Nickel Alloys Melting Points
Reference data and engineering information about nickel alloys melting points for material properties applications.
Overview
Engineering reference data for Nickel Alloys Melting Points in material science and properties.
Key Formulas
Stress
Force per unit area.
Strain
Change in length per original length.
Hooke's Law
Stress proportional to strain in elastic region.
Thermal Expansion
Length change due to temperature.
Variables
| Symbol | Description | Unit |
|---|---|---|
| Stress | Pa | |
| Strain | — | |
| Young's modulus | Pa | |
| Thermal expansion coefficient | 1/°C | |
| Temperature change | °C |
Binary Eutectic Nickel Alloys
The following table outlines the composition and melting points for key binary eutectic alloys involving nickel.
Alloy Component | Weight of Alloy Component (%) | Melting Point (K) | Melting Point (°F) |
|---|---|---|---|
| Sb - Antimony (Stibium) | 36.9 | 1375 | 2016 |
| Sn - Tin (Stannum) | 32.2 | 1403 | 2066 |
| Th - Thorium | 68 | 1303 | 1886 |
| Ti - Titanium | 34 | 1390 | 2043 |
| V - Vanadium | 48 | 1473 | 2192 |
| W - Tungsten (Wolfram) | 45 | 1773 | 2732 |
| Zn - Zinc | 71 | 1148 | 1607 |
Source: engineeringtoolbox.com
Temperature Conversion Formula
The conversion between the Fahrenheit and Celsius temperature scales is given by:
Eutectic Mixture Explanation
A eutectic mixture is a specific composition of a mixture of components that has the lowest possible melting point. For a binary alloy system, this point is where the liquid phase transforms directly into two solid phases upon cooling, representing a unique minimum on the phase diagram.