect and the Lüders effect.[23]
In the case of pure aluminium, the grain size has a minor influence on the strength for metals. In the case of alloys, the influence increases with the alloy content. At 5% Mg, materials with grain sizes of 50 μm achieve uniform elongations of around 0.25, at 250 μm they are around 0.28. AlMg8 already achieves uniform elongations of 0.3 with a grain diameter of 200 μm. With increasing grain size, both the Lüders strain and the Lüders effect decrease.[24]
In the case of very high degrees of deformation with heavily work-hardened alloys, softening can also occur at room temperature. In a long-term study over 50 years, a decrease in strength could be measured by the end. The decrease is greater the higher the degree of deformation and the higher the alloy content. The softening itself is very pronounced at the beginning and quickly subsides. The effect can be avoided by stabilization annealing at around 120 °C to 170 °C for several hours.[25]