Abstract
Fish scales serve as a natural dermal armor with remarkable flexibility and puncture resistance. Through studying fish scales, researchers can replicate these properties and tune them by adjusting their design parameters to create biomimetic scales. Overlapping scales, as seen in elasmoid scales, can lead to complex interactions between each scale. These interactions are able to maintain the stiffness of the fish’s structure with improved flexibility. Hence, it is important to understand these interactions in order to design biomimetic fish scales. Modeling the flexibility of fish scales, when subject to shear loading across a substrate, requires accounting for nonlinear relations. Current studies focus on characterizing these kinematic linear and nonlinear regions but fall short in modeling the kinematic phase shift. Here, we propose an approach that will predict when the linear-to-nonlinear transition will occur, allowing for more control of the overall behavior of the fish scale structure. Using a geometric analysis of the interacting scales, we can model the flexibility at the transition point where the scales start to engage in a nonlinear manner. The validity of these geometric predictions is investigated through finite element analysis. This investigation will allow for efficient optimization of scale-like designs and can be applied to various applications.
Highlights
Natural materials serve as a great inspiration in the development of engineering designs [1,2,3,4,5,6,7,8,9,10,11]
We develop a geometric model that can describe the flexibility of the fish scale model using three simple design variants
Fish scales serve as a natural dermal armor with remarkable properties, such as stiffness and flexibility
Summary
Natural materials serve as a great inspiration in the development of engineering designs [1,2,3,4,5,6,7,8,9,10,11]. Fish scales can provide inspiration for protective systems and designs with variable flexibility [12,13,14]. Recent studies on fish scale designs have shown that fish scales offer remarkable mechanical properties, such as resistance to penetration, while being highly flexible, lightweight structures [15,16,17,18]. The fish scale structure of interest in this study closely resembles elasmoid scales [13,19]. This type of scale is among the most commonly found fish scale types and overcomes significant tradeoffs in mechanical properties for armor design applications [20,21]. Due to their thin structure, and have an equivalent stiffness compared to thicker scale types [22]
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