Bearing flotation compensation for metal rolling applications

The invention claimed is: 1. A process to inferentially determine hydrodynamic bearing flotation in a metal rolling operation for a metal roller bearing, comprising: receiving from a mill stand processing the metal roll a rolling load of the metal roll, a gap between a pair of rollers pressing the metal roll, and a speed of the metal roll through the pair of rollers; receiving from the mill stand a gauge of the metal roll after the metal roll has passed through the pair of rollers; determining the hydrodynamic bearing flotation using the rolling load of the metal roll, the gap between a pair of rollers pressing the metal roll, the speed of the metal roll through the pair of rollers, and the gauge of the metal roll after the metal roll has passed through the pair of rollers; and adjusting the gap between the pair of rollers based on the determined hydrodynamic bearing flotation; wherein the rolling load of the metal roll, the gap between the pair of rollers pressing the metal roll, and the speed of the metal roll through the pair of rollers is fused using a Kalman filter; wherein the hydrodynamic bearing flotation is determined using the Kalman filter; wherein the Kalman filter implements a solution of the Reynolds Equation as a function of the speed of the metal roll through the pair of rollers and the rolling load of the metal roll; wherein one or more parameters for the Reynolds Equation are determined by a modified hysteresis test; and wherein the adjusting the gap is executed during mill speed acceleration and deceleration. 2. The process of claim 1 , wherein the gauge of the metal roll after the metal roll has passed through the pair of rollers is fused, using the Kalman filter, with the rolling load of the metal roll, the gap between the pair of rollers pressing the metal roll, and the speed of the metal roll through the pair of rollers. 3. The process of claim 1 , comprising comparing the gauge of the metal roll after the metal has passed through the pair of rollers with a reference gauge, and adjusting the gap between the pair of rollers based on the comparison of the gauge of the metal roll after the metal roll has passed through the pair of rollers and the reference gauge. 4. The process of claim 1 , wherein the rolling load of the metal roll is determined via a rolling model. 5. The process of claim 4 , wherein the rolling model is a function of one or more of a rolling load, a rolling torque, a forward slip, a material hardness, a roll radius, and a strip width, and wherein the rolling model simplifies a computation relating to a contact area of a roll. 6. The process of claim 1 , wherein the gap between the pair of rollers is determined via a hydraulic gap control (HGC) model. 7. The process of claim 6 , wherein the HGC model is a function of one or more of a mill stretch, a calibration screwdown, a thermal growth function, and a roll eccentricity function. 8. The process of claim 1 , wherein the speed of the metal roll is determined by a main drive model. 9. The process of claim 8 , wherein the main drive model is a function of one or more of a work roll speed, a work roll speed reference, and a time constant. 10. The process of claim 1 , wherein a rolling model, a hydraulic gap control (HGC) model, and a main drive model are assembled into one or more non-linear ordinary differential equations. 11. The process of claim 1 , wherein the hydrodynamic bearing flotation is compensated for using a feedforward process, or using a combination of the feedforward process and a feedback process. 12. A non-transitory computer-readable medium comprising instructions that when executed by a processor execute a process to inferentially determine hydrodynamic bearing flotation in a metal rolling operation for a metal roller bearing, comprising: receiving from a mill stand processing the metal roll a rolling load of the metal roll, a gap between a pair of rollers pressing the metal roll, and a speed of the metal roll through the pair of rollers; receiving from the mill stand a gauge of the metal roll after the metal roll has passed through the pair of rollers; determining the hydrodynamic bearing flotation using the rolling load of the metal roll, the gap between a pair of rollers pressing the metal roll, the speed of the metal roll through the pair of rollers, and the gauge of the metal roll after the metal roll has passed through the pair of rollers; and adjusting the gap between the pair of rollers based on the determined hydrodynamic bearing flotation; wherein the rolling load of the metal roll, the gap between the pair of rollers pressing the metal roll, and the speed of the metal roll through the pair of rollers is fused using a Kalman filter; wherein the hydrodynamic bearing flotation is determined using the Kalman filter; wherein the Kalman filter implements a solution of the Reynolds Equation as a function of the speed of the metal roll through the pair of rollers and the rolling load of the metal roll; wherein one or more parameters for the Reynolds Equation are determined by a modified hysteresis test; and wherein the adjusting the gap is executed during mill speed acceleration and deceleration. 13. The non-transitory computer-readable medium of claim 12 , wherein the gauge of the metal roll after the metal roll has passed through the pair of rollers is fused, using the Kalman filter, with the rolling load of the metal roll, the gap between the pair of rollers pressing the metal roll, and the speed of the metal roll through the pair of rollers. 14. The non-transitory computer-readable medium of claim 12 , comprising instructions for assembling a rolling model, a hydraulic gap control (HGC) model, and a main drive model into one or more non-linear ordinary differential equations. 15. A system comprising: a computer processor; and a computer memory coupled to the computer processor; wherein the computer processor is operable for: receiving from a mill stand processing the metal roll a rolling load of the metal roll, a gap between a pair of rollers pressing the metal roll, and a speed of the metal roll through the pair of rollers; receiving from the mill stand a gauge of the metal roll after the metal roll has passed through the pair of rollers; determining a hydrodynamic bearing flotation using the rolling load of the metal roll, the gap between a pair of rollers pressing the metal roll, the speed of the metal roll through the pair of rollers, and the gauge of the metal roll after the metal roll has passed through the pair of rollers; and adjusting the gap between the pair of rollers based on the determined hydrodynamic bearing flotation; wherein the rolling load of the metal roll, the gap between the pair of rollers pressing the metal roll, and the speed of the metal roll through the pair of rollers is fused using a Kalman filter; wherein the hydrodynamic bearing flotation is determined using the Kalman filter; wherein the Kalman filter implements a solution of the Reynolds Equation as a function of the speed of the metal roll through the pair of rollers and the rolling load of the metal roll; wherein one or more parameters for the Reynolds Equation are determined by a modified hysteresis test; and wherein the adjusting the gap is executed during mill speed acceleration and deceleration. 16. The system of claim 15 , wherein the computer processor is operable for compensating for the hydrodynamic bearing flotation by using a feedforward process, or using a combination of the feedforward process and a feedback process.