Anisotropy factors of polycrystalline graphites

Tensile strength and ductility were measured on commercial grade graphites with different grain sizes. Creep behavior was analysed by the following equation: E = B log t+ct. The data were measured by the umspecimen method. The samples annealed after creep gave the same creep curve at the secondary l

726 CARBON 108. Irradiation of graphite in HFIR\* C. R. Kennedy (Metals and Ceramics i&&ion, Oak Ridge National Laboratory, Oak Ridge, Tennessee). Fifteen different grades of graphite have been irradiated in the High Flux Isotope Reactor to ffuences up to Z-5 X 1O22 nvt (E > 50 keV) at 715°C. The di

Los Angelse, California). An investigation has been undertaken to understand the mode of failure of graphites as a function of their microstructure and to correlate the experimental observations with a theory of failure based on the coincidence alignment of microstructural defects. SEM observations

Measurements of thermal conductivity from 100 to 900°K and electrical resistivity at 80°K have been made on two mutually perpendicular directions of two types of anisotropic polycrystalline graphites and of two isotropic graphites of different densities. The thermal conductivity curves can be fitted

An effective conductivity (thermal or electrical) is derived for polycrystaltine graphite using a very simple approach. The material is modeled as a series of links and junctions, the former representing the crystallies and the latter the intercrystallite region. The large anisotropy of the principa