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Simulation of Internal Wave Wakes and Comparison with Observations J.K.E. Tunaley London Research and Development Corporation, 114 Margaret Anne Drive,

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Presentation on theme: "Simulation of Internal Wave Wakes and Comparison with Observations J.K.E. Tunaley London Research and Development Corporation, 114 Margaret Anne Drive,"— Presentation transcript:

1 Simulation of Internal Wave Wakes and Comparison with Observations J.K.E. Tunaley London Research and Development Corporation, 114 Margaret Anne Drive, Ottawa, Ontario K0A 1L0, Tel: 1-613-839-7943 http://www.London-Research-and-Development.comhttp://www.London-Research-and-Development.com/

2 Outline Objectives Modelling Loch Linnhe Trials Hull Designs Simulations Discussion

3 Objectives Towards an evaluation of use of internal wave wakes in wide area maritime surveillance Towards understanding their generation from surface ships – Start with simplest scenario – Surface ship with stationary wake (in ship frame) The effect of hull form on the wake

4 Georgia Strait: ERS1

5 Modelling Layer models – Discrete (e.g. loch, fjord) – Diffuse Internal wave wake model – Linearized – Far wake

6 Loch Linnhe Trials Trials from 1989 to 1994 in Scotland Ship displacements from 100 to 30,000 tonnes Shallow layer Ship speeds typically 2 to 4 m/s Wake angles 10 to 20º Airborne synthetic aperture radars From Watson et al, 1992

7 Wigley Hull Canoe shaped: Parabolic in 2-D, constant draft Useful theoretical model but block coefficient is 4/9

8 Wigley Offsets

9 Practical Hulls Taylor Standard Series – Twin screw cruiser David Taylor Model Basin Series 60 – Single screw merchant National Physical Laboratory – Round bilge, high speed displacement hulls Maritime Administration (MARAD) Series – Single screw merchant, shallow water British Ship Research Association Series – Single screw merchant

10 DTMB Offsets C B = 0.60

11 Taylor Offsets SternBow

12 Sir Tristram, 2m/s From Watson, Chapman and Apel, 1992

13 Sir Tristram Parameters Ship Length, L (m)136 Ship Beam, B (m)17 Ship Draft, T (m)3.9 Estimated Block Coefficient, C B 0.59 Ship Speed, U (m/s)2.0 Layer Depth, h (m)3.0 Layer Strength, δ0.004 Pixel size (m 2 )4x4

14 Simulated Wake

15 Observed Surface Velocity From Watson et al, 1992

16 Simulated Surface Velocity Wigley: h=5.0 m, δ=0.0024 Wigley: h=3.0 m, δ=0.004)

17 Simulated Surface Velocity Taylor C B =0.48DTMB C B =0.6 Taylor C B =0.7 DTMB C B =0.8

18 Effect of Hull Model In this application: – Minor changes to velocity profile as a function of hull model – Minor changes to velocity profile as a function of C B – Shifts shoulder downwards in plots as C B increases

19 Olmeda (cf Stapleton, 1997) Length = 180 m Beam = 26 m Draft = 9.2 m Speed = 2.2 m/s Wake Angle 18º Layer: h = 3 m, δ = 0.004 Taylor C B =0.7

20 Conclusions Simulations are reasonably consistent with observations Sir Tristram observed maximum water velocity at sensor is about 3 cm/s; same as simulations Olmeda observed maximum velocity at sensor is about 5 cm/s; same as simulations Wake determined mainly by block coefficient Structure in first cycle appears to be similar in observations and simulations

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