Method and device for detecting variables in the outlet of a metallurgical vessel

The invention claimed is: 1. Method for detecting at least one variable relating to a spout of a metallurgical vessel while metal melt passes through the spout of the metallurgical vessel, each of the at least one variable being selected from a group consisting of a proportion of slag during passage of the metal melt through the spout of the metallurgical vessel, a degree of wear of refractory parts defining an outlet channel of the spout, and an amount of solidified metal melt or plugging material in the outlet channel, the method comprising the steps of: heating the metal melt in the outlet channel using an induction coil of an induction heater, the induction coil surrounding the outlet channel; and monitoring the at least one variable using a supply and evaluation unit electrically connected to the induction coil and while the metal melt passes through the outlet channel and is being heated by the induction coil, by producing an alternating current with a predetermined frequency in the induction coil as the metal melt is being heated by the induction coil; and determining impedance of the induction coil resulting from the alternating current in the induction coil which varies relative to the at least one variable such that at least one value of the at least one variable is determined based on the determined impedance; whereby, based on the determined the at least one variable, a closure member for the spout is actuated, heating the metal melt in the outlet channel is adjusted or relining of at least one of the refractory parts defining the outlet channel is undertaken. 2. The method of claim 1 , wherein the step of monitoring the at least one variable, using the supply and evaluation unit electrically connected to the induction coil and while the metal melt passes through the outlet channel and is being heated, further comprises: determining induced current flow in the induction coil which varies relative to the at least one variable such that at least one value of the at least one variable is determined based on both the determined impedance and the induced current flow. 3. The method of claim 1 , further comprising obtaining and saving calibrating reference values for the at least one variable in association with different impedances of the induction coil, and wherein the step of determining impedance of the induction coil such that the at least one value of the at least one variable is determined based on the determined impedance comprises comparing the determined impedance of the induction coil to impedances associated with the saved calibrating reference values. 4. The method of claim 3 , wherein the step of obtaining and saving calibrating reference values for the at least one variable in association with different impedances of the induction coil comprises establishing or determining different values of the at least one variable during and after passage of the metal melt through the outlet channel while the induction coil has a known impedance. 5. The method of claim 1 , wherein the step of determining impedance of the induction coil comprises determining variations of the impedance based on voltage, current and frequency produced in the induction coil by the supply and evaluation unit, wherein a complex resistance (Z), a complex angle (φ) and/or current (I) of the impedance is/are determined by the supply and evaluation unit. 6. The method of claim 1 , wherein the step of monitoring the at least one variable, using the supply and evaluation unit electrically connected to the induction coil and while the metal melt passes through the outlet channel and is being heated, further comprises at least one of: measuring temperature in a vicinity of the outlet channel; and measuring temperature at the induction heater; and wherein at least one value of the at least one variable is determined based on both the determined impedance and the measured temperature. 7. The method of claim 6 , further comprising: comparing, using the supply and evaluation unit, measured temperature to reference temperature values associated with the at least one variable; and when the measured temperature deviates from the reference temperature values, performing at least one of: actuating the closure member for the spout, adjusting heating of the metal melt in the outlet channel, and relining the outlet channel. 8. The method of claim 1 , wherein the refractory parts defining the outlet channel comprise a refractory brick including an electrically conducting coil, an inner casing including an electrically conducting coil, an annular insert including an electrically conducting coil, and a closure plate including an electrically conducting coil, the coil in the refractory brick, the coil in the inner casing, the coil in the annular insert and the coil in the closure plate being electrically connected to the supply and evaluation unit, the method further comprising the steps of: producing using the supply and evaluation unit, alternating current in the coil in the refractory brick, the coil in the inner casing, the coil in the annular insert and the coil in the closure plate; and wherein the step of monitoring the at least one variable, using the supply and evaluation unit electrically connected to the induction coil of the induction heater and while the metal melt passes through the outlet channel and is being heated, further comprises: determining impedance of at least one of the coil in the refractory brick, the coil in the inner casing, the coil in the annular insert and the coil in the closure plate which varies relative to the at least one variable such that at least one value of the at least one variable is determined based in part on the determined impedance of at least one of the coil in the refractory brick, the coil in the inner casing, the coil in the annular insert and the coil in the closure plate. 9. The method of claim 1 , wherein the refractory parts defining the outlet channel comprise a refractory brick including an electrically conducting coil, an inner casing including an electrically conducting coil, and a closure plate including an electrically conducting coil, the coil in the refractory brick, the coil in the inner casing, the coil in the annular insert and the coil in the closure plate being electrically connected to the supply and evaluation unit, the method further comprising the steps of: producing using the supply and evaluation unit, alternating current in the coil in the refractory brick, the coil in the inner casing and the coil in the closure plate; and wherein the step of monitoring the at least one variable, using the supply and evaluation unit electrically connected to the induction coil of the induction heater and while the metal melt passes through the outlet channel and is being heated, further comprises: determining impedance of at least one of the coil in the refractory brick, the coil in the inner casing and the coil in the closure plate which varies relative to the at least one variable such that at least one value of the at least one variable is determined based in part on the determined impedance of at least one of the coil in the refractory brick, the coil in the inner casing and the coil in the closure plate. 10. The method of claim 1 , wherein the metallurgical vessel is a copper anode furnace or a copper converter. 11. A device for performing the method of claim 1 , wherein the outlet opening is formed by a slide closure unit on the spout of the metallurgical vessel, the metallurgical vessel including a housing, refractory closure plates in the housing, at least one connecting refractory inner casing in the housing, the induction coil at least partially