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References (18)
-
Hiroyuki Ueda, A. Moriyama, H. Iwahashi, H. Moritomi (2020)
Organizational issues for disseminating recycling technologies of carbon fiber-reinforced plastics in the Japanese industrial landscapeJournal of Material Cycles and Waste Management, 23
-
Mizuki Ono, M. Yamane, S. Tanoue, H. Uematsu, Y. Yamashita (2021)
Mechanical Properties of Thermoplastic Composites Made of Commingled Carbon Fiber/Nylon FiberPolymers, 13
-
A. Vedernikov, A. Safonov, F. Tucci, P. Carlone, I. Akhatov (2020)
Pultruded materials and structures: A reviewJournal of Composite Materials, 54
-
Vijay Goud, R. Alagirusamy, A. Das, D. Kalyanasundaram (2018)
Dry Electrostatic Spray Coated Towpregs for Thermoplastic CompositesFibers and Polymers, 19
-
(2021)
Commingled composites -
I. Baran, C. Tutum, J. Hattel (2013)
Reliability Estimation of the Pultrusion Process Using the First-Order Reliability Method (FORM)Applied Composite Materials, 20
-
M. Ghaedsharaf, J. Brunel, L. Lebel (2021)
Multiscale numerical simulation of the forming process of biaxial braids during thermoplastic braid-trusion: Predicting 3D and internal geometry and fiber orientation distributionComposites Part A: Applied Science and Manufacturing
-
J. Tate, A. Kelkar, J. Whitcomb (2006)
Effect of braid angle on fatigue performance of biaxial braided compositesInternational Journal of Fatigue, 28
-
Weihao Liu, Haihong Huang, Libin Zhu, Zhifeng Liu (2021)
Integrating carbon fiber reclamation and additive manufacturing for recycling CFRP wasteComposites Part B-engineering, 215
-
N. Alsinani, M. Ghaedsharaf, L. Lebel (2021)
Effect of cooling temperature on deconsolidation and pulling forces in a thermoplastic pultrusion processComposites Part B-engineering, 219
-
S. Takeda, Jonathon Tanks, S. Sugimoto, Y. Iwahori (2020)
Application of sheet-like energy directors to ultrasonic welding of carbon fibre-reinforced thermoplasticsAdvanced Composite Materials, 30
-
P. Novo, J. Silva, J. Nunes, A. Marques (2016)
Pultrusion of fibre reinforced thermoplastic pre-impregnated materialsComposites Part B-engineering, 89
-
E. Mäder, J. Rausch, N. Schmidt (2008)
Commingled yarns : Processing aspects and tailored surfaces of polypropylene/glass compositesComposites Part A-applied Science and Manufacturing, 39
-
Haowen Wei, W. Nagatsuka, Hooseok Lee, I. Ohsawa, K. Sumimoto, Y. Wan, J. Takahashi (2018)
Mechanical properties of carbon fiber paper reinforced thermoplastics using mixed discontinuous recycled carbon fibersAdvanced Composite Materials, 27
-
G. Ben, A. Hirabayashi, Y. Kawazoe (2013)
Evaluation of quasi-isotropic plate and cylindrical shell fabricated with green composite sheetsAdvanced Composite Materials, 22
-
J. Koyanagi, Maruri Takamura, Kodai Wakayama, Kotaro Uehara, Shinichi Takeda (2020)
Numerical simulation of ultrasonic welding for CFRP using energy directorAdvanced Composite Materials, 31
-
Vijay Goud, R. Alagirusamy, A. Das, D. Kalyanasundaram (2019)
Influence of various forms of polypropylene matrix (fiber, powder and film states) on the flexural strength of carbon-polypropylene compositesComposites Part B: Engineering
-
W. Grouve, Francisco Sacchetti, Evan Vruggink, R. Akkerman (2020)
Simulating the induction heating of cross-ply C/PEKK laminates – sensitivity and effect of material variabilityAdvanced Composite Materials, 30
- Publisher
- Taylor & Francis
- Copyright
- © 2023 Japan Society for Composite Materials, Korean Society for Composite Materials and Informa UK Limited, trading as Taylor & Francis Group
- ISSN
- 0924-3046
- eISSN
- 1568-5519
- DOI
- 10.1080/09243046.2023.2207843
- Publisher site
- See Article on Publisher Site
Abstract
Pultrusion molding is one of the high-cycle molding methods for continuous fiber-reinforced plastics using thermoplastic resin, and considering the expansion of industrial applications, shaped parts, such as pipes and L-shapes are more desirable. The following is an example of a product that can be used to achieve this goal. Braided fabrics are one of the most useful preforms for achieving pipe shapes. In this study, commingled yarns and partially impregnated commingled yarns were used as intermediate materials, because excellent impregnation properties and textile workability are required to the fabrication and pultrusion molding of the braided fabrics. However, when forming a pipe shape by pultrusion, the mandrel must be placed in the hollow of the molded product, which causes an increase in pull-out resistance due to shrinkage of the pipe diameter. To solve this problem and achieve high-speed molding of pipe-shaped products by pultrusion molding, this study examined the effects of different intermediate materials and molding conditions on the impregnation state and mechanical properties of molded products, as well as the optimization of the mandrel location. The first part of this study revealed that the impregnation time of partially impregnated commingled yarns is shorter than that of commingled yarns, and as a result, the decrease in void ratio and unimpregnated ratio is smaller, and the decrease in mechanical properties is smaller even if the molding speed is increased. The second part of this study, it was found that the mandrel tip should be positioned so that the temperature of the inner diameter side becomes lower than glass-transition temperature (Tg) during cooling to prevent separating. In addition, it was found that temperature history analysis based on heat conduction calculations is effective in predicting the optimum mandrel position, which varies depending on molding conditions. These results provide a guideline for high-speed pultrusion molding.
Journal
Advanced Composite Materials – Taylor & Francis
Published: Jan 2, 2024
Keywords: Pultrusion molding; continuous fiber reinforced thermoplastic composites; commingled yarn; partially impregnated commingled yarn; braided composite pipe