Publication Type:

Journal Article

Source:

Applied Mechanics and Materials, Trans Tech Publications Ltd, Volume 592-594, Tiruchirappalli, TN, p.2287-2291 (2014)

ISBN:

9783038351634

URL:

http://www.scopus.com/inward/record.url?eid=2-s2.0-84905015617&partnerID=40&md5=d726a2eba57f9d90eb7e916e638833e1

Keywords:

Aquatic, Control, Direction, Direction control, Feasible alternatives, Industrial research, Jet propulsion systems, Jets, molluscs, Propulsion, Propulsion methods, Propulsive efficiencies, Robotics, Robots, Shellfish, SQUIDs, Underwater

Abstract:

Deriving inspiration from the propulsion methods of squids, a pulsatile jet propulsion system is adopted in a robotic model. A squid-like direction control mechanism, which can direct the jet along any direction on a hemispherical work volume, is also implemented. To obtain a suitable robot velocity (Ũv) and a propulsive efficiency (ηp) for testing this mechanism, the stroke ratio (L/D) and outlet diameter are varied and the Ũv and the ηp of various alternatives are estimated experimentally using vision analysis. A Stroke ratio of 3.78 and an outlet diameter of 25.4 mm are found suitable and employed for testing the mechanism. When the jet is deflected by 60° in the horizontal plane, the robot rotates about its centroid, signifying excellent maneuverability. Reverse motion is also demonstrated by removing inlet valves and blocking the outlet through the direction control mechanism. The performance of the direction control mechanism indicates that the robotic model is a feasible alternative to conventional screw-propelled aquatic robots. © (2014) Trans Tech Publications, Switzerland.

Notes:

cited By (since 1996)0; Conference of org.apache.xalan.xsltc.dom.DOMAdapter@151adc81 ; Conference Date: org.apache.xalan.xsltc.dom.DOMAdapter@1682a3fa Through org.apache.xalan.xsltc.dom.DOMAdapter@5adb7da1; Conference Code:106662

Cite this Research Publication

R. Radhika, Gupta, S. K., Rammohan, N., and Arul, S., “Dynamic control of a pulsatile jet propelled aquatic robot”, Applied Mechanics and Materials, vol. 592-594, pp. 2287-2291, 2014.