The influence of interphase regions on local thermal displacements in composites
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Cited by (39)
Thermomechanical characterisation of a thermoplastic polymer and its short glass fibre reinforced composite: Influence of fibre, fibre orientation, strain rates and temperatures
2024, Composites Part A: Applied Science and ManufacturingStructure insight into the interfacial effect of fiber-low density polyethylene composites by the combination of experiment and finite element simulation
2022, Polymer TestingCitation Excerpt :An interface is usually considered to be notably physical or chemical changes between the matrix and reinforcement. Accordingly, complicated changes occur in the implementation of the composite, such chemical reactions, volumetric changes, residual stresses [17]. But traditionally the interface, deemed to be extremely thin, while the corresponding reinforcement and matrix are isotropic and homogeneous.
A review of analytical models to describe pull-out behavior – Fiber/matrix adhesion
2018, Composite StructuresCitation Excerpt :Therefore, it appears very difficult to assign mechanical properties to it. In contrast, the interphase is the geometrical surface of the classic fiber-matrix contact as well as the region of finite volume extending therefrom, wherein the chemical, physical and mechanical properties vary either continuously or in a stepwise manner between those of the bulk fiber and matrix material [3]. In other words, the interphase exists from some point in the fiber through the actual interface into the matrix, embracing all the volume altered during the consolidation or fabrication process from the original fiber and matrix materials.
Mechanical model of giant photoexpansion in a chalcogenide glass and the role of photofluidity
2017, Physica B: Condensed MatterMultiscale modeling of regularly staggered carbon fibers embedded in nano-reinforced composites
2017, European Journal of Mechanics, A/SolidsCitation Excerpt :In the case of three-phase shear lag model, a thin interphase formed as a result of chemical interactions between the fiber and the matrix, is considered. The chemical composition of such interphase differs from both the fiber and matrix constituents but its mechanical properties lie between these two (Drzal, 1986; Kundalwal and Meguid, 2015; Sottos et al., 1992), and such nanoscale interphase has a marginal influence on the bulk elastic properties of a composite. On the other hand, a third phase (that is, relatively thick interphase) made of different material can be engineered between the fiber and the matrix (Kundalwal et al., 2014; Ray and Kundalwal, 2014).
Multiscale modeling of stress transfer in continuous microscale fiber reinforced composites with nano-engineered interphase
2016, Mechanics of MaterialsCitation Excerpt :In the case of three-cylinder pull-out model, a thin layer of interphase, formed as a result of physical and chemical interactions between the fiber and the matrix, is considered. The chemical composition of such an interphase differs from both the fiber and matrix materials but its mechanical properties lie between those of the fiber and the matrix (Drzal, 1986; Sottos et al., 1992; Kundalwal and Meguid, 2015), and such nanoscale interphase has a marginal influence on the bulk elastic properties of a composite. On the other hand, a relatively thick interphase can be engineered between the fiber and the matrix, especially a third phase made of different material than the main constituent phases (see for e.g. Liljenhjerte and Kumar, 2015).