TY - GEN
T1 - Electrode erosion in submerged arc furnaces
AU - Sævarsdóttir, G.
AU - Pálsson, H.
AU - Jónsson, M. P.
AU - Bakken, J. A.
PY - 2007
Y1 - 2007
N2 - The role of the electric arc in the consumption of electrodes in submerged arc furnaces has long been debated. The hostile environment in the furnace does not make direct measurement feasible, so simulation has been used to evaluate the arcs contribution to the erosion. Magnetofluiddynamic (MFD) electric arc simulations and a cathode / anode sub-model developed in order to provide boundary condition to the arc model have been used for this purpose. The cathode / anode sub-model provides current distributions and cathode / anode fall voltages for the arc and temperature distribution for the electrode surface, which is paramount to the erosion rate which in turn is calculated from the Clausius Clapeyron equation and the Hertz Knudsen formula for the vapour transport. In the case of high-current industrial AC arcs, arc currents are typically ∼100 kA, phase voltages ∼100 V and total furnace power ∼10 - 60 MW. The results show that although enormous amounts of material is evaporated, much of it recondenses on the surface. Furthermore the results show that the arc erosion increases strongly with the arc current. If a single arc is present its contribution to erosion is close to the actual total erosion in the furnace. Results from this analysis indicate that there are possibly more than one arc present in the crater, in which case less than 40% of the total erosion would be due to the arc, the rest is chemical erosion.
AB - The role of the electric arc in the consumption of electrodes in submerged arc furnaces has long been debated. The hostile environment in the furnace does not make direct measurement feasible, so simulation has been used to evaluate the arcs contribution to the erosion. Magnetofluiddynamic (MFD) electric arc simulations and a cathode / anode sub-model developed in order to provide boundary condition to the arc model have been used for this purpose. The cathode / anode sub-model provides current distributions and cathode / anode fall voltages for the arc and temperature distribution for the electrode surface, which is paramount to the erosion rate which in turn is calculated from the Clausius Clapeyron equation and the Hertz Knudsen formula for the vapour transport. In the case of high-current industrial AC arcs, arc currents are typically ∼100 kA, phase voltages ∼100 V and total furnace power ∼10 - 60 MW. The results show that although enormous amounts of material is evaporated, much of it recondenses on the surface. Furthermore the results show that the arc erosion increases strongly with the arc current. If a single arc is present its contribution to erosion is close to the actual total erosion in the furnace. Results from this analysis indicate that there are possibly more than one arc present in the crater, in which case less than 40% of the total erosion would be due to the arc, the rest is chemical erosion.
UR - https://www.scopus.com/pages/publications/84857769057
M3 - Conference contribution
SN - 9780230630697
T3 - Innovations In The Ferro Alloy Industry - Proceedings of the XI International Conference on Innovations in the Ferro Alloy Industry, Infacon XI
SP - 752
EP - 761
BT - Innovations In The Ferro Alloy Industry - Proceedings of the XI International Conference on Innovations in the Ferro Alloy Industry, Infacon XI
T2 - 11th International Conference on Innovations in the Ferro Alloy Industry, Infacon XI
Y2 - 18 February 2007 through 21 February 2007
ER -