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Mechanical properties and shear failure surfaces of two alumina powders in triaxial compression

Journal Article · · Journal of Materials Science
OSTI ID:754326
 [1]; ; ;
  1. Sandia National Laboratories
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In the manufacture of ceramic components, near-net-shape parts are commonly formed by uniaxially pressing granulated powders in rigid dies. Density gradients that are introduced into a powder compact during press-forming often increase the cost of manufacturing, and can degrade the performance and reliability of the finished part. Finite element method (FEM) modeling can be used to predict powder compaction response, and can provide insight into the causes of density gradients in green powder compacts; however, accurate numerical simulations require accurate material properties and realistic constitutive laws. To support an effort to implement an advanced cap plasticity model within the finite element framework to realistically simulate powder compaction, the authors have undertaken a project to directly measure as many of the requisite powder properties for modeling as possible. A soil mechanics approach has been refined and used to measure the pressure dependent properties of ceramic powders up to 68.9 MPa (10,000 psi). Due to the large strains associated with compacting low bulk density ceramic powders, a two-stage process was developed to accurately determine the pressure-density relationship of a ceramic powder in hydrostatic compression, and the properties of that same powder compact under deviatoric loading at the same specific pressures. Using this approach, the seven parameters that are required for application of a modified Drucker-Prager cap plasticity model were determined directly. The details of the experimental techniques used to obtain the modeling parameters and the results for two different granulated alumina powders are presented.

Research Organization:
Sandia National Labs., Albuquerque, NM (US)
Sponsoring Organization:
US Department of Energy (US)
DOE Contract Number:
AC04-94AL85000
OSTI ID:
754326
Report Number(s):
SAND2000-1030J; 0000035204-000; 0000035204-000
Journal Information:
Journal of Materials Science, Journal Name: Journal of Materials Science
Country of Publication:
United States
Language:
English

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Related Subjects

36 MATERIALS SCIENCE
ALUMINIUM OXIDES
BULK DENSITY
CERAMICS
COMPRESSION
MANUFACTURING
MATHEMATICAL MODELS
MECHANICAL PROPERTIES
PRESSING
SHEAR PROPERTIES