Nature in Engineering for Monitoring the Oceans (NEMO): An isopycnal soft bodied approach for deep diving autonomous underwater vehicles

Phillips, Alexander B.; Blake, J.I.R.; Boyd, Stephen; Ward, Suzanna C.; Griffiths, Gwyn

doi:10.1109/auv.2012.6380743

Cited by 5 publications

(3 citation statements)

References 33 publications

(28 reference statements)

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“…The power consumption, P tot , of a neutrally buoyant flight style AUV can be assumed to be split between hotel load, P H , which is invariant to forward speed, and propulsion power, P P , which is related to propulsion speed raised to the power 3 [40,41]. For a positively buoyant over-actuated vehicle, additional power is required to maintain depth, P B :…”

Section: Energy Consumptionmentioning

confidence: 99%

Depth control for an over-actuated, hover-capable autonomous underwater vehicle with experimental verification

et al. 2017

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A PI-D based control system is developed for over-actuated, hover-capable AUVs which enables a smooth transition from hover-style to flight-style operation. A system stability and convergence is proven using a Lyapunov-based approach. The performance of the controller is demonstrated by simulation but crucially is proven to provide satisfactory performance experimentally. The approach is able to operate over a range of vehicle ballasting configurations, and to imposed external disturbances. The proposed system is computationally inexpensive and does not require a detailed hydrodynamic model to implement. By monitoring the energy consumption on board, the cost of maintaining depth at a range of forward speeds with different buoyancy conditions can be quantified and their impact on cost of transport is highlighted for future optimisation of energy consumption.

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Section: Energy Consumptionmentioning

confidence: 99%

Depth control for an over-actuated, hover-capable autonomous underwater vehicle with experimental verification

et al. 2017

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“…For a more precise customization of the static balance of the vehicle, three drop-weights placed according to the scheme of Figure 8 should be easily adjusted. This way, in normal operating conditions (vehicle ballasted by drop-weights), the vehicle is neutral with a slight additional buoyancy of about 1%−2%, with respect to the one calculated from vehicle volume, to compensate compressibility of the hull at maximum depth 19 and to make the return to surface easier when state of charge of batteries could be lower; in the case of severe failure, the drop-weights (which are usually hold through a solenoid system) are released assuring an additional buoyancy of about 3%−4% with respect to vehicle volume. In this way, in case of failure, a rapid return to surface is assured.…”

Section: Preliminary Design Of the Hullmentioning

confidence: 99%

Preliminary design and fast prototyping of an Autonomous Underwater Vehicle propulsion system

Allotta

Pugi

Bartolini

et al. 2014

Proceedings of the Institution of Mechanical Engineers, Part M:

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The Mechatronics and Dynamic Modelling Laboratory of the Department of Industrial Engineering, University of Florence, as a partner of THESAURUS (Italian acronym for ‘TecnicHe per l’Esplorazione Sottomarina Archeologica mediante l’Utilizzo di Robot aUtonomi in Sciami’) project, has developed an innovative low-cost, multirole autonomous underwater vehicle, called Tifone. This article deals with the adopted methodologies for the autonomous underwater vehicle design: in particular, the main focus of this study is related to its propulsion system. According to the expected performances and requirements of THESAURUS project, the vehicle has to maintain good autonomy and efficiency (typical features of an autonomous underwater vehicle), with high manoeuvrability and hovering capabilities, which are more common of remotely operated vehicles. Moreover, cooperative underwater exploration and surveillance involve the use of a swarm of vehicles. In particular, the optimization of costs versus benefits is achieved through the design of a fleet of three multirole vehicles. Each autonomous underwater vehicle has five controlled degrees of freedom, thanks to four thrusters and two propellers: in this article, the preliminary design criteria concerning the vehicle and the design and testing of its actuation system are described

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“…Since the range and endurance are limited by the cruise speed (Bingham et al, 2002;Furlong et al, 2007;McPhail, 2009;Stevenson et al, 2007;Tripp, 2006), the options to extend an endurance are: minimising drag (Huggins and Packwood, 1994;Parsons, 1972;Parsons et al, 1974), enhancing propulsive efficiency (Ageev, 2000(Ageev, , 1995Stevenson et al, 2007), increasing specific energy of power sources (Ageev, 2000;Alers, 1981), and reducing hotel load Phillips et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Numerical investigation of a pair of self-propelled AUVs operating in tandem

2015

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This paper investigates the influence of the propeller race on upstream and downstream self-propelled AUVs. Initially simulations of a self-propelled hull are performed at the Reynolds Number 3.2 × 10 6 with the commercial RANS code ANSYS CFX 12.1, utilising a body force model to replicate the impact of the propeller utilising momentum source terms. This is then extended to consider a fleet of two self-propelled vehicles operating at a range of longitudinal offset and transverse separations. The results highlight that operation in close proximity to another self-propelled vessel has a significant impact of both the flow around the hull and drag experienced by the vehicle. A propeller race deduction is proposed to account for the increase in vehicle drag due to the propulsors of other vehicles. The propeller race deduction is dependent upon both longitudinal and transverse separation. From a vehicle or mission design perspective, it is important to correctly understand the true propulsive energy budget of the vehicle and its impact on both range and endurance. This study highlights the importance of considering both thrust deduction and any propeller race deductions when calculating the propulsive power consumption of an individual or fleet of vehicles.

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Nature in Engineering for Monitoring the Oceans (NEMO): An isopycnal soft bodied approach for deep diving autonomous underwater vehicles

Cited by 5 publications

References 33 publications

Depth control for an over-actuated, hover-capable autonomous underwater vehicle with experimental verification

Depth control for an over-actuated, hover-capable autonomous underwater vehicle with experimental verification

Preliminary design and fast prototyping of an Autonomous Underwater Vehicle propulsion system

Numerical investigation of a pair of self-propelled AUVs operating in tandem

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