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Simulation of Internal Wave Wakes and Comparison with Observations J.K.E. Tunaley London Research and Development Corpor

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.com /. Outline. Objectives Modelling

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Simulation of Internal Wave Wakes and Comparison with Observations J.K.E. Tunaley London Research and Development Corpor

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  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.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 CB = 0.60

  11. Taylor Offsets Stern Bow

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

  13. Sir Tristram Parameters

  14. Simulated Wake

  15. Observed Surface Velocity From Watson et al, 1992

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

  17. Simulated Surface Velocity Taylor CB=0.48 DTMB CB=0.6 DTMB CB=0.8 Taylor CB=0.7

  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 CB • Shifts shoulder downwards in plots as CB increases

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