| Preface |
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xv | |
| Contributors |
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xvii | |
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Part I Fibers: Interface and Architecture |
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1 | (84) |
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1 Reinforcement of Ceramic Matrix Composites: Properties of SiC-Based Filaments and Tows |
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3 | (24) |
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3 | (1) |
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1.2 Processing of SiC-Based Filaments |
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4 | (2) |
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1.3 Fracture Characteristics of Single Filaments |
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6 | (5) |
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1.3.1 Statistical Strength Distributions |
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6 | (1) |
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1.3.2 Weibull Distribution of Failure Strengths |
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6 | (2) |
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1.3.3 Determination of Weibull Statistical Parameters |
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8 | (1) |
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1.3.4 Normal Distribution |
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9 | (2) |
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11 | (5) |
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13 | (1) |
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1.4.2 Filaments--Tows Relations: Tow-Based Testing Methods for Determination of Single Filament Properties |
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14 | (2) |
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1.5 Mechanical Behavior at High Temperatures |
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16 | (7) |
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1.5.1 Strength Degradation and Oxidation at High Temperature |
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16 | (1) |
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1.5.2 Static Fatigue Under Constant Load at Intermediate Temperatures: Subcritical Crack Growth |
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16 | (7) |
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23 | (4) |
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23 | (4) |
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27 | (13) |
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2.1 Introduction/Production Routes |
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27 | (1) |
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2.2 Structure of Carbon Fibers |
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28 | (4) |
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2.2.1 Levels 1 and 2, Atomic level |
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28 | (1) |
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2.2.2 Level 3, Lower Nanometer Range |
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28 | (3) |
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2.2.3 Level 4, Upper Nanometer Range |
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31 | (1) |
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2.2.4 Level 5, 10-μm Range |
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32 | (1) |
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2.3 Stiffness and Strength of Carbon Fibers |
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32 | (4) |
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2.4 Concluding Remarks and Future Directions |
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36 | (4) |
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37 | (1) |
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37 | (3) |
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3 Influence of Interfaces and Interphases on the Mechanical Behavior of Fiber-Reinforced Ceramic Matrix Composites |
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40 | (25) |
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40 | (1) |
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3.2 Role of Interfacial Domain in CMCs |
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41 | (8) |
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3.2.1 Crack Initiation at Interfaces |
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41 | (1) |
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3.2.2 Crack Deflection at Interfaces |
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41 | (1) |
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3.2.3 Approaches to Crack Deflection at Interfaces |
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42 | (2) |
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3.2.4 Deflection Criteria Based on the Cook and Gordon Mechanism |
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44 | (1) |
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3.2.5 Influence of Material Elastic Properties on Crack Deflection |
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45 | (4) |
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3.3 Influence of Deflected Cracks |
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49 | (2) |
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3.4 Strengthened Interfaces and Interphases |
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51 | (5) |
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3.5 Various Concepts of Weak Interfaces/Interphases |
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56 | (1) |
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3.6 Determination of Interfacial Properties |
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56 | (4) |
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3.6.1 The Interfacial Tensile Strength |
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57 | (1) |
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3.6.2 Interfacial Shear Strength or Stress |
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57 | (3) |
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60 | (1) |
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60 | (5) |
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61 | (4) |
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4 Textile Reinforcements: Architectures, Mechanical Behavior, and Forming |
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65 | (20) |
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65 | (1) |
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4.2 Textile Composite Reinforcements |
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65 | (9) |
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4.2.1 Multiscale Materials: Fibers, Tows, Fabrics |
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65 | (2) |
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4.2.2 Architecture and Geometry of the Unit Woven Cell |
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67 | (1) |
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4.2.3 Experimental Analysis of the Mechanical Behavior |
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67 | (6) |
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4.2.4 Mechanical Behavior Modeling |
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73 | (1) |
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4.3 Reinforcements of Ceramic Composites |
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74 | (2) |
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4.3.1 Silicon Carbide Fibers |
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74 | (1) |
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4.3.2 Textile Reinforcement |
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75 | (1) |
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4.3.3 Infiltration of the Textile Preform |
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75 | (1) |
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4.4 Preforming Simulation |
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76 | (5) |
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76 | (1) |
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4.4.2 Continuous FE Approaches |
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76 | (1) |
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4.4.3 Hypoelastic Behavior: Simulation of a Double-Dome Forming |
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77 | (1) |
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4.4.4 Composite Reinforcement Forming Using a Semidiscrete Approach |
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77 | (4) |
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81 | (4) |
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82 | (3) |
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Part II Composite Materials |
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85 | (208) |
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5 Carbon/Carbons and Their Industrial Applications |
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87 | (60) |
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87 | (1) |
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5.2 Manufacturing of Carbon/Carbons |
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87 | (10) |
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5.2.1 Carbon Fiber Reinforcements |
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88 | (2) |
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90 | (5) |
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5.2.3 Redensification/Recarbonization Cycles |
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95 | (1) |
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5.2.4 Final Heat Treatment |
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95 | (2) |
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97 | (12) |
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97 | (1) |
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5.3.2 Fiber/Matrix Interface |
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98 | (3) |
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101 | (3) |
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104 | (2) |
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5.3.5 Compressive Strength |
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106 | (2) |
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108 | (1) |
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109 | (1) |
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5.4 Thermal Properties of Carbon/Carbon Composites |
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109 | (9) |
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109 | (1) |
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5.4.2 Thermophysical Properties of Monolithic Carbons |
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110 | (1) |
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5.4.3 Thermal Conductivity of Carbon/Carbons |
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110 | (5) |
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5.4.4 Electrical Properties |
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115 | (1) |
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116 | (1) |
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117 | (1) |
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5.4.7 Thermal Shock Resistance |
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118 | (1) |
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5.4.8 Concluding Remarks and Future Directions |
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118 | (1) |
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5.5 Oxidation Protection of Carbon/Carbon |
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118 | (8) |
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5.5.1 Bulk Protection Systems for Carbon/Carbons |
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119 | (3) |
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5.5.2 Outer Multilayer Coatings |
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122 | (2) |
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5.5.3 Outer Glass Sealing Layers |
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124 | (2) |
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5.6 Industrial Applications of Carbon/Carbons |
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126 | (21) |
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5.6.1 Carbon/Carbons for High-Temperature Furnaces |
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129 | (5) |
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5.6.2 Application for Thermal Treatments of Metals |
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134 | (3) |
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5.6.3 Application of Carbon/Carbon in the Solar Energy Market |
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137 | (3) |
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140 | (7) |
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6 C/SiC and C/C-SiC Composites |
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147 | (70) |
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147 | (2) |
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6.2 Manufacturing Methods |
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149 | (25) |
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6.2.1 Chemical Vapor Infiltration |
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151 | (6) |
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6.2.2 Polymer Infiltration and Pyrolysis |
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157 | (3) |
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160 | (14) |
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174 | (17) |
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174 | (2) |
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6.3.2 Material Composition and Microstructure |
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176 | (2) |
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6.3.3 Mechanical Properties |
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178 | (9) |
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187 | (3) |
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190 | (1) |
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6.3.6 Tribological Properties |
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191 | (1) |
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191 | (18) |
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192 | (8) |
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6.4.2 Applications for Aeronautics |
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200 | (2) |
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6.4.3 Applications for Friction Systems |
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202 | (5) |
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6.4.4 Applications for High Temperature Treatment of Metals |
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207 | (2) |
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209 | (8) |
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209 | (1) |
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210 | (1) |
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211 | (6) |
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7 Advances in SiC/SiC Composites for Aero-Propulsion |
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217 | (19) |
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217 | (1) |
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7.2 Materials and Process Requirements for Structurally Reliable High Temperature SiC/SiC Components |
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218 | (1) |
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7.3 Current Fabrication Routes for SiC/SiC Engine Components |
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219 | (1) |
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7.4 Recent NASA Advancements in SiC/SiC Materials and Processes |
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220 | (12) |
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7.4.1 Advances in SiC-Based Fibers |
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220 | (4) |
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7.4.2 Advances in Interfacial Fiber Coatings |
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224 | (1) |
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7.4.3 Advances in SiC Fiber Architectures |
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225 | (2) |
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7.4.4 Advances in SiC-Based Matrices |
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227 | (2) |
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7.4.5 Advances in SiC/SiC Microstructural Design Methods |
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229 | (3) |
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7.5 Current Microstructural Design Guidelines and Potential Service Issues for Higher Temperature SiC/SiC Components |
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232 | (1) |
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233 | (3) |
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233 | (1) |
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233 | (3) |
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8 Oxide--Oxide Composites |
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236 | (37) |
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236 | (1) |
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8.2 Composite Design for Tough Behavior |
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237 | (3) |
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237 | (1) |
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238 | (2) |
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8.3 Fibers and Fiber Architecture |
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240 | (1) |
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241 | (7) |
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8.4.1 Processing of Interface Coatings |
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242 | (1) |
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8.4.2 Matrix Infiltration |
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243 | (4) |
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247 | (1) |
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8.4.4 Metal Oxidation Processing |
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248 | (1) |
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8.5 Porous Matrix Composite Systems |
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248 | (2) |
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250 | (7) |
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8.6.1 Basic Physical Characteristics |
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250 | (1) |
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8.6.2 Room Temperature Uniaxial Mechanical Properties |
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251 | (2) |
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8.6.3 Long-Term Thermal Exposure |
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253 | (1) |
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254 | (1) |
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8.6.5 Notch Sensitivity and Toughness |
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255 | (1) |
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8.6.6 Off-Axis Properties |
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256 | (1) |
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8.7 Composites with Interface Coatings |
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257 | (4) |
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8.7.1 Weak Oxide--Oxide Phase Boundaries/Weak Oxides |
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257 | (3) |
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260 | (1) |
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260 | (1) |
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261 | (1) |
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8.8 Technology Development |
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261 | (2) |
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8.9 Potential Future for Oxide--Oxide Composites |
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263 | (10) |
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264 | (1) |
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264 | (9) |
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9 Ultrahigh Temperature Ceramic-Based Composites |
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273 | (20) |
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273 | (1) |
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9.2 Ultrahigh Temperature Ceramic-Based Composites with Particulates |
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273 | (12) |
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9.2.1 Fabrication Methods |
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273 | (5) |
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9.2.2 Physical Properties |
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278 | (4) |
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9.2.3 Mechanical Properties |
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282 | (3) |
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9.3 Ultrahigh Temperature Ceramic-Based Composites with Short Fibers |
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285 | (3) |
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9.3.1 Carbon Fiber-Reinforced ZrB2- or HfB2-Based Ceramics Matrix Composites |
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286 | (2) |
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9.3.2 Silicon Carbide Fiber-Reinforced ZrB2-Based Ceramics Matrix Composites |
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288 | (1) |
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9.4 Summary Remarks and Future Outlook |
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288 | (5) |
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290 | (3) |
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Part III Environmental Effects and Coatings |
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293 | (172) |
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10 Environmental Effects on Oxide/Oxide Composites |
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295 | (39) |
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10.1 Introduction/Background |
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295 | (1) |
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10.2 Mechanical Behavior---Effects of Environment |
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296 | (34) |
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10.2.1 Tensile Stress--Strain Behavior |
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296 | (2) |
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298 | (6) |
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10.2.3 Tensile Creep and Recovery |
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304 | (4) |
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10.2.4 Tensile Creep---N720/A and N720/AM Composites with ±45 Fiber Orientation |
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308 | (5) |
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10.2.5 Compression and Compression Creep |
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313 | (4) |
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10.2.6 Creep in Interlaminar Shear |
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317 | (4) |
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10.2.7 Tension--Tension Fatigue |
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321 | (3) |
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10.2.8 Tension--Tension Fatigue with Hold Times |
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324 | (6) |
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10.3 Concluding Remarks and Future Directions |
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330 | (4) |
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331 | (3) |
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11 Stress-Environmental Effects on Fiber-Reinforced SiC-Based Composites |
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334 | (19) |
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11.1 Introduction/Background |
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334 | (1) |
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334 | (3) |
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336 | (1) |
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11.2.2 Interior Oxidation and "Oxidation Embrittlement" (Via Cracks or Exposed Volatile Pathways) |
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336 | (1) |
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337 | (8) |
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11.3.1 Carbon-Fiber-Reinforced SiC Composites (Cf/SiCm) |
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337 | (1) |
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11.3.2 SiC-Fiber-Reinforced SiC Matrix Composites with Carbon Interphases (SiCf/Ci/SiCm) |
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338 | (3) |
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11.3.3 SiC-Fiber-Reinforced SiC Matrix Composites with BN Interphases (SiCf/BNi/SiCm) |
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341 | (4) |
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11.4 Modeling and Design for Stress-Oxidation Degradation |
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345 | (5) |
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11.4.1 Modeling Stressed-Oxidation Degradation in C/SiC Composites---C Fiber Removal |
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345 | (1) |
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11.4.2 Modeling Stressed-Oxidation Degradation in SiC/C/SiC Composites: Interphase Recession and Fiber Flaw Growth |
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346 | (1) |
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11.4.3 Modeling Stressed-Oxidation Degradation in SiC Fiber Composites---Unbridged Crack Growth Due to Fiber Weakening and Stress Concentration at Unbridged Crack Tip |
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347 | (1) |
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11.4.4 Modeling Stressed-Oxidation Degradation in SiC/BN/SiC Composites: Unbridged Crack Growth Due to Strongly Bonded Fibers and Local Fiber Failure |
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347 | (1) |
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11.4.5 Mechanism Map: Henegar and Jones |
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348 | (1) |
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11.4.6 Simple Design Approach: Matrix Cracking Stress |
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348 | (2) |
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11.5 Concluding Remarks and Future Directions |
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350 | (3) |
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350 | (1) |
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350 | (3) |
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12 Environmental Effects: Ablation of C/C Materials---Surface Dynamics and Effective Reactivity |
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353 | (36) |
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12.1 Introduction/Background |
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353 | (12) |
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12.1.1 Materials Description |
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355 | (2) |
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357 | (2) |
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12.1.3 Observation of Roughness Features |
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359 | (6) |
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12.2 Materials Observation: Recession Rate |
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365 | (18) |
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368 | (6) |
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12.2.2 Results and Discussions |
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374 | (9) |
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12.3 Concluding Remarks and Future Directions |
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383 | (6) |
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384 | (1) |
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384 | (5) |
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389 | (16) |
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389 | (1) |
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13.2 Theory of Radiation Damage |
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389 | (3) |
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13.2.1 What Is Radiation Damage? |
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389 | (1) |
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13.2.2 Radiation Defect Production |
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390 | (1) |
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13.2.3 Defect Migration and Evolutions |
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391 | (1) |
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13.2.4 Resultant Macroscopic Effects |
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392 | (1) |
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13.3 Radiation Effects on Ceramics |
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392 | (2) |
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392 | (1) |
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13.3.2 Radiation Damage Evolution in SiC |
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392 | (1) |
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13.3.3 Radiation Effects in SiC |
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393 | (1) |
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394 | (1) |
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13.4 Radiation Effects in Ceramic Matrix Composites |
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394 | (7) |
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13.4.1 SiC/SiC Composites |
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394 | (4) |
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13.4.2 Interphase in SiC/SiC Composites |
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398 | (1) |
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13.4.3 Carbon Fiber Composites |
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399 | (2) |
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13.5 Concluding Remarks and Future Directions |
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401 | (4) |
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402 | (1) |
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402 | (3) |
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14 Foreign Object Damage in Ceramic Matrix Composites |
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405 | (25) |
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14.1 Introduction/Background |
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405 | (1) |
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14.2 Experimental Techniques |
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406 | (3) |
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406 | (1) |
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14.2.2 Materials: CMC and Projectile Materials |
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406 | (1) |
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14.2.3 Configuration and Support of CMC Targets |
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407 | (1) |
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14.2.4 Impact Damage Assessments |
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408 | (1) |
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14.3 Phenomena of Foreign Object Damage in CMCs |
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409 | (13) |
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409 | (1) |
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14.3.2 Impact Damage Morphology |
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410 | (7) |
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14.3.3 Prediction of Impact Force |
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417 | (3) |
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14.3.4 Other Effects in FOD |
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420 | (2) |
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14.4 FOD Response of Environmental Barrier Coatings |
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422 | (2) |
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14.5 Comparison of CMCs and Silicon Nitrides |
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424 | (1) |
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14.6 Consideration Factors of FOD in CMCs |
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425 | (1) |
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426 | (4) |
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426 | (1) |
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426 | (4) |
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15 Environmental Barrier Coatings for SiCf/SiC |
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430 | (22) |
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430 | (1) |
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431 | (6) |
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431 | (1) |
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15.2.2 Key Requirements for EBC |
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432 | (5) |
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437 | (5) |
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437 | (1) |
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15.3.2 First Generation Environmental Coatings |
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438 | (3) |
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15.3.3 Second Generation Environmental Coatings |
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441 | (1) |
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15.3.4 Next Generation Environmental Coatings |
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442 | (1) |
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15.4 Processing, Testing, and Lifing |
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442 | (6) |
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442 | (1) |
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443 | (1) |
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444 | (4) |
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15.5 Concluding Remarks and Future Directions |
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448 | (4) |
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448 | (4) |
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16 Oxidation Protective Coatings for Ultrahigh Temperature Composites |
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452 | (13) |
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452 | (1) |
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16.2 Basic Requirements of Anti-Oxidation Coating for C/C and C/SiC Composites |
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453 | (1) |
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16.2.1 Inhibiting Ability of Oxygen Diffusion |
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453 | (1) |
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16.2.2 Good Match of Thermal Expansion with C/C and C/SiC Composites |
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453 | (1) |
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16.2.3 Low Volatility during Service Process |
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453 | (1) |
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16.2.4 Compatible Stability with C/C or C/SiC Composites |
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453 | (1) |
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16.2.5 Good Interfacial Bonding with C/C or C/SiC Composites |
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454 | (1) |
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16.3 Preparation Methods of Anti-Oxidation Coatings |
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454 | (2) |
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454 | (1) |
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16.3.2 Chemical Vapor Deposition |
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454 | (1) |
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16.3.3 Liquid Phase Reaction |
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454 | (1) |
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455 | (1) |
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455 | (1) |
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16.3.6 Supercritical Fluid Technique |
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455 | (1) |
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455 | (1) |
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456 | (1) |
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16.4 Oxidation-Resistant Coating Systems |
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456 | (4) |
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|
456 | (1) |
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456 | (1) |
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457 | (3) |
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460 | (1) |
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460 | (5) |
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|
461 | (4) |
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465 | (84) |
|
17 Damage and Lifetime Modeling for Structure Computations |
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467 | (53) |
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467 | (1) |
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17.2 Damage Modeling Based on an Anisotropic Damage Theory Including Closure Effects |
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468 | (13) |
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468 | (1) |
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17.2.2 Thermodynamic Framework |
|
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469 | (2) |
|
17.2.3 A First CMC Damage Model |
|
|
471 | (1) |
|
17.2.4 An Advanced CMC Damage Model |
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|
472 | (7) |
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17.2.5 Some tools for the Implementation of the Anisotropic Framework |
|
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479 | (2) |
|
17.3 Multiscale Modeling of the Oxidation/Damage Coupling and the Self-Healing Effects |
|
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481 | (22) |
|
17.3.1 Modeling of Fatigue and of the Transverse Intra-yarn Crack Opening |
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482 | (8) |
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17.3.2 Modeling of the Healing Process |
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490 | (6) |
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17.3.3 Modeling of the SubCritical Cracking of Fibers |
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496 | (1) |
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17.3.4 Simulation of Degradation Mechanisms and Prediction of Lifetime |
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497 | (6) |
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17.4 Prediction Capabilities |
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503 | (17) |
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17.4.1 Calculation of the Local Behavior |
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503 | (3) |
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17.4.2 Lifetime Predictions and Application to Damage Tolerance Analysis |
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506 | (7) |
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17.4.3 Control of the Damage Localization and Static Failure Predictions |
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513 | (2) |
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515 | (5) |
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18 Approach to Microstructure--Behavior Relationships for Ceramic Matrix Composites Reinforced by Continuous Fibers |
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520 | (29) |
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520 | (1) |
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18.2 Composite Mechanical Behavior |
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521 | (5) |
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18.2.1 Tensile Stress--Strain Behavior of Composites Reinforced by Continuous Fibers |
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521 | (3) |
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524 | (2) |
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18.3 Constituent Properties and Length Scales |
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526 | (5) |
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18.3.1 Length Scales: Micro and Minicomposites |
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527 | (1) |
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18.3.2 Fracture Strength of Matrix |
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527 | (1) |
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18.3.3 Flaw Strength Distributions |
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528 | (1) |
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18.3.4 Damage Tolerance and Influence of Macroscopic Flaws |
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528 | (2) |
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18.3.5 Interface Strength and Influence of Interface Cracks on the Mechanical Behavior |
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530 | (1) |
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18.4 Modeling of Stress--Strain Behavior |
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531 | (8) |
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18.4.1 Stochastic Model of Matrix Fragmentation in 1D Composite and Minicomposite |
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531 | (4) |
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18.4.2 Ultimate Failure in 1D Composite and Minicomposite |
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535 | (1) |
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18.4.3 Toward a Probability-Based General Model of Composite Behavior |
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536 | (1) |
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18.4.4 The Stress--Strain Behavior of 1D Composites and Minicomposites |
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536 | (1) |
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18.4.5 Alternate Approach |
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537 | (2) |
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18.5 Virtual Testing: Computational Approach for Woven Composites |
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539 | (3) |
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18.5.1 Multiple Cracking in Transverse Tows |
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539 | (2) |
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18.5.2 Matrix Damage in 2D Woven Composites |
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541 | (1) |
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18.6 Predictions of Rupture Time |
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542 | (3) |
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545 | (4) |
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546 | (3) |
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549 | (20) |
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19 Integration and Joining of Ceramic Matrix Composites |
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551 | (18) |
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19.1 Introduction/Background |
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551 | (1) |
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19.2 Mechanical Joining and Integration of CMC |
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552 | (1) |
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19.3 Adhesive Joining of CMC |
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553 | (1) |
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553 | (1) |
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19.5 Liquid Silicon Infiltration |
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554 | (1) |
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554 | (1) |
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19.7 "Exotic" Techniques for Integration And Joining of CMC |
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555 | (3) |
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19.7.1 Transient-Liquid-Phase Bonding |
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555 | (1) |
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19.7.2 Nanopowder Infiltration and Transient Eutectic Phase |
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555 | (1) |
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19.7.3 Spark Plasma Sintering |
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556 | (1) |
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19.7.4 Micro-Wave-Assisted Joining |
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557 | (1) |
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19.7.5 Laser-Assisted Joining |
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557 | (1) |
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19.7.6 Glass and Glass-Ceramic as Joining Materials for CMC |
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557 | (1) |
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19.7.7 Solid State Displacement Reactions |
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557 | (1) |
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19.7.8 Preceramic-Polymer Joints |
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|
558 | (1) |
|
19.8 Back to Basic: Joints for CMC Like in Wood-Based Products |
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558 | (2) |
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560 | (1) |
|
19.9.1 Joining of CMC for Nuclear Applications |
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|
560 | (1) |
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19.9.2 Joining of CMC for Ultrastable Structures |
|
|
561 | (1) |
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19.10 Mechanical Tests on Joined CMC |
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|
561 | (1) |
|
19.10.1 Shear Strength Tests |
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561 | (1) |
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19.10.2 Nondestructive Tests |
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562 | (1) |
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19.11 Concluding Remarks and Future Directions |
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562 | (7) |
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563 | (1) |
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563 | (6) |
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Part VI Nondestructive Evaluation |
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|
569 | (22) |
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20 Use of Acoustic Emission for Ceramic Matrix Composites |
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|
571 | (20) |
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|
20.1 Introduction/Background |
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|
571 | (1) |
|
20.2 AE Principles and Practice |
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|
572 | (3) |
|
20.3 Event-Based AE Monitoring of CMCs |
|
|
575 | (5) |
|
20.3.1 Event-Based AE of CMC Stress--Strain Behavior |
|
|
576 | (3) |
|
20.3.2 Event-Based AE of CMC-Elevated Temperature Stress-Rupture |
|
|
579 | (1) |
|
20.3.3 Event-Based AE of CMC C-Coupon Testing |
|
|
580 | (1) |
|
20.4 AE Signal Analysis Using Pattern Recognition Techniques |
|
|
580 | (4) |
|
20.4.1 Unsupervised Clustering Methodology Applied to AE Signals |
|
|
583 | (1) |
|
20.4.2 Supervised Pattern Recognition Method |
|
|
584 | (1) |
|
20.5 High Temperature Testing and AE Monitoring |
|
|
584 | (2) |
|
20.5.1 Identification of Damage Mechanism on SiCf/[ Si-B-C] Composite at Intermediate Temperatures (450--750°C) |
|
|
585 | (1) |
|
20.5.2 Identification of Damage Mechanism on Cf/[ Si-B-C] Composite at High Temperature (700--1200°C) |
|
|
586 | (1) |
|
20.6 Acoustic Emission and Lifetime Prediction During Static Fatigue Tests |
|
|
586 | (2) |
|
20.6.1 Detection of Energy Release Acceleration |
|
|
587 | (1) |
|
20.6.2 Application of the Benioff Law to Assess Lifetime of the CMCs |
|
|
588 | (1) |
|
20.7 Concluding Remarks and Future Directions |
|
|
588 | (3) |
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|
589 | (2) |
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|
591 | (78) |
|
21 CMC Applications to Gas Turbines |
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|
593 | (16) |
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|
593 | (1) |
|
21.2 CMC Developments for Military Engines |
|
|
594 | (6) |
|
21.2.1 Demonstration and Developments for Exhaust Section |
|
|
594 | (4) |
|
21.2.2 Demonstration of CMC Afterburner Components |
|
|
598 | (1) |
|
21.2.3 Turbine Component Demonstrations on Military Engines |
|
|
599 | (1) |
|
21.3 CMC R&D for Commercial Engines |
|
|
600 | (7) |
|
21.3.1 CMC R&D for Combustion Chamber |
|
|
601 | (1) |
|
21.3.2 R&D on CMC Turbine Components |
|
|
602 | (2) |
|
21.3.3 Development Activities in the Exhaust Section |
|
|
604 | (2) |
|
21.3.4 CMC Program Demonstrations on Industrial Gas Turbine |
|
|
606 | (1) |
|
21.4 Summary and Insertion Issues |
|
|
607 | (2) |
|
|
|
608 | (1) |
|
22 Ceramic Matrix Composites: Nuclear Applications |
|
|
609 | (38) |
|
|
|
|
|
609 | (1) |
|
22.2 CMC Fusion Applications |
|
|
610 | (6) |
|
|
|
610 | (2) |
|
|
|
612 | (2) |
|
22.2.3 First Wall and Blanket |
|
|
614 | (2) |
|
22.3 CMC Fission Applications |
|
|
616 | (8) |
|
|
|
616 | (2) |
|
22.3.2 CMCs for Structural Materials in VHTRs and SFRs |
|
|
618 | (3) |
|
22.3.3 CMCs for Pin Cladding or Structural Materials in GFRs and LWRs |
|
|
621 | (3) |
|
22.4 Processing of C/C Composites for Nuclear Applications |
|
|
624 | (3) |
|
|
|
624 | (1) |
|
22.4.2 C/C Composites for Fusion Applications |
|
|
624 | (3) |
|
22.4.3 C/C Composites for Fission Reactor Applications |
|
|
627 | (1) |
|
22.5 Processing of SiC/SiC Composites for Nuclear Applications |
|
|
627 | (14) |
|
|
|
627 | (1) |
|
22.5.2 Selection of SiC Fibers |
|
|
628 | (2) |
|
22.5.3 Selection of Architecture |
|
|
630 | (1) |
|
22.5.4 Choice of Interphase |
|
|
630 | (1) |
|
22.5.5 Densification Processes and Associated SiC/SiC Composite Properties |
|
|
631 | (6) |
|
22.5.6 Designs for Hermetic Composites Adapted for Nuclear Applications |
|
|
637 | (4) |
|
22.6 Conclusions and Perspectives |
|
|
641 | (6) |
|
|
|
642 | (1) |
|
|
|
642 | (5) |
|
23 Ceramic Matrix Composites for Friction Applications |
|
|
647 | (22) |
|
|
|
|
|
|
|
647 | (1) |
|
23.2 Carbon/Carbon for Friction Applications |
|
|
647 | (10) |
|
23.2.1 Aircraft Braking Particularities |
|
|
647 | (1) |
|
23.2.2 History and Materials Choice |
|
|
648 | (3) |
|
23.2.3 C/C Tribological Behavior and Constituents |
|
|
651 | (4) |
|
23.2.4 Other C/C Tribological Applications |
|
|
655 | (2) |
|
23.2.5 C/C Limitations and Trends |
|
|
657 | (1) |
|
23.3 Carbon/Ceramic for Friction Applications |
|
|
657 | (11) |
|
23.3.1 History and Milestones of the C/SiC Development |
|
|
659 | (5) |
|
23.3.2 C/SiC Brake Disks for Passenger Cars |
|
|
664 | (2) |
|
23.3.3 C/SiC Materials for Industrial Applications |
|
|
666 | (2) |
|
23.3.4 Future Challenges for C/SiC Materials |
|
|
668 | (1) |
|
|
|
668 | (1) |
| Acknowledgments |
|
669 | (1) |
| References |
|
669 | (4) |
| Index |
|
673 | |
