Melting method in an electric arc furnace and melting apparatus

1 . A melting method comprising: a step of loading solid metal material (M) into an electric furnace ( 11 ); a step of powering the electric furnace ( 11 ) and of generating an electric arc between at least one electrode ( 13 a, 13 b, 13 c ) and the metal material (M); a step of melting the solid metal material (M) to obtain molten material, wherein the step of powering comprises: the supply, by means of an electric power grid ( 16 ), of a mains voltage (Ur), and a mains current (Ir); the transformation, with at least one transformer ( 15 ) of said mains voltage (Ur) and mains current (Ir) into a base voltage (Ub) and a base current (Ib) which are selectively settable; the rectifying of said base voltage (Ub) and base current (Ib) with a plurality of rectifiers ( 19 ) to obtain a direct voltage and electric current; the conversion, with a plurality of converters ( 20 ), of said direct voltage and electric current into an alternating supply voltage (Ua) and alternating supply current (Ia) which are selectively settable by means of a control and command unit ( 21 ) connected to said converters ( 20 ); supplying said supply voltage (Ua) and supply current (Ia) to a plurality of electrodes ( 13 a, 13 b, 13 c ) of the electric furnace ( 11 ), wherein the method provides to regulate the power supply of the electrodes ( 13 a, 13 b, 13 c ) in an independent manner one with respect to the other, so as to vary the respective lengths of the electric arcs and automatically regulate the distribution of the thermal power inside the electric furnace ( 11 ) so as to maximize the thermal power in different zones of the electric furnace ( 11 ) as a function of one or several parameters considered, chosen from the phase of the melting cycle, the position or quantity of the solid metal material (M) in the electric furnace ( 11 ), and the type of metal material (M) to be melted. 2 . The method as in claim 1 , wherein each of said electrodes ( 13 a, 13 b, 13 c ) is connected to a plurality of power supply modules ( 24 a, 24 b, 24 c ) connected in parallel with each other to the electric power grid ( 16 ) and to the electric furnace ( 11 ), said differentiation of the power supply and automatic regulation of the power being carried out by means of the activation or deactivation of each of said power supply modules ( 24 a, 24 b, 24 c ), so that a different electric power supply can possibly be supplied to each electrode ( 13 a, 13 b, 13 c ), and so that each electrode ( 13 a, 13 b, 13 c ) supplies its own thermal power independently of the thermal power supplied by the other electrodes ( 13 a, 13 b, 13 c ). 3 . The method as in claim 1 , wherein it provides to regulate the thermal power delivered by the electrodes ( 13 a, 13 b, 13 c ) by translating the electrodes ( 13 a, 13 b, 13 c ) in a defined transverse direction (X) with respect to their longitudinal axis as a function of the demand for power in a determinate zone of the electric furnace ( 11 ) and/or in a determinate phase of the melting cycle. 4 . The method as in claim 1 , wherein it provides to regulate the thermal power delivered by the electrodes ( 13 a, 13 b, 13 c ) by varying the number of electrodes ( 13 a, 13 b, 13 c ) in a determinate zone of the electric furnace ( 11 ) as a function of the demand for power in a determinate zone of the electric furnace ( 11 ) and/or in a determinate phase of the melting cycle. 5 . The method as in claim 1 , wherein it comprises the detection, by means of sensors ( 28 ), of the distribution of energy in the different zones of the electric furnace ( 11 ) and the calculation, by means of an algorithm, of the optimal charge distribution for the electric furnace ( 11 ) as a function of the detected data. 6 . The method as in claim 5 , it comprises memorizing the melting cycles and the energy distribution associated with each melting cycle, so that said control and command unit ( 21 ) can process an “ideal” model of a melting process and automatically self-regulate the thermal power delivered by the electrodes ( 13 a, 13 b, 13 c ) as a function of the data detected and memorized so that the, or each, melting cycle follows the pattern of said “ideal” model. 7 . An apparatus for melting metal material (M) comprising an electric arc furnace ( 11 ) and an electric power supply apparatus ( 31 ) of the electric furnace ( 11 ), which comprises: at least one transformer ( 15 ) connected to an electric power grid ( 16 ) for supplying a mains voltage (Ur) and a mains current (Ir), having a predefined mains frequency (fr), said transformer ( 15 ) being configured to transform said mains voltage (Ur) and said mains current (Ir) respectively into an alternating base voltage (Ub) and an alternating base current (Ib); a plurality of rectifiers ( 19 ) connected to the transformer ( 15 ) and configured to transform said base voltage (Ub) and said base current (Ib) into direct voltage and electric current; a plurality of converters ( 20 ) connected to said rectifiers ( 19 ) and configured to convert direct voltage and current into an alternating supply voltage and current; a control and command unit ( 21 ) configured to control and command the functioning of said converters ( 20 ) and to regulate said supply voltage (Ua) and supply current (Ia) over time; power regulating means ( 24 a, 24 b, 24 c ) associated with, and controllable by, said control and command unit ( 21 ) and configured to regulate the power supply of the electrodes ( 13 a, 13 b, 13 c ) in an independent manner one with respect to the other in order to vary the respective lengths of the electric arcs and regulate the distribution of the thermal power inside the electric furnace ( 11 ) so as to maximize the thermal power in different zones of the electric furnace ( 11 ) as a function of one or several of either the phase of the melting cycle, the position or quantity of the solid metal material (M) in the electric furnace ( 11 ), or the type of metal material (M) to be melted. 8 . The apparatus as in claim 7 , said power regulating means comprise a plurality of power supply modules ( 24 a, 24 b, 24 c ) connected, in parallel with each other, to said electric power grid ( 16 ) and to said electric furnace ( 11 ), and each associated with one of said electrodes ( 13 a, 13 b, 13 c ), wherein each of said power supply modules ( 24 a, 24 b, 24 c ) is provided with said transformer ( 15 ), said rectifiers ( 19 ) and said converters ( 20 ), wherein said power supply modules ( 24 a, 24 b, 24 c ) can be selectively activated and deactivated by said control and command unit ( 21 ) respectively to increase/decrease the power of the respective electrode ( 13 a, 13 b, 13 c ) with which they are associated. 9 . The apparatus as in claim 7 , wherein it comprises transverse movement means ( 26 ) configured to translate at least one of said electrodes ( 13 a, 13 b, 13 c ) in a defined direction (X) transverse to their longitudinal axis. 10 . The apparatus as in claim 7 , wherein it comprises a plurality of electrodes ( 13 c, 13 d ) which can be moved in at least one direction (X) transverse to their longitudinal axis so as to define diversified concentrations of them as a function of the demand for power in a determinate zone of the electric furnace ( 11 ) and/or in a determinate phase of the melting cycle. 11 . The apparatus as in claim 7 , wherein it comprises a plurality of sensors ( 28 ) distributed in various zones of the e