High-strength heat-treatable aluminium alloy and article made thereof

FIELD: metallurgy.

SUBSTANCE: invention relates to metallurgy of light alloys, particularly, to super strong heat-treatable aluminium alloys of Al-Zn-Mg-Cu system intended for making semis, i.e. formed and rolled tubes, stamped covers to be used as has centrifuge parts. Articles are made from alloy containing the following components in wt %: zinc 8.0-9.0, magnesium 2.3-3.0, copper 2.0-2.6, zirconium 0.1-0.2, beryllium 0.0001-0.002, cerium 0.005-0.05, calcium 0.005-0.05, titanium 0.005-0.05, iron up to 0.15, silicon up to 0.1, and at least of element of the group: manganese up to 0.1, aluminium making the rest.

EFFECT: higher strength, ductility, toughness, fatigue strength.

2 cl, 2 tbl, 1 ex

 

The present invention relates to the field of metallurgy of light alloys and, in particular, alloys based on aluminum, which are designed to produce deformed semi-finished products in the form of compressed and rolled pipes, extruded caps are used as parts of a gas centrifuge working for a long time in difficult conditions at moderately elevated temperatures.

Known aluminum alloy brand VPC the following chemical composition, wt.%:

Zinc - 8,0-9,0

Magnesium - 2,3-3,0

Copper - 2,0-2,6

Zirconia - 0,1-0,2

Aluminum - rest.

(Wrought aluminium alloys of high purity. Of the brand. OST 1 90026-80).

The disadvantage of this alloy is low structural strength due to their fragility, resulting from the tendency to grain boundary fracture. The brittleness of the alloy also determines its low adaptability in metallurgical production. The alloy has an increased tendency to hot and cold cracking during casting of ingots, is characterized by low velocities expires during compaction and allows very limited deformation during forging and rolling.

Known aluminum alloy of the following chemical composition, wt.%:

Zinc - 8,0-9,0

Magnesium - 2,3-3,0

Copper - 2,0-2,6

Zirconia - 0,1-0,2

Iron - 0,05-0,3

Silicon - 0,03-0,15

Beryllium is 0.0001-0,002

Hydrogen is (0,-3,6)×10 -5

Aluminum - rest.

(RF patent for the invention №2164541, class SS/10 published 27.03.2001,, prototype.

The disadvantage of this alloy is low structural strength due to their fragility, resulting from the tendency to grain boundary fracture. This reduces the life of the product. Alloy few tech in metallurgical production in casting ingots in the processing of their pressure.

Features alloy based on aluminum the following chemical composition, wt.%:

Zinc - 8,0-9,0

Magnesium - 2,3-3,0

Copper - 2,0-2,6

Zirconia - 0,1-0,2

Beryllium is 0.0001-0,002

Cerium - 0,005-0,05

Calcium - 0,005-0,05

Titanium - 0,005-0,05

Iron-0.15

Silicon, up to 0.1.

At least one element from the group:

Manganese 0.1

Chrome to 0.05.

We offer alloy based on aluminum has the following chemical composition and differs from the known fact that it further comprises cerium, calcium, titanium and at least one element of group - manganese or chromium, with the following ratio of components (mass fraction)%:

Zinc - 8,0-9,0

Magnesium - 2,3-3,0

Copper - 2,0-2,6

Zirconia - 0,1-0,2

Beryllium is 0.0001-0,002

Cerium - 0,005-0,05

Calcium - 0,005-0,05

Titanium - 0,005-0,05

Iron-0.15

Silicon 0.1

At least one element from the group:

Manganese 0.1

Chromium 0.05

Aluminum - rest.

Proposed is the range of the alloy is characterized by high structural strength due to low susceptibility to intergranular fracture due to high ductility intergranular boundaries. In the rise noticeable characteristics that describe the plasticity of the metal. Elongation increases by 30%, the impact strength by 40%, increased resistance to repeated loads. As a consequence increases the resource product.

Reducing fragility beneficial effect on technology of plasticity in metals production. Decreases the propensity for hot and cold cracks in casting ingots, increases their ductility at handling pressure.

The reason for the increase of ductility and fracture toughness lies in the reduction of grain boundary embrittlement due to complex microalloying alloy for a given compound that increases the ductility intergranular boundaries. The percentage of intergranular fracture in the transition from the known alloy to offer reduced several times.

The advantages of the alloy are also manifested in the product made from the above alloy.

Example.

In an electric resistance furnace with a capacity of 170 kg were cast ingots with a diameter of 65 mm and a diameter of 215 mm from the known and the proposed alloys.

Chemical composition shown in table 1.

Table 1
The actual chemical composition of the cast ingot from the local and the proposed alloys, weight%
AlloyAlZnMgCuZrBeCECATih2FeSiMnCr
Knownbase8,62,62,40,120,0006--2,1×10-50,120,07--
Offerbase8,52,72,30,130,00150,010,0070,03-0,10 0,060,030,01

The ingots were ofhomogeneous regime 420°C, 6 hours +460°C, 20 hours.

Ingots with a diameter of 65 mm cut-to-length harvesting ⌀65×87 mm, was on the ground on ⌀62 mm stamped in several transitions on the workpiece under details in the form of caps.

Ingots with a diameter of 215 mm cut-to-length blanks (length 600 mm were ground on a diameter of 200 mm and two systems with subsequent prokladkoi on the diameter of 290 mm From the received forgings were megacephaly blanks from which the extruded tube ⌀138×4 mm

Stamping in the form of caps were placed vertically in special hardening basket in a checkerboard pattern with a gap of about 40 mm, the Temperature in the hardening furnace was maintained at a level of 470°C with accuracy of ±3°C. When immersed basket with punchings in a bath of water at room temperature was carried out intensive bubbling water with compressed air supplied from the bottom of the tub.

The pipes were tempered from the vertical quenching furnace with a temperature of 470±3°C in the tank with water at room temperature with a vertical dive. After quenching warped tubes ruled the drawing with the residual plastic deformation of 1.5%.

Tempered stamping and tube artificially aged very early because the mode 140°C, 16 hours).

Table 2 presents the mechanical properties of forgings and extruded pipes of the world is aqueous and the proposed alloys.

Table 2
The actual mechanical properties of forgings and pipe of known and proposed alloys.
The average values of the results of 10 trials
AlloyPrefabricatedσin, MPaσ02, MPaδ, %Ψ, %KCU, KGM/cm2
knownStamping6606104,0120,5
Pipe6806305,0150,6
offerStamping6706207,5180,8
Pipe690 6508,0210,85

Of thermally enhanced tubes known and proposed alloys cut samples with hub stresses (Kt=2,3; f=3 Hz; R=0,1) for trials on low-cycle endurance under pulsating tensile σmax=160 MPa. Samples of known alloy withstood 130-190 thousand of cycles to failure, and samples of the proposed alloy - 270-350 thousand cycles.

Thus, the analysis of the results of the test tubes of known and proposed alloys shows a clear advantage of the latter.

We offer alloy has a higher value relative elongation δ and relative narrowing Ψ, toughness KCU and particularly higher resistance to fatigue loads. This gives the opportunity to increase the resource product.

1. Heavy-duty wrought alloy based on aluminum containing zinc, magnesium, copper, zirconium, beryllium, iron, silicon, characterized in that it further comprises cerium, calcium, titanium and at least one element from the group of manganese and chromium in the following ratio, wt.%:

Zinc8,0-9,0
Magnesium 2,3-3,0
Copper2,0-2,6
Zirconia0,1-0,2
Beryllium0,0001-0,002
Cerium0,005-0,05
Calcium0,005-0,05
Titanium0,005-0,05
Ironto 0.15
Silicon0.1

At least one element from the group:
Manganese0.1
Chrome0.05
Aluminumrest

2. The product of heavy-duty wrought alloy based on aluminum, characterized in that it is made from an alloy according to claim 1.



 

Same patents:

FIELD: metallurgy.

SUBSTANCE: plate from aluminium alloy consists of 6.8-8.5 wt % Zn, 1.75-2.3 wt % Cu, 1.5-1.84 wt % Mg and up to 0.25 wt % at least of one of Zr, Hf, Sc, Mn and V, and if necessary, additives crushing the grain, and the rest includes aluminium and inevitable impurities; at that, plate has the thickness of not more than 2.00 inches. Plate has the ratio between yield strength and failure viscosity, which meets the following equation: FT_LT ≥ -4.0* (TYS_L)+453. Plate has TYS_L that is at least 80 ksi and FT_LT that is at least 100 ksi√ inch, where TYS_L - tensile yield strength of the plate in direction L, in ksi, which is measured in compliance with ASTM E8 and ASTM B557, FT_LT - failure viscosity (Kapp) of the plate in flat stressed state in direction L-T, in ksi√inch, which is measured in compliance with ASTM E561 and B646 on specimen of aluminium alloy with central crack in position T/2 of the plate; at that, specimen has the width of 16 inches, thickness of 0.25 inches and initial length of preliminary fatigue crack of 4 inches.

EFFECT: plates are made from aluminium alloys having high failure viscosity at maintaining the acceptable strength level.

32 cl, 10 dwg, 10 tbl, 4 ex

FIELD: weapons and ammunition.

SUBSTANCE: method consists in obtaining the workpiece to be rolled and its heating, hot rolling of plate according to the size requirements, cooling down to room temperature and artificial ageing. Production of workpieces to be rolled involves rolling according to the size requirements of ingots and/or slabs from aluminium alloys for sandwich plate and assembly of a pack using them. Pack is heated at 500-550°C during 5-7 hours. Rolling according to the size requirements is performed at 410-450°C. Additional hardening is performed at 450-480°C. Artificial ageing is performed at temperature of 110-120°C during 24-36 hours.

EFFECT: improving armour properties and durability of sandwich plate.

5 cl, 1 tbl

FIELD: metallurgy.

SUBSTANCE: aluminium-based alloy contains the following, wt %: zinc - 6.35 - 8.0, magnesium - 0.5 - 2.5, copper - 0.8 -1.3, iron - 0.02 - 0.25, silicon - 0.01 - 0.20, zirconium - 0.07 - 0.20, manganese - 0.001 - 0.1, chrome - 0.001 - 0.05, titanium - 0.01 - 0.10, boron - 0.0002 -0.008, beryllium - 0.0001 - 0.05, at least one element from potassium, sodium, calcium group in quantity of 0.0001 - 0.01 each, aluminium is the rest; at total content of zinc, magnesium, copper within 8.5-11.0, and that of zirconium, manganese and chrome - within 0.1-0.35. Method involves loading and melting of charge components, flux treatment of molten metal, molten metal purification, further vacuum treatment of molten metal in mixer and casting of ingots; boron is added to molten metal in the form of Al-Ti-Be alloy which is distributed at least one hour before molten metal pouring to mixer along the whole surface area of mixer bottom; at that, mixer is pre-heated to temperature which is by 15-30°C more than molten metal temperature, and vacuum treatment of molten metal in mixer is performed at temperature of 695-720°C, during 45-90 minutes.

EFFECT: invention allows obtaining high-strength aluminium alloys with absence of primary intermetallic compounds, decreased content in them of non-metallic inclusions and dissolved gases, with stable properties and optimum size of grain on basis of standard furnace and process equipment.

2 cl, 3 tbl

FIELD: metallurgy.

SUBSTANCE: there proposed is aluminium-based alloy intended for manufacture of deformed semi-finished products in the form of sheets, formings, rods, tubes or in any other form to be used in gas centrifuges, low pressure compressors, vacuum molecular pumps and in other heavily loaded items operating at moderately increased temperatures. Alloy contains the following components, wt %: zinc 6.6-7.4, magnesium 3.2-4.0, copper 0.8-1.4, scandium 0.12-0.30, zirconium 0.06-0.20, titanium 0.01-0.07, molybdenum 0.01-0.07, nickel 0.35-0.65, iron 0.35-0.65, silcone 0.10-0.30, and aluminium is the rest.

EFFECT: improving strength properties of alloy at room temperature.

3 tbl, 1 ex

FIELD: metallurgy.

SUBSTANCE: aluminium-based cast alloy has the following chemical composition, in wt %: Cu 3.5-6.0, Mg 0.2-0.9, Ti 0.1-0.4, Zr 0.1-0.5, Mn 0.2-1.2, Zn 0.5-2.5, Sc 0.15-0.5, Al making the rest.

EFFECT: reduced metal consumption, higher reliability in operation.

2 tbl

FIELD: metallurgy.

SUBSTANCE: invention relates to alloy of AA7000 series and to the manufacturing method of products from this aluminium alloy, and namely to aluminium deformed products of relatively large thickness, namely of 30 to 300 mm. Method involves casting of workpiece - ingot of aluminium alloy of AA7000 series, which contains >0.12 to 0.35% Si, pre-heating and/or homogenisation of workpiece, hot deformation treatment of workpiece using one or more methods chosen from the group, which involves rolling, extrusion and forging, optionally cold deformation treatment, solution treatment, workpiece solution treatment cooling, optional tension or compression or other cold deformation treatment for release of stresses, which is performed by straightening or drawing or by cold rolling, ageing of workpiece in order to achieve the required state. At least one heat treatment is performed at temperature in the range of more than 500°C, but lower than solidus temperature of the considered aluminium alloy. The above heat treatment is performed either: (i) after heat treatment by homogenisation prior to hot deformation treatment, or (ii) after solution treatment, or (iii) both after heat treatment by homogenisation prior to hot deformation treatment, and after solution treatment.

EFFECT: obtaining the product from deformed aluminium alloy, which has improved balance of properties, and namely destruction viscosity, tensile yield point, tensile ultimate strength and relative elongation.

30 cl, 8 tbl, 3 ex

FIELD: metallurgy.

SUBSTANCE: group of inventions can be used at manufacture of semi-finished products in the form of forgings, formings, pressed rods and channels, rolled plates and sheets from high-strength alloys of Al-Zn-Mg-Cu system, which are intended to be used in power structures of aerospace equipment and transport means, on which stringent strength, crack resistance, fatigue life, corrosion resistance requirements are imposed. In order to solve the set task, high-strength alloy on the basis of aluminium, which contains the following, wt %, is proposed: Zn 6.2-8.0, Mg 1.5-2.5, Cu 0.8-1.2, Zr 0.05-0.15, Fe 0.03-0.15, Ti 0.01-0.06, at least one element of the group of metals: Ag 0.01-0.5, Sc 0.01-0.35, Ca 0.0001-0.01, Al and inevitable impurities are the rest. In particular version of alloy the inevitable impurities include not more than 0.05 of Si, Mn, Cr, Ni and not more than 0.01 of Na, H2, O2, B, P. Method for obtaining an item from this alloy involves ingot casting, its homogenisation, hot deformation and strengthening heat treatment of the item, which includes hardening and staged ageing; at that, during the ingot casting there performed is melt purification by blowing with argon or mixture of argon with chlorine and out-of-furnace purification using rotor and/or filtering devices, and homogenisation is performed as per one-stage mode at temperature which is by 55-130°C lower than unbalanced solidus (tu.s.) temperature of this alloy with exposure during 8-36 h or as per two-stage mode at temperature at the first stage at the temperature which is by 175-280°C lower than tu.s. temperature, and at the second stage at the temperature which is by 75-125°C lower than tu.s., with exposure at each stage to 24-36 h; hot deformation is performed at temperature of 300-420°C, hardening is performed at temperature which is by 50-120°C lower than tu.s. during the time determined with the item thickness, with further cooling to temperature of not more than 80°C.

EFFECT: improving the set of mechanical and corrosive characteristics, and characteristics of crack resistance, life time and manufacturability.

10 cl, 1 tbl

FIELD: metallurgy.

SUBSTANCE: invention refers to alloys on base of aluminium, particularly to Al-Zn-Cu-Mg alloys on base of aluminium, and also to procedure of fabrication of rolled or forged deformed product of it and to rolled or forged deformed product proper. The procedure consists in following stages: a) casting an ingot, containing wt % Zn 6.6-7.0, Mg 1.68-1.8, Cu 1.7-2.0, Fe 0-0.13, Si 0-0.10, Ti 0-0.06, Zr 0.06-0.13, Cr 0-0.04, Mn 0-0.04, additives and other side elements ≤0.05 each, b) homogenising of the said ingot at 860-930°F or, preferably, at 875-905°F, c) hot deformation treatment of the said ingot with temperature at input 640-825°F, but preferably - 650-805°F by rolling or forging to a plate with finish thickness from 2 to 10 inches, d) thermal treatment for solid solution and quenching the said plate, e) drawing the said plate with residual deformation from 1 to 4 %, f) ageing the said plate by heating at 230-250°F during from 5 to 12 hours and 300-360°F during from 5 to 30 hours during equivalent time t(eq) between 31 and 56 hours. Equivalent time t(eq) is determined from formula:

where T corresponds to instant temperature in K during annealing, while Tcontr corresponds to control temperature equal to 302°F (423K), and t(eq) is expressed in hours.

EFFECT: production of deformed product possessing improved combination of mechanical strength for corresponding level of crack resistance and resistance to corrosion cracking under load.

8 cl, 2 dwg, 10 tbl, 4 ex

FIELD: metallurgy.

SUBSTANCE: alloy on base of aluminium contains following components wt %: zinc 5-8, magnesium 2-3.1, nickel 1-4.2, iron 0.02-1, zirconium 0.02-0.25 %, copper 0.05-0.3 %. Also, temperature of equilibrium solidus of material is as high as 550°C and hardness is as high as 180 HV. Alloy has a structure corresponding to matrix formed with solid solution of aluminium with uniformly distributed disperse particles of secondary discharges in it and particles of aluminides containing nickel and iron of eutectic origin uniformly distributed in matrix. Also, alloy contains matrix and aluminides at the following ratio, vol % aluminides containing nickel and iron 5.0-6.3, matrix - the rest.

EFFECT: production of new high-strength alloy thermally hardenable and designed both for fabrication of shaped casting and of deformed semi-products.

4 cl, 5 tbl, 4 ex

FIELD: metallurgy.

SUBSTANCE: product consists of following components, wt %: Zn 9.0-14.0, Mg 1.0-5.0, Cu 0.03-0.25, Fe <0.30, Si <0.25, Zr from 0.04 to less, than 0.3 and one or more elements chosen from group consisting of: Ti <0.30, Hf <0.30, Mn <0.80, Cr <0.40, V <0.40 and Sc <0.70, random elements and impurities, each <0.05, totally <0.15, and aluminium - the rest. The procedure for fabrication of product out of aluminium alloy consists in casting an ingot, in homogenisation and/or in preliminary heating the ingot upon casting, in hot treatment of the ingot into preliminary finished product with one or more methods, chosen from the group including rolling, extrusion and forging. Not necessarily, the preliminary treated product can be heated or hot treated and/or cold treated to a required shape of a blank; further formed blank is subjected to heat treatment to solid solution, to hardening blank heat treated to solid solution; not necessarily, hardened blank can be stretched or compressed, or cold treated by other way to stress relief, for example, by levelling sheet products or artificial ageing, till obtaining a required condition.

EFFECT: product with reduced tendency to forming hot cracks and with improved characteristics of strength, fracture toughness and hardness over 180 HB at artificially aged state.

32 cl, 6 tbl, 6 ex

FIELD: metallurgy.

SUBSTANCE: aluminum based protective alloy comprises, in mass %, 4-5 of zinc, 0.01-0.06 of indium, 0.01-0.1 solder, 0.01-0.1 of zirconium, and aluminum the remainder.

EFFECT: enhanced corrosion protection.

2 tbl

Aluminum-base alloy // 2280092

FIELD: metallurgy.

SUBSTANCE: invention relates to aluminum-base alloys used for making deformed semifinished products used in industry and building. Proposed alloy comprises the following components, wt.-%: zinc, 4.5-5.6; magnesium, 1.6-2.1; manganese, 0.2-0.8; scandium, 0.03-0.09; zirconium, 0.05-0.12; copper, 0.1-0.3; titanium, 0.01-0.07; molybdenum, 0.01-0.07; cerium, 0.001-0.01, and aluminum, the balance, wherein the ratio content of zinc to magnesium = 2.6-2.9. Invention provides the development of alloy providing enhancing corrosion resistance of articles.

EFFECT: improved and valuable properties of alloy.

2 tbl, 1 ex

FIELD: metallurgy of aluminum alloys; manufacture of wrought semi-finished products for transport engineering and other industries.

SUBSTANCE: proposed alloy includes the following components, mass-%: zinc, 3.6-4.1; magnesium, 0.6-1.1; manganese, 0.2-0.5; zirconium, 0.05-0.12; chromium, 0.05-0.15; copper, 0.1-0.2; titanium, 0.01-0.06; molybdenum, 0.01-0.06; the remainder being aluminum.

EFFECT: enhanced corrosion resistance and technological ductility of semi-finished items at plastic metal working.

2 tbl, 1 ex

FIELD: metallurgy.

SUBSTANCE: invention relates to aluminum-base material. Proposed material comprises the following components, wt.-%: zinc, 6-8; magnesium, 2.5-3.5; nickel, 0.6-1.4; iron, 0.4-1.0; silicon, 0.02-0.2; zirconium, 0.1-0.3; scandium, 0.05-0.2, and aluminum, the balance wherein the temperature of equilibrium solidus of material is 540°C, not less, the hardness value of material is 200 HV, not less. Invention provides the development of the novel high-strength material designated for both producing fashioned ingots and deformed semifinished product possessing high mechanical properties. Invention can be used in making articles working under effect of high loading, such as car articles and sport inventory articles.

EFFECT: improved and valuable properties of material.

4 cl, 2 dwg, 4 tbl, 3 ex

FIELD: nonferrous metallurgy.

SUBSTANCE: invention relates to ultrastrong economically alloyed aluminum-based alloys belonging to system Al-Zn-Mg-Cu. Alloy and article made therefrom are, in particular, composed of, %: zinc 3.5-4.85, copper 0.3-1.0, magnesium 1.2-2.2, manganese 0.15-0.6, chromium 0.01-0.3, iron 0.01-0.15, silicon 0.01-0.12, scandium 0.05-0.4, at least one element from group: zirconium 0.05-0.15, cerium 0.005-0.25, and aluminum - the rest.

EFFECT: increased characteristics of corrosion resistance, bondability with all welding techniques, and lowered fatigue crack growth rate.

2 cl, 2 tbl

FIELD: metallurgy.

SUBSTANCE: invention proposes alloy containing the following components, wt.-%: zinc, 5.4-6.2; magnesium, 2.51-3.0; manganese, 0.1-0.3; chrome, 0.12-0.25; titanium, 0.03-0.10; zirconium, 0.07-0.12; beryllium, 0.0002-0.005; sodium, 0.0001-0.0008; copper, 0.2, not above; iron, 0.3, not above; silicon, 0.2, not above, and aluminum, the balance. Alloy provides enhancing uniformity of armor structure and its welded seams, stable armor resistance of extended armor welded seams independently on disposition of units to bed welded, elimination of splits from armor rear site in case its resistance to a missile impact, elimination possibility for reducing tenacity of armor during its exploitation including using under conditions of combination with dynamic protection of armored-body and armor-carrying mechanized objects. Invention can be used in producing armor for individual protection and for protection of mechanized armor-carrying objects against effecting agents.

EFFECT: improved and valuable properties of alloy.

1 tbl

FIELD: metallurgy.

SUBSTANCE: invention proposes alloy comprising the following components, wt.-%: zinc, 4.7-5.3; magnesium, 2.1-2.6; chrome, 0.12-0.25; titanium, 0.03-0.10; zirconium, 0.07-0.12; beryllium, 0.0002-0.005; iron, 0.05-0.35; silicon, 0.05-0.25; boron, 0.0003-0.003; sodium, 0.0001-0.0008; copper, 0.2, not above, and aluminum, the balance. Proposed alloy provides enhancing the armor structure uniformity and its welded joints, to provide stable armor resistance of extended welded joints of armor and independently of location of units to be welded, to exclude splitting off from rear side of armor in case armor not piercing by a missile, to exclude possibility for decreasing tenacity of armor in exploitation including using under conditions of combination with external dynamic protection of armored-carcass and armored-carrying mechanized objects. Invention can be used in producing armor for armored-carrying equipment for protection against effect of affection agents.

EFFECT: improved and valuable technical properties of alloy.

FIELD: metallurgy.

SUBSTANCE: invention proposes alloy comprising the following components, wt.-%: zinc, 4.7-5.3; magnesium, 2.1-2.6; manganese, 0.05-0.15; chrome, 0.12-0.25; titanium, 0.03-0.10; zirconium, 0.07-0.12; beryllium, 0.0002-0.005; iron, 0.05-0.35; silicon, 0.05-0.25; sodium, 0.0001-0.0008; copper, 0.2, not above, and aluminum, the balance. Proposed alloy provides enhancing armor structure uniformity and its welded joins, to provides stable armor resistance of armor welded joints being independently on location of units to be welded, to exclude splitting off from rear side of armor in case armor not piercing by missile, to provide high tenacity of armor including its using under conditions of combination with external dynamic protection of armored-carcass and armor-carrying mechanized objects. Invention can be used in producing armor for armor-carrying equipment for its protection against protection of affecting agents.

EFFECT: improved and valuable properties of alloy.

FIELD: metallurgy.

SUBSTANCE: the present innovation deals with obtaining aluminum-based alloys necessary for manufacturing stampings, particularly those of automobile wheels disks. The alloy in question has got the following composition, weight%: copper 0.8-2.2; magnesium 1.2-2.6; manganese 0.2-0.6; iron ≤0.25; silicon ≤0.20; zinc 5.0-6.8; titanium ≤0.1; chromium 0.08-0.17; zirconium 0.01÷0.12; boron 0.0008-0.005; antimony 2.5-3.5; indium 2.5-3.5; boron 0.4-0.5; hydrogen (0.3-4.1)10-5, aluminum - the rest. The alloy in question is of optimal combination of strength and plasticity that guarantee the required level of performance characteristics of automobile wheels disks, the decrease of their weight in combination with high technological effectiveness at volumetric stamping, especially complex-shaped articles.

EFFECT: higher strength and plasticity of the alloy.

2 cl, 1 ex, 3 tbl

Aluminum-base alloy // 2319762

FIELD: metallurgy, alloys.

SUBSTANCE: invention relates to compositions of deformable aluminum-base alloys. Proposed alloy comprises the following components, wt.-%: zinc, 5.0-7.0; magnesium, 0.4-0.8; copper, 0.8-1.2; manganese, 0.8-1.2; zirconium, 0.2-0.3; titanium, 0.2-0.3; niobium, 0.2-0.3; nickel, 3.0-5.0; boron, 0.02-0.03, and aluminum, the balance. Proposed alloy possesses the enhanced strength. Proposed alloys can be used in aircraft construction and automobile construction.

EFFECT: improved and valuable property of alloy.

1 tbl

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