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Quasi-brittle failure is a phenomenon, which is characterized by the development
of a nonlinear fracture process zone in front of the crack tip with a finite
size compared to the overall structural dimensions. This process zone involves
various microscopic activities during a loading process, which categorizes into
different stages, such as nucleation and growth of microcracks, localization
of these microcracks in a narrow process zone, and at last, the coalescence
between the active set of densely distributed microcracks which leads to the
formation of a macroscopic stress-free crack front. This material degradation
process induces a typical nonlinear response with a small pre-peak hardening
region, followed by a softening phase. A wide range of materials exhibits
this type of material behavior, such as concrete, rock, bone, ice, and various
composites, making failure analysis in quasi-brittle materials an emerging and
critical research domain. Various models based on smeared and discrete numerical
framework are available in the literature that provides extensive numerical
capabilities to address this type of failure phenomenon with some limitations.
A smeared or continuous approach to failure introduces an intrinsic internal
length scale that smears out the crack over a certain width, limiting their applications
to problems requiring an explicit representation of a crack. Conversely,
discontinuous or discrete approaches explicitly represent a crack topology but
require additional ad-hoc criteria for crack initiation and propagation. This
thesis aims to develop a coherent computational framework that combines the advantages of both approaches and uses a continuous-discontinuous failure
description to model the complete quasi-brittle failure process in a single FE
analysis.
The initial focus is to develop an improved gradient-enhanced nonlocal
damage framework that captures inelastic material behavior in quasi-brittle
solids, which includes crack initiation, crack propagation, and other material
instabilities. Some of the key objectives are to obtain regularized solutions
with sharp damage profiles with maximum damage in front of the crack tip
while addressing the limitations of damage models available in the literature.
Two gradient damage models have already been proposed to this contribution,
which uses smoothed and micromorphic stress-based anisotropic interaction
tensors to govern the spatial diffusive behavior. The damage models are based
on a generalized micromorphic approach where fine-scale fluctuations due
to interactions within the diffused network of micro-cracks in the fracture
process zone are reflected at the macro-scale via incorporating a regularization
process using an internal length scale through an additional microforce balance
equation. The damage models are tested on various numerical examples and
found to circumvent the limitations of conventional damage models by ensuring
correct damage bandwidths using low-order finite elements during numerical
simulations.
The next part of the thesis presents a continuous-discontinuous computational
framework that provides a discontinuous character to the quasi-brittle
fracture process, modeled in a continuous setting using a gradient-enhanced
nonlocal damage framework. The continuous-discontinuous FE framework is
developed where the problem field is enhanced using discontinuous interpolation
exploiting the local partition of unity via eXtended Finite Element (XFEM)
approach, thereby extending the numerical kinematics of the localizing gradient
damage framework to provide a continuous-discontinuous failure description.
The enhanced kinematics of the proposed continuous-discontinuous formulation
helps to successfully eliminate the issue of damage spreading during the final failure stages, with crack paths consistent with the experimental observations.
A new path-following arc-length control Newton-Raphson solution scheme
based on the internal and dissipated energy rates is developed to trace the
nonlinear structural response in the presence of snapbacks.
Finally, the last part of this thesis work focuses on applying the
developed numerical methodologies to various engineering structural failure
problems for materials exhibiting quasi-brittle failure phenomena. Some
of the applications include capturing the structural size-effect in concrete
structures and modeling anisotropic damage evolution in composite materials.
The objective to capture the structural size-effect phenomenon is fulfilled by
reproducing the results of experimental investigations using a single set of
material and numerical parameters. Whereas, a finite element formulation
based on a anisotropic gradient-enhanced continuum damage model is proposed
to address anisotropic damage evolution due to progressive intra-laminar
fracture in a composite layered materials using distinct damage variables
associated with different failure modes. A few benchmark problems are taken
from the literature to test the applicability and robustness of the anisotropic
damage model. |
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