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Fiber reinforcement carbon

The results presented below were obtained using a 2 mm thick carbon fiber reinforced epoxy composite laminate with 16 layers. The laminate was quasi isotropic with fiber orientations 0°, 90° and 45°. The laminate had an average porosity content of approximately 1.7%. The object was divided in a training area and an evaluation area. The model parameters were determined by data solely from the training area. Both ultrasound tranducers used in the experiment had a center frequency of 21 MHz and a 6 dB bandwidth of 70%. [Pg.890]

Carbon-Carbon Composites. Carbon—carbon composites are simply described as a carbon fiber reinforcement in one or many directions using a carbon or graphite matrix material (see Composite materials). [Pg.5]

Carbon-Fiber Composites. Cured laminates of phenoHc resins and carbon-fiber reinforcement provide superior flammabiHty resistance and thermal resistance compared to unsaturated polyester and epoxy. Table 15 shows the dependence of flexural strength and modulus on phenoHc—carbon-fiber composites at 30—40% phenoHc resin (91). These composites also exhibit long-term elevated temperature stabiHty up to 230°C. [Pg.307]

Carbon Composites. Cermet friction materials tend to be heavy, thus making the brake system less energy-efficient. Compared with cermets, carbon (or graphite) is a thermally stable material of low density and reasonably high specific heat. A combination of these properties makes carbon attractive as a brake material and several companies are manufacturing carbon fiber—reinforced carbon-matrix composites, which ate used primarily for aircraft brakes and race cats (16). Carbon composites usually consist of three types of carbon carbon in the fibrous form (see Carbon fibers), carbon resulting from the controlled pyrolysis of the resin (usually phenoHc-based), and carbon from chemical vapor deposition (CVD) filling the pores (16). [Pg.273]

Most recent studies (69) on elevated temperature performance of carbon fiber-based composites show that the oxidation resistance and elevated temperature mechanical properties of carbon fiber reinforced composites are complex and not always direcdy related to the oxidation resistance of the fiber. To some extent, the matrix acts as a protective barrier limiting the diffusion of oxygen to the encased fibers. It is therefore critical to maintain interfacial bonding between the fiber and the matrix, and limit any microcracking that may serve as a diffusion path for oxygen intmsion. Since interfacial performance typically deteriorates with higher modulus carbon fibers it is important to balance fiber oxidative stabiHty with interfacial performance. [Pg.7]

Eig. 10. The variation of the density of carbon-fiber reinforced epoxy resin with the fiber volume fraction, based on the rule of mixtures. [Pg.10]

Fig. 12. (a) The variation of the tensile strength of unidirectional carbon-fiber-reinforced epoxy resin as a function of the fiber volume fraction, (b) The variation of the tensile strength of unidirectional carbon-fiber-reinforced epoxy resin as a function of the fiber volume fraction for low fiber volume... [Pg.12]

Ting, J.-M. and Lake, M.L., Vapor-grown carbon-fiber reinforced carbon composites, Carbon, 1995, 33(5), 663 667... [Pg.165]

Chen, P. and Chung, D.D.L., Carbon fiber reinforced concrete for smart structures. [Pg.166]

Fig. 9. The effect of voids due to poor wetting on adhesive strength, (a) The zippering effect of voids aligned in the plane of shear, (b) Macro-voids in the resin formed during the manufacture of a carbon fiber reinforced prepregs. (c) Micro-voids caused by axial crenulations along carbon fiber surfaces. Fig. 9. The effect of voids due to poor wetting on adhesive strength, (a) The zippering effect of voids aligned in the plane of shear, (b) Macro-voids in the resin formed during the manufacture of a carbon fiber reinforced prepregs. (c) Micro-voids caused by axial crenulations along carbon fiber surfaces.
Carbon-fiber reinforcement is more effective in resisting creep than glass-fiber reinforcement. [Pg.82]

Other. Laminated plastic (industrial laminate), sandwich molding, filled plastic, cellular plastic, glass reinforced plastic (GRP), carbon fiber reinforced plastic (CFRP). [Pg.602]

A broad variety of structural polymers is nowadays available that are suitable for applications as different as carbon fiber reinforced materials, encapsulation of electronic devices or adhesive bonding. Each of these polymers belongs to one of two classes thermosets or thermoplastics. [Pg.317]

Chen P.and Chung, D.D.L., Carbon fiber reinforced concrete as an intrinsically smart concrete for damage assessment during dynamic loading, pp. 168-9, Extended Abstracts, 22st Biennial Conference on Carbon, 1995, pp 168 169. [Pg.188]

Hydrogen gas is odorless and colorless. It burns almost invisibly and a fire may not be readily detected. Compressed hydrogen gas could be ignited with the static discharge of a cell phone. But, an accident may not cause an explosion, since carbon fiber reinforced hydrogen tanks are nearly indestructible. There is always the danger of leaks in fuel cells, refineries, pipelines and fueling stations. [Pg.37]

Fu SY, Lauke B, Mader E, Yue CY, Hu X. Tensile properties of short-glass-fiber- and short-carbon-fiber-reinforced polypropylene composites. Composites Part A Applied Science and Manufacturing. 2000 31(10) 1117-25. [Pg.250]

See other pages where Fiber reinforcement carbon is mentioned: [Pg.5]    [Pg.387]    [Pg.73]    [Pg.204]    [Pg.204]    [Pg.85]    [Pg.6]    [Pg.8]    [Pg.145]    [Pg.159]    [Pg.18]    [Pg.413]    [Pg.2]    [Pg.834]    [Pg.364]    [Pg.170]    [Pg.26]    [Pg.410]    [Pg.119]    [Pg.166]    [Pg.180]    [Pg.142]    [Pg.178]    [Pg.178]    [Pg.556]    [Pg.556]   
See also in sourсe #XX -- [ Pg.311 ]



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