Shape-changing pulsed-jet thruster for new generation AUVs
Shape-changing pulsed-jet thruster for new generation AUVs
The offshore industry is in growing demand of robots capable of dealing with increasingly complex tasks in always more forbidding scenarios. However, standard underwater vehicles are power inefficient and poorly manoeuvrable, making them inadequate for this purpose. Aquatic animals have been looked upon as the perfect autonomous undersea platform and, among aquatic animals, soft-bodied ones may constitute the paradigm of inspiration to design a new breed of working class vehicles. In this talk we argue that the recourse to soft aquatic robots can disclose a solution to the problems commonly encountered in underwater operations. The scope of this talk is to introduce the current state of the art in shape-changing pulsed-jet propulsion and the benefits it can provide in the design of a new generation of AUVs.
We start by showing experimental and numerical results which demonstrate how jetting maneuvers produced by volume-changes of a body in water can generate as much as 260% more thrust per pulsation than an equivalent rigid body. This is due to a combination of separation control and recovery of added mass energy. In order for this assets to be employed, specific requirements in terms of design and actuation need to be met. Hence, we present a first series of prototypes characterised by extreme structural compliance and capable of performing a pulsed-jetting routine such as that required to exploit the contribution from hydrodynamic terms. We eventually discuss the limitations of the existing prototypes and illustrate the ongoing developments of this new technology.
Giorgio-Serchi, Francesco
8571dc14-19c1-4ed1-8080-d380736a6ffa
Weymouth, Gabriel
b0c85fda-dfed-44da-8cc4-9e0cc88e2ca0
28 April 2016
Giorgio-Serchi, Francesco
8571dc14-19c1-4ed1-8080-d380736a6ffa
Weymouth, Gabriel
b0c85fda-dfed-44da-8cc4-9e0cc88e2ca0
Giorgio-Serchi, Francesco and Weymouth, Gabriel
(2016)
Shape-changing pulsed-jet thruster for new generation AUVs.
Next Generation Marine Power & Propulsion, Southampton, United Kingdom.
25 - 27 Apr 2016.
Record type:
Conference or Workshop Item
(Other)
Abstract
The offshore industry is in growing demand of robots capable of dealing with increasingly complex tasks in always more forbidding scenarios. However, standard underwater vehicles are power inefficient and poorly manoeuvrable, making them inadequate for this purpose. Aquatic animals have been looked upon as the perfect autonomous undersea platform and, among aquatic animals, soft-bodied ones may constitute the paradigm of inspiration to design a new breed of working class vehicles. In this talk we argue that the recourse to soft aquatic robots can disclose a solution to the problems commonly encountered in underwater operations. The scope of this talk is to introduce the current state of the art in shape-changing pulsed-jet propulsion and the benefits it can provide in the design of a new generation of AUVs.
We start by showing experimental and numerical results which demonstrate how jetting maneuvers produced by volume-changes of a body in water can generate as much as 260% more thrust per pulsation than an equivalent rigid body. This is due to a combination of separation control and recovery of added mass energy. In order for this assets to be employed, specific requirements in terms of design and actuation need to be met. Hence, we present a first series of prototypes characterised by extreme structural compliance and capable of performing a pulsed-jetting routine such as that required to exploit the contribution from hydrodynamic terms. We eventually discuss the limitations of the existing prototypes and illustrate the ongoing developments of this new technology.
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Published date: 28 April 2016
Venue - Dates:
Next Generation Marine Power & Propulsion, Southampton, United Kingdom, 2016-04-25 - 2016-04-27
Organisations:
Fluid Structure Interactions Group
Identifiers
Local EPrints ID: 404943
URI: http://eprints.soton.ac.uk/id/eprint/404943
PURE UUID: 096182f2-ee9e-4e55-93d6-5e0f162ead48
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Date deposited: 25 Jan 2017 11:03
Last modified: 12 Dec 2021 03:59
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Contributors
Author:
Francesco Giorgio-Serchi
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