CuSn5Zn5Pb5-C | CC491K Material Datasheet
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| Material Number | Material Name | Material Number (single) | Standard | Scope | Standard Status | Country | Predecessor | Successor | VDA 231-106 classification | Application temperature [°C] | |
|---|---|---|---|---|---|---|---|---|---|---|---|
| CC491K (DIN EN 1982 : 1998-12) | CuSn5Zn5Pb5-C | CC491K | DIN EN 1982 : 1998-12 | DIN EN 1982 : 1998-12 replaced by DIN EN 1982 : 2008-08 | Replaced | Germany | G-CuSn5ZnPb | CuSn5Zn5Pb5-C | 3.2 | ≤ 225 | 1) |
| 1) Remark: CuSn5Zn5Pb5-C, mat. No. CC491K (former G-CuSn5ZnPb, mat. No. 2.1096 acc. to DIN 1705), is seawater resistant and shows favorable general corrosion resistance. It is a short-chipping, good machinable material. It allows the achievement of high-grade surfaces. It is due to its favorable castability particularly suitable for all types of moldings in fitting and apparatus construction. Successful application for the following components: water and steam fittings up to 225°C, normally loaded pump casings and centrifuge cover, water bearing rims, brush holder for electric motors, accessories of tilt wagons as well as sliding plates in machine, vehicle and transmission manufacturing as well as for decorative castings. Processing properties: machinability: very good soft soldering: good hard soldering: conditionally gas fusion welding: bad gas shielded welding: bad burnishing: good galvanizing: good suitability for dip tinning: good (material specification applies for G-CuSn5ZnPb acc. to DIN) |
Chemical Composition
| Cu [%] | Ni [%] | P [%] | Pb [%] | Sn [%] | Zn [%] | |
|---|---|---|---|---|---|---|
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Material Compliance
| REACh | RoHS |
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Mechanical Properties
| Casting Method | Designation of the delivered Condition DIN | Delivery Condition EN | Temperature [°C] | Tensile Strength [MPa] | Yield Strength (0.2% offset) [MPa] | Elongation A [%] | Hardness HB | HBW | |
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| blur | blur | blur | blur | blur | blur | blur | blur | 1)2) |
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Physical Properties
| Temperature [°C] | Melting Temperature [°C] | Density [g/cm³] | Young's Modulus [GPa] | Mean Coefficient of Thermal Expansion (reference 20°C) [10^-6*K^-1] | Thermal Conductivity [W/(m*K)] | Specific Electrical Resistance [µΩm] | Mean Specific Heat Capacity [kJ/(kg*K)] | Electric Conductivity [MS/m] | |
|---|---|---|---|---|---|---|---|---|---|
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Cross Reference
| Material Name | Country | Standard |
|---|---|---|
| CuSn5Pb5Zn5 (423135) | Czech Republik/Slovakia | CSN 423135 |
| CuSn5Pb5Zn5 | France | NF A53-707-87 |
| CuSn5Pb5Zn5 (LG2) | Great Britain | BS 1400-85 |
| BrO5C5S5 | Russia | GOST 613-79 |
| CuPb5Sn5Zn5 | International | ISO 1338-77 |
| BC6 | Japan | JIS H 5111-79 |
| CuSn5Zn5Pb5 | Poland | PN-79/H-87026 |
| öCuSn5Zn5Pb5 | Hungary | MSZ 8579-84 |
| C83600 | USA | AMS 4855 |
| C83600 | USA | ASME B 16.24 |
| C83600 | USA | ASME B 16.32 |
| C83600 | USA | ASME B16.15 |
| C83600 | USA | ASME B16.18 |
| C83600 | USA | ASME B16.23 |
| C83600 | USA | ASME B16.26 |
| C83600 | USA | ASME SB-62 |
| C83600 | USA | ASTM B 271 |
| C83600 | USA | ASTM B 30 |
| C83600 | USA | ASTM B 505 |
| C83600 | USA | ASTM B 584 |
| C83600 | USA | ASTM B 62 |
| C83600 | USA | FED QQ-C-390 |
| C83600 | USA | FED WW-P-460 |
| C83600 | USA | FED WW-T-725 |
| C83600 | USA | FED WW-U-516 |
| C83600 | USA | Ingot 115 |
| C83600 | USA | MIL SPEC MIL-V-18436 |
| C83600 | USA | SAE J461 |
| C83600 | USA | SAE J462 |
| C83600A | Australia | AS 1565 |
| G-CuSn5ZnPb (2.1096) | Germany | DIN 1705 |
| G-CuPb5Sn5Zn5 | Switzerland | VSM 10810-4 |
| G-CuPb5Sn5Zn5 | Finland | SFS 2209 |
| ZCuSn5Pb5Zn5 | China | GB 1176 |
| CuSn5Pb5Zn5 | Norway | NS 16530 |
| CuSn5Pb5Zn5 (5204) | Sweden | SIS 145204 |
| CuSn5Zn5Pb5 (C-3520) | Spain | UNE 37-103-2 |
| öCuSn5Zn5Pb5 | Hungary | MSZ 8579 |
| G-CuSn5Zn5Pb5 | Italy | UNI 7013-8 |
| Rodgods 5204 | Denmark | DS 3001 |
| F-CuSn5Pb5Zn5 | Portugal | NP 1211 |
Producer/Supplier/Trade names
| Tradename | Supplier |
|---|---|
| G-CuSn5ZnPb | Ed. Fitscher GmbH & Co KG, Oberhausen |
| GC-CuSn5ZnPb | Schreier Metall GmbH, Erkrath |
| GC-CuSn5ZnPb | Ed. Fitscher GmbH & Co KG, Oberhausen |
| GO5 | Wieland-Werke AG, Ulm |
| Bögra Rotguß Rg5 | BÖGRA Technologie GmbH, Solingen |
| G-CuSn5ZnPb | Wieland-Werke AG, Ulm |
| G-CuSn5ZnPb | CUMSAL GmbH, Wilnsdorf |
| G-CuSn5ZnPb | Mittelrheinische Metallgießerei H. Beyer GmbH & Co KG, Andernach |
| G-CuSn5ZnPb | Fehrmann Metallverarbeitung GmbH, Hamburg |
| GB2 | Wieland-Werke AG, Ulm |
| GZ-CuSn5ZnPb | Schreier Metall GmbH, Erkrath |
| GZ-CuSn5ZnPb | Ed. Fitscher GmbH & Co KG, Oberhausen |
| Rg5 | Mittelrheinische Metallgießerei H. Beyer GmbH & Co KG, Andernach |
| Rg5 | Schreier Metall GmbH, Erkrath |
| St-Rg5 | Manfred J.C. Niemann, Bremen |
Linear-elastic
| Temperature [°C] | Young's modulus [GPa] | Bulk modulus [GPa] | Shear modulus [GPa] | Poisson's ratio |
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Yield strength
| Temperature [°C] | 0.1% Proof strength [MPa] | 0.2% Proof strength [MPa] | Yield strength [MPa] |
|---|---|---|---|
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Electrical resistivity
| Temperature [°C] | Specific electrical resistance [µΩm] |
|---|---|
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Coefficient thermal expansion
| Related Temperature [°C] | Temperature [°C] | Coefficient thermal expansion [10^-6*K^-1] |
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Specific heat
| Temperature [°C] | Specific heat [kJ/(kg*K)] |
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Density
| Temperature [°C] | Density [g/cm³] |
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Tensile strength
| Temperature [°C] | Tensile strength [MPa] |
|---|---|
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Thermal conductivity
| Temperature [°C] | Thermal conductivity [W/(m*K)] |
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Classification
| WIAM Material | Treatment | Semi-finished product | Dimension [mm] | Load type | Failure criteria | Rolling direction | Maximum stress [MPa] | Strain at maximum stress [%] | Source description |
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Designation
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