Abstract
In this study, fiber breaking behavior, fiber orientation, length variation, and changes in melt flow ability of long glass fiber reinforced polypropylene (L-FRP) composites under different mold cavity geometry, melt fill path, and plasticization parameters were investigated. The matrix material used was polypropylene and the reinforcement fibers were 25 mm long. An ultra-long-fiber composite injection molding machine (with a three-stage plunger and injection mechanism design) was used with different mold cavity geometry and plasticization parameters. Different screw speeds were used to explore the changes in fiber length and to provide a reference for setting fiber length and parameter combinations. Flow-length specimen molds with different specimen thickness, melt fill path, and gate design were used to observe the effect of plasticizing properties on the flow ability of the L-FRP composite materials. The experimental results showed that the use of an injection molding machine with a mechanism that reduced the amount of fiber breakage was advantageous. It was also found that an increase in screw speed increased fiber breakage, and 25 mm long fibers were shortened by an average of 50% (to 10 mm). Long fibers were more resistant to melt filling than short fibers. In addition, the thickness of the specimen and the gate design were also found to affect the filling process. The rounded angle gate and thick wall product decreased the flow resistance and assisted the flow ability and fiber distribution of the L-FRP injection molding.
Highlights
Long-fiber reinforced polymer (L-FRP) composite injection molding has gained significant attention in recent years because of its many favorable characteristics, such as lightweight, low cost, good stiffness, high tensile modulus, and superior impact strength [1,2]
Kumar et al investigated the effects of the injection pressure and screw speed on two thermoplastics compounded with different initial fiber lengths [17,18,19,20]
As the screw speed increased, so did the shear rate, which caused more fibers to break during the plasticization process and reduced the fiber length
Summary
Long-fiber reinforced polymer (L-FRP) composite injection molding has gained significant attention in recent years because of its many favorable characteristics, such as lightweight, low cost, good stiffness, high tensile modulus, and superior impact strength [1,2]. The fibers can be damaged when the L-FRPs material is moved through a plasticization screw [10], and the injection molding of L-FRPs is not an easy job. This is made more complicated by the fact that the fiber orientation is determined by the flow process during injection. Injection-molded L-FRP specimens typically have a skin/shell/core structure [11], and fiber orientation in the loading direction is important for the modulus and strength of L-FRP composites. The results of this research can be applied to the manufacture of automobile and aircraft components that need both mechanical strength and a high tensile modulus
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