System and method of operating a batch melting furnace

The invention claimed is: 1. A method of controlling a batch metal melting process in a melting furnace, comprising: determining at least one furnace parameter characterizing a melting furnace; adding a charge containing solid metal into the melting furnace; detecting at least one charge parameter characterizing the charge; firing a burner into the melting furnace to provide heat to melt the charge, and exhausting combustion products from the furnace through a passage; detecting at least one process parameter characterizing progress of melting the charge; calculating a furnace efficiency based on the at least one furnace parameter; calculating a predicted process pour readiness time based on the at least one charge parameter, the at least one process parameter, and the furnace efficiency by: calculating a theoretical energy requirement based on the at least one charge parameter; calculating a target fuel consumption based on the theoretical energy requirement and the overall furnace efficiency; calculating an actual fuel consumption based on the at least one process parameter; and calculating the predicted process pour readiness time based on comparing the target fuel consumption with the actual fuel consumption; and controlling the metal melting process based on the predicted process pour readiness time; wherein the passage to exhaust burner combustion products includes a flue; and wherein the at least one process parameter includes one or more of: burner firing rate, reactant enthalpy rate, exhaust enthalpy rate, flue temperature, furnace wall temperature, fuel heating value, flue exit combustion intensity, baghouse temperature, flue gas composition, flue duct temperature, furnace door temperature, furnace door gap size, furnace shell temperature, furnace chamber temperature, charge melt rate, furnace heat loss, elapsed melt operation time, and charge visual appearance. 2. The method of claim 1 , further comprising: detecting at least one output parameter characterizing output of the melting process; and calculating the overall furnace efficiency based on the at least one furnace parameter and the at least one output parameter. 3. The method of claim 2 , further comprising: recording the at least one output parameter for multiple prior melting processes; and calculating the overall furnace efficiency based on the recorded at least one output parameter for multiple prior melting processes. 4. The method of claim 1 , wherein the at least one charge parameter includes one or more of: charge weight, flux weight, flux composition, volatile contaminant content, expected yield, initial temperature, tapping temperature, pouring temperature, charge size, charge shape, charge surface-to-volume ratio, charge material composition, and charge melting temperature. 5. The method of claim 1 , wherein when the furnace is a rotary furnace, the at least one process parameter further includes one or more of: furnace rotation speed, rotation motor current, rotation motor torque, and furnace vibration; and wherein the furnace is a reverberatory furnace, the at least one process parameter further includes one or more of: gas pressure for bubbler gas stirring applications, roof temperature, wall temperature, floor temperature, speed of circulation of the melt, energy expended in circulation of the melt, and melt temperature inside the furnace chamber. 6. The method of claim 1 , wherein the at least one furnace parameter includes one or more of: furnace type, furnace size, furnace condition, furnace age, refractory type, refractory age, scrap history, fuel cost, oxidizer cost, flux cost, and furnace operating procedures.