Fabrication, testing and modeling of a new flexible armor inspired from natural fish scales and osteoderms

Chintapalli, Ravi Kiran; Mirkhalaf, Mohammad; Dastjerdi, Ahmad Khayer; Barthelat, François

doi:10.1088/1748-3182/9/3/036005

Cited by 98 publications

(75 citation statements)

References 17 publications

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“…Mechanical characterization typically involved tensile testing (Ikoma et al, 2003;Garrano et al, 2012;Lin et al, 2011;Zhu et al, 2012) or indentation and puncture tests on individual scales (Bruet et al, 2008;Meyers et al, 2012;Zhu et al, 2012) or multiple scales (Zhu et al, 2013). Fish scales have also started to inspire new flexible protective systems (Browning et al, 2013;Chintapalli et al, 2014). Tensile tests on natural teleost fish scales confirmed the scale as a stiff, strong a tough material.…”

Section: Introductionmentioning

confidence: 99%

Teleost fish scales amongst the toughest collagenous materials

Dastjerdi

Barthelat

2015

Journal of the Mechanical Behavior of Biomedical Materials

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Section: Introductionmentioning

confidence: 99%

Teleost fish scales amongst the toughest collagenous materials

Dastjerdi

Barthelat

2015

Journal of the Mechanical Behavior of Biomedical Materials

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“…In the case of shark skin, the hard dermal denticles forming its epidermis bestow it special surface morphology and features. Moreover, the dermis and the subcutaneous tissue beneath the epidermal layer form the main bulk of the skin's structural organization called the elastic matrix, or compliant surface in a literature 30. Naresh et al 31 investigated the mechanical behaviors and the histological characteristics of shark skin in detail.…”

Section: Shark Skin Structurementioning

confidence: 99%

“…Hydrophilic or hydrophobic behavior can suppress instability growth in the boundary layer by changing the interaction behavior of the flow‐wall interface; thus, drag reduction is achieved. Third, physical and mechanical properties of matrixes, including flexibility 30, stiffness 64, and viscoelasticity 49, can induce the riblet‐structured wall to exhibit different responses to fluid flow, thereby resulting in different drag‐reduction effects.…”

Section: Progress In Research and Applications Of Biomimetic Drag‐rmentioning

confidence: 99%

Progress and Perspective of Studies on Biomimetic Shark Skin Drag Reduction

Liu

2016

ChemBioEng Reviews

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Shark skin surfaces of fast-swimming sharks are characterized as non-smooth because of the presence of dermal denticles or riblet structures and exhibit an excellent drag-reduction effect. A review of the surface morphology, structure and mechanical behaviors of shark skin is given. Investigations into the microstructures of a single denticle and the mechanical behaviors of complete fresh shark skin containing both epidermal and dermal layers were reported. The results show that some nanostructured protuberances exist on the concave groove surface of a denticle. In particular, the complete fresh shark skin exhibits an excellent elasticity, and its stress-strain curve is different from that of the corresponding epidermal layer. Furthermore, the mechanisms of drag reduction by riblets and complaint wall were introduced, various methods of fabricating biomimetic riblet-structured surfaces were classified and summarized, and studies on the drag-reduction effects and applications of biomimetic riblet-structured surfaces were also reviewed. Based on these analyses and on the understanding of the drag-reduction mechanisms, the concept of a synergistic drag-reduction effect that is attributed to a non-smooth surface and an elastic matrix was proposed for the first time.

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“…This design showed that overlapping of scales provides flexibility, damage tolerance, and more importantly resistance to puncture. Similarly, armadillo scales have also been used as a source of inspiration for designing flexible armor fabricated using hexagonal glass plates placed on an elastomer substrate [25]. This type of synthetic armors also yielded a good resistance to puncture as well as flexibility.…”

Section: Introductionmentioning

confidence: 99%

Bending of biomimetic scale covered beams under discrete non-periodic engagement

Ali¹,

Ebrahimi²,

Ghosh³

2019

International Journal of Solids and Structures

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Covering elastic substrates with stiff biomimetic scales significantly alters the bending behavior via scales engagement. This engagement is the dominant source of nonlinearity in small deflection regime. As deformation proceeds, an initially linear bending response gives way to progressive stiffening and thereafter a geometrically dictated 'locked' configuration. However, investigation of this system has been carried out un-*

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Fabrication, testing and modeling of a new flexible armor inspired from natural fish scales and osteoderms

Cited by 98 publications

References 17 publications

Teleost fish scales amongst the toughest collagenous materials

Teleost fish scales amongst the toughest collagenous materials

Progress and Perspective of Studies on Biomimetic Shark Skin Drag Reduction

Bending of biomimetic scale covered beams under discrete non-periodic engagement

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