High Leaded Tin Bronze C93200 vs High Leaded Tin Bronze C93800
Property comparison of High Leaded Tin Bronze C93200 and High Leaded Tin Bronze C93800, both copper alloy.
| Property | High Leaded Tin Bronze C93200 | High Leaded Tin Bronze C93800 | Difference |
|---|---|---|---|
| Yield strength | 124 MPa | 110 MPa | -11% |
| Tensile strength | 241 MPa | 207 MPa | -14% |
| Elongation | 20 % | 18 % | -10% |
| 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 | 8,930 kg/m³ | 8,930 kg/m³ | 0% |
| Thermal conductivity | 47 W/m·K | 47 W/m·K | 0% |
| Specific heat | 375 J/kg·K | 375 J/kg·K | 0% |
| Coefficient of thermal expansion | 0.000019 1/K | 0.000019 1/K | 0% |
| Melting point | 930 °C | 930 °C | 0% |
Difference is High Leaded Tin Bronze C93800 relative to High Leaded Tin Bronze C93200. 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
What else is in Engineering Database
AI built for engineering. Searches the engineering database, performs calculations, gives source-backed engineering insights.
Get started for free ↗Reference Data375 engineering tablesMaterial properties, pipe and shape dimensions, code tables, and electrical ratings across mechanical, civil, chemical, electrical, materials, and manufacturing engineering.
Browse dataCalculatorsDeterministic engineering calculatorsSizing, checking, and conversion tools that run against the reference tables. Inputs are code-compliant, outputs are traceable to the source standard.
Browse calculators