Multified-based modeling of material failure in high performance reinforced cementitious composites

Revision as of 16:30, 17 October 2017

Abstract

Cementitious materials such as mortar or concrete are brittle and have an inherent weakness in resisting tensile stresses. The addition of discontinuous fibers to such matrices leads to a dramatic improvement in their toughness and remedies their deficiencies. It is generally agreed that the fibers contribute primarily to the post-cracking response of the composite by bridging the cracks and providing resistance to crack opening (Suwaka & Fukuyama 2006).

On the other hand, the multifield theory is a mathematical tool able to describe materials which contain a complex substructure (Mariano & Stazi 2005). This substructure is endowed with its own properties and it interacts with the macrostructure and influences drastically its behavior. Under this mathematical framework, materials such as cement composites can be seen as a continuum with a microstructure. Therefore, the whole continuum damage mechanics theory, incorporating a new microstructure, is still applicable.

A formulation, initially based on the theory of continua with microstructure Capriz (Capriz 1989), has been developed to model the mechanical behavior of the high performance fiber cement composites with arbitrarily oriented fibers. This formulation approaches a continuum with microstructure, in which the microstructure takes into account the fibermatrix interface bond/slip processes, which have been recognized for several authors (Li 2003, Naaman 2007b) as the principal mechanism increasing the ductility of the quasi-brittle cement response. In fact, the interfaces between the fiber and the matrix become a limiting factor in improving mechanical properties such as the tensile strength. Particularly, in short fiber composites is desired to have a strong interface to transfer effectively load from the matrix to the fiber. However, a strong interface will make difficult to relieve fiber stress concentration in front of the approaching crack. According to Naaman (Naaman 2003), in order to develop a better mechanical bond between the fiber and the matrix, the fiber should be modified along its length by roughening its surface or by inducing mechanical deformations. Thus, the premise of the model is to take into account this process considering a microfield that represents the slipping fiber-cement displacement. The conjugate generalized stress to the gradient of this micro-field verifies a balance equation and has a physical meaning.

This contribution includes the computational modeling aspects of the high fiber reinforced cement composites (HFRCC) model. To simulate the composite material, a finite element discretization is used to solve the set of equations given by the multifield approach for this particular case. A two field discretization: the standard macroscopic and the microscopic displacements, is proposed through a mixed finite element methodology. Furthermore, a splitting procedure for uncoupling both fields is proposed, which provides a more convenient numerical treatment of the discrete equation system.

The initiation of failure in HPFRCC at the constitutive level identified as the onset of strain localization depends on the mechanical properties of the all compounds and not only on the matrix ones. As localization criteria is considered the bifurcation analysis in combination with the localized strain injection technique presented by Oliver et al. (Oliver et al. 2010a). It consists of injecting a specific localization mode during the localization stage, via mixed finite element formulations, to the path of elements that are going to capture the cracks, and, in this way, the spurious mesh orientation dependence is removed.

Model validation was performed using a selected set of experiments that proves the viability of this approach. The numerical examples of the proposed formulation illustrated two relevant aspects, namely: 1) the role of the bonding mechanism in the strain hardening behavior after cracking in the HPFRCC and 2) the role that plays the finite element formulation in capturing the displacement localization in the localization stage.

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-==1 Title, abstract and keywords==
+==Abstract==
-Your document should start with a concise and informative title. Titles are often used in information-retrieval systems. Avoid abbreviations and formulae where possible. Capitalize the first word of the title.
+Cementitious materials such as mortar or concrete are brittle and have an inherent weakness in resisting tensile stresses. The addition of discontinuous fibers to such matrices leads to a
+dramatic improvement in their toughness and remedies their deficiencies. It is generally
+agreed that the fibers contribute primarily to the post-cracking response of the composite by
+bridging the cracks and providing resistance to crack opening (Suwaka & Fukuyama 2006).
-Provide a maximum of 6 keywords, and avoiding general and plural terms and multiple concepts (avoid, for example, 'and', 'of'). Be sparing with abbreviations: only abbreviations firmly established in the field should be used. These keywords will be used for indexing purposes.
+On the other hand, the multifield theory is a mathematical tool able to describe materials
+which contain a complex substructure (Mariano & Stazi 2005). This substructure is endowed
+with its own properties and it interacts with the macrostructure and influences drastically its
+behavior. Under this mathematical framework, materials such as cement composites can be
+seen as a continuum with a microstructure. Therefore, the whole continuum damage mechanics
+theory, incorporating a new microstructure, is still applicable.
-An abstract is required for every document; it should succinctly summarize the reason for the work, the main findings, and the conclusions of the study. Abstract is often presented separately from the article, so it must be able to stand alone. For this reason, references and hyperlinks should be avoided. If references are essential, then cite the author(s) and year(s). Also, non-standard or uncommon abbreviations should be avoided, but if essential they must be defined at their first mention in the abstract itself.
+A formulation, initially based on the theory of continua with microstructure Capriz
+(Capriz 1989), has been developed to model the mechanical behavior of the high performance
+fiber cement composites with arbitrarily oriented fibers. This formulation approaches
+a continuum with microstructure, in which the microstructure takes into account the fibermatrix
+interface bond/slip processes, which have been recognized for several authors (Li
+, Naaman 2007b) as the principal mechanism increasing the ductility of the quasi-brittle
+cement response. In fact, the interfaces between the fiber and the matrix become a limiting
+factor in improving mechanical properties such as the tensile strength. Particularly, in short
+fiber composites is desired to have a strong interface to transfer effectively load from the
+matrix to the fiber. However, a strong interface will make difficult to relieve fiber stress
+concentration in front of the approaching crack. According to Naaman (Naaman 2003), in
+order to develop a better mechanical bond between the fiber and the matrix, the fiber should
+be modified along its length by roughening its surface or by inducing mechanical deformations.
+Thus, the premise of the model is to take into account this process considering a microfield that represents the slipping fiber-cement displacement. The conjugate generalized stress
+to the gradient of this micro-field verifies a balance equation and has a physical meaning.
-==2 The main text==
+This contribution includes the computational modeling aspects of the high fiber reinforced
+cement composites (HFRCC) model. To simulate the composite material, a finite
+element discretization is used to solve the set of equations given by the multifield approach
+for this particular case. A two field discretization: the standard macroscopic and the microscopic
+displacements, is proposed through a mixed finite element methodology. Furthermore,
+a splitting procedure for uncoupling both fields is proposed, which provides a more convenient
+numerical treatment of the discrete equation system.
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+The initiation of failure in HPFRCC at the constitutive level identified as the onset of
+strain localization depends on the mechanical properties of the all compounds and not only
+on the matrix ones. As localization criteria is considered the bifurcation analysis in combination
+with the localized strain injection technique presented by Oliver et al. (Oliver et al.
+a). It consists of injecting a specific localization mode during the localization stage, via
+mixed finite element formulations, to the path of elements that are going to capture the
+cracks, and, in this way, the spurious mesh orientation dependence is removed.
-Most of the documents in Scipedia are written in English (write your manuscript in American or British English, but not a mixture of these). Anyhow, specific publications in other languages can be published in Scipedia. In any case, the documents published in other languages must have an abstract written in English.
+Model validation was performed using a selected set of experiments that proves the viability
+of this approach. The numerical examples of the proposed formulation illustrated two
+relevant aspects, namely: 1) the role of the bonding mechanism in the strain hardening behavior
+after cracking in the HPFRCC and 2) the role that plays the finite element formulation in
+capturing the displacement localization in the localization stage.
-===2.1 Subsections===
+[[Media:Draft_Samper_397495699_4385_M139.pdf|M139.pdf]]
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+==References==
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+See pdf document
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-{| style="margin: 1em auto 1em auto;border: 1pt solid black;border-collapse: collapse;"
-|-
-| style="text-align: center;"|Thickness
-| style="text-align: center;"|3.175 mm
-|-
-| style="text-align: center;"|Young Modulus
-| style="text-align: center;"|12.74 MPa
-|-
-| style="text-align: center;"|Poisson coefficient
-| style="text-align: center;"|0.25
-|-
-| style="text-align: center;"|Density
-| style="text-align: center;"|1107 kg/m<sup>3</sup>
-|}
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