Theoretical and experimental evaluation of double-notch shear strength of G-10CR glass-cloth/epoxy laminates at cryogenic temperatures

Article Abstract:

Theoretical and experimental characterizations were used to study the cryogenic interlaminar shear behavior of G-10CR glass-cloth/epoxy laminates. Measurements of the interlaminar shear strength of glass-cloth/epoxy laminates at low temperatures were done through the use of the double-notch shear test. The effect of specimen thickness and notch separation on the shear stress distribution in the expected fracture plane was investigated by means of a three-dimensional finite element analysis.

Research, Composite materials, Low temperature engineering, Cryogenics, Laminated materials, Laminates, Materials at low temperatures, Low temperature materials

---

Analytical and experimental studies of short-beam interlaminar shear strength of G-10CR glass-cloth/epoxy laminates at cryogenic temperatures

Article Abstract:

Cryogenic interlaminar beam tests in the form of three-point flexure are examined both experimentally and analytically. The maximum shear stress at the mid-plane for the specimens failed in pure shear appears to be a true indication of the cryogenic interlaminar shear strength of the short-beam specimen.

Measurement, Beams (Structural), Mechanical properties

---

Similar abstracts:

• Abstracts: Double cantilever beam measurement and finite element analysis of cryogenic mode I interlaminar fracture toughness of glass-cloth/epoxy laminates
• Abstracts: Determination of friction coefficient by employing the ring compression test. Finite element modeling of chip formation in the domain of negative rake angle cutting
• Abstracts: A study of beta processing of Ti-6Al-4V: is it trivial? Microstructural characterization of ultrasonically welded aluminum
• Abstracts: Modified anisotropic Gurson yield criterion for porous ductile sheet metals. Stress-based forming limits in sheet-metal forming
• Abstracts: The effects of tooling imperfections on the initiation of wrinkling in finite element modeling of a deep drawing process

This website is not affiliated with document authors or copyright owners. This page is provided for informational purposes only. Unintentional errors are possible.