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Tungsten Alloy

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Overview 

Tungsten heavy alloys illustrate the advantages of microencapsulated powders. A brief background of this alloy system follows.
Tungsten heavy alloys generally are refractory metal, which have two-phase composites consisting of W-Ni- Fe or W-Ni- Cu or even W-Ni-Cu-Fe, some tungsten alloy is added Co、Mo、Cr, etc. They have very high melting point and have a density twice that of steel and are more than 50% heavier than lead. Tungsten content in conventional heavy alloys varies from 90 to 98 weight percent and is the reason for their high density (between 16.5 and 18.75 g/cc). Nickel, iron and copper serve as a binder matrix, which holds the brittle tungsten grains together and which makes the alloys ductile and easy to machine. Nickel-iron is the most popular additive, in a ratio of 7Ni:3Fe or 8Ni:2Fe (weight ratio). The conventional processing route for tungsten heavy alloys includes mixing the desired amount of elemental powders, followed by cold pressing and liquid phase sintering to almost full density. The matrix alloy melts and takes some tungsten into solution during liquid phase processing, resulting in a microstructure through which large tungsten grains (20–60µm) are dispersed in the matrix alloy. The as-sintered material often is subjected to thermo mechanical processing by swaging and aging, which results in increased strength and hardness in the heavy alloys.
 

Applications:

Apply for apparatus and instrument for medical, military and airspace industries. The majority of current uses for WHAs (tungsten heavy alloys) are best satisfied with the W-Ni-Fe system. Alloys such as 93W-4.9Ni-2.lFe and 95W-4Ni-lFe represent common compositions. The addition of cobalt to a W-Ni-Fe alloy is a common approach for slight enhancement of both strength and ductility. The presence of cobalt within the alloy provides solid-solution strengthening of the binder and slightly enhanced tungsten-matrix interfacial strength. Cobalt additions of 5 to 15% of the nominal binder weight fraction arc most common.

Specifications:

Grade Size of Blanks
(mm)		 Density (g/cm3) Hardness
(HRC)		 Tensile Strength
(N/mm2)
W242(95W) Ø11×162
Ø8.5×170		 ≥18.00 ≥25 ≥800  
W152(93W) / ≥17.30 ≥25 ≥500
W142(95W) ≥18.00 ≥25 ≥800
W221(97W) ≥18.40 ≥28 ≥920
GW90(90W) ≥17.00 ≥20 /

 

Tungsten Alloy Rod

Grade Physical and Mechanical Properties:
Density
(g/cm3)		 Hardness
(HRC)		 Tensile Strength
(MPa)		 Elongation(%) Toughness
(MJ/m2)
W263H 17.25±0.15 ≥35 ≥1050 ≥8 ≥0.3
W253H 17.40±0.15 ≥35 ≥1050 ≥8 ≥0.3
W243H 17.60±0.15 ≥35 ≥1050 ≥7 ≥0.3
W232H 18.10±0.15 ≥37 ≥1050 ≥6 ≥0.1
W231H 18.30±0.15 ≥37 ≥1050 ≥3 ≥0.1
W221H 18.50±0.15 ≥37 ≥1050 ≥2 ≥0.07
W243H 17.60±0.15 ≥40 ≥1300 ≥6 ≥0.15
W232E 18.10±0.15 ≥40 ≥1300 ≥6 ≥0.15
W273 17.10±0.15 ≥23 ≥900 ≥24 ≥1.30
W263 17.25±0.15 ≥23 ≥900 ≥23 ≥1.20
W253 17.40±0.15 ≥24 ≥900 ≥22 ≥1.10
W243 17.60±0.15 ≥24 ≥920 ≥20 ≥0.90
W232 18.10±0.15 ≥25 ≥920 ≥14 ≥0.45
W231 18.30±0.15 ≥26 ≥920 ≥12 ≥0.30
W221 18.50±0.15 ≥27 ≥920 ≥10 ≥0.22
WNiCu 16.00-18.50 ≥22 ≥450 2-8 -

 

Tungsten Alloy Ring

Grade Physical and Mechanical Properties
Density
(g/cm3)		 Hardness
(HRC)		 Tensile Strength
(MPa)		 Elongation
(%)		 Toughness
(MJ/m2)
W263H 17.25±0.15 ≥35 ≥1050 ≥8 ≥0.3
W253H 17.40±0.15 ≥35 ≥1050 ≥8 ≥0.3
W243H 17.60±0.15 ≥35 ≥1050 ≥7 ≥0.3
W232H 18.10±0.15 ≥37 ≥1050 ≥6 ≥0.1
W231H 18.30±0.15 ≥37 ≥1050 ≥3 ≥0.1
W221H 18.50±0.15 ≥37 ≥1050 ≥2 ≥0.07
W243H 17.60±0.15 ≥40 ≥1300 ≥6 ≥0.15
W232E 18.10±0.15 ≥40 ≥1300 ≥6 ≥0.15
W273 17.10±0.15 ≥23 ≥900 ≥24 ≥1.30
W263 17.25±0.15 ≥23 ≥900 ≥23 ≥1.20
W253 17.40±0.15 ≥24 ≥900 ≥22 ≥1.10
W243 17.60±0.15 ≥24 ≥920 ≥20 ≥0.90
W232 18.10±0.15 ≥25 ≥920 ≥14 ≥0.45
W231 18.30±0.15 ≥26 ≥920 ≥12 ≥0.30
W221 18.50±0.15 ≥27 ≥920 ≥10 ≥0.22
WNiCu 16.00-18.50 ≥22 ≥450 2-8 -

 

Tungsten Alloy Bar and Cube

Grade  RWM Group B Nominal composition % Weight Rockwell Hardness Electrical Conductivity %ACS Ultimate Tensile Strength PSI Cross Breaking Strength PSI Density GMS/CC Thermal Exp in/in cx10(6) at 20°c Thermal Conductivity W/CM °c 20-400°c
CW55 - 45 copper
55 tungsten		 79B 55 63000 110000 12.6 11.8 2.4
CW68 - 32 copper
68 tungsten		 88B 52 75000 130000 13.93 10.9 2.1
CW70 Class 10 30 copper
70 tungsten		 90B 50 85000 140000 14.18 10.77 2.01
CW75 Class 11 25 copper
75 tungsten		 94B 48 90000 150000 14.7 10.22 1.89
CW78 Class 11&12 22 copper
78 tungsten		 96B 46 94000 160000 15.12 9.3 1.84
CW80 Class 12 20 copper
80 tungsten		 98B 44 96000 170000 15.58 9.2 1.82
CW85 - 15 copper
85 tungsten		 102B 36 75000 170000 16.19 7.97 1.75
CW90 - 10 copper
90 tungsten		 106B 28 70000 150000 17.05 6.49 1.47
CW75 - 25 copper
75 tungsten		 109B 28 16000 200000 14.6 - -

 

Tungsten Alloy Ball

Grade Physical and Mechanical Properties
Density
(g/cm3)		 Hardness
(HRC)		 Tensile Strength
(MPa)		 Elongation
(%)		 Toughness (MJ/m3)
W273 17.10±0.15 ≥23 ≥900 ≥24 ≥1.30
W263 17.25±0.15 ≥23 ≥900 ≥23 ≥1.20
W253 17.40±0.15 ≥24 ≥900 ≥22 ≥1.10
W243 17.60±0.15 ≥24 ≥920 ≥20 ≥0.90
W232 18.10±0.15 ≥25 ≥920 ≥14 ≥0.45
W231 18.30±0.15 ≥26 ≥920 ≥12 ≥0.30
W221 18.50±0.15 ≥27 ≥920 ≥10 ≥0.22
WNiCu 16.00-18.50 ≥22 ≥450 2-8 -