Mechanism investigation and comparison of long-term deformations caused by process-induced residual stresses in thermosetting CF/epoxy and thermoplastic CF/PAEK composite laminates
Kazuki Ryuzono, Sera Koo, Yamato Hoshikawa, Yoshiaki Kawagoe, Tomonaga Okabe
Abstract
This study experimentally and numerically investigated the mechanisms of process-induced deformations (PIDs) and subsequent long-term deformations (LTDs) in thermosetting CF/epoxy (T700G/2510) and thermoplastic CF/PAEK (T700G/LM-PAEK) aerospace-grade prepreg laminates. Warpage deformations in asymmetric cross-ply laminates after autoclave fabrication were measured over 84 days under controlled conditions (60 °C and 50%RH). A finite element analysis integrating anisotropic viscoelastic constitutive law and geometric nonlinearity was conducted to predict the PID and LTD using the material properties derived from the lamina-level thermomechanical analysis and dynamic mechanical analysis (DMA). The experimental results revealed that T700G/LM-PAEK exhibited a larger PID, which was attributed to its larger thermal strain and higher modulus during molding. In contrast, T700G/2510 exhibited a larger LTD, which was attributed to its higher sensitivity to moisture absorption. Although incorporating a moisture-sensitive shift factor was required for predicting the LTD of T700G/2510, the simulation accurately reproduced the PID and LTD for both materials. To validate the deformation simulation and provide insights into the viscoelastic behavior of the resin in aerospace-grade commercial prepregs with undisclosed chemical compositions, a self-consistent micromechanics model was further employed. This model estimated the equivalent viscoelastic properties of the resin from lamina-level DMA data. The findings demonstrated that both macroscale deformation prediction and microscale resin characterization can be achieved using only standard DMA tests on such prepregs. • Process-induced deformation (PID) and long-term deformation (LTD) are measured. • PID is larger in T700G/LM-PAEK (CF/PAEK); LTD is larger in T700G/2510 (CF/epoxy). • Temperature-dependent relaxation and thermal expansion explain the PID mechanism. • Moisture effects explain the LTD mechanism; T700G/LM-PAEK shows higher resistance. • Equivalent resin viscoelasticity of both prepregs is estimated using micromechanics.