DE102018206660A1 - Method for operating a cooling section and installation for producing rolled products - Google Patents

Abstract

The invention relates to a method for operating a cooling section (3) of a plant (1) for producing rolled products, wherein the cooling section (3) is operated using a physical cooling model, which is assigned using at least one adaptation value associated with a particular process parameter , is adaptable to the respective cooling task. In order to improve operation of the cooling section (3), the adaptation value is determined using a kriging method from at least one predetermined adaptation value.

Description

The invention relates to a method for operating a cooling section of a plant for producing rolled products, wherein the cooling section is operated using a physical cooling model, which is adaptable to the respective cooling task using at least one adaptation value associated with a particular process parameter.

Furthermore, the invention relates to a system for producing rolled products, comprising at least one rolling train, in particular a hot strip mill or a plate mill, at least one downstream of the rolling mill cooling section and at least one cooling circuit driving control electronics, drive electronics is set up, the cooling section using a physical cooling model to operate, which is adaptable to the respective cooling task using at least one adaptation value associated with a particular process parameter.

A plant for producing rolled products can be designed, for example, for the continuous production of metal strips. Such a plant may have a hot strip rolling mill, which is connected downstream of a cooling section. Such a cooling section is usually operated using a physical cooling model of the cooling section and the rolling stock to be cooled. In order to be able to adapt the cooling section to different cooling tasks, for example in order to adapt the cooling power that can be generated with the cooling section to different rolling stock thicknesses, conventionally adaptation algorithms are used, based on the result of which the cooling section is controlled. Such an adaptation algorithm searches in certain parameter classes for an adaptation value with which the given operating mode of the cooling section can be adapted to the next cooling task. Such an adaptation value is determined empirically in advance and stored. Alternatively, corresponding physical models have been partially replaced by interpolation variants.

GB 2 484 917 A discloses a method of cooling a metal plate. A target cooling flow is calculated for a plurality of points along the length of a longitudinally profiled plate. In addition, the position of the metal plate is monitored with respect to flows in a refrigerating machine. Further, the flows are set according to the target cooling flows at the plurality of points. The target cooling flows may be interpolated to produce a reference profile along at least a portion of the length of the metal plate. The method may include calculating an expected entrance thickness and temperature of the metal plate at the plurality of points and comparing these with measured values to calculate a required flow change. The method ensures that the exit temperature of the metal plate is accurately controlled by the chiller, even if the metal plate has different thicknesses along its length.

JP H06 218 414 A discloses a cooling control method for hot rolled steel sheet. The temperature of the steel sheet is calculated by means of a prescribed temperature estimation formula using sample information on the thickness, strip flow rate, finish temperature, intermediate finish temperature, and coiling temperature. Such learning values that the predicted temperature values match actual values are determined individually between a finish thermometer and an intermediate thermometer and between the intermediate thermometer and a winding thermometer. The formulas of several types of heat transfer coefficients are corrected, these corrections being made repeatedly over the entire length of the steel sheet, and errors of the heat transfer coefficients generated during rolling of the steel sheet are corrected in real time.

JP 2010 005 682 A discloses a cooling device between a finishing mill of a hot rolling line and a reel, the cooling device being divided into a first half zone and a second half zone. In the half-zones, a metal strip is cooled differently and the temperature of the metal strip is measured by a near-infrared camera capable of photographing a full length or part of the full length so that the temperature of the hot-rolled metal strip is controlled immediately before winding can be.

US 8 920 024 B2 discloses a steel plate quality assurance system and apparatus therefor, wherein the steel plate quality assurance system on a steel plate manufacturing line having a finish rolling line of a steel plate production line and an accelerated cooling device arranged in the feed direction of the steel plate production line on the downstream side of the finish rolling line, a temperature of at least the upper surface of a steel plate or the bottom surface of the steel plate to perform quality assurance. The system includes temperature measuring means, temperature analyzing means and means for determining mechanical properties.

US 2016/0288181 A1 discloses an operating method for a cooling zone wherein a flat rolled product is transported through a cooling zone such that portions of the rolling stock pass through successive effective areas of cooling means. Virtual rolling stock points are assigned to the sections. During the transport of the sections through the cooling zone, the sections are monitored by means of a working cycle. The cooling devices are controlled such that they correspond to the actual cooling performance at the respective rolling stock points, which are assigned to the cooling devices. As a result, that portion, which is located in each case in the effective range of the respective cooling device, is acted on by a respective amount of coolant. The cooling devices are subdivided into open and unopened cooling devices. A rolling stock point is selected in each case iteratively. Before the respective section, starting from a starting point, reaches the effective range of the next released cooling device, a state is determined which the respective rolling stock point has at the starting point.

In the case of a metal strip or sheet which is to be produced outside the previously used process values or process parameters with an existing plant, no meaningful adaptation value can be determined for adaptation of the cooling section. In the case of pure interpolation models, physical fundamentals are particularly lacking in order to allow extrapolations.

An object of the invention is to improve an operation of a cooling section of a plant for producing rolled products.

This object is solved by the independent claims. Advantageous embodiments are given in the following description, the dependent claims and the figure, these embodiments each taken alone or in various combinations of at least two of these embodiments can represent each other a further developing, especially preferred or advantageous, aspect of the invention.

According to a method according to the invention for operating a cooling section of a plant for producing rolled products, the cooling section is operated using a physical cooling model that can be adapted to the respective cooling task by using at least one adaptation value associated with a particular process parameter. In addition, the adaptation value is determined using a Kriging method from at least one predetermined adaptation value.

The determination of the adaptation value using the kriging method from the at least one predetermined adaptation value allows extrapolation of known adaptation values to unknown process areas. This means, for example, that from the known adaptation values for metal products in a thickness range of 2 mm to 3 mm, adaptation values for metal products in a thickness range of 3 mm to 4 mm can be calculated without the latter metal products having been produced with the respective system. This refers to all relevant process variables, in particular the thickness, the cooling rate, the temperatures, the chemical analysis and the cooling rates. Consequently, metal products can be produced optimally with an existing plant with previously unknown process parameters, since the cooling section can be adapted more precisely to the respective process parameters, which makes a more precise adjustment of desired target temperatures and / or other target properties of the metal product produced possible. The use of the Kriging method or Kriging algorithm for determining the adaptation value for adapting the cooling section to the respective cooling task in combination with the physical cooling model makes it possible to calculate adaptation values for areas for which no empirical values are available, which ultimately leads to a better settlement of the cooling section allowed.

interpoliert durch entsprechende Gewichtung der räumlichen Korrelationen von Nachbarpunkten, wobei Z(x_i) ein bekannter Wert an der Stelle x_i ist, ω_i ein zu ermittelndes Gewicht, N die Anzahl bekannter Werte, x₀ die Position, für die der Wert Z* interpoliert werden soll, und m(x_i) der Erwartungswert von Z(x_i) ist.A Kriging method is originally a geostatic method that allows you to estimate missing values and their accuracy based on distributed measurement points. This is an unknown point using the basic formula $$Z*\left(x_0\right)={\displaystyle \underset{t}{\overset{N}{\Sigma }}{\omega }_t\left(Z\left(x_i\right)-m\left(x_i\right)\right)}$$

interpolated by corresponding weighting of the spatial correlations of neighboring points, where Z (x _i ) is a known value at the point x _i , ω _{i is} a weight to be determined, N is the number of known values, x _{0 is} the position for which the value Z * is to be interpolated, and m (x _i ) is the expected value of Z (x _i ).

The adaptation values of the cooling section can be divided into various classifications, such as the classifications "strip thickness", "strip reference temperature" and "selected cooling strategy". If the different classifications are interpreted as spatial variables of an adaptation value, surfaces are interpolated in the selected dimensions and provided with estimation methods in the Kriging method.

With the help of the Kriging method, it is also possible to take into account influences that are not taken into account in physical cooling models and are also not depicted in adaptation value classes. This relates to external influences of the rolling stock, such as unevenness (edge waves, center waves, quater buckles and the like); but also various preliminary processes could be processed by the Kriging process.

With the method according to the invention, an improved adaptation algorithm for the cooling section can be provided in order to be able to improve the prediction accuracy of the temperature calculation. This allows a more accurate setting of the cooling section and thus a better application of rolled products with the desired material properties.

According to an advantageous embodiment, as a predetermined adaptation value, an adaptation value to a predetermined temperature value at a specific position of a product to be cooled, to a predetermined temperature value of the cooled product at a reel downstream of the cooling section, to a predetermined thickness value of the product to be cooled, to a predetermined chemical Analysis of the cooled product to be cooled or used for a given cooling strategy of the cooling model.

A plant according to the invention for producing rolled products comprises at least one rolling train, in particular a hot strip mill or a heavy plate train, at least one cooling line downstream of the rolling train and at least one control electronics activating the cooling section, wherein drive electronics are set up to operate the cooling section using a physical cooling model Use of at least one adaptation value, which is assigned to a specific process parameter, to which the respective cooling task can be adapted. The control electronics is also set up to determine the adaptation value using a Kriging method from at least one predetermined adaptation value.

With the system, the advantages mentioned above with respect to the method are connected accordingly. In particular, the method according to one of the above-mentioned embodiments or a combination of at least two of these embodiments can be carried out with one another by means of the system.

According to an advantageous embodiment, the drive electronics is set up, as a predetermined adaptation value, an adaptation value to a predetermined temperature value at a specific position of a product to be cooled, to a predetermined temperature value of the cooled product at a reel downstream of the cooling section, to a predetermined thickness value of the product to be cooled, to use for a given chemical analysis of the cooled product to be cooled or to a given cooling strategy of the cooling model. With this embodiment, the advantages mentioned above with respect to the corresponding embodiment of the method are connected accordingly.

• 1: eine schematische Darstellung eines Ausführungsbeispiels für eine erfindungsgemäße Anlage.
• 1 zeigt eine schematische Darstellung eines Ausführungsbeispiels für eine erfindungsgemäße Anlage 1 zum Herstellen von Walzprodukten.

In the following, the invention is explained by way of example with reference to the appended FIGURE by way of a preferred embodiment, wherein the features explained below can represent an advantageous or further developing aspect of the invention both individually and in combination of at least two of these features. It shows:

• 1 : a schematic representation of an embodiment of a system according to the invention.
• 1 shows a schematic representation of an embodiment of a system according to the invention 1 for producing rolled products.

The attachment 1 has a rolling mill 2 in the form of a hot strip mill or a plate mill.

In addition, the plant 1 one of the rolling mill 2 downstream cooling section 3 and one the cooling section 3 triggering control electronics 4 on. The control electronics 4 is set up, the cooling section 3 operate using a physical cooling model that is adaptable to the particular cooling task using at least one adaptation value associated with a particular process parameter. The control electronics 3 is set up to determine the adaptation value using a Kriging method from at least one predetermined adaptation value.

In addition, the control electronics 4 set as a predetermined adaptation value an adaptation value to a predetermined temperature value at a certain position of a not shown, to be cooled rolled product, to a predetermined temperature value of the cooled rolled product at one of the cooling section 3 downstream reel device 5 to use to a given thickness value of the rolled product to be cooled, to a predetermined chemical analysis of the cooled product to be cooled or to a predetermined cooling strategy of the cooling model.

LIST OF REFERENCE NUMBERS

1

investment

2

rolling train

3

cooling section

4

control electronics

5

coiler

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• GB 2484917 A [0004]
• JP H06218414 A [0005]
• JP 2010005682 A [0006]
• US 8920024 B2 [0007]
• US 2016/0288181 A1 [0008]

Claims (4)

Method for operating a cooling section (3) of a plant (1) for producing rolled products, wherein the cooling section (3) is operated using a physical cooling model that is adapted to the respective one using at least one adaptation value associated with a particular process parameter Cooling task is adaptable, characterized in that the adaptation value is determined using a Kriging method from at least one predetermined adaptation value. Method according to Claim 1 , characterized in that as a predetermined adaptation value, an adaptation value to a predetermined temperature value at a specific position of a product to be cooled, to a predetermined temperature value of the cooled product at a downstream of the cooling device reel (5), to a predetermined thickness value of the cooled product to a predetermined chemical analysis of the cooled product to be cooled or to a predetermined cooling strategy of the cooling model is used. Plant (1) for producing rolled products, comprising at least one rolling train (2), in particular a hot strip mill or heavy plate train, at least one cooling track (3) connected downstream of the rolling train (2) and at least one control electronics (4) controlling the cooling track (3), wherein control electronics (4) is set up to operate the cooling section (3) using a physical cooling model that can be adapted to the respective cooling task using at least one adaptation value assigned to a specific process parameter, characterized in that the control electronics ( 4) is arranged to determine the adaptation value using a Kriging method from at least one predetermined adaptation value. Plant after Claim 3 , characterized in that the control electronics (4) is arranged as a predetermined adaptation value to an adaptation value to a predetermined temperature value at a certain position of a cooled product to a predetermined temperature value of the cooled rolled product on a reel downstream of the cooling device (5) given thickness value of the cooled product to be used for a given chemical analysis of the cooled product or to a predetermined cooling strategy of the cooling model.

Images