System, method and computer program for controlling a production plant consisting of a plurality of plant parts, in particular a metallurgical production plant for producing industrial goods such as metal semi-finished products and/or metal end products

The invention claimed is: 1 . A system ( 1 ) for controlling a metallurgical production plant ( 3 ) having a plurality of plant parts ( 2 ) for producing metal semi-finished products and/or metal end products, wherein each plant part ( 2 ) has an input quality window ( 4 ), an output quality window ( 5 ), and a process window ( 6 ), wherein the input quality window ( 4 ) of a respective plant part ( 2 ) defines quality characteristics of an input product that are required by the respective plant part ( 2 ), and wherein the output quality window ( 5 ) of a respective plant part ( 2 ) defines permissible quality characteristics of an output product of the respective plant part ( 2 ) after processing the input product, wherein the output quality window ( 5 ) of an upstream plant part ( 2 ) corresponds to the input quality window ( 4 ) of a downstream plant part ( 2 ), wherein the process window ( 6 ) defines setting values ( 7 ) for a plant automation unit of the respective plant part ( 2 ) that can be implemented by the respective plant part ( 2 ), wherein each plant part ( 2 ) detects a current state by sensors ( 8 ) and adapts the process window ( 6 ) of the plant part ( 2 ) to the detected current state, wherein the system ( 1 ) for controlling the production plant ( 3 ) determines setting values ( 7 ) for the respective plant automation unit for each plant part ( 2 ) in view of all plant parts ( 2 ), such that the setting values are within the process windows ( 6 ) and such that a product produced in the production plant ( 3 ) meets the quality characteristics required by all of the input quality windows ( 4 ) and all of the output quality windows ( 5 ) of the plurality of plant parts ( 2 ), wherein the system ( 1 ) further determines an optimized sequence of a plurality of products to be produced in the production plant ( 3 ) by taking into account, for each of the plurality of products, the respective production steps across the plurality of plant parts ( 2 ), including the corresponding input quality windows ( 4 ), output quality windows ( 5 ), and current process windows ( 6 ), and wherein the optimized sequence is determined such that products having comparable or similar quality requirements are produced consecutively, so that differences between setting values ( 7 ) for the plant automation units of successive products are minimized. 2 . The system ( 1 ) according to claim 1 , wherein, after the product to be produced has been processed by a plant part ( 2 ), the system ( 1 ) updates the setting values ( 7 ) for the plant automation units of the subsequent plant parts ( 2 ) based on an achieved output quality of the processed plant part ( 2 ) and current process windows ( 6 ) of the subsequent plant parts ( 2 ). 3 . The system ( 1 ) according to claim 1 , wherein the system ( 1 ) takes into account possible setting value change rates that can be implemented by the respective plant automation units when determining the setting values ( 7 ) for the plant automation units of the respective plant parts ( 2 ). 4 . The system ( 1 ) according to claim 1 , wherein the system ( 1 ) creates a prediction model ( 9 ) for future states of the plant parts ( 2 ) at respective times at which products of the optimized sequence are to be processed, and wherein the system ( 1 ) takes into account the states of the plant parts ( 2 ) predicted by the prediction model ( 9 ) and resulting future process windows ( 6 ) when determining the optimized sequence of the plurality of products and determining the setting values ( 7 ) for the plant automation units of the plant parts ( 2 ). 5 . The system ( 1 ) according to claim 4 , wherein the prediction model ( 9 ) is based on one or more of the current states of the plant parts ( 2 ) detected by the sensors ( 8 ), achieved product qualities of the plant parts ( 2 ), and other measured values associated with the production plant ( 3 ), and is configured to predict, for each product of the optimized sequence, an expected state of each plant part ( 2 ) at a time at which the respective product is processed. 6 . The system ( 1 ) according to claim 1 , wherein the system ( 1 ) takes into account a plurality of plant parts ( 2 ) of the same type, such that processing of a production step can alternatively take place on different plant parts ( 2 ). 7 . The system ( 1 ) according to claim 1 , wherein the plant parts ( 2 ) comprise optical sensors ( 8 ) for detecting geometric information of the products produced in the respective plant part ( 2 ). 8 . The system ( 1 ) according to claim 1 , wherein the setting values ( 7 ) for the plant automation units of the plurality of plant parts ( 2 ) are determined by a model ( 12 ). 9 . A method for controlling a metallurgical production plant ( 3 ) having a plurality of plant parts ( 2 ) for producing metal semi-finished products and/or metal end products, wherein each plant part ( 2 ) has an input quality window ( 4 ), an output quality window ( 5 ), and a process window ( 5 ), wherein the input quality window ( 4 ) of a respective plant part ( 2 ) defines quality characteristics of an input product that are required by the respective plant part ( 2 ), and wherein the output quality window ( 5 ) of a respective plant part ( 2 ) defines permissible quality characteristics of an output product of the respective plant part ( 2 ) after processing the input product, wherein the output quality window ( 5 ) of an upstream plant part ( 2 ) corresponds to the input quality window ( 4 ) of a downstream plant part ( 2 ), wherein the process window ( 6 ) defines setting values ( 7 ) for a plant automation unit of the respective plant part ( 2 ) that can be implemented by the respective plant part ( 2 ), the method comprising: detecting current states in the plurality of plant parts ( 2 ) by sensors ( 8 ), adapting the respective process windows ( 6 ) of the plurality of plant parts ( 2 ) based on the detected current states of the plurality of plant parts ( 2 ), determining respective setting values ( 7 ) for respective plant automation units of the plurality of plant parts ( 2 ) in view of all plant parts ( 2 ) of the production plant ( 3 ), such that the determined respective setting values ( 7 ) are within the adapted respective process windows ( 6 ), and such that a product produced in the production plant ( 3 ) meets the quality characteristics required by all of the input quality windows ( 4 ) and all of the output quality windows ( 5 ) of the plurality of plant parts ( 2 ), and determining an optimized sequence of a plurality of products to be produced in the production plant ( 3 ), by taking into account, for each of the plurality of products, respective production steps across the plurality of plant parts ( 2 ), including corresponding input quality windows ( 4 ), output quality windows ( 5 ), and current process windows ( 6 ), wherein the optimized sequence is determined such that products having comparable or similar quality requirements are produced consecutively, thereby minimizing changes in setting values ( 7 ) for the plant automation units between successive products. 10 . The method according to claim 9 , further comprising updating the setting values ( 7 ) for the plant automation units of the subsequent plant parts ( 2 ) after the product to be produced has been processed by a plant part ( 2 ), wherein the updating takes place on based on an achieved output quality of the processed plant part ( 2 ) and current process windows ( 6 ) of the subsequent plant parts ( 2 ). 11 . The method according to claim 9 , further comprising taking