Effect of Fabrication Conditions of Spread Commingled Yarns as Intermediate Materials for Molding on the Performance

• Published in: Journal of Textile Engineering Vol. 68; no. 5; pp. 77 - 85
• Main Authors: MOTOCHIKA, Toshihiro, OHISHI, Masaki, OHTANI, Akio, NAKAI, Asami
• Format: Journal Article
• Language: English; Japanese
• Published: Osaka The Textile Machinery Society of Japan 15.10.2022; Japan Science and Technology Agency
• Subjects: Boundary conditions; Carbon fibers; CFRP; Commingled yarn; Continuous fiber composites; Dispersion; Fiber reinforced polymers; Intermediate material; Mechanical properties; Recyclability; Reinforcing fibers; Thermoplastic composite; Thermoplastic resins; Thermosetting resins; Workability; Yarn; Yarns
• ISSN: 1346-8235; 1880-1986
• DOI: 10.4188/jte.68.77

In recent years, continuous fiber-reinforced thermoplastic composites have attracted attention for their high mechanical properties, secondary workability, and recyclability. However, it is not easy to impregnate thermoplastic resin into reinforcing fiber bundles because the melt viscosity of thermoplastic resin before curing is higher than that of thermosetting resin. One of the methods to solve this problem is to use intermediate materials, and this study focused on a commingled yarn by using the fiber tow spreading-commingling technology (hereinafter referred to as spread commingled yarn). In this study, spread commingled yarns were produced under different fabrication speed conditions, and the impregnation properties of molded products using the spread commingled yarns were investigated to obtain guidelines for high-speed production of highly impregnated spread commingled yarn. The effects of un-impregnation ratio of the molded products on the mechanical properties of the molded products were also investigated. The results of this study revealed that increasing the dispersion ratio of carbon and resin fibers was most important for the use of spread commingled yarn as an intermediate material for molding. In order to increase the dispersion ratio, it was important to increase the f/v value, which was the vibration frequency of the transducer divided by the spread commingled yarn production speed under conditions where the transducer and carbon fibers were in contact. The quantitative demonstration of the boundary condition that switch between contact and non-contact suggests a design guideline for improving the production rate of highly dispersed spread commingled yarn.