145 research outputs found
Matrix cracking in polymeric composites laminates: Modelling and experiments
Composites ability to retain functionality in the presence of damage is a crucial safety and economic issue. Generally the first damage mode in composite laminates is matrix cracking, which affects the mechanical properties of the structure long before its load-bearing capacity is exhausted. In this paper, a detailed analysis of the effect of matrix cracking on the behaviour of cross-ply [0/90]s and unbalanced symmetric [0/45]s glass/epoxy laminates loaded statically in tension is performed. Theoretical predictions of stiffness reduction due to damage are based on the Equivalent Constraint Model (ECM), which takes into account concurrent matrix cracking in all plies of the laminate, although matrix cracking under consideration is developing only within the off-axis ply of the laminates. The longitudinal Young’s modulus predictions are compared to experimentally derived data obtained using laser Raman spectroscopy (LRS). The good agreement between predicted and measured values of the reduced longitudinal Young’s modulus validates the ECM model and proves that its basic assumptions are accurate. Thus, the predictions for all the mechanical properties by the ECM model are within a realistic range, while experimental evidence is required for further validation
Production and mechanical characterization of graphene micro-ribbons
Patterning of graphene into micro- and nano-ribbons allows for the tunability
in emerging fields such as flexible electronic and optoelectronic devices, and
is gaining interest for the production of more efficient reinforcement for
composite materials. In this work we fabricate micro-ribbons from CVD graphene
by combining UV photolithography and dry etching oxygen plasma treatments.
Raman spectral imaging confirms the effectiveness of the patterning procedure,
which is suitable for large-area patterning of graphene on wafer-scale, and
confirms that the quality of graphene remains unaltered. The produced
micro-ribbons were finally transferred and embedded into a polymeric matrix and
the mechanical response was investigated by in-situ mechanical investigation
combining Raman spectroscopy and tensile/compressive tests
A mechanical system for tensile testing of supported films at the nanoscale
Standard tensile tests of materials are usually performed on freestanding specimens. However, such requirement is difficult to implement when the materials of interest are of nanoscopic dimensions due to problems related to their handling and manipulation. In the present paper, a new device is presented for tensile testing of thin nanomaterials, which allows tests to be carried out on specimens initially deposited onto a macroscopic pre-notched substrate. On loading, however, no substrate effects are introduced, allowing the films to be freely stretched. The results obtained from a variety of thin metal or polymeric films are very promising for the further development of this technique as a standard method for nanomaterial mechanical testin
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