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DC Electrode Positive Polarity. (Direct Current Reverse Polarity) (see Figure B.5)
In this case, there is a continuous flow of electrons from the workpiece to the electrode. The reverse polarity is used for welding alloys covered with a layer of refractory oxide.
With this polarity the electrode functions as anode and is subjected to a high degree of heat; the workpiece is bombarded by positive ions sent from the electrode which break the surface oxide.
In Electrode Positive Polarity, high currents cannot be used, since they would cause an excessive wear of the electrode.
NOTE: (The Invertec
FIGURE B.5
D.C.-Pulsed TIG
(see Figure
The use of pulsed direct current allows better control of the weld pool during certain operating conditions.
When compared with traditional TIG welding per- formed at the same average current, pulsed welding results in a smaller heat affected zone which results in fewer deformations and reduced chance of cracking and gas entrapment.
Increasing the frequency constricts the arc, increases stability and improves weld quality.
FIGURE B.6
DC TIG- NOT PULSED
A.C. (Alternating Current) (AC/DC model only)
(see Figure B.7)
Alternating Current welding is typically used for Tig welding aluminum (and its alloys) or magnesium. The polarity alternates between Electrode Positive and Electrode Negative (EN). During the positive half- wave the oxide is broken. During the negative half- wave, the electrode cools, the workpiece melts and penetration occurs.
FIGURE B.7
Greater % EN = MORE PENETRATION | 50% (EN) | Lesser % EN = more CLEANING |
Changing the wave balance alters the ratio between the cleaning and the penetrating current.
When AC welding, a pulsed current can be used, with similar effects to those described in pulsed direct current welding.
FIGURE B.8
A.C.- PULSED TIG