Electric furnace

1 . An electric furnace provided with a double type melting furnace in which two melting furnaces are included and at least partially combined together, in order to melt different iron sources, the electric furnace comprising: a) a first upper cell that forms a first upper space of a first melting furnace in which a first iron source is introduced and molten; b) a second upper cell that is disposed in a horizontal direction of the first upper cell and forms a second upper space of a second melting furnace in which a second iron source is introduced and molten; c) a lower cell that comprises lower portions of the first upper cell and the second upper cell and forms a single integrated space; and d) a partition wall unit configured to vertically move up and down between the first upper cell and the second upper cell, and separates the first lower space of the first melting furnace and the second lower space of the second melting furnace. 2 . The electric furnace according to claim 1 , wherein the first upper cell has a furnace wall formed of a refractory material so that the melting furnace has a fire-resisting structure. 3 . The electric furnace according to claim 1 , wherein the first upper cell includes: a first electrode member, of which at least a portion is inserted into the first upper space of the first melting furnace; and a plurality of iron source feeders. 4 . The electric furnace according to claim 3 , wherein the first electrode member includes a plurality of alternate current (AC) electrodes that are radially disposed around the center of the small ceiling of the first roof part, and the plurality of iron source feeders configured to continuously feed the first iron source, respectively, toward ignition points of individual AC electrodes corresponding to individual iron source feeders. 5 . The electric furnace according to claim 1 , wherein the second upper cell includes: a second electrode member, of which at least a portion is inserted into the second upper space of the second melting furnace and configured to melt the second iron source with arc heat; and a pre-heat feeder on one side of the second electrode member on top of the second upper cell, configured to store a predetermined amount of the second iron source in a storage space inside the pre-heat feeder, preheats the second iron source stored in the above storage space using waste heat generated inside the second melting furnace, and then, feeds the second iron source through the second upper space of the second melting furnace. 6 . The electric furnace according to claim 5 , wherein the second electrode member includes: an upper direct current (DC) electrode provided on the second upper space side of the second melting furnace; and a lower DC electrode on the bottom of the lower cell to face with the upper DC electrode in the vertical direction, and is provided on the second lower space side of the second melting furnace, and wherein the lower DC electrode includes: a first lower electrode, in which a central axis is formed to be coaxial with a central axis of the upper DC electrode on the bottom of the lower cell, so that the lower DC electrode can directly face with the upper DC electrode; and a second lower electrode, in which a central axis is formed to be inclined at a predetermined angle to the central axis of the upper DC electrode on the bottom of the lower cell and thus to be biased toward the pre-heat feeder with respect to the upper DC electrode, so that the lower DC electrode can face with the upper DC electrode in an inclined direction. 7 . The electric furnace according to claim 6 , wherein the second electrode member induces a current flow between the upper DC electrode and the second lower electrode immediately after feeding the second iron source by the pre-heat feeder, while inducing a current flow between the upper DC electrode and the first lower electrode after the second iron source is completely molten. 8 . The electric furnace according to claim 1 , wherein a volume of the first melting furnace consisting of the first upper space of the first upper cell and the first lower space of the lower cell is smaller than a volume of the second melting furnace consisting of the second upper space of the second upper cell and the second lower space of the lower cell. 9 . The electric furnace according to claim 1 , wherein, in order to communicate the first upper space of the first melting furnace with the second upper space of the second melting furnace, the electric furnace further includes an exhaust gas duct that connects the first upper cell and the second upper cell in a duct form and feeds waste heat generated in the first melting furnace toward the second melting furnace. 10 . The electric furnace according to claim 1 , wherein the first melting furnace includes: a first slag door, which is provided at a boundary portion between the first upper cell and the lower cell and is configured in a double door form that includes an upper door opening upward and a lower door opening downward to face each other in the vertical direction, so that the slag generated in the first melting furnace can be selectively excluded. 11 . The electric furnace according to claim 10 , wherein the first melting furnace opens the upper door to maintain a height of the slag in the first melting furnace at a predetermined level during operation, while opening the lower door when excluding the slag inside the first melting furnace. 12 . The electric furnace according to claim 1 , wherein the second melting furnace includes: a second slag door, which is provided at a boundary portion between the second upper cell and the lower cell and is configured in a single door form to be opened upward or downward, so that the slag generated in the second melting furnace can be selectively excluded. 13 . The electric furnace according to claim 1 , wherein, in order to control a flow of molten metal between the first melting furnace and the second melting furnace, the electric furnace further includes a bottom gas blowing device that is disposed on the bottom of the lower cell and is provided with a plurality of plugs to discharge gas. 14 . The electric furnace according to claim 1 , wherein the lower cell is provided with a tapping port on a floor surface forming the first lower space at a position corresponding to the first electrode member, which is installed on the small ceiling of the first roof part formed on top of the first upper cell, so as to tap the molten metal in the double type melting furnace. 15 . The electric furnace according to claim 14 , wherein the floor surface forming the first lower space, in which the tapping port is formed, in the lower cell is higher than a floor surface forming the second lower space. 16 . The electric furnace according to claim 14 , wherein the electric furnace further includes: a tilting device that can tilt the double type melting furnace, in which the first melting furnace and the second melting furnace are at least partially combined, in the horizontal direction or enables double tilting of the same in the horizontal direction and a width direction perpendicular to the vertical direction. 17 . The electric furnace according to claim 16 , wherein the tilting device includes: a support cylinder that supports the double type melting furnace and configured to tilting the same; and a plurality of drive cylinders, specifically, at least three drive cylinders that are radially disposed around the support cylinder to support the double type melting furnace on at