Figure 3.24 Ratio of the thermal expansion to the thermal expansion coefficient as a function of temperature for copper and aluminum. More

Fig. 4.13 Coefficient of thermal expansion (CTE) of Osprey controlled-expansion alloys (based on aluminum-silicon) as a function of the proportion of silicon, in weight percent More

Figure 3.20 Thermal expansion coefficient vs. temperature for several low-expansion materials. More

Fig. 22 Thermal analysis of oriented plastic. CTE, coefficient of thermal expansion More

Fig. 2 Effect of coefficient of thermal expansion in heat treating a shaft. Source: Ref 6 More

Fig. 3 Two gear designs showing the effect of coefficient of thermal expansion. At left is a widely used design, which is very troublesome to heat-treat. A preferred design is shown at right. Source: Ref 11 More

Fig. 8.6 The relation between thermal expansion coefficient and the temperature at which the viscosity is 10 7 Pa·s (10 8 poise). Compositions that promote lower working temperatures have higher coefficients of thermal expansion. More

Fig. 21 Effect of glass addition on coefficient of thermal expansion. PBT, polybutylene terephthalate; PC, polycarbonate More

Fig. 2.1 Mean coefficient of thermal expansion (CTE) between 25 °C (77 °F) and the temperature shown for a conventional nickel-base superalloy (Inconel 718), a conventional low-CTE superalloy (Incoloy 909), and a three-phase-strengthened low-CTE superalloy (Inconel 783). Source: Ref 5 More

Fig. 22.29 Coefficient of thermal expansion (CTE) of plasma-sprayed beryllium deposited parallel and normal to the spray direction. Source: Castro et al. 1998 More

Fig. 13 Mean coefficient of thermal expansion for various types of ductile Ni-Resists. Similar behavior is exhibited by flake graphite (gray) Ni-Resists. RT, room temperature (20 °C or 70 °F). Source: Ref 9 More

Fig. 4.14 Mean coefficient of thermal expansion from room temperature to indicated temperature of normal-purity beryllium block and sheet. Source: Pinto 1979b More

Fig. 4.16 Coefficient of thermal expansion (α) of beryllium versus temperature for vacuum hot pressed S-200F. Source: Haws 1988 More

Fig. 4.17 Coefficient of thermal expansion of a beryllium cube in two orthogonal directions, showing excellent isotropy. The cube was hot isostatic pressed beryllium using impact-ground powder. Source: Billone et al. 1995 More

Figure 1 Coefficient of thermal expansion mismatches in plastic IC packages. More

Fig. 4.9 General relationship between coefficient of thermal expansion, or CTE (between 273 and 373 K), and melting point for metals, T m . Adapted from Li and Krsulich [1996 ] More

Fig. 4.6 General relationship between coefficient of thermal expansion, or CTE (between 273 and 373 K), and melting point for metals, T m . Adapted from Li and Krsulich [1996] More

Fig. 4.8 Coefficient of thermal expansion (CTE) of low-carbon steel and iron-nickel alloys as a function of temperature. The low CTE of iron-nickel alloys exists only over a limited range of temperature. Normal expansion behavior is observed above about 400 °C (750 °F). More

Fig. 4.9 Coefficient of thermal expansion of liquid-phase sintered tungsten and molybdenum materials as a function of the content of the main braze constituents, namely copper and nickel. More

Fig. 4.10 Coefficient of thermal expansion of double-sided copper-clad molybdenum at room temperature as a function of the copper thickness More