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TMR4225 Marine Operations, Lecture content:

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1 TMR4225 Marine Operations, 2006.02.16 Lecture content:
AUV hydrodynamics Mathematical model – 6 DOF HUGIN navigation and control system

2 HUGIN history AUV demo (1992-3) HUGIN I & II (1995-6)
Diameter: m Length: 3.62/4.29 m Displacement: m**3 HUGIN I & II (1995-6) Diameter: m Length: 4.8 m Displacement: m**3 HUGIN 3000C&C and 3000CG ( ) Diameter: m Length: 5.3 m Displacement: m**3

3 Hugin UUV

4 Actual HUGIN problems Roll stabilization of HUGIN 1000
Low metacentric height 4 independent rudders PI type regulator with low gain, decoupled from other regulators (heave – pitch – depth, sway – yaw, surge) Task: Keep roll angle small ( -> 0) by active control of the four independent rudders Reduce the need for thrusters and power consumption for these types of tasks Docking on a subsea installation Guideposts Active docking devices on subsea structure (robotic arm as on space shuttle for capture of satelittes)

5 Principal Investigator
AUV-LAB MIT Odyssey IV Principal Investigator C. Chryssostomidis F. Hover Design Team R. Damus S. Desset J. Morash V. Polidoro

6 Russian proposal for Arctic oil and gas production
No existing infrastructure Harsh environment (ice and low temperatures) Using subsea vehicles for drilling and prosuction

7 A future Arctic oil and gas scenario

8 Underwater Drilling System
Submarine Drilling Vessel Bottom Template

9 Possible Shtokman solution?
SDV TRUV SSV ROV BT TLP Container TMS 2…3 km

10 % probability of sea ice (April) in Barents Sea (Orheim, Houston, 2005)
Shtokman

11 Example: 3 days track for iceberg (marking per 3 hours) (Orheim, Houston, March 2005)

12 Phases of an AUV/UUV mission
Pre launch Launching Penetration of wave surface (splash zone) Transit to work space Entering work space, homing in on work task Completing work task Leaving work space Transit to surface/Moving to next work space Penetration of surface Hook-up, lifting, securing on deck

13 Group work no. 1 – Student feedback
Launching Launching arrangement; A-Frame, crane etc Readiness for operation, eg. various equipment on board All openings on the hull surface must be closed (watertightness)

14 Group work no. 1 – Student feedback
Penetration of splash zone Impact loads Hydro-elasticity Relative motion; phase, amplitude, frequency Change of parametres from air to water (buoyancy, eigenfrequency, etc.) Wire tensions

15 Group work no. 1 – Student feedback
Transit to work space Navigation/control system (current/flow/(diving)), DP Buoyancy during transit ( different layers of salinity in the sea) Resistance/propulsion/endurance/power supply Material/hullform ( the vehicle has to withstand high external pressure)

16 Group work no. 1 – Student feedback
Entering work space, homing in on work task No group looked at this activity

17 Group work no. 1 – Student feedback
Completing work task Battery capacity Check if mission is completed Check the current conditions Safe manoeuvring to avoid collisions, damage of propellers Interaction between thrusters

18 Group work no. 1 – Student feedback
Leaving work space No group looked at this activity

19 Group work no. 1 – Student feedback
Transit to surface/Moving to next work place Changing buoyancy (pressure/gravity) Resistance forces (transit between workfields) Current forces Wave influence near surface Subsea navigation, track control, specification of way points

20 Group work no. 1 – Student feedback
Penetration of surface Movements induced by: Waves Current (viscous forces) Buoyancy/gravity Reaching the surface -> change of: Wetted surface (viscous) Buoyancy (volume) According to the sea state, we can have a very unstable system

21 Group work no. 1 – Student feedback
Hook-up Sea state; ship motion, AUV motion Effect of wind in the crane Centre of gravity of AUV Lifting Splash zone, wind, safety distance Securing on deck Safe bed Transport on deck to storage container

22 Web sites: http://www.ausi.org/research/research.html

23 R&D program on Underwater navigation
Develop navigation systems to be used for missions with long period of submerged vehicle Error robust systems, optimal use of working sensors Develop mathematical models and algoritms for new sensors with extreme precision In water testing of new sensors and mathematical models Project is based on experience and solutions used for the HUGIN family of vechicles

24 TMR4225 Marine Operations, Sum up the 3 most important learning outcomes of todays lecture Have your expectations been fulfilled? If not, why not?

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