The Paton Welding Journal, 2022, #3, 9-18 pages
Characteristics of high-frequency pulsed current arc with refractory cathode
I. Krivtsun1, V. Demchenko1, I. Krikent1, U. Reisgen2, O. Mokrov2, R. Sharma2
1E.O. Paton Electric Welding Institute of the NASU.
11 Kazymyr Malevych Str., 03150, Kyiv, Ukraine. E-mail: krivtsun@paton.kiev.ua
2RwtH Aachen University, iSf – welding and Joining institute
pontstr. 49, 52062, Aachen, germany
Abstract
A self-consisted mathematical model is presented, describing nonstationary processes of energy, momentum, mass and charge
transfer in plasma column and anode boundary layer of an electric arc burning in atmospheric pressure inert gas at pulsed modulation
of current. A numerical study of distributed and integrated characteristics of 2 mm long argon arc was performed in the
case of current modulation by rectangular pulses at 10 kHz frequency and different values of the duty cycle (0.3; 0.5; 0.7) under
the condition that the average current value remains unchanged and equal to 140 A. Calculated time dependencies of plasma
temperature, velocity and current density in the arc column centre, as well as axial values of plasma temperature and pressure
near the anode surface, anode current density and heat flux into the anode are given for the selected values of duty cycle. Radial
distributions of averaged over the current modulation period heat flux, introduced by the arc into the anode, pressure and force
of friction of arc plasma flow on its surface were calculated, which are the determinant ones for simulation of thermal and
hydrodynamic processes in the metal being welded in tig welding with high-frequency pulsed current (HfpC) modulation.
Results of simulation of nonstationary arc characteristics are compared with the respective results for a direct current (DC) arc,
at current equal to average value of modulated current. Analysis of the obtained results leads to the conclusion that in the case of
HFPC TIG welding at 10 kHz frequency decrease of duty cycle (increase of pulse current) at constant value of average current
leads to greater force impact of such an arc on weld pool metal and to increase of its penetrability, respectively.
Keywords: electric arc, refractory cathode, arc column, anode boundary layer, tig welding, pulsed current modulation,
frequency, duty cycle, simulation
Received: 13.04.2022
Accepted: 16.05.2022
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Suggested Citation
I. Krivtsun, V. Demchenko, I. Krikent, U. Reisgen, O. Mokrov, R. Sharma (2022) Characteristics of high-frequency pulsed current arc with refractory cathode.
The Paton Welding J., 03, 9-18.