Composites reinforced along cube diagonals. I. Shear and compression resistance
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Keywords
Compression Resistance Cube Diagonal
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Literature cited
- 1.I. G. Zhigun and V. A. Polyakov, Properties of Spatially Reinforced Plastics [in Russian], Riga (1978).Google Scholar
- 2.I. G. Zhigun and N. P. Radimov, “Special features of the mechanical properties of threedimensionally reinforced carbon-carbon composites,” Mekh. Kompozitn. Mater., No. 3, 504–507 (1982).Google Scholar
- 3.I. G. Zhigun and N. P. Radimov, “Effect of the reinforcement structure and the type of matrix on the shear and compression resistance of spatially reinforced Polikarbon composites,” Mekh. Kompozitn. Mater., No. 1, 37–42 (1985).Google Scholar
- 4.L. Delnest and B. Peres, “An inelastic finite element model for four-directional carboncarbon composite material,” Aerokosm. Tekhn.,2, No. 6, 3–11 (1984).Google Scholar
- 5.Yu. M. Tarnopol'skii, I. G. Zhigun, and V. A. Polyakov, Spatially Reinforced Composites [in Russian], Moscow (1987).Google Scholar
- 6.A. F. Kregers and A. F. Zilauts, “Limiting values of the reinforcement coefficients of fiber-reinforced composites with a spatial structure,” Mekh. Kompozitn. Mater., No. 5, 784–790 (1984).Google Scholar
- 7.A. F. Kregers and Yu. G. Melbardis, “Determination of the deformability of spatially reinforced composites by the method of averaging stiffnesses,” Mekh. Polim., No. 1, 3–8 (1978).Google Scholar
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© Plenum Publishing Corporation 1988