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Aluminum Bronze C64200
Specs: QQ-C-465, ASTM-B-150, ASTM-B-124
UNS# C64200
Aluminum Silicon Bronze C64200 consists mainly of Aluminum, Copper and Silicon, with less than 1% Tin. C64200 has exceptional wear-resistant properties and offers an unusual flexibility of services to industries such as marine, hardware, pole line hardware, valve seals, valve stems and gears.
Details
Alloy C64200 (CuAl7Si2) is a ternary Aluminum Bronze containing copper, aluminum and silicon.
It was initially developed for the marine defense industry where the combination of corrosion resistance in seawater and low magnetic permeability was important in the construction of vessels used for underwater mine detection.
The alloy now finds a wider application in seawater environments where ductility, ease of machining, high impact strength and good corrosion resistance are important characteristics.
Aluminum Silicon Bronze C64200 also maintains its properties at cryogenic temperatures.
The alloy is easily hot worked and can be cold worked to improve the mechanical strength, being in the main an α structure.
Applications
Specifications
Mechanical Properties
Composition
Physical Properties
Applications
Automotive
- Valve Guides
Industrial
- Gears and Drive Cams
- Valves Bodies
- Valve Stems
Electrical
- Pole Line Hardware
Marine
- Non-Magnetic Anchor Chains
- Anchors
- Anchor Couplings
- Fasteners Nuts and Bolts
- Non-Magnetic Instrumentation
Specifications
| International Standards | Material Designation | Sheet & Plate | Rod & Bar | Forgings Stampings |
|---|---|---|---|---|
| USA ASTM | UNS C63000 | ASTM B 171 | ASTM B 150 | ASTM B 124 ASTM B 283 |
| ASME | ASME SB 171 | ASME SB 150 | ASME SB 283 | |
| AMS | AMS 4640 | |||
| SAE | SAE J463 SAE J461 | SAE J463 SAE J46 | ||
| Federal | QQ-C-00465 | MIL-B- 161666 | ||
| Europe EN 12420 1999 | CuAl10Ni5Fe4 CW307G | EN 1653 | EN 12163 EN 12165 EN 12167 | EN 12165 EN 12420 1999 |
| Germany DIN | 2.0966 CuAl10Ni5Fe4 | DIN 17670-1 DIN 17675-1 | DIN 17665 1983 | |
| France NFA | CuAl9Ni5Fe4 CuAl9Ni5Fe3 | NFA 51-113 1983 NFA 51-115 1983 | NFA 51-116 1989 | NFA 51-116 I989 |
| Japan JIS | C6301 | JIS H3100 | ||
| Russia GOST 18175 | BrAZN10-4-4 | GOST 1628 GOST 1206 | ||
| China GB 5233:1985 | QA10-4-4 | GB4429 | ||
| ISO ISO 428:1983 | CuAl10Fe5Ni5 | ISO 1634-2 | ISO 1637 ISO 1639 |
Mechanical Properties
| Product Form | Condition | UTS N/mm² Ksi | 0.5% Yield N/mm² Ksi | Elong % | Hardness HB |
|---|---|---|---|---|---|
| Rod & Bar | ½-1” (12-25mm) | 690-793 100-115 | 345-483 50-70 | 5-15 | 190-230 |
| Rod & Bar | >1”-2” (>25.4-50mm) | 621-689 90-100 | 310-400 45-58 | 6-18 | 180-210 |
| Rod & Bar | >2”-3” (>50-75mm) | 586-621 85-90 | 296-379 43-55 | 10-20 | 180-210 |
| Plate | <= 2” (<=50mm) | 621-703 90-102 | 248-303 36-44 | 10-15 | 160-200 |
| Plate | 2”- 3.5” (50mm-88.9mm) | 585- 621 85-90 | 228-269 33-39 | 10-15 | 140-160 |
| Plate | >3.5”-5.0” (>88.9mm-127mm) | 552- 586 80-85 | 207-228 30-33 | 10-15 | 130-140 |
Composition
| Element | Cu | Al | Fe | Ni | Mn |
|---|---|---|---|---|---|
| Composition | 81.25 | 10 | 3 | 5 | 0.75 |
Physical Properties
| Physical Properties | Imperial Units | Metric Units |
|---|---|---|
| Density | 0.274 lb/in³ | 7.58g/cm³ |
| Melting Range | 1890-1930ºF | 1035-1054ºc |
| Mean Liner Expansion 0-200ºc | 16.2μm/m.ºc | |
| Mean Liner Expansion 0-400 ºF | 0.009 in/in/ ºF x10³ | |
| Specific Heat | 0.105Btu/lb/ ºF | 377J/kg ºK |
| Relative Magnetic Permeability | 1.35 | |
| Thermal Conductivity | 22Btu/ft h/ ºF | 38W/m. ºK |
| Electrical Resistivity | 116ohm-circmil/ft | 19.28 µ_-cm @20°c |
| Electrical Conductivity | 8% IACS | 0.041 MS/cm @20°c |
| Modulus of Elasticity 10³ | 17ksi | 117N/mm² |
| Modulus of Rigidity | 6.4ksi | 44.13N/mm² |
| Relative Magnetic Permeability | 1.4 |
While the data is believed to be accurate, Wieland Diversified makes no representation or warranty of any kind (expressed or implied) and assumes no responsibility with respect to the accuracy and values shown above; this information should only be used as a guide.
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