Development of biomimetic squid-inspired suckers

Biomechanical properties of squid suckers were studied to provide inspiration for the development of sucker artefacts for a robotic octopus. Mechanical support of the rings found inside squid suckers was studied by bending tests. Tensile tests were carried out to study the maximum possible sucking force produced by squid suckers based on the strength of sucker stalks, normalized by the sucking areas. The squid suckers were also directly tested to obtain sucking forces by a special testing arrangement. Inspired by the squid suckers, three types of sucker artefacts were developed for the arm skin of an octopus inspired robot. The first sucker artefact made of knitted nylon sheet reinforced silicone rubber has the same shape as the squid suckers. Like real squid suckers, this type of artefact also has a stalk that is connected to the arm skin and a ring to give radial support. The second design is a straight cylindrical structure with uniform wall thickness made of silicone rubber. One end of the cylinder is directly connected to the arm skin and the other end is open. The final design of the sucker has a cylindrical base and a concave meniscus top. The meniscus was formed naturally using the surface tension of silicone gel, which leads to a higher level of the liquid around the edge of a container. The wall thickness decreases towards the tip of the sucker opening. Sucking forces of all three types of sucker artefacts were measured. Advantages and disadvantages of each sucker type were discussed. The final design of suckers has been implemented to the arm skin prototypes.

[1]  Paul Marks Projector phones: cool app or visual pollution , 2009 .

[2]  Andrew M. Smith NEGATIVE PRESSURE GENERATED BY OCTOPUS SUCKERS: A STUDY OF THE TENSILE STRENGTH OF WATER IN NATURE , 1991 .

[3]  S. Woo,et al.  The Effects of Multiple Freeze–Thaw Cycles on the Biomechanical Properties of the Human Bone-Patellar Tendon-Bone Allograft , 2011, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[4]  W. Nachtigall Biological Mechanisms of Attachment: The Comparative Morphology and Bioengineering of Organs for Linkage, Suction, and Adhesion , 1974 .

[5]  Richard H. C. Bonser,et al.  Design of a biomimetic skin for an octopus-inspired robot — Part II: Development of the skin artefact , 2011 .

[6]  W. Kier,et al.  The arrangement and function of octopus arm musculature and connective tissue , 2007, Journal of morphology.

[7]  Ian A. Gravagne,et al.  Uniform regulation of a multi-section continuum manipulator , 2002, Proceedings 2002 IEEE International Conference on Robotics and Automation (Cat. No.02CH37292).

[8]  W. Kier,et al.  Trunks, Tongues, and Tentacles: Moving with Skeletons of Muscle , 1989 .

[9]  G. W. Snedecor Statistical Methods , 1964 .

[10]  Smith Cephalopod sucker design and the physical limits to negative pressure , 1996, The Journal of experimental biology.

[11]  Ian D. Walker,et al.  ROBOTIC MANIPULATORS INSPIRED BY CEPHALOPOD LIMBS , 2011 .

[12]  Germán Sumbre,et al.  Neurobiology: Motor control of flexible octopus arms , 2005, Nature.

[13]  Richard H. C. Bonser,et al.  Design of a biomimetic skin for an octopus-inspired robot — Part I: Characterising octopus skin , 2011 .

[14]  E. R. Trueman,et al.  The skin of cephalopods (Coleoids): general and special adaptations , 1988 .

[15]  P. Dario,et al.  Design concept and validation of a robotic arm inspired by the octopus , 2011 .

[16]  Professor Dr. Werner Nachtigall Biological Mechanisms of Attachment , 1974, Springer Berlin Heidelberg.

[17]  B. Hochner,et al.  Control of Octopus Arm Extension by a Peripheral Motor Program , 2001, Science.

[18]  S. Hatzikiriakos,et al.  Effect of freezing on the passive mechanical properties of arterial samples , 2010 .

[19]  Y Gutfreund,et al.  Organization of Octopus Arm Movements: A Model System for Studying the Control of Flexible Arms , 1996, The Journal of Neuroscience.

[20]  C F Abrams,et al.  Effects of freezing on mechanical properties of rat skin. , 1992, American journal of veterinary research.

[21]  Tamar Flash,et al.  How to move with no rigid skeleton? The octopus has the answers. , 2002, Biologist.

[22]  W. Kier,et al.  The Structure and Adhesive Mechanism of Octopus Suckers1 , 2002, Integrative and comparative biology.

[23]  W. Kier,et al.  The Morphology and Mechanics of Octopus Suckers. , 1990, The Biological bulletin.

[24]  John Young The anatomy of the nervous system of Octopus vulgaris , 1971 .

[25]  Yewang Su,et al.  Concave biological surfaces for strong wet adhesion , 2009 .