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Alloy В96Ц (1960)

Alloy 01311C Alloy 1105 Alloy 1151 Alloy 1161 Alloy 1163 Alloy 1201 Alloy 1205 Alloy 1213 Alloy 1215 Alloy 1320 Alloy 1370 Alloy 1420 (01420) Alloy 1424 Alloy 1430 Alloy 1440 Alloy 1441 Alloy 1450 Alloy 1531 Alloy 1541 Alloy 1541pc Alloy 1543 Alloy 1577 Alloy 1905 Alloy 1911 Alloy 1915 Alloy 1925 Alloy 1931 Alloy 1933 Alloy 1935 Alloy 1953 Alloy 1955 Alloy 1973 Alloy 1980 (B48-4) Alloy 1985h Alloy 8011 Alloy 8011A Alloy 8111 Alloy A1Mg1M1 Alloy ABT101 (1901) Alloy ABT102 (1903) Alloy AB (1340) Alloy AVD1 Alloy AVD1-1 ABE Alloy Alloy AD1pl Alloy AD31 (1310) Alloy AD31E (1310E) Alloy AD33 (1330) Alloy AD35 (1350) Alloy AW Alloy AZh0.6 Alloy AZh0.8 Alloy AZh1 Alloy AK10 (SvAK10) AK12D alloy Alloy AK4 (1140) Alloy AK4-1 (1141) Alloy AK4-2 (1143) Alloy AK5 Alloy AK6 (1360) Alloy AK6-1 Alloy AK8 (1380) AKM Alloy Alloy AKCM Alloy AM4 Alloy AMg0.5 (1505) Alloy AMg0,5pc Alloy AMg0.7 Alloy AMG1 (1510) Alloy AMg1.5 Alloy AMg2 (1520) Alloy AMg2.5 Alloy AMg3 (1530) Alloy AMg3.5 Alloy AMg3S Alloy AMg4 (1540) Alloy AMg4.5 Alloy AMg5 (1550) Alloy AMg5P (1557) Alloy AMg6 (1560) Alloy AMg61 (1561) Alloy AMg61H (1561H) Alloy AMg63 (СвАМг63) Alloy AMg65 Alloy AMSH1 Alloy AMSH2 Alloy AMZ (1400) Alloy AMTS (1401) Alloy AMSh1 (AMSh-1) Alloy APBA-1 (1551) Alloy ACpl Alloy B-1341 Alloy B-1461 Alloy B-1469 Alloy B-1963 Alloy B48P Alloy B65 (1165) Alloy B91 (1913) Alloy B92 (1920) Alloy B93 (B93pch; 1930) Alloy B94 (1940) Alloy B95 (1950) Alloy B95-1 Alloy B95-2 Alloy B95och Alloy B95P (1957) Alloy B95pch Alloy B96C (1960) Alloy B96C1 Alloy B96C3 (1965-1) Alloy VD1 Alloy VD17 (1170) Alloy D1 (1110) Alloy D12 (1521) Alloy D16 (1160) Alloy D16P (1167) Alloy D18 (1180) Alloy D19 (1190) Alloy D19P (1197) Alloy D19h Alloy D1P (1117) Alloy D20 (1200) Alloy D21 (1210) Alloy D23 (WAD23; 1230) Alloy D24 (VAD1; 1191) Alloy K48-1 Alloy K48-2 (1941) Alloy K48-2pch (1943) Alloy K48P Alloy M40 Alloy MM (1403) Alloy SAB1 Alloy SAW2 Alloy SAB6 Alloy SAB9 Alloy SIL 1C Alloy SIL 2S

Designation

Name The value
Designation GOST Cyrillic В96Ц
Designation GOST Latin B96Ts
Transliteration V96Ts
The chemical elements В96Zn
Name The value
Designation GOST Cyrillic 1960
Designation GOST Latin 1960
Transliteration 1960
The chemical elements 1960

Description

Alloy В96Ц used: for the manufacture of loaded power details and designs; to the end parts of centrifuges designed to produce enriched uranium 235, in the form of hot-pressed pipes and forgings and extruded products for the rocket bodies and screw pumps; profiles with cross-sectional area of 200 cm2 and a diameter of circumcircle up to 350mm suitable for use in the aviation industry and special machine building industries.

Note

One of the most durable aluminium alloys.

Standards

Name Code Standards
Sectional and shaped rolling В52 GOST 13616-97, GOST 13617-97, GOST 13618-97, GOST 13619-97, GOST 13620-90, GOST 13621-90, GOST 13622-91, GOST 13623-90, GOST 13624-90, GOST 13737-90, GOST 13738-91, GOST 17575-90, GOST 17576-97, GOST Р 50066-92, GOST Р 50067-92, GOST Р 50077-92, OST 1 92093-83, OST 1 92069-77, OST 1 90113-86
Non-ferrous metals, including rare metals, and their alloys В51 OST 1 90048-90, OST 1 90026-80, TU 1-804-106-2012
Metal forming. Forgings В03 OST 1 90073-85
Bars В55 OST 1 90395-91, TU 1-4-31-88
Sheets and stripes В53 TU 1-804-088-2012

Chemical composition

Standard Mn Cr Si Fe Cu Al B Ti Zn Zr Mg Be
OST 1 90026-80 ≤0.1 ≤0.05 ≤0.1 ≤0.15 2-2.6 The rest - - 8-9 0.1-0.2 2.3-3 -
TU 1-804-106-2012 ≤0.1 ≤0.05 ≤0.2 ≤0.3 2-2.6 The rest ≤0.005 ≤0.05 8-9 0.1-0.2 2.3-3 ≤0.002
OST 1 90048-90 ≤0.1 ≤0.05 ≤0.3 ≤0.4 2-2.6 The rest - ≤0.03 8-9 0.1-0.2 2.3-3 -
TU 1-804-088-2012 ≤0.1 ≤0.05 ≤0.2 ≤0.3 2-2.6 The rest - ≤0.03 8-9 0.1-0.2 2.3-3 ≤0.002
Al is the base.
According to OST 1 90026-80 the chemical composition is given for an alloy of high purity В96Цпч (1960пч). The total content of other impurities is ≤ 0.10%. The content of each other impurity is ≤ 0.050%.
According to the OST 1 90048-90 the chemical composition is given for the alloy B96C (1960). Mass fraction of each other impurity (not regulated) ≤ 0.05%, total mass fraction of other impurities ≤ 0.10%.
According to TU 1-804-106-2012 the chemical composition is given for the alloy B96C (1960). The total mass fraction of other impurities is ≤ 0.10%. The content of beryllium and boron is not determined, but guaranteed by calculation.
According to TU 1-804-088-2012 the chemical composition is given for the alloy B96C (1960). The total mass fraction of other impurities is ≤ 0.10%. The content of beryllium is not determined, but guaranteed by calculation.

Mechanical characteristics

Section, mm sT|s0,2, MPa σB, MPa d5, % Brinell hardness number, MPa
Forgings supplied
- ≥550 ≥600 ≥4 ≥170
Forgings for OST 1 90073-85. Mode T3: Quenching + artificial aging
≤75 410-500 480-560 ≥4 ≥140
75-100 400-490 470-550 ≥3 ≥140
≤75 420-510 490-580 ≥7 ≥140
75-100 410-500 480-570 ≥7 ≥140
≤75 410-500 480-560 ≥5 ≥140
75-100 400-490 470-550 ≥4 ≥140
≤75 420-510 490-580 ≥7 ≥140
75-100 410-500 480-570 ≥7 ≥140
Forgings-sections up to 80 mm OST 1 90073-85. Mode T1: Quenching + artificial aging (indicated by the direction of samples)
- ≥540 ≥2 ≥170
≥540 ≥590 ≥4 ≥170
≥490 ≥550 ≥3 ≥170
≥570 ≥620 ≥5 ≥170
Extruded normal strength with the cross-sectional area 200 cm2 and a diameter of the circumscribed circle of up to 350 mm. (sample longitudinal cross-section shows the thickness of the shelf). Quenching + artificial aging
≥540 ≥590 ≥4 -
Extruded high tensile strength with the cross-sectional area 200 cm2 and a diameter of the circumscribed circle of up to 350 mm. (sample longitudinal cross-section shows the thickness of the shelf). Quenching + artificial aging
≤5 ≥470 ≥530 ≥6 -
10-75 ≥490 ≥570 ≥6 -
5-10 ≥480 ≥550 ≥6 -
Tubes extruded in the delivered state on the other 1-804-088-2012. Quenching + artificial aging
≥607.6 - ≥3 -
Forming in the state of delivery on the other 1-804-106-2012. Quenching + Artificial aging
≥627 - ≥3 -

Description mechanical marks

Name Description
Section Section
sT|s0,2 Yield strength or limit of proportionality with a tolerance for residual deformation of 0.2%
σB Limit short-term strength
d5 Elongation after rupture

Technological properties

Name The value
Macrostructure and contamination Control of the macrostructure of the forgings on the other 1-804-106-2012 is in diametrical section on the four stampings from the party-termosumki Macrostructure of the forgings shall conform to poliatlonu agreed with FSUE "VIAM" and "NCC". Control of macrostructure of extruded pipe on the other 1-804-088-2012 on the manufacturer is not possible.
Microstructure Control of the microstructure of forgings on the other 1-804-106-2012 is made on the same stamping from the party-termosumki. Method for the determination of burnout according to GOST 27637. Control of the microstructure of extruded pipe on the other 1-804-088-2012 perereca produced according to the GOST 27637 on the samples selected from the output end of each pipe, after quenching or after quenching and artificial aging.
Features of heat treatment Re-heat treatment of forgings on the other 1-804-106-2012 and extruded pipe on the other 1-804-088-2012 is allowed only once.

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