Trends in the Design and Analysis of Components Fabricated From CFCCs
Author:
Duffy S. F.1, Palko J. L.1, Sandifer J. B.2, DeBellis C. L.2, Edwards M. J.2, Hindman D. L.3
Affiliation:
1. Civil Engineering Department, Cleveland State University, Cleveland, OH 44115 2. Babcock & Wilcox, Research and Development Division, Alliance, OH 44601 3. Babcock & Wilcox, Lynchburg Research Center, Lynchburg, VA 24506
Abstract
Continuous fiber ceramic composite materials (CFCCs) are being considered for an increasing number of commercial applications. They provide the potential for lighter, stronger, more corrosion-resistant components that can perform at higher temperature for long periods of time. Global competitiveness demands a shortening of the time for CFCC commercialization. Thus, considerable efforts has been expended to develop and improve the materials, and to a lesser extent, to develop component design methods and data bases of engineering properties. To shorten the time to commercialization, project efforts must be integrated, while balancing project resources between material development and engineering design. Currently a good balance does not exist for most materials development projects. To rectify this imbalance, improvements in engineering design and development technologies must be supported and accelerated, with a focus on component issues. This will require project managers to give increasing emphasis to component design needs in addition to their current focus on material development.
Publisher
ASME International
Subject
Mechanical Engineering,Energy Engineering and Power Technology,Aerospace Engineering,Fuel Technology,Nuclear Energy and Engineering
Reference10 articles.
1. Chuang, T.-J., and Duffy, S. F., 1994, “A Methodology to Predict Creep Life for Advanced Ceramics Using Continuum Damage Mechanics Concepts,” in: Life Prediction Methodologies and Data for Ceramic Materials, ASTM STP 1201, C. R. Brinkman and S. F. Duffy, eds., American Society for Testing and Materials, Philadelphia, pp. 207–227. 2. DeBellis, C. L., and Kneidel, K. E., 1987, “Thermal and Fluid Design of a High-Temperature Ceramic Fiber Composite Heat Exchanger,” presented at the AIChE Sessions of the 24th National Heat Transfer Conference, Pittsburgh, PA. 3. Duffy, S. F., and Gyekenyesi, J. P., 1989, “Time Dependent Reliability Model Incorporating Continuum Damage Mechanics for High-Temperature Ceramics,” NASA TM-102046. 4. Duffy
S. F.
, and ArnoldS. M., 1990, “Noninteractive Macroscopic Statistical Failure Theory for Whisker Reinforced Ceramic Composites,” Journal of Composite Materials, Vol. 24, No. 3, pp. 293–308. 5. Duffy
S. F.
, and ManderscheidJ. M., 1990, “Noninteractive Macroscopic Reliability Model for Ceramic Matrix Composites with Orthotropic Material Symmetry,” ASME JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER, Vol. 112, No. 4, pp. 507–511.
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