Characterization of the mixed-mode interlaminar fracture toughness of an additive manufacturing continuous carbon fiber reinforced-thermoplastic composite

Jonnathan D. Santos; Sakineh Fotouhi; José M. Guerrero; Norbert Blanco

doi:10.1002/pc.29943

Characterization of the mixed-mode interlaminar fracture toughness of an additive manufacturing continuous carbon fiber reinforced-thermoplastic composite

Jonnathan D. Santos
, Sakineh Fotouhi
, José M. Guerrero
, Norbert Blanco

Grupo de Investigación Análisis y Tecnología de Estructuras en Ingeniería (ATEI)

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

1 Cita (Scopus)

Resumen

There is a lack of knowledge concerning the interlaminar fracture toughness under mixed-mode ratios of 3D-printed composites. In this work, several additive manufacturing (AM) continuous Fiber Reinforced Thermoplastic (cFRT) specimens have been tested to characterize the initiation and propagation of interlaminar fracture toughness under three different mixed-mode G_II/(G_I + G_II) ratios: 25, 50, and 75%. The results obtained do not exhibit the common tendency seen in traditional laminated composite materials, in which the fracture toughness increases with the mixed-mode ratio. While the fracture toughness for the 50% mixed-mode ratio falls between the corresponding mode I and mode II values, the fracture toughness for the 25% and 75% ratios falls outside this range. To provide a reasonable explanation, fractography and microstructure analyses were conducted to quantify fiber, matrix, and void contents. It was concluded that this uncommon behavior is probably related to the intrinsic variability of the material and manufacturing process. Highlights: Continuous fibers improve mechanical properties of 3D-printed composite parts. Delamination is a critical failure mode for laminated composite materials. Characterization of mixed-mode delamination is key for simulation and design. First complete study of mixed-mode delamination for 3D-printed composites.

Idioma original	Inglés
Páginas (desde-hasta)	13480-13495
Número de páginas	16
Publicación	Polymer Composites
Volumen	46
N.º	14
DOI	https://doi.org/10.1002/pc.29943
Estado	Publicada - 10 oct. 2025

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Publisher Copyright:
© 2025 The Author(s). Polymer Composites published by Wiley Periodicals LLC on behalf of Society of Plastics Engineers.

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10.1002/pc.29943

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Evaluación del Desempeño Estructural de la Fractura de Materiales de Ingeniería con Fibras Cerámicas Ligeras para Refuerzo de Elementos Estructurales
Santos Benitez, J. D. (Investigador principal), Curay Flores, A. J. (Estudiante Investigador), Avilés Montero, D. F. (Estudiante Investigador), Crespo Beltran, F. M. (Estudiante Investigador), Aviles Diaz, N. E. (Investigador Secundario), Montalvo Cedillo, C. A. (Investigador Secundario), Vallejo Bojorque, M. A. (Investigador Secundario), Jurado Mogrovejo, J. C. (Investigador Secundario), Reinoso Piscocama, P. G. (Estudiante Investigador), Jarama Guambaña, J. O. (Estudiante Investigador), Guiracocha Pulla, S. M. (Estudiante Investigador), Espinoza Pesantez, A. S. (Estudiante Investigador), Carpio Chuchuca, E. H. (Estudiante Investigador), Arcentales Auquilla, V. E. (Estudiante Investigador), Santos Patiño, L. F. (Estudiante Investigador), Cardenas Arichabala, J. V. (Estudiante Investigador), Mejia Carpio, I. A. (Estudiante Investigador), Orellana Angamarca, V. M. (Estudiante Investigador), Hurtado Minchala, A. B. (Estudiante Investigador), Serpa Duy, C. V. (Investigador Secundario), Kuja Vega, S. A. (Estudiante Investigador) & Sanchez Puente, G. S. (Estudiante Investigador)
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title = "Characterization of the mixed-mode interlaminar fracture toughness of an additive manufacturing continuous carbon fiber reinforced-thermoplastic composite",

abstract = "There is a lack of knowledge concerning the interlaminar fracture toughness under mixed-mode ratios of 3D-printed composites. In this work, several additive manufacturing (AM) continuous Fiber Reinforced Thermoplastic (cFRT) specimens have been tested to characterize the initiation and propagation of interlaminar fracture toughness under three different mixed-mode GII/(GI + GII) ratios: 25, 50, and 75\%. The results obtained do not exhibit the common tendency seen in traditional laminated composite materials, in which the fracture toughness increases with the mixed-mode ratio. While the fracture toughness for the 50\% mixed-mode ratio falls between the corresponding mode I and mode II values, the fracture toughness for the 25\% and 75\% ratios falls outside this range. To provide a reasonable explanation, fractography and microstructure analyses were conducted to quantify fiber, matrix, and void contents. It was concluded that this uncommon behavior is probably related to the intrinsic variability of the material and manufacturing process. Highlights: Continuous fibers improve mechanical properties of 3D-printed composite parts. Delamination is a critical failure mode for laminated composite materials. Characterization of mixed-mode delamination is key for simulation and design. First complete study of mixed-mode delamination for 3D-printed composites.",

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note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Polymer Composites published by Wiley Periodicals LLC on behalf of Society of Plastics Engineers.",

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Characterization of the mixed-mode interlaminar fracture toughness of an additive manufacturing continuous carbon fiber reinforced-thermoplastic composite. / Santos, Jonnathan D.; Fotouhi, Sakineh; Guerrero, José M. et al.
En: Polymer Composites, Vol. 46, N.º 14, 10.10.2025, p. 13480-13495.

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

TY - JOUR

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AU - Santos, Jonnathan D.

AU - Fotouhi, Sakineh

AU - Guerrero, José M.

AU - Blanco, Norbert

PY - 2025/10/10

Y1 - 2025/10/10

N2 - There is a lack of knowledge concerning the interlaminar fracture toughness under mixed-mode ratios of 3D-printed composites. In this work, several additive manufacturing (AM) continuous Fiber Reinforced Thermoplastic (cFRT) specimens have been tested to characterize the initiation and propagation of interlaminar fracture toughness under three different mixed-mode GII/(GI + GII) ratios: 25, 50, and 75%. The results obtained do not exhibit the common tendency seen in traditional laminated composite materials, in which the fracture toughness increases with the mixed-mode ratio. While the fracture toughness for the 50% mixed-mode ratio falls between the corresponding mode I and mode II values, the fracture toughness for the 25% and 75% ratios falls outside this range. To provide a reasonable explanation, fractography and microstructure analyses were conducted to quantify fiber, matrix, and void contents. It was concluded that this uncommon behavior is probably related to the intrinsic variability of the material and manufacturing process. Highlights: Continuous fibers improve mechanical properties of 3D-printed composite parts. Delamination is a critical failure mode for laminated composite materials. Characterization of mixed-mode delamination is key for simulation and design. First complete study of mixed-mode delamination for 3D-printed composites.

AB - There is a lack of knowledge concerning the interlaminar fracture toughness under mixed-mode ratios of 3D-printed composites. In this work, several additive manufacturing (AM) continuous Fiber Reinforced Thermoplastic (cFRT) specimens have been tested to characterize the initiation and propagation of interlaminar fracture toughness under three different mixed-mode GII/(GI + GII) ratios: 25, 50, and 75%. The results obtained do not exhibit the common tendency seen in traditional laminated composite materials, in which the fracture toughness increases with the mixed-mode ratio. While the fracture toughness for the 50% mixed-mode ratio falls between the corresponding mode I and mode II values, the fracture toughness for the 25% and 75% ratios falls outside this range. To provide a reasonable explanation, fractography and microstructure analyses were conducted to quantify fiber, matrix, and void contents. It was concluded that this uncommon behavior is probably related to the intrinsic variability of the material and manufacturing process. Highlights: Continuous fibers improve mechanical properties of 3D-printed composite parts. Delamination is a critical failure mode for laminated composite materials. Characterization of mixed-mode delamination is key for simulation and design. First complete study of mixed-mode delamination for 3D-printed composites.

KW - 3-D printing

KW - fracture toughness

KW - mechanical testing

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Characterization of the mixed-mode interlaminar fracture toughness of an additive manufacturing continuous carbon fiber reinforced-thermoplastic composite

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Evaluación del Desempeño Estructural de la Fractura de Materiales de Ingeniería con Fibras Cerámicas Ligeras para Refuerzo de Elementos Estructurales

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