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Abstract

Mo fiber-reinforced resin mineral composite (RMC) belongs to a multiphase material, whose mechanical strength depends on the property of components and microstructure characteristics of Mo fibers including surface state, fiber content, fiber shape, and so on. The reinforcing mechanism of Mo fiber is analyzed and the reinforcing effects of new and scrap fibers on RMC are studied, respectively, in the paper. Typical samples with different fiber parameters are prepared to validate the aforementioned assumptions. Experimental results and finite element simulation prove that scrap Mo fibers can improve the mechanical properties of RMC better than ordinary new Mo fibers because of the discharge pits randomly distributed on the surface of scrap fibers. The reinforcing effect is best while the fiber content is 1.2% of the total mass. If the length, diameter, and mass fraction of fibers are identical, special-shaped fibers such as U, V, N, W perform better obviously, and their maximum pulling load is much bigger than ordinary linear fibers.

Keywords

Resin mineral composite Mo fiber reinforcing effect special-shaped fiber compression strength flexural strength

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References

Orak

. Investigation of vibration damping on polymer concrete with polyester resin. Cement Concrete Res 2000; 30: 171–174.

Vivancos

Luis

Costa

. Optimal machining parameters selection in high speed milling of hardened steels for injection moulds. J Mater Process Tech 2004; 155–156: 1505–1512.

Cortés

Castillo

. Comparison between the dynamical properties of polymer concrete and grey cast iron for machine tool applications. Mater Design 2007; 28: 1461–1466.

Wan

Huang

. Tribological properties of three-dimensional braided carbon/kevlar/epoxy hybrid composites under dry and lubricated conditions. Mat Sci Eng A 2007; 452–453: 202–209.

Choi

Yuan

. Experimental relationship between splitting tensile strength and compressive strength of GFRC and PFRC. Cement Concrete Res 2005; 35: 1587–1591.

Chandradass

Bae

D-S

. Preparation and properties of barium titanate nanopowder/epoxy composites. Mater Manuf Process 2008; 23: 116–122.

Thomason

. The influence of fiber length, diameter and concentration on the modulus of glass fiber reinforced polyamide. Compos Part A 2008; 39: 1732–1738.

Muthukumar

Mohan

. Studies on polymer concretes based on optimized aggregate mix proportion. J Europen Polym 2004; 40: 2167–2177.

Callaghan

Vaziri

Hamid

. Effect of fiber volume fraction and length on the wear characteristics of glass fiber-reinforced dental composites. Dent Mater 2006; 22: 84–93.

10.

Aiello

Ombres

. Cracking analysis of FRP-reinforced concrete flexural members. Mech Compos Mater 2000; 36: 389–394.

11.

Gould

Harmon

. Confined concrete columns subjected to axial load, cyclic shear, and cyclic flexure-part I: Analytical Models. J ACI Struct 2002; 99: 32–41.

12.

Wang

Zureick

A-H

Cho

B-S

. Properties of fiber reinforced concrete using recycled fibres from carpet industrial waste. J Mater Sci 1994; 29: 4191–4199.

13.

Febo

Severini

Leonardo

Formaro

Mario

Pegoraro

Luca

Posca

. Chemical modification of carbon fiber surfaces. Carbon 2002; 40: 735–741.

14.

Wang

. Effect of inclining angles, bundling and surface treatment on synthetic fiber pull-out from cement matrix. Composites 1990; 21: 132–140.

15.

Hegemier

Murakami

. On global shear transfer across a crack or joint plane penetrated by continuous fiber reinforcement with application to reinforced concrete. J Solids Struct 1990; 26: 1115–1131.

16.

Sujivorakul

Waas

Naaman

. Pullout response of a smooth fiber with an end anchorage. J Engine Mech 2000; 12: 986–993.

Mechanical properties of Mo fiber-reinforced resin mineral composites

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