Method for operating an electric arc furnace

The invention claimed is: 1. A method for operating an electric arc furnace having at least one electrode, the method comprising the steps of: introducing material as an actual mass flow into the electric arc furnace, wherein the electric arc furnace is an electric reduction furnace for melting and reducing the material introduced; feeding electrical energy via the at least one electrode into the electric reduction furnace to melt the introduced material according to a required electrical energy input determined previously; and determining the required electrical energy input into the electric reduction furnace depending on the mass flow q mactual input into the furnace, wherein the required energy input is determined as a power setpoint value P setpoint and is introduced into the electric reduction furnace by either a power open-loop control or a power closed-loop control, wherein the step of determining the required energy input comprises the following sub steps: predefining or determining a specific energy demand as an energy demand parameter k 1 , wherein the determining is effected depending on a predefined expected energy value for operation of the electric reduction furnace, the mass flow q mactual input into the electric reduction furnace, and/or depending on properties of the input material; predefining or determining thermal energy stored in a vessel of the electric reduction furnace in relation to a mass of slag and to a mass of the material tapped from the electric reduction furnace as a loss parameter k 0 ; and determining the required electrical energy input as a power setpoint value P setpoint for the electric reduction furnace depending on the mass flow q mactual input into the electric reduction furnace, the energy demand parameter k 1 and the loss parameter k 0 . 2. The method as claimed in claim 1 , wherein the properties of the material introduced into the electric arc furnace which are taken into account when determining the specific energy demand are at least one of the group consisting of: chemical composition, temperature and/or moisture content of the input material, and whether the input material had previously already been subjected to a prereduction. 3. The method as claimed in claim 1 , wherein the determination of the required electrical energy input P setpoint is effected using a predefined functional relationship between the power setpoint value and the parameters q mactual , k 0 and k 1 , and optionally also a correction factor k 2 . 4. The method as claimed in claim 3 , wherein the functional relationship is represented as follows: P setpoint =( k 0 +k 1 *q mactual )* k 2 . 5. The method as claimed claim 1 , wherein the determination of the required electrical energy input P setpoint and of at least individual parameters from among those required for calculating said energy input is effected continuously during the operation of the electric reduction furnace. 6. The method as claimed in claim 5 , wherein the individual parameters are the mass flow q mactual , the specific energy demand k 1 and/or the loss parameter k 0 . 7. The method as claimed in claim 1 , wherein actual power input into the electric reduction furnace is set to a power setpoint value in the power open-loop control or is controlled to the power setpoint value in the power closed-loop control, in each case by varying an ignition angle of a power converter as actuator or by varying a setting of a tap switch of a transformer of the electric reduction furnace as actuator.