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9. Chaotic multigrid methods for the solution of elliptic equations

Author

Hawkes, J., Vaz, G., Phillips, A.B., Klaij, C.M., Cox, S.J., Turnock, S.R., Hawkes, J., Vaz, G., Phillips, A.B., Klaij, C.M., Cox, S.J., and Turnock, S.R.

Abstract

Supercomputer power has been doubling approximately every 14 months for several decades, increasing the capabilities of scientific modelling at a similar rate. However, to utilize these machines effectively for applications such as computational fluid dynamics, improvements to strong scalability are required. Here, the particular focus is on semi-implicit, viscous-flow CFD, where the largest bottleneck to strong scalability is the parallel solution of the linear pressure-correction equation — an elliptic Poisson equation. State-of-the-art linear solvers, such as Krylov subspace or multigrid methods, provide excellent numerical performance for elliptic equations, but do not scale efficiently due to frequent synchronization between processes. Complete desynchronization is possible for basic, Jacobi-like solvers using the theory of ‘chaotic relaxations’. These non-deterministic, chaotic solvers scale superbly, as demonstrated herein, but lack the numerical performance to converge elliptic equations — even with the relatively lax convergence requirements of the example CFD application. However, these chaotic principles can also be applied to multigrid solvers. In this paper, a ‘chaotic-cycle’ algebraic multigrid method is described and implemented as an open-source library. It is tested on a model Poisson equation, and also within the context of CFD. Two CFD test cases are used: the canonical lid-driven cavity flow and the flow simulation of a ship (KVLCC2). The chaotic-cycle multigrid shows good scalability and numerical performance compared to classical V-, W- and F-cycles. On 2048 cores the chaotic-cycle multigrid solver performs up to faster than Flexible-GMRES and faster than classical V-cycle multigrid. Further improvements to chaotic-cycle multigrid can be made, relating to coarse-grid communications and desynchronized residual computations. It is expected that the chaotic-cycle multigrid could be applied to other scientific fields, wherever a scalable elliptic-e

Published
2018

10. On the Strong Scalability of Maritime CFD

Author

Hawkes, J., Vaz, G., Phillips, A.B., Cox, S.J., Turnock, S.R., Hawkes, J., Vaz, G., Phillips, A.B., Cox, S.J., and Turnock, S.R.

Abstract

Since 2004, supercomputer growth hasbeen constrained by energy efficiency rather than raw hardware speeds. Tomaintain exponential growth of overall computing power, a massive growth inparallelization is under way. To keep up with these changes, computationalfluid dynamics (CFD) must improve its strong scalability – its ability tohandle lower cells-per-core ratios and achieve finer-grain parallelization. Amaritime-focused, unstructured, finite-volume code (ReFRESCO) is used toinvestigate the scalability problems for incompressible, viscous CFD using two classicaltest-cases. Existing research suggests that the linear equation-system solveris the main bottleneck to incompressible codes, due to the stiff Poisson pressure equation. Here, these results are expandedby analysing the reasons for this poor scalability. In particular, a number ofalternative linear solvers and preconditioners are tested to determine if thescalability problem can be circumvented, including GMRES, Pipelined-GMRES,Flexible-GMRES and BCGS. Conventional block-wise preconditioners are tested,along with multi-grid preconditioners and smoothers in various configurations.Memory-bandwidth constraints and global communication patterns are found to bethe main bottleneck, and no state-of-the-art solution techniques which solve thestrong-scalability problem satisfactorily could be found. There is significantincentive for more research and development in this area.

Published
2017

11. RANS-based full-scale power predictions for a general cargo vessel, and comparison with sea-trial results

Author

Starke, A.R., Drakopoulos, K., Toxopeus, S.L., Turnock, S.R., Starke, A.R., Drakopoulos, K., Toxopeus, S.L., and Turnock, S.R.

Abstract

Blind self-propulsion predictions for the 2016 LR Workshop on Ship Scale Hydrodynamic Computer Simulation have been carried out to simulate the full scale performance of a self-propelled ship in ballast. The single screw ship of 11542 tonnes had been scanned in drydock so the computational model used the actual as operated hull form. It will be shown that using a hybrid RANS-BEM method, the predicted ship speeds at self-propulsion are over-estimated by 0.17-0.28 knots compared to the trial data. The various aspects that influence the accuracy of the direct prediction of power and RPM using CFD are critically discussed.

Published
2017

12. Comparison of various approaches to numerical simulation of ship resistance and propulsion

Author

Badoe, C., Winden, B., Lidtke, Artur Konrad, Phillips, A.B., Hudson, D.A., and Turnock, S.R.

Subjects
animal structures
Abstract

The operation of a marine propeller dominates the flow interaction effects and alters the resistance on an upstream hull and the forces on a downstream rudder. A study is carried out into how these effects can be resolved by comparing four different methods. A classical prescribed body force approach in which an averaged nominal wake is used as input for the propeller model with prescribed thrust and torque; Two coupled BEMt-RANS solver which accounts for the non-uniform inflow into the propeller and a time resolved discretize propeller approach employing the use of an Arbitrary Mesh Interface model (AMI). The main differences between these four methods are also outlined quantitatively. The accurate results obtained using the two coupled BEMt-RANS approaches makes them fast and robust methods which can be used for ship resistance and self-propulsion estimation in the initial design phase

Published
2014

13. Performance analysis of massively-parallel computational fluid dynamics

Author

Hawkes, J., Turnock, S.R., Cox, S.J., Phillips, A.B., and Vaz, G.

Abstract

As modern supercomputers edge towards exascale, their architectures are becoming more parallel. In order for computational fluid dynamics (CFD) simulations to operate efficiently on newer machines, a complete harmony between hardware, software and numerical algorithms is required. In the work presented here, a typical CFD code is instrumented, and a strong-scalability study performed to identify areas of the execution which require improvement, using the well-known KVLCC2 test case. The effects of changing discretization schemes, mesh structure, turbulence models and linear solvers are all tested. The results show that data exchange among cores and the inner-loop pre-conditioners both have a large impact on performance in a massively-parallel environment, and should be the focus of future developments.

Published
2014

14. Developing tools for assessing bend-twist coupled foils

Author

Banks, J., Marimon Giovannetti, Laura, Turnock, S.R., and Boyd, S.W.

Subjects
Physics::Fluid Dynamics
Abstract

This paper details a set of experimental tests conducted on a NACRA F20 curved dagger board in the University of Southampton’s RJ Mitchell wind tunnel. Digital image correlation (DIC) was used to measure the full field deflection at the board tip and particle image velocimetry (PIV) was used to capture the position and strength of the tip vortex. Preliminary CFD simulations of the rigid experimental geometry are compared to this data

Published
2014

15. Ship wake field analysis using a coupled BEMt-RANS approach

Author

Badoe, C., Turnock, S.R., and Phillips, A.B.

Abstract

The prediction of a ship’s wake field and self-propulsion capabilities has traditionally been centered on experiments; however with the advancement in modern computing power, this can be achieved through the use of computational methods. An advantage with the use of CFD is its ability to provide insight into flow characteristics close to the wall, which are difficult to obtain through experiments. The most interesting and challenging aspect of using CFD in this analysis, is the influence of the propeller action and the unsteady hydrodynamic of the rudder working in the propeller wake. One approach to address the problem is to discretize the ship, propulsor and the rudder using unsteady RANS computations (Carrica et al., 2011). Due to the small time steps and high computational cost involved, simulations are often performed using representative propeller models or body force method. The level of complexities in the body force propeller approach varies from prescribing the body forces, Badoe et al., (2012), Phillips et al., (2010), through to coupling a more complex propeller performance code which accounts for the non-uniform inflow at the propeller plane, Phillips et al., (2009). There are several self-propulsion computations using body force propeller models reported in the literature. Banks et al., (2010) performed a RANS simulation of multiphase flow around the KCS hull form using a propeller model with force distribution based on the Hough and Ordway thrust and torque distribution (Hough and Ordway, 1965). Simonsen and Stern, (2003) coupled a body force propeller model based on potential theory formulation in which the propeller was represented by bound vortex sheets on the propeller disk and free vortices shed from the downstream of the propeller to a RANS code to simulate the manoeuvring characteristic of the Esso Osaka with a rudder. In the present work an investigation is carried out into the sensitivity with which the wakefield of a container ship in calm water is resolved using a coupled BEMt-RANS sectorial approach.

Published
2014

16. Potential of chaotic iterative solvers for CFD

Author

Hawkes, J., Vaz, G., Turnock, S.R., Cox, S.J., and Phillips, A.B.

Abstract

Computational Fluid Dynamics (CFD) has enjoyed the speed-up available from supercomputer technology advancements for many years. In the coming decade, however, the architecture of supercomputers will change, and CFD codes must adapt to remain current.Based on the predictions of next-generation supercomputer architectures it is expected that the first computer capable of 1018 floating-point-operations-per-second (1 ExaFLOPS) will arrive in around 2020. Its architecture will be governed by electrical power limitations, whereas previously the main limitation was pure hardware speed. This has two significant repercussions. Firstly, due to physical power limitations of modern chips, core clock rates will decrease in favour of increasing concurrency. This trend can already been seen with the growth of accelerated “many-core” systems, which use graphics processing units (GPUs) or co-processors. Secondly, inter-nodal networks, typically using copper-wire or optical interconnect, must be reduced due to their proportionally large power consumption. This places more focus on shared-memory communications, with distributed-memory communication (predominantly MPI - “Message Passing Interface”) becoming less important.The current most powerful computer, Tianhe-2, capable of 33 PFlops, consists of 3,120,000 cores. The first exascale machine, which will be 30 times more powerful, is likely to be 300-times more parallel – which is a massive acceleration in parallelization compared to the last 50 years. This concurrency will come primarily from intra-node parallelization. Whereas Tianhe-2 features an already-large O(100) cores per node, an exascale machine must consist of O(1k-10k) cores per node.CFD has benefited from weak scalability (the ability to retain performance with a constant elements-per-core-ratio) for many years; its strong scalability (the ability to reduce the elements-per-core ratio) has been poor and mostly irrelevant. With the shift to massive parallelism in the next few years, the strong scalability of CFD codes must be investigated and improved.In this paper, a brief summary of earlier results is given, which identified the linear-equation system solver as one of the least-scalable parts of the code. Based on these results, a chaotic iterative solver, which is a totally-asynchronous, non-stationary, linear solver for high-scalability, is proposed. This paper focuses on the suitability of such a solver, by investigating the linear equation systems produced by typical CFD problems. If the results are optimistic, future work will be carried out to implement and test chaotic iterative solvers.

Published
2014

17. Grid-based GA path planning with improved cost function for an over-actuated hover-capable AUV

Author

Tanakitkorn, Kantapon, Wilson, P.A., Turnock, S.R., and Phillips, A.B.

Abstract

For an AUV to perform a long-range mission with its maximum endurance, its energy consumption during transit must be kept to a minimum. This paper presents an improved cost function for a grid-based genetic algorithm (GA) path planning in 2D static environments. The proposed function consists of energy consumption terms that are estimated according to dynamics of a hover-capable AUV - notably Delphin2 AUV. It seeks for a path that requires least effort for the vehicle to move along. A simulation was written in Matlab and the outcomes of the GA with the improved cost function are compared with the ones of a GA with an optimal distance approach as well as an A* approach. It is found that outcomes of an improved cost function require less energy compared with the other techniques

Published
2014

18. An analysis of a swimmer’s passive wave resistance using experimental data and CFD simulations

Author

Banks, J., James, M.C., Turnock, S.R., and Hudson, D.A.

Abstract

The passive resistance of a swimmer on the free surface has previously been researched experimentally. The contribution of wave resistance to total drag for a swimmer with a velocity around 2.0 m.s-1 was found to vary from 5% for Vorontsov and Rumyantsev (2000), to 21 % for Toussaint et al. (2002) and up to 60% according to Vennell et al. (2006). The exact resistance breakdown of a swimmer remains unknown due to difficulties in the direct measurement of wave resistance. As noted by Sato and Hino (2010), this lack of experimental data makes it difficult to validate numerical simulations of swimmers on the free surface.This study is therefore aimed at presenting direct measurements of a swimmer’s total drag and wave resistance, along with the longitudinal wave cuts which may be used to validate numerical simulations. In this paper, experimental data of a swimmer’s resistance are presented at two different velocities (case 1 = 1.7 m.s-1 and case 2 = 2.1 m.s-1). Total drag was measured using force block dynamometers mounted on a custom-built tow rig (Webb et al., 2011). Moreover, a longitudinal wave cut method was used to directly evaluate wave resistance (Eggers, 1955).The two conditions tested were simulated using the open-source Computational Fluid Dynamics (CFD) code OpenFOAM (OpenFOAM® (2013)). The body geometry is a generic human form, morphed into the correct attitude and depth using the above- and under-water video footage recorded during the experiment. 3D Unsteady Reynolds-Averaged Navier-Stokes (URANS) simulations were performed using the Volume of Fluid (VOF) method to solve the air-water interface. A similar numerical technique was used by Banks (2013a) to assess the passive resistance of a swimmer. Two cases were simulated and the error in total drag compared to the experimental data was found to be 1 % and 22 % respectively. In this paper, the resistance components over a swimmer’s typical range of speeds are investigated and compared with the experimental data

Published
2014

19. Flow past a sphere at the free-surface using URANS

Author

James, M., Turnock, S.R., and Hudson, D.A.

Abstract

The flow past a sphere located at the free-surface, was studied over the critical Reynolds number range: 2x10^5 to 4x10^5. Experiments were carried out in the Lamont tank at the University of Southampton. Due to the inclusion of a free-surface, the solver interFoam (version OF-2.2.0) was used to simulate the flow past the sphere with a Courant number of 1.2 to allow the simulations to run faster without compensating on the results’ accuracy. Maximum wave resistance occurs when the sphere is half-submerged due the maximum crosssectional area of the sphere. The wave resistance component becomes negligible at an immersion depth greater than 175%D.

Published
2013

21. Application of the VORTFIND algorithm for the identification of vortical flow features around complex three-dimensional geometries

Author

Phillips, A.B. and Turnock, S.R.

Subjects
Physics::Fluid Dynamics
Abstract

Accurate prediction of the hydrodynamic forces and moments acting on a manoeuvring marine vehicle using Reynolds averaged Navier–Stokes simulations requires sufficient mesh resolution to capture off-body vortical structures. Because the path of these structures is not known a priori, a vortex identification and capture strategy is required alongside an iterative mesh adaption process. An improved version of the VORTFIND algorithm, which can identify multiple vortices of variable strength and rotational direction using a K-means algorithm is described. The algorithm is applied to velocity fields generated from Reynolds averaged Navier–Stokes simulations to increase the mesh resolution in the vortex core region, ensuring sufficient mesh density to capture the downstream propagation of the vortex for a submarine hull at drift and ship propeller–rudder interaction

Published
2013

23. Retro-fit solutions for energy efficient shipping

Author

Collison, R.E., James, M.C., Turnock, S.R., and Hudson, D.A.

Abstract

With the increase in fuel prices and growing pressure on the marine industry to reduce greenhouse gas emissions, there is a demand for both new and current ships in operation to develop novel ways to reduce their fuel consumption. In January 2013, the International Maritime Organisation (IMO) provided mandatory methods on how both new and existing ships will be assessed on their emissions via the Energy Efficiency Design Index (EEDI)and the Ship Energy Efficiency Management Plan (SEEMP) respectively. Existing ships are less suitable for major design changes, so they must rely on engine room systems upgrades or the use of retro-fit devices. This research paper presents how the efficiency of an existing tanker hull form could be increased by 10% with the use of cost-effective retro-fit solutions. A method, involving CFD simulations performed using OpenFOAM and validated with wind tunnel tests, is explained. An in-house code, based on the Blade-Element Momentum Theory (BEMT), is used to provide some propeller characteristics: efficiency, torque and thrust coefficients.Although, the efficiency output from the BEMT code is not the propulsive coefficient, the different appendage configurations may still be directly compared using this efficiency, denoted BEMT throughout this paper. This procedure successfully detects changes in propeller efficiency at model scale due to devices and thus provides a route to investigate a wide variety of devices. Preliminary results highlightes that efficiency gains up to 3% could be obtained with vanes and up to 9% with flow increasing ducts

Published
2013

24. University of Southampton Fluid-Structure Interactions Group OpenFOAM research

Author

Lloyd, T.P., James, M, Turnock, S.R., Phillips, A.B., Badoe, C, and Banks, J

Abstract

An overview is given of current research in maritime CFD using the open source flow solver OpenFoam through examples of unsteady propulsors representations, free surface capture and hull-propulsor-rudder interaction for energy efficient shipping. Fundamental unsteady flow as hydroacoustic sources on a 2D foil is also solved.

Published
2012

26. Initial numerical propeller rudder interaction studies to assist fuel efficient shipping

Author

Badoe, C., Phillips, A.B., and Turnock, S.R.

Abstract

The importance of a rudder cannot be understated; although relatively small, the hydrodynamic forces and moments developed on it are essential in the assessment of the manoeuvring characteristics of a ship. Additionally, ship rudders are almost always placed downstream of the propeller so they can take advantage of the increased local velocity due to the presence of the propeller. The knowledge of the interaction effects between the rudder and the propeller is a focal aspect for the improvement of ship’s performance. Propeller and rudder are considered as a propulsion unit in which the former is an active device that generates the thrust to keep the ship on move and the latter a control surface that produces the transverse force to keep the ship on course (Kracht 1992). In this paper, a method for rapidly computing the flow field and integrated forces acting on a rudder in a propeller race is presented.

Published
2012

27. Interdisciplinary research collegium in advanced maritime systems design

Author

Franklin, M., Shenoi, R.A., Wilson, P.A., Turnock, S.R., and Hudson, D.A.

Abstract

The education of naval architects, marine engineers and others who are the active contributors to the ship design processes is heavily focussed on engineering fundamentals, often aligned with traditional university course constraints. The concept of a research collegium is described whose aim is to provide an environment where young people in their formative postgraduate years can learn and work in a small, mixed discipline group drawn from the worldwide maritime community to develop their skills whilst completing a project in advanced ship design. The brief that initiates each project sets challenging user requirements which encourage each team to develop an imaginative solution, using their individual knowledge and experience, together with learning derived from teaching which form a common element of the early part of the collegium

Published
2011

29. CFD-based methods for numerical modelling of scour

Author

Melling, G., Dix, J.K., Turnock, S.R., and Whitehouse, R.

Abstract

Marine local scour is understood as the removal of sediment from around the base of an object on the seabed caused by waves and currents. The introduction of a flow obstruction to the seafloor will have a significant impact on the local hydrodynamics, causing acceleration, pressure gradients, boundary-layer separation and increased turbulence at the seabed and in the wake of the object. Where the seabed cannot resist the increased magnitude of impinging shear forces, e.g. in non-cohesive mobile sediment such as sands, sediment will be eroded to form a characteristic scour hole. Scour, left unchecked can cause structural damage and major economic losses. The ability to predict scour, both vertical and lateral, is thus a prerequisite for the optimised design of a structure and provision of scour protection.At present, empirical equations are used for simple two-dimensional objects such as vertical and horizontal cylindrical type in the forecast of maximum scour depths. Fewer relations are available for the quantification lateral scour extent and evolution of the scour pit with time. For a more comprehensive scour prediction or assessment of more complex structures, expensive and time-consuming physical model experiments are required.The aim of this PhD project is to develop a numeric method for scour modelling in openFOAM CFD which will be capable of predicting scour around complex three-dimensional seabed structures. In this study, we will focus on the discussion of the available approaches for scour modelling using CFD methods.

Published
2011

30. A method for analysing fluid structure interactions on a horizontal axis tidal turbine

Author

Nicholls-Lee, R.F., Turnock, S.R., and Boyd, S.W.

Subjects
Physics::Fluid Dynamics
Abstract

Free stream tidal turbines are rotating bodies in fast flowing tidal currents, and as such are exposed to fluctuating loads from the surrounding fluid. These time varying forces will cause the blades to deform dynamically, potentially deflecting the blade shape away from the optimum orientation as well as exciting resonant responses that may enhance fatigue loading. It is important to understand this hydroelastic response for all but the stiffest blades. A loosely coupled, modular approach to fluid structural interactions (FSI) has been developed for the analysis of horizontal axis tidal turbine blades (HATTs). This paper discusses the methodology behind the FSI process and illustrates the technique through a case study of a 20m diameter, three bladed, horizontal axis tidal turbine, in which the deflection of the blades is examined through the iterative procedure.

Published
2011

31. RANS simulations of the multiphase flow around the KCS hullform

Author

Banks, J., Phillips, A.B., Bull, P.W., and Turnock, S.R.

Abstract

A commercial RANS code is used to investigate the multiphase flow field surrounding the KCS hull form. Results are presented for the associated wave pattern (case 2.1), dynamic sinkage and trim (case 2.2b) and self propulsion parameters for the hull using a body force propeller model (case 2.3a)

Published
2010

32. Application of RANS to hydrodynamics of bilge keels and baffles

Author

Querard, A.B.G., Temarel, P., and Turnock, S.R.

Subjects
Physics::Fluid Dynamics
Abstract

This investigation first focuses on modelling the flow around cantilever plates in normal oscillation, providing key guidance for attaining sufficient accuracy for most engineering applications, in terms of turbulence modelling, mesh refinement and time step selection. The modelling approach is then applied to the hydrodynamics of a ship-like section fitted with vertical bilge keels, rolling at free surface. The results obtained from RANS are compared to available experimental data and predictions obtained from potential flow analysis. Viscous effects arising from the presence of the bilge keels are shown to influence more hydrodynamic coefficients than just roll fluid damping. Finally, empirical formulae commonly used to allow for the influence of viscous roll damping are compared to RANS predictions and experimental data.

Published
2010

33. Development of hybrid diesel - electric propulsion system for ships

Author

Dedes, E, Hudson, D.A., and Turnock, S.R.

Abstract

In our days, when environmental protection and low petroleum consumption are the top priorities of a marine engineer and a naval architect, the design and construction of fully optimized engines, smart installations and exploitation of the highest percentage of energy produced is required. As a result innovations, optimization, new concept design and simulation play a significant role in marine industry. Although 93% of the world’s trade is done by ships and by the year 2011 the emissions of CO2 will contribute to 4% of world’s CO2 emissions as well as 37% and 28% of NOx¬ and SOx emissions respectively, the marine sector is targeted.The problem of high emissions exists, when the engine operates in the non optimum condition, a percentage relevant to engine’s MCR, tuned by the engine manufacturer. This means that in transient load (project SMOKERMEN, 2002; project HERCULES, 2007) large amounts of smoke, particle matter, NOx and SOx hazardous gasses are produced. Two stroke engines on board ships are directly coupled to the propeller using a rotating shaft. While ships operate in constantly changing environment and chartering commands change during voyage, propulsion unit have to adapt its speed and produced torque. Therefore engine loading changes to less efficient points and the SFOC is increased. Meanwhile, temperature of combustion and pressure differ from the most efficient and connected to them formulation of NOx increases along with increase in SOx, CO2¬ and smoke. Our work is based on real operational data provided by a Greek maritime corporation with a fleet of 65 cargo ships. The obtained data contains information from 3 Post Panamax new built sister vessels, regarding fuel consumption, engine loading, weather and sea conditions along with bunker characteristics (e.g. Sulphur percentage). Phase one of the project is separated into 3 parts. The first part includes worldwide adopted methods for emission calculation. Project utilizes the “activity based method” (NTUA - Laboratory of Marine Transportations, 2008) which uses proper emission factors taken from relevant literature (VDMA Engines and Systems, 2008; MARPOL, 2005; EMEP/ CORINAIR, 2000). The second part, utilizes the voyage data of the vessels, correlates the consumption and engine loading with the weather characteristics. Furthermore, applies the assumption of constant loading of diesel engines and the existence of storage medium in order to estimate the fuel savings of the hybrid vessel. At the third part, industrial and market research was performed to find the proper storage medium. As first step, batteries were examined and different types were compared, judging by their energy density, weight, operational factors and restrictions. Also a proposal for sizing the alternative propulsion system was done and economical assessment was performed. Finally conclusions were discussed and they are summarized below:Hybrid Technology has significant fuel savings that can be increased due to further optimization of Turbochargers and by the operation of engine in smaller margin. Furthermore emission reduction in NOx is successful due to lower combustion temperatures. Moreover, ship design and cargo capacity will be affected making the overall task difficult. Finally, Hybrid Technology is economically feasible and the Internal Rate of Return of investment varies between 4.7% until 20.7% depending on the storage medium type and the availability of kWh.

Published
2010

34. Accurate capture of rudder-propeller interaction using a coupled blade element momentum-RANS approach

Author

Phillips, A.B., Furlong, M.E., and Turnock, S.R.

Subjects
body regions, animal structures, musculoskeletal, neural, and ocular physiology, technology, industry, and agriculture, macromolecular substances
Abstract

Ship rudders are almost always placed downstream of the propeller so they can take advantage of the increased local velocity due to the presence of the propeller race. The methods discussed in this paper replicate the flow integrated effects of the propeller which generates an accelerated and swirled onset flow onto the rudder. As long as the radial variation in axial and tangential momentum (including hull and rudder interaction effects) generated by the propeller are included, then the influence of the unsteady propeller flow can be removed and ’steady’ calculations performed to evaluate propeller rudder interaction. Three different body force propeller models will beconsidered and numerical results will be compared with experiments by Molland and Turnock [1, 2, 3], using the modified Wageningen B4.40 propeller and Rudder No.2

Published
2010

35. Kayak blade-hull interactions: A body force approach for self-propelled simulations

Author

Banks, J., Phillips, A.B., Turnock, S.R., Hudson, D.A., Taunton, D.J., Banks, J., Phillips, A.B., Turnock, S.R., Hudson, D.A., and Taunton, D.J.

Abstract

A sprint kayak experiences an unsteady flow regime due to the local influence of the paddle. However, kayak designs are usually optimised for steady-state, naked hull resistance. To determine whether unsteady paddle effects need to be included in kayak design, the hydrodynamic interactions between a kayak paddle and a hull are assessed using computational fluid dynamics. A body force model of a drag-based paddle stroke is developed using a blade element approach and validated against experimental data. This allows the paddle-induced local velocities to be simulated without the need to fully resolve the detailed flow around a moving paddle geometry. The increase in computational cost, compared to the naked hull simulation, is 8%. A case study investigating the impact of different paddle techniques on the hydrodynamic forces acting on a self-propelled kayak is conducted. A 0.23% difference in self-propelled resistance was observed, while an estimated 0.5% additional increase can be attributed to paddle-induced draught increases. An estimate of small changes in resistance on race times indicates that reductions of even a fraction of a percent are worth pursuing, indicating that the developed methodology may provide a useful design tool in the future.

Published
2014

36. Model predictive control of a hybrid autonomous underwater vehicle with experimental verification

Author

Steenson, L.V., Turnock, S.R., Phillips, A.B., Harris, C., Furlong, M.E., Rogers, E., Wang, L., Bodles, K., Evans, D.W., Steenson, L.V., Turnock, S.R., Phillips, A.B., Harris, C., Furlong, M.E., Rogers, E., Wang, L., Bodles, K., and Evans, D.W.

Abstract

In this work model predictive control is used to provide transit and hover capabilities for an autonomous underwater vehicle where the description of the system dynamics used include terms measured experimentally. The resulting controller manoeuvres the vehicle in the presence of constraints on the actuators and results obtained from the deployment of the vehicle in an inland lake for the study of the Zebra mussel, an invasive species, are also given.

Published
2014

37. Fluid-structure interactions of anisotropic thin composite materials for application to sail aerodynamics of a yacht in waves

Author

Trimarchi, D., Turnock, S.R., Chapelle, D., and Taunton, D.

Abstract

In recent years technological innovations has allowed large improvements to be made in sail design and construction. Sails and in particular kite-sails have application for sport, ships’ auxiliary propulsion and even power generation. Sails are divided into upwind and downwind sails (Fig.1), where upwind sails operate as lifting surfaces with small angles of attack whereas traditional downwind sails acted as drag device. New designs of downwind sails have reduced the area of separated flow and increased the lifting behaviour of the sails. In order to capture the lifting behaviour and regions of separation present in both types of sail careful application of computational fluid dynamic analysis tools are required. Solutions of the Reynolds averaged Navier- Stokes equations (RANSE) are often used as a part of the design process of high performance sailing yachts.The present paper discusses some initial investigations and future guidelines in order to get a more detailed description of the physics involved in sail FSI. Three main fields are therefore covered: the use of CFD in order to accurately capture flow features and a comparison with experimental results; structural modelling; and approach to coupling

Published
2009

38. Tidal turbines that survive?

Author

Turnock, S.R., Nicholls-Lee, R., Wood, R.J.K., and Wharton, J.A.

Abstract

Tidal turbines offer an exciting opportunity to exploit ocean current flows to generate sustainable energy. However, a key to their success is the ability to operate with minimal intervention in the ocean over extended periods (15-20 years). This talk explored the likely design and operational issues that will influence satisfactory performance associated with material corrosion and biofouling. The main difficulty is that turbine economic viability is capital driven so whole system, including operation and maintenance needs to be as cost-effective as possible. Although can use approaches developed from those applied for ship design and in the offshore industry there is a need to appreciate that cost-drivers are different. For instance a ‘Gold plated’ technology approach from oil and gas industry may not deliver cost-effective solutions.

Published
2009

39. Use of cryogenic buoyancy systems for controlled removal of heavy objects from the seabed

Author

Nicholls-Lee, R.F., Boyd, S.W., and Turnock, S.R.

Abstract

The concept design of a lightweight cryogenic marine heavy lift buoyancy system has been investigated. The approach makes use of a novel cryogenic system for provision of buoyancy within the ocean environment. The objective is to be able to lift or lower large displacement objects under full remote control. The nature of subsea lifting and lowering operations requires a high degree of precise control for operational safety, reasons and to preserve the structural integrity of the load. The lift operation occurs in two phases: Development of lift to overcome seabed suction, and then rapid reduction of buoyancy to maintain a controlled ascent. Descent involves controlled release of the buoyancy. The proposed buoyancy system consists of a buoyancy chamber and an integral cryogenic gas generation unit. The application of an on-board gas generation unit allows the removal of the engineering challenges associated with use of compressors and the concomitant complex manifold of connecting umbilical pipe work. It provides for a fully remote system completely eliminating all risk associated with extensive physical surface to subsea connection throughout the entire lift operation. The opening stages of the project work include the development of a system that will operate efficiently and effectively to a depth of 350m. An initial general arrangement for the buoyancy system has been developed. A number of these systems involve considerable design and development, these include: structural design of the buoyancy chamber, mechanical systems to control and connection to the lift device, the cryogenic system itself and overall process control systems. As part of the design process for such an arrangement, numerical simulation of the complete system has been undertaken in order to develop mechanical, cryogenic and process control systems efficiently and effectively. This system simulation has been developed using Matlab Simulink. This paper considers the overall design concept and associated system development issues. These are illustrated through use of the time accurate simulation of alternative design configurations that confirm the viability of the concept. A main conclusion is that minimisation of the dry weight of the system is critical to cost-effective operation of the project.

Published
2009

40. Design metrics for evaluating the propulsive efficiency of future ships

Author

Molland, A.F., Turnock, S.R., and Hudson, D.A.

Subjects
ComputerApplications_COMPUTERSINOTHERSYSTEMS
Abstract

There is an increasing need for the ship design process to take account of environmental issues such as the emission of greenhouse gases and the likely extension of a carbon dioxide charging mechanism to international shipping. These issues, together with the need for economic viability, provide further incentives to improve the efficiency of propulsion of ships. The main components of powering are firstly reviewed. Individual components and other power saving devices are identified which should contribute to improvements in the overall efficiency of propulsion. Suitable design metrics and procedures, taking into account economic and environmental factors, are recommended for the design of future ships.

Published
2009

41. Design and Control of a Flight-Style AUV with Hovering Capability

Author

Liu, J., Furlong, M.E., Palmer, A., Phillips, A.B., Turnock, S.R., and Sharkh, S.M.

Abstract

The small flight-style Delphin AUV is designed to evaluate the performance of a long range survey AUV with the additional capability to hover and manoeuvre at slow speed. Delphin’s hull form is based on a scaled version of Autosub6000, and in addition to the main thruster and control surfaces at the rear of the vehicle, Delphin is equipped with four rim driven tunnel thrusters. In order to reduce the development cycle time, Delphin was designed to use commercial-off-the-shelf (COTS) sensors and thrusters interfaced to a standard PC motherboard running the control software within the MS Windows environment. To further simplify the development, the autonomy system uses the State-Flow Toolbox within the Matlab/Simulink environment. While the autonomy software is running, image processing routines are used for obstacle avoidance and target tracking, within the commercial Scorpion Vision software. This runs as a parallel thread and passes results to Matlab via the TCP/IP communication protocol. The COTS based development approach has proved effective. However, a powerful PC is required to effectively run Matlab and Simulink, and, due to the nature of the Windows environment, it is impossible to run the control in hard real-time. The autonomy system will be recoded to run under the Matlab Windows Real-Time Windows Target in the near future. Experimental results are used to demonstrating the performance and current capabilities of the vehicle are presented.

Published
2009

42. [Report of] Specialist Committee V.4: ocean, wind and wave energy utilization

Author

Nielsen, F.G., Argyriadis, K., Fonseca, N., Le Boulluec, M., Liu, P., Suzuki, H., Sirkar, J., Tarp-Johansen, N.J., Turnock, S.R., Waegter, J., and Zong, Z.

Subjects
Physics::Atmospheric and Oceanic Physics
Abstract

The committee's mandate was :Concern for structural design of ocean energy utilization devices, such as offshore wind turbines, support structures and fixed or floating wave and tidal energy converters. Attention shall be given to the interaction between the load and the structural response and shall include due consideration of the stochastic nature of the waves, current and wind.

Published
2009

43. Investigating sailing styles and boat set-up on the performance of a hydrofoiling Moth dinghy

Author

Findlay, M.W. and Turnock, S.R.

Abstract

The adoption of hydrofoils in the International Moth class of dinghy has posed new challenges to sailors both in terms of the set-up of the boat and hydrofoils, and their sailing techniques and styles. The experience of sailors in the class indicates that the height above the water surface at which the boat is flown (ride height) and the amount of windward heel (heel angle) are critical factors affecting performance, particularly in upwind sailing. The fore-aft position of the helm affects the stability of the craft and, in conjunction with the aft foil settings, alters the pitch orientation of the craft and offers potential for significant gains in performance. A four degree of freedom velocity prediction programme (VPP) with the capability to investigate these factors is presented and used to demonstrate how the fore-aft position of the helm and the aft foil may be used in conjunction to maximise speed.

Published
2008

44. Performance prediction of a free stream tidal turbine with composite bend-twist coupled blades

Author

Nicholls-Lee, R.F., Turnock, S.R., and Boyd, S.W.

Subjects
Physics::Fluid Dynamics
Abstract

Free stream tidal turbines are a source of growing interest in the marine renewable energy field. Some designs use variable pitch blade control devices in order to maximize the efficiency of the turbines; however these are complex to design, construct and maintain under the severe load conditions sub sea devices experience. There is an interest in the use of composite materials for potential improvements in hydrodynamic and structural performance of Horizontal Axis Tidal Turbines (HATT). In addition to the advantages of high strength-to-mass and high strength to stiffness ratios, anisotropy of the laminated fibre composites can be designed to allow 3D tailoring of the blade deformation. Anisotropic structures show different levels of elastic coupling, depending on the ply angle in the layers that comprise such a material. Passive control of a turbine blade can be achieved by taking advantage of the directionality of the anisotropic composite material. A structure that undergoes both bending and twisting due to a pure bending load is said to exhibit bend-twist coupling. This type of behaviour has been identified as a potential method for load reduction - particularly fatigue loads, and an increase in both efficiency and annual energy capture in wind turbines [1]. Preliminary studies have since shown that this may also be the case for HATTs [2]. A computationally efficient, yet realistic, model has been developed in order to estimate the amount of induced twist present on a bend-twist coupled blade in a tidal stream. This model takes into account the effect on the induced twist of fibre orientation, blade loading and cross section, material mechanical properties, and shell thickness. The method has been incorporated into a Blade Element Momentum code, modified to predict the performance of free stream tidal devices; such that the performance of a HATT with composite bend-twist coupled blades could be estimated. It has been shown that, when compared to a free stream tidal turbine with fixed blades of a similar configuration, a HATT that utilises composite bend-twist couple blades can reduced fatigue loading, bring the turbine efficiency closer to the Betz limit and increase the annual energy capture.

Published
2008

45. Comparisons of CFD simulations and in-service data for the self propelled performance of an Autonomous Underwater Vehicle

Author

Phillips, A.B., Turnock, S.R., and Furlong, M.

Abstract

A blade element momentum theory propeller model is coupled with a commercial RANS solver. This allows the fully appended self propulsion of the autonomous underwater vehicle Autosub 3 to be considered. The quasi-steady propeller model has been developed to allow for circumferential and radial variations in axial and tangential inflow. The non-uniform inflow is due to control surface deflections and the bow-down pitch of the vehicle in cruise condition. The influence of propeller blade Reynolds number is included through the use of appropriate sectional lift and drag coefficients. Simulations have been performed over the vehicles operational speed range (Re = 6.8 × 106 to 13.5 × 106). A workstation is used for the calculations with mesh sizes up to 2x106 elements. Grid uncertainty is calculated to be 3.07% for the wake fraction. The initialcomparisons with in service data show that the coupled RANS-BEMT simulation under predicts the drag of the vehicle and consequently the required propeller rpm. However, when an appropriate correction is made for the effect on resistance of various protruding sensors the predicted propulsor rpm matches well with that of in-service rpm measurements for vessel speeds (1m/s - 2m/s). The developed analysis capturesthe important influence of the propeller blade and hull Reynolds number on overall system efficiency.

Published
2008

46. The simulation of free surface flows with Computational Fluid Dynamics

Author

Godderidge, B, Phillips, A.B., Lewis, S.G., Turnock, S.R., Hudson, D.A., and Tan, M.

Abstract

Computational fluid dynamics is a powerful and versatile tool for the analysis of flow problems encountered in themaritime environment. The University of Southampton Fluid-Structure Interactions research group use ANSYS CFX tomodel a wide variety of flow problems; to gain insight into flow physics, improve designs and increase the efficiencyand safety of marine vehicles. A series of three case studies from on-going research looks at: loads applied on liquefiednatural gas tanks due to sloshing, slamming pressures experienced by high speed craft as well as the influence ofpropellers on the resistance characteristics of autonomous underwater vehicles. The presence of the free surface,complex shapes and the unsteady nature of these applications make their simulation with computational fluid dynamicsparticularly challenging. The successful validation of the computational models has resulted in the development of aselection process for suitable multiphase models as well as cost-effective meshing strategies.

Published
2008

47. Investigation of the effects of hydrofoil set-up on the performance of an international moth dinghy using a dynamic VPP

Author

Findlay, M.W. and Turnock, S.R.

Abstract

The International Moth dinghy is a 3.355m long single handed, una-rigged monohull dinghy. The class rules allow the use of hydrofoil that in certain wind conditions can significantly reduce resistance. A new velocity prediction program (VPP) has been developed to evaluate the impact of hydrofoil design and set-up on the performance of a Moth dinghy by simulating racing on a windward - leeward course. The VPP generates polar diagrams indicating the speed of the craft in a range of true wind strengths and angles. Sail force and windage are modelled using aerofoil theory. The drag model includes hull skin friction and residuary resistance, profile and induced drag for every foil, wavemaking drag of the lifting foils and spray drag of the surface piercing foils. Using an iterative process the VPP determines the boat speed that balances resistive forces with drive force, heeling moment and righting moment and vertical lift forces with weight. A series of case studies demonstrate the use of the VPP by examining the effects of changing the span of the forward foil, adding end plates, and using different foil geometries on performance.

Published
2008

48. Urans simulations of static drift and dynamic manoeuvres of the KVLCC2 tanker

Author

Turnock, S.R., Phillips, A.B., and Furlong, M.

Abstract

Computational Fluid Dynamics is used to investigate the global forces and moments acting on the KVLCC2 hull form under going straight line, drift and pure sway planar motion mechanism tests. Simulated results are compared with experimental results for the unappended hull in shallow waterand a fully appended hull with a propeller acting at the ship self propulsion point. A body fitted mesh undergoes transverse motion within an overall fixed mesh to capture planar motion mechanism tests. A blade element momentum code is coupled with the RANS solver for the self propulsion case. A workstationis used for the calculations with mesh sizes up to 2x106 elements. Computational uncertainty is typically 2-3% for side force and yaw moment but greater than 15% for resistance. With this mesh motion strategy manoeuvres can be well represented within a practical computational time scale.

Published
2008

49. Development of a floating tidal energy system suitable for use in shallow water

Author

Turnock, S.R., Muller, G., Nicholls-Lee, R.F., Denchfield, S., Hindley, S., Shelmerdine, R., and Stevens, S.

Abstract

A proposal is made for the use of a traditional streamwaterwheel suspended between two floating catamaranNPL series demi-hulls as means of generating electricalpower. Two prototype devices, of lengths 1.6m and 4.5m,have been developed, constructed and tested. It was foundthat the concept is sound although greater investment isrequired with regards to the materials and bothhydrodynamic and aerodynamic design of the waterwheelto ensure an economically viable system. The workpresented concentrates on practical aspects associated withdesign, construction and trial testing in Southampton waterof the 4.5m prototype. The relatively low cost, ease ofdeployment, and the fact that conventional boat mooringsystems are effective, combine to make this an attractivealternative energy solution for remote communities.

Published
2007

50. Robo-Yacht: a human behaviour-based tool to predict the performances of yacht-crew systems

Author

Scarponi, M., McMorris, T., Shenoi, R.A., Turnock, S.R., and Conti, P.

Abstract

Many numerical tools are available in the yacht design domain to predict yacht performances. These are based on experimental data and well-established numerical techniques. However, being competitive sailing an uncertainty-rich discipline, there is also a need to assess the performances of a yacht’s crew. This is indeed the main area for performance gains. The present study aims at predicting the performances of yacht-crew systems, by including numerical models for human behaviour within those referred to the yacht dynamics. In particular, the problem of decision-making under weather uncertainty is formulated in terms of a game of chance having nature as a second player and involving risk. Within this context, it is shown that decisionmaking models often used in management sciences can be advantageously used. This approach has led to the development of a sailing simulator referred to as ‘Robo-Yacht’, based on the International America’s Cup Class. A case study is investigated that involves three strategical alternatives and four possible weather scenarios: gains and losses are assessed through the simulator and a formula to express expected payoffs is derived. When different attitudes towards risk (neutral, risk-averse and risk-taking) are expressed as different utility functions, it is shown that sailors’ choices can be conveniently modeled based on a maximization of expected utility. The ‘automatic crew’ can actually make decisions that appear to be consistent with widely accepted principles of race strategy. A risk function is also derived in order to take into account opponents’ choices and, where necessary, modify the strategic plan accordingly.

Published
2007

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