Degradation of torsional behaviors of 3-D braided thin-walled tubes after atmospheric thermal ageing

Degradations of torsional behavior is a key issue to the evaluation of the 3-D braided tubes in thermal-oxidizing environment for a long-term service. Here we report the effect of thermal oxygen ageing on torsional behaviors of 3-D carbon fiber/epoxy resin braided composite tubes. The torsional behaviors of the 3-D braided tubes were quasi-statically tested after ageing at 110 degrees C and 180 degrees C for 8, 16 and 32 days respectively. Three-dimensional digital image correlation (3D-DIC) technique was used to display shear strain distribution. A microstructure finite element analysis (FEA) model was established to reveal the torsional damage mechanisms. We found that both temperature rise and ageing time extension will decrease the shear modulus and torque strength. Temperature has a greater influence on modulus and torque strength degradation than ageing time does. Ageing at 110 degrees C, resin crack and yarn breakage are the main torsional damages, while at 180 degrees C, yarn pull-out emerges as a further torsional damage.

Automated summary

Both temperature rise and ageing time extension will decrease the shear modulus and torque strength, with temperature having a greater influence on modulus and torque strength degradation than ageing time. Ageing at different temperatures results in different torsional damages, such as resin crack and yarn breakage at 110 degrees C and yarn pull-out at 180 degrees C.