1. Presented by:- SWAPNIL S. CHILLE TE-Mechanical Exam no:-

4. Very High Pressure Very Low Temperature Wet Gas Dissolved in Water In this condition normal welding is impossible  Under water welding method enables us to weld properly under this condition.  Under water welding is an important tool for under water fabrication work.

5. What is under water welding?  Under water welding is the process of welding at elevated pressures, normally underwater.  A number of different welding techniques can be used underwater.

6. HISTORY  The first ever under water welding was carried out by British Admiralty for sealing leaking ship rivets below the water line.  In 1946 special waterproof electrodes were developed in Holland by Van Der Willingen.

7. UNDER WATER WELDING WET WELDING DRY/HYPERBARIC WELDING

8. WET WELDING  Wet Welding indicates that welding is performed underwater, directly exposed to the wet environment.  A special electrode is used and welding is carried out manually just as one does in open air welding.  Supply is connected to the welder/driver via cables or hoses

9.  MMA (Manual Metal Arc) welding is commonly used process in the repair of offshore platforms.  Complete insulation of the cables and hoses are essential in case to prevent the chance for electric shock

10.  The work is connected to the positive side of dc source and electrode to the negative  The two parts of the circuit are brought together and then slightly separated  An electric current occurs in the gap and causes a sustained spark which melts the bare metal forming a weld pool PRINCIPLE OF OPERATION

11.  The flux covering the electrode melts to provide a shielding gas.  Arc burns in the cavity formed inside the flux covering, which is designed to burn slower than the metal barrel to the electrode

12. Advantages  The versatility and low cost.  Less costlier than dry welding.  Speed with which it is carried out  No enclosures so no time is lost for building.

13. Disadvantages  Rapid quenching of the weld metal by the surrounding water.  Welders working under water are restricted in manipulating arc.  Hydrogen embrittlement causes cracks.  Poor visibility due to water contaminance.

14.  chamber is created near the area to be welded and the welder does the job by staying inside the chamber.  It produces high quality weld joints.  The gas-tungsten arc welding process is used mostly for pipe works  Gas metal arc welding is the best process for this welding. DRY WELDING

15. CLASSIFICATION OF DRY WELDING There are two basic types of dry welding : i.Hyperbaric welding ii.Cavity welding

16. Hyper baric welding:-  It is carried out in chamber sealed around the structure to be welded  The chamber is filled with a gas at the prevailing pressure, to push water back  The welder fitted with breathing mask and other protective devices on the pipe line  Mask filled with a breathable mixture of helium and oxygen in the habitat  The area under the floor of the habitat is open to water, so hyper baric welding is termed as “HABITATWELDING”

17. Limitation:-  As depth increase pressure also increases, it affects both for driver and welding process

18. Cavity welding:-  Cavity welding is another approach to weld in water free environment  Conventional arrangements for feeding wire and shielding gas  Introducing cavity gas and the whole is surrounded by a trumpet shaped nozzle through which high velocity conical jet of water passes.  It avoids the need for a habitat chamber and it lends itself to automatic and remote control.  The process is very suitable for flat structures

19. Advantages:-  Welder/diver safety  Good quality weld  Surface monitoring  Non destructive testing

20. Disadvantages:-  The habitat welding requires large quantities of complex equipment and much support equipment on the surface  Cost is extremely high

21. RISKS & PRECAUTIONS  Risk of electric shock so achieving electrical insulation of electrical welding equipments  Hydrogen and oxygen are produced by the arc in wet welding are potentially explosion so precaution must be taken to avoid the build up of pockets of gas  The life or health of the welder will be in risk from nitrogen introduce into the blood stream, precautions include the provision of an emergency air or gas applied

22. Scope of further developments  Hyper baric welding is well established and generally well researched.  Research being carried out for welding at a range of 500 to 1000m deep.  THOR-1 (Tig Hyperbaric Orbital Robot) is developed where diver performs pipe fitting, installs the tracks and orbital head on the pipe and rest process is automated.

23. APPLICATIONS  Offshore construction for tapping sea resources  Temporary repair work caused by ship’s collisions, unexpected accidents  Salvaging vessels sunk in the sea  Repair and maintenance of ships  Construction of large ships beyond the capacity of existing docks