Structural integrity during remanufacture of a topologically interlocked material

Mather, Adam N; Cipra, Raymond J.; Siegmund, Thomas

doi:10.1108/17579861211210009

Cited by 35 publications

(28 citation statements)

References 34 publications

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“…The present model only considers elastic deformation in the unit elements. As shown in Mather et al (2012), and based on the estimates of strain, this assumption can indeed be violated. Assuming an ultimate stress for ABS of 50.00 MPa and consequently an ultimate strain of 0.03, the model presented would at least predict the peak loads well, but would overestimate the amount of deflection to failure.…”

Section: Discussionmentioning

confidence: 93%

“…Dyskin et al (2003a) expanded and generalized this concept, and introduced the term topologically interlocked materials (TIM) for this class of low-dimensional materials created from individual unit elements interacting with each other by contact and embedded within a constraining framework. It has been demonstrated that TIMs can possess attractive mechanical properties including: (i) high damage tolerance (Dyskin et al, 2003b;Khor, 2008;Schaare et al, 2008), (ii) negative stiffness characteristics under certain loading conditions (Estrin et al, 2011;Schaare et al, 2008), (iii) variable stiffness as adjusted by control of constraint (Brugger et al, 2009;Dyskin et al, 2003b), (iv) quasi-ductile response obtained from brittle constituent materials (Dyskin et al, 2001(Dyskin et al, , 2003a and (v) remanufacturability (Mather et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

“…However, by employing a plate bending theory appropriate for a continuous solid, one does not account for the fact that no tensile stresses can be transmitted across the contact surfaces between the individual unit elements in a TIM. Also, a model for the characterization of the damage evolution in TIMs was developed in (Mather et al, 2012) by expanding previously developed models for prestressed mortar walls. This model explains the local conditions in the element-to-element contact, but fails to predict the overall characteristics of the TIMs.…”

Section: Introductionmentioning

confidence: 99%

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Transverse loading of cellular topologically interlocked materials

Khandelwal

Siegmund

Cipra

et al. 2012

International Journal of Solids and Structures

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a b s t r a c tTopologically interlocked materials (TIMs) are a class of materials made by a structured assembly of an array of identically shaped and sized unit elements that are held in a confining framework. The assembly can resist transverse forces in the absence of adhesives between the unit elements. The present study focuses on topologically interlocked materials with cellular unit elements. The resulting materials achieve their properties by a combination of deformation of the individual unit elements and their contact interaction. Drop tower tests were conducted to characterize the mechanical behavior of the cellular TIMs made of an intrinsically brittle base material. The TIMs were found to exhibit perfect softening, independent of the relative density of the cellular units. The analysis of the experiments revealed a positive correlation between strength and toughness in contrast to more conventional materials. An analytical model for the prediction of the observed material behavior is developed. Model predictions are in agreement with experimental data. The implications of the present findings for the design of these novel materials are discussed.

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Section: Discussionmentioning

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Transverse loading of cellular topologically interlocked materials

Khandelwal

Siegmund

Cipra

et al. 2012

International Journal of Solids and Structures

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“…As adhesionless granular system, TIMs require an external constraint to provide resistance under the action of external load. TIM systems have already been shown to possess attractive mechanical properties including: (i) high damage tolerance ( [29]- [31]), (ii) negative stiffness characteristics under certain loading conditions ( [32], [33]), (iii) a quasi-ductile mechanical response response even if constituent materials are brittle ( [29], [34]- [36]), (iv) remanufacturability [37], and (v) advantageous dependence of stiffness, strength and toughness with variation in relative density if cellular unit elements are considered [38]. Past work has demonstrated the effect of change of the initial constraint conditions on the TIM system stiffness and load carrying capacity.…”

Section: Deshmukh and Mckinleymentioning

confidence: 99%

Adaptive mechanical properties of topologically interlocking material systems

Khandelwal

Siegmund

Cipra

et al. 2015

Smart Mater. Struct.

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ABSTRACT:Topologically interlocked material systems are two-dimensional granular crystals created as ordered and adhesion-less assemblies of unit elements of the shape of platonic solids. The assembly resists transverse forces due to the interlocking geometric arrangement of the unit elements. Topologically interlocked material systems yet require an external constraint to provide resistance under the action of external load.Past work considered fixed and passive constraints only. The objective of the present study is to consider active and adaptive external constraints with the goal to achieve variable stiffness and energy absorption characteristics of the topologically interlocked material system through an active control of the in-plane constraint conditions. Experiments and corresponding model analysis are used to demonstrate control of system stiffness over a wide range, including negative stiffness, and energy absorption characteristics.The adaptive characteristics of the topologically interlocked material system are shown to solve conflicting requirements of simultaneously providing energy absorption while keeping loads controlled.Potential applications can be envisioned in smart structure enhanced response characteristics as desired in shock absorption, protective packaging and catching mechanisms.

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“…Khandelwal et al [15] experimentally examined the quasi-static responses of TIMs asembled with regular tetrahedra, and proposed an analytic model to predicted the quasi-static beaviors of TIM with thrust line theory. Mather et al [16] studied the remanufacturability of TIMs, illustrated that only small portion of units could not be reused after failure of the TIMs. And for applications of TIMs, Estrin et al [17] proposed the potential application of TIM as protective tiles for the space shuttle.…”

Section: Introductionmentioning

confidence: 99%

Mechanics of Multiscale Energy Dissipation in Topologically Interlocked Materials-11.1 STIR

Siegmund¹

2013

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The public reporting burden for this collection of information is estimated to average 1 hour per response, including the time for reviewing instructions, searching existing data sources, gathering and maintaining the data needed, and completing and reviewing the collection of information. The objective of the present study is to provide understanding of potential energy absorption and dissipation mechanisms and benefits of topologically interlocked material assemblies (TIMs) under impact loading. The study is motivated by earlier findings that TIMs under low rate loading demonstrated attractive properties including the capability to arrest and localize cracks and to exhibit a quasi-ductile response even when the unit elements are made of brittle materials. It is hypothesized that TIMs due to their modularity would possess advantageous impact Number of Papers published in non peer-reviewed journals:

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Structural integrity during remanufacture of a topologically interlocked material

Cited by 35 publications

References 34 publications

Transverse loading of cellular topologically interlocked materials

Transverse loading of cellular topologically interlocked materials

Adaptive mechanical properties of topologically interlocking material systems

Mechanics of Multiscale Energy Dissipation in Topologically Interlocked Materials-11.1 STIR

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