Abstract
Biomimetic scales provide a convenient template to tailor the bending stiffness of the underlying slender substrate due to their mutual sliding after engagement. Scale stiffness can therefore directly impact the substrate behavior, opening a potential avenue for substrate stiffness tunability. Here, we have developed a biomimetic beam, which is covered by tunable stiffness scales. Scale tunability is achieved by specially designed plate like scales consisting of layers of low melting point alloy (LMPA) phase change materials fully enclosed inside a soft polymer. These composite scales can transition between stiff and soft states by straddling the temperatures across LMPA melting points thereby drastically altering stiffness. We experimentally analyze the bending behavior of biomimetic beams covered with tunable stiffness scales of two architectures—one with single enclosure of LMPA and one with two enclosures of different melting point LMPAs. These architectures provide a continuous stiffness change of the underlying substrate post engagement, controlled by the operating temperature. We characterize this response using three-point bending experiments at various temperature profiles. Our results demonstrate for the first time, the pronounced and reversible tunability in the bending behavior of biomimetic scale covered beam, which are strongly dependent on the scale material and architecture. Particularly, it is shown that the bending stiffness of the biomimetic scale covered beam can be actively and reversibly tuned by a factor of up to 7. The developed biomimetic beam has applications in soft robotic grippers, smart segmented armors, deployable structures and soft swimming robots.
Highlights
Once the DLS are heated up to 47 ◦C < Tscales < 62 ◦C, LMPA2 melts and its initial stiffness, reduces significantly. This has shifted its force-displacement plot to the right by an amount of 1 mm since the top layer is LMPA2 which has been melted
We have investigated for the first time, a biomimetic beam covered with tunable stiffness scales to achieve a continuous stiffness change of the underlying substrate
Scales stiffness is tuned by enclosing phase change low melting point alloys (LMPAs) materials into a 3D-printed soft shell
Summary
The layers would be essentially fully enclosed chambers containing these liquids, lowering the stiffness of these plate like scales to their lowest permissible values Bending stiffness of both the SLS and DLS are characterized experimentally, using three-point bending experiments at various scales temperatures. At their extreme phases, the maximum and minimum stiffness of scales translate to similar extremum in bending stiffness of the biomimetic beam, there exists a continuum of stiffness at intermediate temperatures This is investigated by first heating the samples and continuously loading them via cyclic three-point bending experiments as they continue to cool down and LMPAs start solidifying (cooling time to room temperature is 20 mins). We find that bending stiffness gains post scales engagement can be tuned by almost an order of magnitude
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