NiCr20Ti
2014-09-15 09:12:24 Origin: Remark:0 Click:
Descriptions NiCr20Ti datasheet, NiCr20Ti Chemical, NiCr20Ti Properties Steelmaking, Blooming, Hot forging, Hot rolling, Heat treatment, Straightening, 100% Ultrasonic flaw detection test, Cold working or Machined. All of these materials conform to Military standard, nuclear power. 100% Ultrasonic test ASTM E2375 /SAE AMS 2154 /SEP 1923 /GB/T 4162 /EN 10228-3.
MATERIAL DATASHEET - DIN NiCr20Ti
MATERIAL CATEGORY - High temperature high strength steel and superalloy
MATERIAL SPECIFICATIONS - DIN 17742, 17460, 17480, DIN EN 103021, 10296, 10095
CHEMICAL COMPOSITION (WEIGHT %)
C (%): 0.08 ~ 0.15
Si (%): ≤ 1.00
Mn (%): ≤ 1.00
P (%)≤: 0.020
S (%)≤: 0.015
Cr (%): 18.0 ~ 21.0
Ni (%): ≥ 72.0
Mo (%): -
Ti: (%): 0.20 ~ 0.60
Si (%): ≤ 1.00
Mn (%): ≤ 1.00
P (%)≤: 0.020
S (%)≤: 0.015
Cr (%): 18.0 ~ 21.0
Ni (%): ≥ 72.0
Mo (%): -
Ti: (%): 0.20 ~ 0.60
Others (%): Co ≤5.0, Al≤0.30, B ≤0.006, Fe ≤5.0, Cu ≤0.50
MECHANICAL PROPERTIES - HOT WORKING, HEAT TREATMENT AND HARDNESS
Hot forming temperature /℃: 1150~850
Heat treatment temperature /℃ | annealing: -
Heat treatment temperature /℃ | quenching or solution: 1035~1065 air
Heat treatment temperature /℃ | tempering: 900~950
Heat treatment temperature /℃ | ageing: -
Condition: quenching
Mechanical property under room temperature |σb/MPa: ≥640
Mechanical property under room temperature |σs≥/MPa: 235
Mechanical property under room temperature |δ5≥(%): 26
Mechanical property under room temperature |Akv(DVM): 103
Heat stability temperature/℃: -
Non-scale temperature in air /℃: 1200
MECHANICAL PROPERTY UNDER HIGH TEMPERATURE
Mechanical property above 200℃ σ0.2/MPa,at following temperature /℃|200: 304
Mechanical property above 200℃ σ0.2/MPa,at following temperature /℃|300: 304
Mechanical property above 200℃ σ0.2/MPa,at following temperature /℃|400: 304
Mechanical property above 200℃ σ0.2/MPa,at following temperature /℃|500: 294
Mechanical property above 200℃ σ0.2/MPa,at following temperature /℃|600: 265
Mechanical property above 200℃ σ0.2/MPa,at following temperature /℃|700: 226
Mechanical property above 200℃ σ0.2/MPa,at following temperature /℃|800: 118
Mechanical property above 200℃ σ0.2/MPa,at following temperature /℃|300: 304
Mechanical property above 200℃ σ0.2/MPa,at following temperature /℃|400: 304
Mechanical property above 200℃ σ0.2/MPa,at following temperature /℃|500: 294
Mechanical property above 200℃ σ0.2/MPa,at following temperature /℃|600: 265
Mechanical property above 200℃ σ0.2/MPa,at following temperature /℃|700: 226
Mechanical property above 200℃ σ0.2/MPa,at following temperature /℃|800: 118
Creep rupture strength /MPa,at following time/h and temperature /℃|1000h|600: -
Creep rupture strength /MPa,at following time/h and temperature /℃|1000h|700: 103
Creep rupture strength /MPa,at following time/h and temperature /℃|1000h|800: 31
Creep rupture strength /MPa,at following time/h and temperature /℃|1000h|900: -
Creep rupture strength /MPa,at following time/h and temperature /℃|10000h|600: -
Creep rupture strength /MPa,at following time/h and temperature /℃|10000h|700: 59
Creep rupture strength /MPa,at following time/h and temperature /℃|10000h|800: 19
Creep rupture strength /MPa,at following time/h and temperature /℃|10000h|900: -
Creep rupture strength /MPa,at following time/h and temperature /℃|100000h|600: -
Creep rupture strength /MPa,at following time/h and temperature /℃|1000h|700: 103
Creep rupture strength /MPa,at following time/h and temperature /℃|1000h|800: 31
Creep rupture strength /MPa,at following time/h and temperature /℃|1000h|900: -
Creep rupture strength /MPa,at following time/h and temperature /℃|10000h|600: -
Creep rupture strength /MPa,at following time/h and temperature /℃|10000h|700: 59
Creep rupture strength /MPa,at following time/h and temperature /℃|10000h|800: 19
Creep rupture strength /MPa,at following time/h and temperature /℃|10000h|900: -
Creep rupture strength /MPa,at following time/h and temperature /℃|100000h|600: -
Creep rupture strength /MPa,at following time/h and temperature /℃|100000h|700: 36
Creep rupture strength /MPa,at following time/h and temperature /℃|100000h|800: 14
Creep rupture strength /MPa,at following time/h and temperature /℃|100000h|900: -
Creep rupture strength /MPa,at following time/h and temperature /℃|100000h|800: 14
Creep rupture strength /MPa,at following time/h and temperature /℃|100000h|900: -
TYPICAL APPLICATIONS
Superalloy is widely used to produce the high temperature components for gas turbine in the field of aviation, naval vessels and industry, such as turbine blade, guide blade, turbine disc, high pressure compressor disc, combustor, and also production of energy conversion devices, such as aerospace craft, rocket motor, nuclear reactor, petrochemical equipments, coaly transforming and so on.
Gas turbine
Turbine blade
Fuel nozzle
Heat treating fixture
Furnace muffle
Nuclear reactor
Turbine blade
Fuel nozzle
Heat treating fixture
Furnace muffle
Nuclear reactor
Turbine engine parts - mechanical gears, gear shaft, main axis, blade
Mechanical parts - bolt and nut, fastener
Heat treatment furnace flask and components, especially in the carbonization.
These materials must stand up to high heat, extreme oxidation potential and recycling.
These materials must stand up to high heat, extreme oxidation potential and recycling.
PRODUCT PROFILE & FORMS
Round bar / Wire rod (Diameter): 5.5mm to 550mm
Square bar / Flat bar: 3mm to 1000mm
Plate / Sheet steel / Steel strip: 0.1mm to 1000mm
Width: 8mm to 1000mm
Length: random length or based on the customer's special requirement.
Forged steel shape: stepped shafts with flanks / discs /tubes /slugs /donuts /cubes /other different shapes based on OEM.
TECHNICAL SALES ASSISTANCE
If you meet further on any technical enquiry, pleased to email or call our resident team of qualified production engineers, Email: sales@ccsteels.com
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