Sindo Kou

Welding Metallurgy


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        EBW : The keyhole in EBW acts like a “black body” trapping the energy from the electron beam. As a result, the efficiency of the electron beam is very high.

Schematic illustration of the heat source efficiencies in several welding processes.

      2.1.2 Melting Efficiency

      where V is the welding speed, H base the energy required to raise a unit volume of base metal to the melting point and melt it, and H filler the energy required to raise a unit volume of filler metal to the melting point and melt it. The quantity inside the parentheses represents the volume of material melted while the denominator represents the heat transfer from the heat source to the workpiece.

Schematic illustration of the melting efficiency: (a) transverse weld cross section, (b) lower heat input and welding speed, (c) higher at higher heat input and welding speed, (d) variation with dimensionless parameter ηEIV/Hαv.

      Source: DuPont and Marder [7]. Welding Journal, December 1995, © American Welding Society

      .

      Figures 2.9b,c show the transverse cross‐sections of two steel welds differing in the melting efficiency [7]. Here, EI = 3825 W and V = 10 mm/s for the shallower weld of lower melting efficiency (Figure 2.9b) and EI = 10 170 W and V = 26 mm/s for the deeper weld of higher melting efficiency (Figure 2.9c). Note that the ratio EI/V is about the same in the two cases.

      Fuerschbach and Knorovsky [5] proposed the following empirical equation for the melting efficiency:

      or

      (2.7)equation

      It should be noted that the melting efficiency cannot be increased indefinitely by increasing the welding speed without increasing the power input. To do so, the power input must be increased along with the welding speed. It should also be noted that in the presence of a surface‐active agent such as sulfur in steel, the weld pool can become much deeper even though the welding parameters and physical properties in Eq. (2.5) remain unchanged (Chapter 3).

      2.1.3 Power Density Distribution of Heat Source

      2.1.3.1 Effect of Electrode Tip Angle

Schematic illustration of the effect of electrode tip angle on shape and power density distribution of gas–tungsten arc. Schematic illustration of the effect of electrode tip angle on shape of gas–tungsten arc.

      Source: Glickstein [15]. Welding Journal, August 1976, © American Welding Society.

Schematic illustration of the effect of electrode tip geometry on shape of gas–tungsten arc welds in </p>
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