Steelmaking furnace with humidity control device

We claim: 1. A steel strip annealing furnace with a dew point control system, the furnace including: a furnace having an upper region and a lower region; a furnace atmosphere injector configured to inject furnace atmospheric gases into an injection region in the upper region of the furnace; a steam generator coupled with the atmosphere injection system to mix steam into the furnace atmospheric gases; a control system for controlling the steam generator to provide a desired dew point within the furnace; the control system including an input dew point (DP) set point signal generator generating a DP set point signal corresponding to a desired furnace DP; the control system further including two DP sensors measuring a local dew point and transmitting a signal representative of the measured local dew point; one of the DP sensors being an upper DP sensor positioned in the upper region of the furnace and adjacent the injection region; the other of the DP sensors being a lower DP sensor positioned in the lower region of the furnace, remote from the injection region; the control system further including two proportional-integral-derivative (PID) controllers configured in a cascaded loop configuration; the control system further including three signal convertors (SC), each SC designed to receive a DP input signal and convert the DP input signal into a partial pressure of steam (PPS) output signal; a lower of the PID controllers being connected to a first SC of the SCs, the first SC having an input DP set point signal from the DP set point signal generator, and an output PPS set point signal transmitted to the lower PID controller; the lower PID controller also connected to a second SC of the SCs, the second SC having an input lower feedback DP signal from the lower DP sensor and an output lower feedback PPS signal transmitted to the lower PID controller; the lower PID controller comparing the PPS set point signal and the lower feedback PPS signal and generating a lower PID error value; the lower PID error value being added to the PPS set point signal to generate a lower PID output PPS signal; the lower PID controller connected to the upper PID controller, the lower PID controller transmitting the lower PID output PPS signal to the upper PID controller, the lower PID output PPS signal becoming an upper input PPS set point signal for the upper PID controller; the upper PID controller also connected to a third SC of the SCs, the third SC having an input upper feedback DP signal from the upper DP sensor and an output upper feedback PPS signal transmitted to the upper PID controller; the upper PID controller comparing the upper input PPS set point signal to the upper feedback PPS signal and generating an upper PID error value added to the upper input PPS set point signal to generate an upper PID output signal; the upper PID controller connected to a steam generator controller; the upper PID controller transmitting the upper PID output signal to the steam generator controller thereby controlling the injection of steam into the furnace. 2. The annealing furnace with dew point control system as recited in claim 1 wherein the control system further includes a feed forward control unit. 3. The annealing furnace with dew point control system as recited in claim 2 wherein the feed forward control unit calculates a signal to be added to the upper PID output signal. 4. The annealing furnace with dew point control system as recited in claim 3 wherein the signal to be added to said upper PID output signal is calculated based on known upcoming changes in a steel grade or chemistry, line speed, and steel strip width.