Patent Application
20210291270
The proposed invention relates to the field of metallurgy, namely, to aluminium-based alloys used for the production of powders applied in the manufacture of parts using additive technologies, including the method of selective laser melting.
AlSi10Mg aluminium alloy is known, which is used for the manufacture of parts using additive technologies, containing the following elements, % wt: 9-11 silicon, 0.45-0.6 magnesium, 0.05 manganese, 0.05 zinc, <0.55 iron, <0.1 copper (see Process optimization and microstructural analysis for selective laser melting of AlSi10Mg. K. Kempen, L. Thijs, E. Yasa, M. Badrossamay, W. Verheecke, J P. Kruth. Solid Freeform Fabrication Symposium Conference, Vol. 22, Pages 484-495, 2011).
This alloy shows high processability during printing process of parts, but the high eutectic content results in low ductility. In addition, heat treatment results in relatively low strength.
For complex parts operating under various loads, including alternating loads, materials with a higher set of characteristics and high ductility are required, while the structure must have high thermal stability to work in conditions of process and operational heating.
An aluminium-magnesium alloy is known (CN 105838939 published on Aug. 10, 2016), containing the following components, % wt: 3-6 magnesium, 0.1-0.5 chromium, 0.4-0.7 zinc, 0.25-0.4 silicon, 0.1-0.5 manganese, 0.1-0.5 nickel, 0.05-0.2 zirconium, 0.2-0.5 copper, 0.1-0.2 bismuth, 0.1-0.2 titanium, 0.1-0.2 cerium. The disadvantage of this invention is the high content of elements, such as zinc and bismuth, which easily evaporate during the selective laser melting process, thus changing the chemical composition of the finished part. Also, the addition of copper impairs the weldability of the material, which also affects the quality of the finished parts.
An aluminium alloy is known (CN 105695823 published on Jun. 22, 2016), having improved mechanical properties, containing the following components, % wt: 4.5-5.0 magnesium, 0.5-1.0 manganese, 0.2-0.6 zirconium, 0.12-0.25 chromium, 0.28-0.30 vanadium, 0.1-0.15 titanium, 0.006-0.2 silicon, 0.008-0.2 iron, 0.01-0.05 copper, 0.005-0.25 zinc, 0.05-0.15 boron. The disadvantage of this invention is an insufficient concentration of chromium (0.12-0.25% wt), which leads to insufficient hardening from the addition of chromium.
A rapidly solidified aluminium powder alloy containing an increased chromium content is known (U.S. Pat. No. 5,049,211 published on Sep. 17, 1991). The alloy contains chromium of 1 to 7% wt, as well as at least one element from the group of Hf, W, Mo, Nb, Ta of up to 6% wt. The alloy is characterized by high strength and good thermal stability. However, due to a high content of transition metals, the ductility is low, which also results in low impact strength.
An aluminium alloy is known (US 20170298477 published on Oct. 19, 2017), containing the following components, % wt: 1.0-8.0 magnesium, 0.2-3 scandium, 0.1-1.5 zirconium, 0.5-5 calcium. The disadvantage of this invention is the high cost of the alloy due to the presence of scandium in its composition, as well as the presence of a large amount of calcium, which can evaporate during selective laser melting process.
The closest prior art of the proposed invention is an aluminium-based alloy (EP 0304284 published on Aug. 17, 1988) containing the following elements (% wt):
0.4-1.2 chromium,
0.3-0.8 zirconium,
1.5-2.5 manganese,
0-2.0 magnesium,
Balance is aluminium.
The alloy has good strength and thermal stability, which enables to use it for the manufacturing of parts. A high content of manganese leads to good casting properties. However, due to high concentration of transition metals, the plasticity of the material is quite modest. A reduced magnesium content does not result in significant hardening.
The technical objective of the invention is an increase in the strength characteristics of aluminium alloy for the manufacturing of parts using powder and additive technologies while maintaining a high level of elongation, high thermal stability and the absence of defects in the form of hot cracks.
The set technical objective is accomplished by the proposed aluminium material (alloy) in the form of a powder containing elements in the following composition (% wt):
and at least one element from the group comprising:
A product, made of the specified powder aluminium material by using additive technologies, is also proposed.
Powder production is can be carried out using the following technology, which provides additional benefits:
Magnesium additive provides both solid-solution hardening and the formation of the required solidification range for the formation of a dense structure when exposed to a laser beam radiation.
It is known that alloys of the Al—Mg system with a magnesium content of 3-4% wt are characterised by a rather high tendency to hot cracking. Considering the results of manufacturing 3D parts by selective laser melting (SLM) to increase the resistance to the formation of hot cracks and increase the alloy strength, it is proposed to dope the alloy with magnesium in an amount of 4.5-6.5% by weight.
Zirconium is introduced to form the dispersed precipitates of Al3Zr during the supersaturated solid solution decomposition. Zirconium has a low diffusion coefficient in the aluminium matrix, which results in the formation of nano-sized phases during high-temperature ageing. Since the Zr-containing phase is coherent with the aluminium matrix, a strong hardening effect is achieved. The zirconium content is proposed in such a way as to ensure the production of a supersaturated solid solution and to avoid the appearance of large intermetallics in the powder, considering the high crystallisation rates. Chromium also forms a supersaturated solid solution in the aluminium matrix and does not form a joint intermetallic compound with zirconium, which enables to form a larger number of phases during the ageing process and increase strength. In alloys containing magnesium, the Al18Cr2Mg3 phase can be formed instead of the Al7Cr phase, which allows for the formation of a larger volume of intermetallic phases that increase strength. Also, chromium and zirconium at certain ratios increase each other's solubility in aluminium. At the same time, the greatest positive effect is achieved with a Cr/Zr ratio in a range of 0.5 to 1.5.
The addition of boron to the alloy provides a modification effect in the manufacture of parts due to the formation of nanoscale boride particles. A more dispersed structure has a more favourable effect on the performance of the finished part.
At least one element from the group of iron, manganese, nickel is introduced for additional hardening due to both the formation of a solid solution and the formation of intermetallic phases with aluminium, and at high concentrations, an increase in the castability of alloys is achieved, which is associated with the formation of eutectic when these elements are introduced in accordance with equilibrium phase diagrams.
The drawings show:
The proposed invention is described by the following example.
The alloy was prepared in the following sequence:
Aluminium was melted and heated to a temperature of 830-850° C. Then zirconium was added with a melted Al-10% Zr alloying additive. Chromium and iron were added with Cr80F20 (80% Cr 20% flux) and Fe80F20 (80% Fe, 20% flux) tablets; manganese and nickel, in the form of pure metals.
The melt was heated to 810-830° C., kept for 1 hour at a temperature of 790-820° C., and stirred every 15-20 minutes.
After removing the slag, carnallite flux was added on the surface of the melt at the rate of 2 kg/t, and after its melting, magnesium was added.
The melt was held for 30 minutes, while being stirred every 15 minutes.
Boron was introduced into the melt in the form of a Al-5% B master alloy, then the melt was held for 15 minutes and after that stirred.
Slag was removed from the surface of the melt and samples were taken to the chemical composition control.
Based on the results of the quick analysis, the chemical composition was adjusted to the calculated one.
Then the melt was atomized through a nozzle to produce spherical powders. The obtained powders were classified to obtain a fraction of 20-63 μm.
Nitrogen-oxygen gas mixture was used as a carriage gas in atomization process.
As a result, powders of the following chemical composition were obtained, as shown in Table 1.
The resulting powders were used to obtain samples using selective laser melting technology. The EOS M290 printer was used to make samples. Printing was carried out at a laser power of 250 W with various hatch distance and scanning speeds in the range of 200-1000 mm/s.
The quality of the obtained samples was determined by the microstructure. Microspecimens were prepared according to the standard technology, the study was carried out on an unetched surface using a METAM RV-21 inverted metallographical microscope.
Images of the structure are shown in
Also, samples were made to determine the hardness and tensile properties. The hardness was determined using an EMCO-TEST hardness tester, and the tensile tests were carried out in accordance with GOST-1497.
The samples were examined after annealing at a temperature of 400° C. for 5 hours.
AlSi10Mg alloy, which was annealed at a temperature of 300° C. for 2 hours, was put into a perspective. The test results are presented in Table 2.
The resulting material has a 25% increased tensile strength with a 70% improved elongation.
Besides, due to the formation of dispersoids with a slow diffusion rate in aluminium, it is possible to maintain high hardness values during prolonged annealing at a temperature of 200° C. Alloys 5-0 and 6-0, having a strong difference between the chromium and zirconium content, show slightly reduced elongation due to the formation of larger intermetallics. This fact is caused by the reduced solubility of the elements in the aluminium matrix when the ratio deviates from the optimal one.
The technical result is an increase in the strength of aluminium alloy for the manufacture of parts using powder and additive technologies while maintaining a high level of elongation, high thermal stability and the absence of defects.
This application is a continuation of and claims priority to PCT Application No. PCT/RU2018/000796 filed Dec. 7, 2018, which is incorporated herein by reference in its entirety for all purposes.
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/RU2018/000796 | Dec 2018 | US |
| Child | 17341279 | US |
