Leaded Tin Bronze C92300 vs Leaded Tin Bronze C92900
Property comparison of Leaded Tin Bronze C92300 and Leaded Tin Bronze C92900, both copper alloy.
| Property | Leaded Tin Bronze C92300 | Leaded Tin Bronze C92900 | Difference |
|---|---|---|---|
| Yield strength | 138 MPa | 179 MPa | +30% |
| Tensile strength | 276 MPa | 324 MPa | +17% |
| Elongation | 25 % | 20 % | -20% |
| Elastic modulus | 120,000 MPa | 120,000 MPa | 0% |
| Shear modulus | 45,000 MPa | 45,000 MPa | 0% |
| Poisson ratio | 0.31 | 0.31 | 0% |
| Density | 8,800 kg/m³ | 8,800 kg/m³ | 0% |
| Thermal conductivity | 52 W/m·K | 52 W/m·K | 0% |
| Specific heat | 377 J/kg·K | 377 J/kg·K | 0% |
| Coefficient of thermal expansion | 0.000018 1/K | 0.000018 1/K | 0% |
| Melting point | 960 °C | 960 °C | 0% |
Difference is Leaded Tin Bronze C92900 relative to Leaded Tin Bronze C92300. Values are taken from the representative row of each material; both materials may have multiple heat treatments or conditions on their individual pages.
Identification
- standard
- ANSI
- standard
- ANSI
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