Mechanical Behaviour of CeramicsCUP Archive, 1979年3月8日 - 165 頁 Although the basis for understanding the brittle fracture strength of ceramics was established by A. A. Griffith in 1920, much of our detailed knowledge was developed during the 1970s. This book was first published in 1979, when the science of the mechanical behaviour of engineering ceramics had reached a consolidated stage and was being applied ever increasingly to engineering situations. The bulk of the information was still scattered in scientific journals and this volume sought to consolidate these. This book presents the scientific foundations of mechanical behaviour and demonstrates how these can be used in engineering situations. The emphasis is on principles, illustrated by a careful selection of experimental data. This book will continue to have value as a reference work on this exciting subject. |
內容
1 | 1 |
1 | 7 |
1 | 13 |
3 | 19 |
5 | 28 |
7 | 42 |
4 | 49 |
3 | 56 |
3 | 70 |
The fracture strength of ceramics | 75 |
Impact resistance and toughness | 104 |
Thermal stresses and fracture in ceramics | 118 |
Engineering design data | 132 |
157 | |
163 | |
1 | 64 |
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常見字詞
alumina amount applied assumed atomic behaviour bend bonding brittle calculated ceramics component compressive compressive stresses consider constant containing controlled crack critical crystals curve Davidge deformation dependence developed direction discussed dislocation distribution effects elastic engineering estimate example experimental factor failure fibres Figure flaw flow stress force fracture fracture stress given gives glass grain boundaries greater Griffith illustrated important impurity increase indicated initiated ions lattice lead length less limited materials matrix maximum measured mechanical microstructure modulus observed obtained occurs original oxidation parameter particles particular phase planes plastic pores possible present produced propagate properties quenching range ratio region relative shear shows significant silicon similar simple single crystals slip slip systems specimen strain strength structure surface energy temperature theoretical theory thermal tion typical usually values variation varies volume