Semisolid-rolling and annealing process of woven carbon fibers reinforced Al-matrix composites

doi:10.1016/j.jmst.2017.01.002

Abstract

Abstract:

Semisolid-rolling method was successfully developed to prepare the Ni-coated woven carbon fibers reinforced Al-matrix composite. Due to the appropriate matrix flowability and rolling pressure, the Al-matrix could infiltrate into the woven fibers sufficiently and attach to the reinforcements closely forming a smooth interface. The rolling speed of 4 rad/min offered a subtle equilibrium between the heat transfer and the material deformation. The covering matrix should be controlled at semisolid state to provide a better infiltration behavior and a protective effect on the carbon fibers. With the addition of fibers, an improvement for more than 25% was obtained in the bending strength of the materials. Furthermore, the woven carbon fibers could strengthen the composite in multiple directions, rather than only along the fiber longitudinal directions. The annealing process promoted the Ni coating to react with and to diffuse into the matrix, resulted in an obvious increase of the bending strength.

Key words: Metal-matrix composites, Woven carbon fiber, Semisolid-rolling process, Annealing, Mechanical property

Zhang Junjia, Liu Shichao, Lu Yiping, Jiang Li, Zhang Yubo, Li Tingju. Semisolid-rolling and annealing process of woven carbon fibers reinforced Al-matrix composites[J]. J. Mater. Sci. Technol., 2017, 33(7): 623-629.

Figures/Tables 6

Fig. 1. Macro-morphologies of the composites obtained with different rolling speeds: (a) 1 rad/min; (b) 2 rad/min; (c) 3 rad/min; (d) 4 rad/min; (e) 5 rad/min; (f) 6 rad/min.

Fig. 2. the morphologies of the composites obtained with different covering Al:(a) liquid covering Al, (b) mushy covering Al, (c) solid covering Al and (d) stripping the woven carbon fibers from the Al-composite using concentrated sodium hydroxide solution.

Fig. 3. schematic diagrams of (a) sampling method, (b) fiber distribution in sample A and (c) fiber distribution in sample B.

Fig. 4. results of the three-point bending tests: (a) stress-deflection curves; (b) micro-structure of the sample A; (c) micro-structure of the sample B.

Fig. 5. Effect of annealing time on the bending strength: (a) bending strength of composite and matrix; (b) improvement resulted from the fibers addition.

Fig. 6. Micromorphologies of the annealed composites after different time: (a) 0 min; (b) 30 min; (c) 90 min; (d) 150 min.

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