Characterization and control of the fiber-matrix interface in ceramic ...

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182 15. R. A. J. Sambell, D. H. Bowen, and D. C. Phillips, "Carbon Fiber Composites with Ceramic and Glass Matrices, Part 1: Discontinuous Fibres," J . Mater. Sci. 7, 663-75 (1972). 16. F. Galasso, M. Basche, and D. Kuemle, "Preparation, Structure, and Properties of Continuous Silicon Carbide Filaments," Appl. Phys. Lett. 9, 37 (1966). 17. S. Yajima et al., "Synthesis of Continuous Sic Fibers with High Tensile Strength," J . Am. Ceram. Soc. 59(7-8), 324-27 (1976). 18. S. Yajima et al., "Anomalous Characteristics of the Microcrystalline State of SI.C Fibres," Nature 27(21), 706-7 (1979). 19. K. M. Prewo and J. J. Brennan, "High-Strength Silicon Carbide Fiber-Reinforced Glass-Matrix," J . Mater. Sci. 15, 463-8 (1980). 20. K. M. Prewo, J. J. Brennan, and G. K. Layden, "Fiber Reinforced Glasses and Glass-Ceramics for High Performance Applications," Ceram. Bull. 65(2), 305-22 (1986). 21. R. A. J. Sambell, "The Technology of Ceramic-Fibre Ceramic- Matrix Composites," Coniposites 1(5), 276-85 (1970). 22. W. B. Ilillig, "Strength and Toughness of Ceramic Matrix Composites," Ann. Rev. Mater. Sci. 17, 341-83 (1987). 23. W. Hillig, "Ceramic Composites by Infitration," Ceram. Eng. Sci. Proc. 6(7-8), 674-83 (1985). 24. I. W. Donald and P. W. McMillan, "Review: Ceramic Matrix Composites," J . Mater. Sci. 11, 949-72 (1976). 25. G. C. Wei and P. F. Becher, "Development o f Sic-Whisker- Reinforced Ceramics," Am. Ceram. SOC. Bull. 64(2), 298-304 (1985). 26. D. K. Shetty, "Sic Monofilament-Reinforced Si3N4 Matrix Composites," Ceram. Eng. Sci. Proc. 6(7-81, 632-45 (1985). 27. K. P. Boisvert and R. J. Diefendorf, "Polymeric Precursor for Sic Matrix Composites," C erm. Eng. Sci. Proc. 9(7-8), 873-80 (1988). 28. T. Starr, J. N. Harris, and D. L. Mohr, "Reaction-Sintered Silicon Nitride With Short Fiber Reinforcement," Ceram. Eng. Sci. Proc. 8(7-8), 985-91 (1987). 29. R. H. Jones et al., "Interfacial Chemistry-Structure and Fracture of Ceramic Composites," to be published in Ceram. Eng. Sci. Proc. 9(7-8), 655-62 (1988). 30. R. Naslain et al., "Chemical Vapor Infiltration Technique," pp. 293-304 in Euro-CVD-Four, Eindhoven, The Netherlands, 1983.
183 31. J. C. Whithers, "Chemical Vapor Deposition of Ceramic Composites Containlng Whisker and Fiber Reinforcements," pp. 597-20 in Third International Conference on Chemical Vapor Deposition, edited by F. A. Glaski,,American Nuclear Society, Hinsdale, Ill., 1972. 32. W. H. Pfiefer et al., "Consolidation of Porous Structures by CVD," pp. 463-83 in Second International Conference on Chemical Vapor Deposition, edited by J. M. Blocher, Jr. and J. C. Whithers, Electrochemical Society, New York, 1970. 33. J. D. Theis, Jr., "The Process Development and Mechanical Testi-ng of a Carbon/Carbon Composite Fabricated by Chemical Vapor Infiltration o€ a Filament Wound Substrate," pp. 561-73 in Third International Conference on Chemical Vapor Deposition, edited by F. A. Glaski, American Nuclear Society, Hinsdale, Ill., 1972. 34. L. R. Newkirk et al., "Chemical Vapor Deposition Fabrication of Filament-Reinforced Composites for High Temperature Applications," pp. 82-101 in Chemically Vapor Deposited Coatings, edited by H. 0. Pierson, Am. Ceram. Soc., Columbus, Ohio, 1981. 35. H. 0. Pierson, "Carbon Composites from Wool Felt; Substrates," pp. 487-505 in Second International Conference on Chemical Vapor Deposition, edited by J. M. Blocher, Jr. and J. C. Whithers, Electrochemical Society, New York, 1970. 36. J. J. Gebhardt, "CVD Boron Nitride Infiltration of Porous Structures: Properties of Low Temperature Deposits," pp. 460-72 in Fourth rnternational Conference on Chemical Vapor Deposition, edited by G. F. Wakefield and J. M. Blocher, Js., Electrochemical Society, Princeton, N.J., 1973. 31. H. Hannache, R. Naslain, and C. Bernard, "Boron Nitride Chemical Vapor Infiltration of Fibrous Materials from BCl3-Nli3-H~ or BP3-NH3 Mixtures: A Thermodynamic and Experimental Approach," J . Less Conimon Met. 95, 221-46 (1983). 38. F. Christrin, R. Naslain, and C. Bernard, "A Thermodynamic and Experimental Approach of Silicon Carbide CVD Application to the CVD- Infiltration of Porous Carbon/Carbon Composites," pp. 499-514 in Seventh International Conference on Chemical Vapor Deposition, edited by T. 0. Sedgwick, Electrochemical Society, Princeton, N.J., 1974. 39. J. Rossignol, I, Langlais, and R. Naslain, "A Tentative Modelization of Titanium Carbide CVP Within the Pore Network of Two- Dimensional Carbon/Carbon Composite Preforms," pp. 596-614 in Ninth International Conference on Chemical Vapor Deposition, edited by M. Robinson et al., Electrochemical Society, Princeton, N.J., 1984. 40. A. J. Caputo, R. A. Lowden, and Is. P. Stinton, Improvements in the Fabrication of Ceramic-Fiber-Geramie-Matrix Composites by Chemical Vapor Deposition, OlZNL/TM-9652, Oak Ridge National Laboratory, Oak Kidge, Tenn., June 1985.
Page 3:
ORNL/TM-11039 Metals and Ceramics D
Page 6 and 7:
Page 9.3 Composite Fabrication . .
Page 9:
LIST OF TABLES Table Page 5,l. Prop
Page 12 and 13:
Figure 8.3. 9.1.. 9.2. 9.3. 9.4. 9.
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Figure 10.18. 10.19. 10.20. 10. 21.
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ACKNOWLEDGMENTS The author wishes t
Page 19 and 20:
CWCTERIZATION AND CONTROL OF THE FI
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1. INTRODUCTION During the last sev
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The development of low-density, hig
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3. FABRICATION TECHNIQUES 3.1 Intro
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11 isostatic pressing (HIP), can be
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13 utilizing the comparatively low-
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16 ORN L- DWG 85- 4 i 4 18RS HEAT1
Page 37 and 38:
5. COMPOSITE DESIGN 5.1 Introductio
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21 5,2 Mechanical Considerations Th
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23 GRNL-DWG 88-74 26 Figure 5.1. Th
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25 Equation (6) shows that the stre
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27 of reinforcement. There are two
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29 in strength. Conversely, the fib
Page 49 and 50:
-I_- Table 5.2. Thermally induced a
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33 1.2 ID 0.8 ;.r 1 e fi v 0.6 a4 Q
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35 will affect the interface and, t
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38 fiber-matrix bonding; thus, a fu
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40 In the analysis of the mechanica
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42 1.2 I .o .6 - E f aa '3 0.6 cn 3
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44 will result in the matrix being
Page 64 and 65:
I I MATRIX MATRIX Figure 7.1. Schem
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48 F = 2a2H, where H is the hardnes
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50 OWL-PHOTO 6866-86 i d c I 20pm F
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52 where Af is the surface area of
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54 Figure 7.4. Tensile and shear st
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56 I I I / -c rc -c / . Om / / I /
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58 ORNL-OWG 87-i 8234 F Figure 7.7.
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coating and the distribution of she
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62 O m PHOTO 6676-87 i SIC FIBERS -
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the composite, therefore an interme
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methane as the reactant and is, thu
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9. EXPERIMENTAL PROCEDURES 9.1 Depo
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71 furnace. The furnace is, therefo
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73 further protection. A 6.5-cm-dia
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76 of the specimen slowly decreased
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78 The programmer is also equipped
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80 graphite holders through multipl
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82 temperature by simply switching
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84 ORNk DWG 87- 4494 3 METAL LOGR A
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86 9.5 Fracture Surface Analvsis Th
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88 treated and untreated halves wer
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90 9.8.2 Tensile testinq In an init
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92 ORNL-DUG 85-11767R.2 ? ! 2 f CEN
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94 fracture of individual Nicalon f
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96 Figure 10.1. SiC-infiltrated Nic
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99 compared with the dimensions acq
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101 Table 10.3. Strength and modulu
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100 ORNL- DWG 87-1 6292 R CVI-I73 7
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BULK FIBER SAMPLE NO. 173: FIBER SU
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107 similar samples show the film o
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Figure 10.7. SEM micrographs showin
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111 Table 10.4. Thermochemical eval
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100 ORNL-DUG 87-15969R CVI- 170 75
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115 Analysis conversion of of the m
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117 A 1 I S N 31 N I I'd I LN 3H 3
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119 n 0 W n 9 v P n w- n v
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121 s m f c I m z - Ir 2 a 0 9 In u
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Figure 10.14. SEM micrographs of in
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J ORNL-DWC 88-6289 z cF u) w I- z O
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127 300 I CVI-480 I I 1 0 R N L-DWG
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io0 I I I I CVI- 172 75 - - 0 z v -
Page 149 and 150: 131 RAL 033021 RAL 033023 Figure 10
Page 151: 133 include: the reaction of boron
Page 154 and 155: 136 that BN coatings react with the
Page 156 and 157: 75 7 ORNL-DWG 87-48234 50 - - c5 z
Page 158 and 159: 140 Table 10.9. Thermochemical eval
Page 160 and 161: OANL-bwo 88-9025 ORNL-DWG 66-9027 I
Page 162 and 163: 144 uncoated tows were 14 k 2 pm; t
Page 165 and 166: 11. DISCUSSION 11.1 Constituent Pro
Page 167 and 168: 149 The properties of CVD Sic have
Page 169 and 170: 151 11.2.1 Matrix cracking In the N
Page 171 and 172: 153 OWL-DWG 88-10677 CVI- (78 22 I
Page 173 and 174: 155 Table 11.3. Property comparison
Page 175 and 176: 157 a f ““f f- L c I Figure 11.
Page 177 and 178: 159
Page 179 and 180: 161 The equations demonstrate that
Page 181 and 182: 163 calculations of the matrix depo
Page 183 and 184: 165 In four of the samples, the fib
Page 185 and 186: 167 Table 11.4. Properties of glass
Page 187 and 188: 169 rare-earth magnets and coils to
Page 189 and 190: 171 stress fields along the fiber i
Page 191 and 192: 173 11.3.2 Tensile testinp, The use
Page 193 and 194: 17 5 contraction have been ignored,
Page 195: 177 the system, and when the result
Page 198 and 199: 180 reduces fiber strength. The str
Page 202 and 203: 184 41. A. J. Caputo et al., "Fiber
Page 204 and 205: 186 71, N. F. DOW, Study of Stresse
Page 206 and 207: 188 98. M. H. Rawlins et al., "Inte
Page 208 and 209: 190 125. R. Warren and C-H. Anderss
Page 210 and 211: 192 155. M. F. Doerner and W, D. Ni
Page 213 and 214: APPENDIX A. AUGER ELECTRON SPECTROS
Page 215: APPENDIX B DETAILS OF THE FIBER-SHE
Page 218 and 219: 200 Those for the fiber (primed) ar
Page 220 and 221: 202 89-92. 93. 94. 95" 96. 97. 98-9
Page 222 and 223: 204 130-133. E. I. DUPONT DE NEMOUR
Page 224 and 225: 206 173. NATIONAL ACADEMY OF SCIENC
Page 226 and 227: 208 203 - 204. 20s. 206 - 207. 208.
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