Copper Tig Welding; Continuous Wire Welding (Mig/Mag) - voestalpine Böhler Welding URANOS 2000 SMC Betriebsanweisung

Preparing the edges
Careful cleaning and preparation of the edges are required.
Choosing and preparing the electrode
You are advised to use thorium tungsten electrodes (2% thorium-
red coloured) or alternatively cerium or lanthanum electrodes
with the following diameters:
Ø electrode (mm)
1.0
1.6
2.4
The electrode must be sharpened as shown in the figure.
(°)
30
60÷90
90÷120
Filler metal
The filler rods must have mechanical characteristics comparable
to those of the parent metal.
Do not use strips obtained from the parent metal, since they
may contain working impurities that can negatively affect the
quality of the welds.
Shielding gas
Typically, pure argon (99.99%) is used.
Welding Ø Electrode
current (A) (mm)
6-70 1.0
60-140 1.6
120-240 2.4

7.2.2 Copper TIG welding

Since TIG welding is a process characterized by high heat con-
centration, it is particularly suitable for welding materials with
high thermal conductivity, like copper.
For TIG welding of copper, follow the same directions as for TIG
welding of steel or special instructions.

7.3 Continuous wire welding (MIG/MAG)

Introduction
A MIG system consists of a direct current power source, wire
feeder, wire spool, torch and gas.
MIG manual welding system
The current is transferred to the arc through the fusible elec-
trode (wire connected to positive pole); in this procedure the
melted metal is transferred onto the workpiece through the arc
stream. The automatic feeding of the continuous filler material
electrode (wire) is necessary to refill the wire that has melted
during welding.
54
current range (A)
15÷75
60÷150
130÷240
current range (A)
0÷30
30÷120
120÷250
Gas nozzle Argon flow
n° Ø (mm) (l/min)
5-6
4/5 6/8.0
6-7
4/5/6 6.5/8.0/9.5
7-8
6/7 9.5/11.0
Methods
In MIG welding, two main metal transfer mechanisms are
present and they can be classified according to the means by
which metal is transferred from the electrode to the work-
piece. The first one, defined "SHORT-ARC", produces a small,
fast-solidifying weld pool where metal is transferred from the
electrode to the workpiece only for a short period when the
electrode is in contact with the weld pool. In this timeframe,
the electrode comes into direct contact with the weld pool
generating a short circuit that melts the wire which is there-
fore interrupted. The arc then turn on again and the cycle is
repeated (Fig. 1a).
Fig. 1a
Fig. 1b
SHORT cycle (a) and SPRAY ARC welding (b)
Another mechanism for metal transfer is called the "SPRAY-
ARC" method, where the metal transfer occurs in the form of
very small drops that are formed and detached from the tip of
the wire and transferred to the weld pool through the arc stream
(Fig. 1b).
Welding parameters
The visibility of the arc reduces the need for the user to strictly
observe the adjustment tables as he can directly monitor the
weld pool.
- The voltage directly affects the appearance of the bead, but
the dimensions of the weld bead can be varied according to
requirements by manually moving the torch to obtain variable
deposits with constant voltage.
- The wire feeding speed is proportional to the welding cur-
rent.
Fig.2 and 3 show the relationships between the various welding
parameters.
Fig.2 Diagram for selection the of best working characteristic.