Operating method for a cooling zone

1 . An operating method for a cooling zone for cooling a flat rolled material; wherein the cooling zone has a multiplicity of cooling installations; the method comprising: transporting the rolled material through the cooling zone such that portions of the rolled material successively pass through effective ranges of the cooling installations; assigning one virtual rolled material point to each of the portions of the rolled material; tracking the portions of the rolled material during transportation of the portions of the rolled material through the cooling zone at an operating cycle (δt′); and controlling the cooling installations according to actual cooling outputs (mi) of the cooling installations assigned to the respective rolled material points (P) for the respective cooling installations so that portion of the rolled material that is in each case located in an effective range of the respective cooling installation is impinged with a respective amount of coolant; subdividing the cooling installations into released cooling installations which release coolant during the operating method and non-released cooling installations, which prevent release of coolant during the operating method, wherein those cooling outputs which have been applied by non-released cooling installations during the operating method are also considered in development of the state of the rolled material point, and the cooling outputs of these cooling installations are accepted as given; iteratively selecting a virtual rolled material point (P) in respective ones of the portions of the rolled material and, in relation to the respective virtual rolled material point (P); prior to the respective portion of the real rolled material, proceeding from a pre-defined starting point (xA), reaching an effective range of the next released cooling installation: determining a state (E) which comprises at least one energy variable and which the respective portion of the rolled material at the starting point (xA) of the cooling zone; determining a total amount of coolant for the rolled material point (P) by a defined total cooling function (F 1 ) and assigned as a residual amount of coolant (M) to the rolled material point (P); mathematically simulating by using a motion diagram of transporting the rolled material point (P) through the cooling zone up to a pre-defined destination (xZ), wherein the diagram states a transportation speed vE for the selected rolled material point (P) at a simulation time (t) and calculated from the starting point (xA); conjointly calculating temporal development of the state (E) of the rolled material point (P) during the simulation by means of a model; each time when the rolled material point (P) reaches the effective range of one of the released cooling installations, determining a respective temporary cooling output (mi) by the then-current state (E) of the rolled material point (P) while using a cooling curve (F 2 , F 3 ) which is assigned to the respective released cooling installation, assigning the rolled material point (P) for the respective released cooling installation the lower of the two values of temporary cooling output (mi) and residual amount of coolant (M) as the final cooling output (mi), and reducing the residual amount of coolant (M) by the final cooling output (mi); determining an actual variable (I) of the temperature by means of the state (E) of the rolled material point (P) at the destination (xZ) and comparing the actual variable with a pre-defined target variable (EZ), of temperature and adapting the total cooling function (F 1 ) by means of the comparison; defining the actual cooling outputs (mi) for a number of the rolled material points (P) while using the final cooling outputs (mi) which have been determined for the selected rolled material point (P), and assigning to the respective rolled material points (P), the respective released cooling installation being assigned thereby. 2 . The operating method as claimed in claim 1 , further comprising: at least one further virtual, non-selected rolled material point (P 2 to P 4 ) lies between two directly successive selected virtual rolled material points (P 1 , P 5 ); the selecting of the later selected virtual rolled material point (P 5 ) and the carrying out of the calculations in relation to the virtual rolled material point (P 5 ) are completed before those portions of the rolled material that correspond to the non-selected rolled material points (P 2 to P 4 ), and proceeding from the starting point (xA), reach the effective range of the next released cooling installation; and determining the actual cooling outputs (mi) for the non-selected rolled material points (P 2 to P 4 ) are determined by interpolation of the final cooling outputs (mi) which have been determined for the two adjacent selected rolled material points (P 1 , P 5 ). 3 . The operating method as claimed in claim 1 , further comprising at least one part of the cooling installations acting on the upper side of the rolled material, such that cooling curves (F 2 ) for the one part of the cooling installations which act on the upper side of the rolled material are mutually congruent. 4 . The operating method as claimed in claim 3 , further comprising a further part of the cooling installations acting on the lower side of the rolled material, such that cooling curves (F 3 ) for further part of the cooling installations which act on the lower side of the rolled material are mutually congruent. 5 . The operating method as claimed in claim 4 , wherein the cooling curves (F 2 ) for the one part of the cooling installations that act on the upper side of the rolled material, on the one hand, and the cooling curves (F 3 ) for the further part of the cooling installations that act on the lower side of the rolled material, on the other hand, are mutually congruent or mutually dissimilar. 6 . The operating method as claimed in claim 1 , wherein the starting point (xA) lies ahead of the cooling zone or in the cooling zone. 7 . The operating method as claimed in claim 6 , further comprising by means of a temperature measurement spot, detecting a temperature (T) of each respective portion of the rolled material and; disposing the temperature measurement point at the starting point (xA), and determining the state (E) of the rolled material point (P) at the starting point (xA) by means of the detected temperature (T). 8 . The operating method as claimed in claim 6 , wherein no temperature measurement spot is disposed at the starting point (xA). 9 . The operating method as claimed in claim 1 , wherein the predetermined destination (xZ) lies in the cooling zone or behind the cooling zone. 10 . The operating method as claimed in claim 1 , further comprising again performing those steps that follow selecting the rolled material point (P) after adapting the total cooling function (F 1 ) for the same rolled material point (P). 11 . The operating method as claimed in claim 1 , further comprising considering time lags (t 1 , t 2 ) of the cooling installations when actuating the cooling installations. 12 . The operating method as claimed in claim 11 , further comprising the cooling installations have time lags (t 1 , t 2 ), in that those steps that follow selecting the respective rolled material point (P) are completed at a completion time point, in that the respective portion of the real rolled material, proceeding from the starting point (xA), reaches the effective range of the next released cooling installation at a cooling start time point, and in that a temporal difference between the completion time point and the cooling start time point is at lea