Method for ascertaining control variables for active profile and flatness control elements for a rolling stand and profile and average flatness values for hot-rolled metal strip

The invention claimed is: 1. A method for hot rolling a metal strip and ascertaining control variables for active profile and flatness control elements for at least one rolling stand, comprising: hot rolling the metal strip in a plurality of i=1 . . . I successive passes through the at least one rolling stand; individually adjusting active profile and flatness control elements of the at least one rolling stand for each pass; and ascertaining profile and center flatness values for the metal strip by the following steps: a1) specifying a target profile value and a target center flatness after a last pass and process-related center flatness thresholds for the metal strip after individual passes (i), wherein an interval range or a singular target center flatness value is specified for the target center flatness after the last pass; a2) specifying pass-specific interval ranges in each case for the target center flatness of the metal strip after a predetermined pass (k) with i=1<k<I and for the target center flatness values after the subsequent passes (i) with k<i≤I−1, wherein the interval ranges lie in each case within the center flatness thresholds; b) inputting specifications into a technological model for simulating the hot rolling; and c) successively calculating control variables for the active profile and flatness control elements and a calculated profile value (Cx) and a calculated center flatness value for the individual passes (i) with assistance of the technological model based on of the specifications, wherein the successively calculating of the control variables for the profile and flatness control elements and of the profile and center flatness values for the metal strip for the individual passes with the assistance of the technological model is carried out, with additional consideration of the respective specified pass-specific interval ranges for the target center flatness of the metal strip for the passes k≤i≤I. 2. The method according to claim 1 , further comprising: d) checking whether a difference between the calculated profile value and the specified target profile value for the metal strip lies within a specified tolerance range in each case after a pass; and d1) if the difference is within the tolerance range: storing the control variables for the profile and flatness control elements as “suitable”; or d2) if the difference is outside the tolerance range: extending the interval range for the target center flatness of the metal strip after the pass k in step a2); and iteratively repeating steps c) and d) with successive individual extension of the interval range for each subsequent pass k=k+1 until the difference lies within the tolerance range or the iteration ends at the last stand. 3. The method according to claim 2 , further comprising: f) adjusting the profile and flatness control elements with the control variables determined or stored as “suitable”; and g) hot rolling the metal strip with the at least one rolling stand with the profile and flatness control elements adjusted in accordance with step f). 4. The method according to claim 1 , wherein the interval range for the target center flatness after a single pass is specified to be 0% to +/−50% of the respective process-related center flatness threshold after the respective pass. 5. The method according to claim 1 , wherein in step a2), an earliest/first predetermined pass (k), for which the interval range or the singular target center flatness value of the metal strip is specified, is the second pass with k=2. 6. The method according to claim 1 , wherein the calculated profile value and the specified target profile value for the metal strip each relate to a same predetermined distance (X) offset inwardly in a width direction from an edge of the metal strip. 7. The method according to claim 1 , wherein the calculated profile value and the specified target profile value are respectively either absolute or relative profile values. 8. The method according to claim 1 , wherein in step c), the control variables for the active profile and flatness control elements are further iteratively calculated for each pass, such that, after each pass, the calculated center flatness value is in the specified pass-specific interval range for the target center flatness. 9. The method according to claim 1 , wherein in step a1), a target contour for the metal strip is also specified after the individual passes; in step c), the strip contour of the metal strip is also calculated after each pass; and in step c), the control variables for the profile and flatness control elements are furthermore calculated iteratively for each pass in such a manner that, after each pass, the calculated strip contour corresponds as closely as possible to the predetermined target contour. 10. The method according to claim 1 , wherein the center flatness of the metal strip can be determined after a pass with one of the following options: a) evaluation of the parabolic component of the calculated strip elongation ΔL/L over a width of the metal strip; b) as with a), but with a stronger weighting of the strip elongations in the middle area of the metal strip than in the area of the edge of the metal strip; c) evaluation of the difference between relative profile values of the metal strip after passes i and i−1, in each case at a fixed/same reference point a>X further inwards from the edge of the metal strip in a width direction; d) arithmetic averaging of the calculated strip elongation ΔL/L from different calculation points over a defined width range, preferably over the middle width range; e) evaluation of the difference between the calculated relative profile values of the metal strip after passes i and i−1, in each case at a variable reference point with a>X further inwards from the edge of the metal strip in the width direction, wherein a is selected as a function of a strip width, a thickness of the metal strip and a material quality. 11. The method according to claim 1 , wherein the active profile and flatness control elements are devices for the axial displacement of S-shaped profiled work rolls, corresponding to a change in work roll crown ΔCAW, and/or devices for crossing the work rolls; and/or bending devices for bending the work rolls. 12. The method according to claim 11 , wherein when using the device for the axial displacement of the S-shaped profiled work roll, the following applies at least to the first rolling stand with active profile and flatness control elements: Δ C AW >K AW′ ·BL 2 with KAW=0.14 mm/m 2 or KAW=0.18 mm/m 2 as factor, ΔC AW in mm referring to a work roll crown adjustment range=max. AW crown−min AW crown (parabolic proportion related to AW bale length as reference width), and BL in m referring to a work roll bale length. 13. The method according to claim 11 , wherein when using the device for the axial displacement of the S-shaped profiled work roll, an equivalent roll gap profile adjustment range ΔC WS for the sum of the profile and flatness control elements of the rolling stand is generated at least at the first rolling stand with active profile and flatness control elements to: Δ C WS >K B′ ·B max 2 with K B =0.16 mm/m 2 or KB=0.20 mm/m 2 as factor, ΔCWS in mm referring to a change of the roll gap profile when changing the setting position of the profile control element or control elements of the stand between the min./max. adjustment range (calculated values without taking into account the interaction with the strip at the strip profile reference point, for example X=40 mm or X=25 mm