This slag-supplying container of an electric furnace for reduction processing of steel-making slag includes: a container body that causes hot steel-making slag to flow to the electric furnace; a slag discharging portion connected with an electric-furnace-side slag-supplying port; a slag receiving portion that receives the hot steel-making slag supplied; a lid that opens and closes the slag receiving portion; an exhausting portion that discharges exhaust gas from the electric furnace; and, a tilting unit that tilts the container body to adjust the amount of inflow of the hot steel-making slag to the electric-furnace-side slag-supplying port.

The invention relates to a system and method for bottom electrode compound bottom blowing of multi-media of DC electric arc furnace, which belongs to the field of steelmaking technology. The system includes a plurality of bottom electrodes located at the bottom of furnace, wherein some of the bottom electrodes are bottom blowing electrodes with hollow structures, and some of the bottom blowing electrodes are at least one type of Type I bottom electrode, Type II bottom electrode and Type III bottom electrode; the Type I bottom electrode is used to blow carbonaceous materials into the molten pool to carburize the molten pool to accelerate scrap melting; the Type II bottom electrode is used to blow slagging powder into the molten pool to form molten slag particles in the molten metal to increase the gas-slag-gold three-phase reaction interface area during the dephosphorization reaction; the Type III bottom electrode is used to blow gas into the molten pool to accelerate mass transfer in the molten pool; the system also includes a control unit connected to the bottom blowing electrode to realize online adjustment of the blowing parameters in combination with the power supply intensity of the bottom blowing electrode during the smelting process. The invention can improve production efficiency and reduce consumption of raw and auxiliary materials.

A DC arc furnace 10 comprises a vessel 12 comprising a roof 14, a base 16 and a sidewall 18. The vessel defines a chamber 20 for a body of material having an upper surface 44. An anode electrode 24 and a cathode electrode 26 extend parallel to one another and terminate a distance d from the upper surface. The anode and cathode are located on a first horizontal line 28 and define a gap between them. A first conductor 36 links a positive pole 32 to the anode and a second conductor 38 links a negative pole to the cathode. The first conductor comprises a first section 36.1 extending continuously underneath the base parallel to the first line, so that current flows in the first section in a direction A directly opposite to current flow B through the body of material between the anode and the cathode.