Electromechanical phase-field fracture modelling of piezoresistive CNT-based composites
Metadatos
Mostrar el registro completo del ítemEditorial
Elsevier
Materia
Carbon nanotubes (CNTs) Finite Element Analysis Smart materials Fracture Phase field Piezoresistivity
Fecha
2023Referencia bibliográfica
L. Quinteros, E. García-Macías and E. Martínez-Pañeda. Electromechanical phase-field fracture modelling of piezoresistive CNT-based composites. Comput. Methods Appl. Mech. Engrg. 407 (2023) 115941 [https://doi.org/10.1016/j.cma.2023.115941]
Patrocinador
National Agency for Research and Development (ANID), Chile/Scholarship Program/DOCTORADO BECAS CHILE/2020 - 72210161; Consejería de Transformación Económica, Conocimiento, Empresas y Universidades de la Junta de Andalucía (Spain) through the research project P18-RT-3128; UKRI Future Leaders Fellowship (grant MR/V024124/1)Resumen
We present a novel computational framework to simulate the electromechanical response of self-sensing carbon nanotube (CNT)-based composites experiencing fracture. The computational framework combines electrical-deformation-fracture finite element modelling with a mixed micromechanics formulation. The latter is used to estimate the constitutive properties of CNT-based composites, including the elastic tensor, fracture energy, electrical conductivity, and linear piezoresistive coefficients. These properties are inputted into a coupled electro-structural finite element model, which simulates the evolution of cracks based upon phase-field fracture. The coupled physical problem is solved in a monolithic manner, exploiting the robustness and efficiency of a quasi-Newton algorithm. 2D and 3D boundary value problems are simulated to illustrate the potential of the modelling framework in assessing the influence of defects on the electromechanical response of meso- and macro-scale smart structures. Case studies aim at shedding light into the interplay between fracture and the electromechanical material response and include parametric analyses, validation against experiments and the simulation of complex cracking conditions (multiple defects, crack merging). The presented numerical results showcase the efficiency and robustness of the computational framework, as well as its ability to model a large variety of structural configurations and damage patterns. The deformation-electrical-fracture finite element code developed is made freely available to download.