成形加工 34 巻, 5 号

X 線マイクロ CT を用いた GFRP 内部のガラス繊維配向解析 : スプライン曲線フィッティングによる曲率を有する繊維への対応

It is important to know the distribution of the length and orientation of glass fibers (GFs) in GFRP moldings to predict their warpage. In our previous study, we developed a method to extract GFs one-by-one from 3-dimensional data acquired with X-ray micro CT using straightcylinder model fitting. However, there are curved fibers in many cases and we could not extract them correctly. In this study, we modified our fitting model to a curved-cylinder one with a splinecurve axis to also extract the curved fibers correctly.

レーザーラマン分光法を用いたポリスチレン射出成形品の分子配向解析

In this study, we analyzed the molecular orientation in injection molded polystyrene using laser Raman spectroscopy. We evaluated the degree of molecular orientation according to the peak intensity ratio at 1000 cm^-1 and 620 cm^-1 (I₁₀₀₀/I₆₂₀), with the flow direction of the injection moldings set at 45° relative to the laser polarization plane in a crossed Nicols configuration. In addition, we determined whether the orientation was parallel or orthogonal to the flow by measuring I₁₀₀₀/I₆₂₀ while varying the angle between the flow and the polarization plane of the Raman analyzer, with the flow direction set at 45° to the laser polarization plane. Furthermore, we analyzed the direction of molecular orientation in detail by measuring I₁₀₀₀/I₆₂₀ in a crossed Nicols configuration while varying the angle between the flow and the laser polarization plane. These methods showed that the molecular orientation inside the polystyrene injection moldings was highest around 200μm from the surface, and the orientation gradually decreased from there to around 400μm. There was almost no change in the molecular orientation from 400μm to the center of the moldings. Overall, the orientation inside the moldings was almost parallel to the flow. The molecular orientation at a depth of 400μm or more from the surface was also relaxed through heat treatment below the glass transition temperature (T_g). We suggest that the relaxation of the residual molecular orientation at a depth of 400μm or more during heating below T_g affects dynamic viscoelasticity and thermal deformation.