Continuous fiber ceramic composite

Ellingson, W., as cited in Singh, R.N., Webb, J.E., Wang, H., Anadakumar, U. (1995), Thermal shock, damage is major concern , CFCC News A communication of the continuous fiber ceramic composite program, Oak Ridge National Laboratory, 6, 12-15. 

Wang, H., Singh, R.N., Lowden, R.A. (1994), Thermal shock behaviour of continuous fiber ceramic composites , Ceram. Eng. SciProc., 15(4), 292-302. 

CBA cost-benefit analysis GFGC continuous fiber ceramic composite... 

Continuous fiber ceramic composite program United States power generation shrouds combustors thermophotovoltaic power 900°C (1,652°F) for > 25,000 hrs... 

Continuous fiber ceramic composite program United States industrial processing chemical pumps radiant burners gas filters furnace hardware reforming tubes 350°C (662°F) for 30,000 hrs in an environment containing organic and inorganic chemicals... 

DOE. 1993. Continuous Fiber Ceramic Composite (CFCC) Program Phase I, Volume 1, Report Number 1.0, Task 1 Applications Assessment, August 31, 1993 (DOE/CE/41000-01). Washington, D.C. U.S. Department of Energy. 

Goettler, R. 1993. Oxide/oxide sol-gel continuous fiber ceramic composites. Presented at Annual Department of Energy Continuous Fiber Ceramic Composite Program Working Group Meeting, Knoxville, Tennessee, September 1-2, 1993. 

Thermal and mechanical properties of HiPerComp composites have been measiued at various stages during their development. Consequently the data presented here differs somewhat from previously published data summaries [1] since the material system and processing techniques have continued to evolve with time. The data presented here for Prepreg HiPerComp was mostly measured as part of the DOE-sponsored Continuous Fiber Ceramic Composites (CFCC) program on material fabricated in 2000 and 2001. Data for the Slurry Cast HiPerComp material was measured in 2003. Please note that this data is presented for informative purposes only, and should not be construed as, or used for, engineering specifications. 

RCG/Hagler, Bailly, Inc., Industrial Environmental Market Opportunities for Continuous-Fiber Ceramic Composites , DOE/OR Report 950 prepared for the Office of Industrial Technologies, U.S. DOE, December 1990. 

M. G. Jenkins and S. S. Kohles, High-Temperature Performance and Retained Strength of an Oxide-Oxide Continuous Fiber Ceramic Composite, Ceram. Eng. Sci. Proc., 19 [3] 317-325 (1998). 

S. Shanmugham, D. P. Stinton, F. Rebillat, A. Bleier, T. M. Besmann, E. Lara-Curzio, and P. K. Liaw, Oxidation-Resistant Interfacial Coatings for Continuous Fiber Ceramic Composites, Cer. Eng. Sci. Proc., 16 [4] 389-399 (1995). 

L. P. Zawada and S. S. Lee, The effect of hold times on the fatigue behavior of an oxide/oxide ceramic composite, in Thermal and Mechanical Test Methods and Behavior of Continuous-Fiber Ceramic Composites, M. G. Jenkins, et al., Eds., American Society for Testing and Materials, West Conshohocken, PA, (1997). 

M. B. Ruggles-Wrenn, S. Mall, C. A. Eber, L. B. Harlan, Effects of Steam Environment on High-Temperature Mechanical Behavior of Nextel 720/Alumina (N720/A) Continuous Fiber Ceramic Composite, Composites Part A, 37(11), 2029-40 (2006). 

Wessel, J. K. 2004. Handbook of Advanced Materials. Hoboken, NJ John Wiley Sons. This book brings together the most recent information about advanced materials and their properties. Materials range from polymer composites, continuous fiber ceramic composites to intermetallics and light metal alloys. Chapters on standards and codes, nondestructive evaluation, and rapid prototyping are included. Available online on Wiley Online Library. 

G.A. Graves and L. Chuck, Hoop Tensile Strength and Fracture Behavior of Continuous Fiber Ceramic Composite (CFCC) Tubes from Ambient to Elevated Temperatures , J. Composites Technology and Research, Vol 19, No 3 (1997)... 

Figure 5 Schematic of continuous fiber ceramics composite processing.

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