Application of the Equivalent Transformation Layering Calculation Model in Heavy Cross-Section FGCs - Axis-Symmetrical Mechanics Problems

Liu Ding Tang; Xue Bin Zhang; Bing Zhe Li

doi:10.4028/www.scientific.net/MSF.475-479.1533

Paper Titles

Effects of the Rotating Speed of Centrifugal Machine on the Gradient Structure and Properties of Heavy Cross-Sectional WCP/Fe-C Composites
p.1517

In-Situ Fabrication and Fracture Characteristics of Structural Gradient Ni/Ni-Aluminide//Ti/Ti-Aluminide Layered Materials
p.1521

A New Technique for Fabrication of Flat PP/Talc Graded Material
p.1525

Calculation of Thermal Stresses in Mo-Ti FGM with a Continuous Change of Composition
p.1529

Application of the Equivalent Transformation Layering Calculation Model in Heavy Cross-Section FGCs - Axis-Symmetrical Mechanics Problems
p.1533

Characteristic Wave Impedance of Ti-Mo System Composites and FGM
p.1537

Determination of the Impact Fatigue Behavior of the Mo Surface Modified Ti6Al4V Alloy
p.1541

The Damage Mechanisms under Different Fretting Modes of Bonded Molybdenum Disulfide Coating
p.1545

Numerical Simulation on Thermal Shock Resistance of TiB2-Cu Interpenetrating Phase Composites
p.1551

HomeMaterials Science ForumMaterials Science Forum Vols. 475-479Application of the Equivalent Transformation...

Application of the Equivalent Transformation Layering Calculation Model in Heavy Cross-Section FGCs - Axis-Symmetrical Mechanics Problems

Abstract:

Based on equivalent transformation by means of mathematically rigorous analytics, the stress analysis of heavy cross-sectional, non-homogeneous Functionally Graded Composites (FGCs) has been performed by the layering calculation model in axis-symmetrical mechanics problems. The partially calculated results of the non-homogeneous layered thick-walled metal tube are similar to the design and practice of machine forging moulds manufactured with special welding electrodes developed by the German Capilla Company. The analysis is used complementary to the investigation of the quantitative analysis of thermo-mechanical properties, or the so-called anti-design and the optimization of the graded structure for FGCs.