X.J. Xian scite author profile

Bamboo reinforced epoxy possesses reasonably good properties to warrant its use as a structural material, and is fabricated by utilizing bamboo, an abundant material resource, in the technology of fibre composites. Literature on bamboo-plastics composites is rare.This work is an experimental study of unidirectional bamboo-epoxy laminates of varying laminae number, in which tensile, compressive, flexural and interlaminar shear properties are evaluated. Further, the disposition of bamboo fibre, the parenchymatous tissue, and the resin matrix under different loading conditions are examined. Our results show that the specific strength and specific modulus of bamboo-epoxy laminates are adequate, the former being 3 to 4 times that of mild steel. Its mechanical properties are generally comparable to those of ordinary glass-fibre composites. The fracture behaviour of bamboo-epoxy under different loading conditions were observed using both acoustic emission techniques and scanning electron microscopy. The fracture mode varied with load, the fracture mechanism being similar to glass and carbon reinforced composites. Microstructural analyses revealed that natural bamboo is eligibly a fibre composite in itself; its inclusion in a plastic matrix will help solve the problems of cracking due to desiccation and bioerosion caused by insect pests. Furthermore, the thickness and shape of the composite can be tailored during fabrication to meet specific requirements, thereby enabling a wide spectrum of applications.

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Compressive and flexural behavior of ultra-high-modulus polyethylene fiber and carbon fiber hybrid composites

Xian

Choy

et al. 1999

Composites Science and Technology

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Fatigue fracture behaviour of carbon-fiber-reinforced modified bismaleimide composites

Xian

Choy

1994

Composites Science and Technology

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The interlaminar fracture behaviour and toughening mechanisms of new carbon fibre-reinforced bismaleimide composites

Xian

Choy

1995

Composites

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The interlaminar fracture behaviour of carbon fibre-reinforced bismaleimide (BMI) composites prepared by using a new modified BMI matrix has been investigated by various methods. Laminates of three typical stacking sequences were evaluated. Double cantilever beam, end-notch flexure and edge-delamination tension tests were conducted under conventional conditions and in a scanning electron microscope. The strain energy release rates in Mode I and Mode II, G~ and G,~, as well as the total strain energy release rate, Gin,., have becn determined and found to be higher than those for laminates with an epoxy matrix. Dynamic delamination propagation was also studied. The toughening mechanisms are discussed.

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X.J. Xian

Analyses of the mechanical properties and microstructure of bamboo-epoxy composites

Compressive and flexural behavior of ultra-high-modulus polyethylene fiber and carbon fiber hybrid composites

Fatigue fracture behaviour of carbon-fiber-reinforced modified bismaleimide composites

The interlaminar fracture behaviour and toughening mechanisms of new carbon fibre-reinforced bismaleimide composites

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