COOLING BAR AND COOLING PROCESS WITH VARIABLE COOLING RATE FOR STEEL SHEETS

Abstract

A cooling device with variable cooling rate for treating metal materials, in particular for cooling steel sheets in plate mills, hot strip mills or thermal treatment lines, by means of a spray nozzle cooling system. The cooling device consists of at least two cooling bars one of each two cooling bars being situated on the lower side and the other on the upper side transversely to the sheet travel direction of the sheet and centrally between two roller table rollers and includes a spray nozzle cooling system with which a plurality of full jet nozzles and a plurality of full cone nozzles are associated, the full jet nozzles being arranged symmetrically to the full cone nozzles. A method for operating the cooling device according to the disclosure

Claims

1-14. (canceled)

15. A cooling device with variable cooling rate for treating steel materials, in particular for cooling steel sheets in plate mills, hot strip mills or thermal treatment lines, by a spray nozzle cooling system, comprising: roller table rollers, wherein the cooling device consists of at least two cooling bars, one of each two cooling bars being situated on the lower side and the other on the upper side transversely to the sheet travel direction of the sheet and centrally between two roller table rollers, and comprises a spray nozzle cooling system, wherein the spray nozzle cooling system is associated with a plurality of full jet nozzles and a plurality of full cone nozzles, the full jet nozzles being arranged symmetrically to the full cone nozzles.

16. The cooling device with variable cooling rate according to claim 15, wherein the full jet nozzles are feedable with a cooling medium such that the sheet to be rolled is thereby able to be cooled at a high cooling rate of 5 to 150 K/s, preferably of 50 K/s.

17. The cooling device with variable cooling rate according to claim 15, wherein the full cone nozzles are feedable with a cooling medium such that the strip to be rolled is thereby able to be cooled at a low cooling rate of less than 1 K/s to 19 K/s.

18. The cooling device with variable cooling rate according to claim 15, wherein not only full jet nozzles and full cone nozzles are combinable, but any type of known nozzles and types of feed, such as flat jet, hollow cone nozzles and U-tubes, are insertable into the cooling bars.

19. The cooling device with variable cooling rate according to claim 15, wherein within a cooling bar, it is possible to switch between a high cooling rate by means of a full jet nozzle and a low cooling rate by means of a full cone nozzle, as required and continuously, so that a seamless overlap of cooling rates is able to be set.

20. The cooling device with variable cooling rate according to claim 19, wherein within the cooling bar, both the full cone nozzles and the full jet nozzles are feedable with a coolant and operable at the same time or at different times and independently of one another.

21. The cooling device with variable cooling rate according to claim 20, wherein the coolant quantity and the coolant surge pressure are controllable for each full jet nozzle and full cone nozzle within the cooling bar individually and online.

22. The cooling device with variable cooling rate according to claim 21, wherein the cooling for the sheet to be rolled is carried by spray cooling with the coolant, the cooling rate and/or the respective required final temperature being controllable based on the liquid quantity and/or the number of the respective full jet nozzles and full cone nozzles (spray nozzles) that are switched on.

23. A method for operating the cooling device according to claim 15, wherein the sheet to be rolled is cooled depending on the desired grade with a cooling rate set correspondingly, by means of a cooling medium which is conducted into two cooling bars, one of each two cooling bars being situated on the lower side and the other on the upper side of the sheet and transversely to the sheet travel direction and centrally between at least two roller table rollers, and the cooling medium is sprayed onto the sheet to be cooled via a plurality of full jet nozzles and full cone nozzles or flat jet and hollow cone nozzles 12 or U-tubes associated with the cooling bars, the full jet nozzles or flat jet nozzles being arranged symmetrically to the full cone nozzles or the hollow cone nozzles or the U-tubes within the cooling bars.

24. The method according to claim 23, wherein within a cooling bar, a switch is made between a high cooling rate by means of a full jet nozzle and a low cooling rate by means of a full cone nozzle, as required and continuously, or the full jet nozzles are combined and the full cone nozzles with one another and thereby a seamless overlap of cooling rates is set.

25. The method according to claim 24, wherein the coolant quantity and coolant surge pressure are controlled for each full jet nozzle and full cone nozzle within the cooling bar individually online.

26. The method according to claim 25, wherein at least one control parameter is measured for controlling the cooling rate, wherein the control parameter is the mechanical property such as hardness or a microstructure parameter such as phase distribution and grain size within the sheet.

27. The method according to claim 26, wherein the control parameter is further combined with information on the dimension and the material grade and/or with the target properties such as hardness and strength of the strip to be rolled.

28. The method according to claim 27, wherein process sensors collect information on the strip temperature, actual flatness in front of and behind the cooling device and the actual values are compared with target values, so that, from this value information, a model computer calculates online the cooling mode required for the cooling, the cooling time and the required coolant quantity depending on the desired material grade of the strip.

29. The cooling device with variable cooling rate according to claim 16, wherein not only full jet nozzles and full cone nozzles are combinable, but any type of known nozzles and types of feed, such as flat jet, hollow cone nozzles and U-tubes, are insertable into the cooling bars.

30. The cooling device with variable cooling rate according to claim 17, wherein not only full jet nozzles and full cone nozzles are combinable, but any type of known nozzles and types of feed, such as flat jet, hollow cone nozzles and U-tubes, are insertable into the cooling bars.

Description

[0023] The invention will be explained in more detail below by way of an exemplary embodiment with reference to the accompanying drawings. In the figures:

[0024] FIG. 1 shows the side view of the cooling device according to the invention in a schematic sectional representation, wherein the cooling device is arranged between two roller tables of a rolling line;

[0025] FIG. 2 shows the schematic side view of a cooling bar forming the cooling device in cross-section;

[0026] FIG. 3 shows the graphic representation of a cooling device on which the performance of the method according to the invention is to be based;

[0027] FIG. 4 shows a graphic detail view of the interaction between the computerized cooling model and the cooling device of FIG. 3 according to the invention.

[0028] As shown in FIG. 1, apparatus 10 essentially consists of two opposing cooling bars 16, 16a and 17, 17a arranged between two roller table rollers 12, 13, 14. Cooling bars 16, 16a and 17, 17a are implemented with a very compact design. To this end, two cooling systems 16 and 17 as well as 16a and 17a have basically been combined to form a cooling unit 18 and 18a.

[0029] It is intended for cooling units 18, 18a to be operated in an interlinked and synchronized manner. Cooling bars 16, 16a are associated with the upper side of the sheet and cooling bars 17, 17a with the lower side of the sheet.

[0030] FIG. 2 shows an enlarged representation of lower cooling bar 17 of FIG. 1, cooling bars 16, 16a and 17a being constructed in the same way.

[0031] As further shown in FIGS. 1 and 2, the compact design is based on there being at least two types of nozzles, in this case full jet nozzles 19 and full cone nozzles 20, arranged and integrated in cooling bar 16, 16a and 17, 17a in a special manner. A nozzle cooling system preferably having full jet nozzles 19, 19a for a high cooling rate, and a nozzle cooling system preferably having full cone nozzles 20 for low cooling rates (gentle cooling) are installed, by which a cooling medium 29 can be selectively directed at sheet 22.

[0032] Full cone nozzles 20 are arranged centrally and full jet nozzles 19, 19a are spaced therefrom and arranged in parallel next to full cone nozzles 20 in cooling bar 16, 16a and 17, 17a. Preferably, the nozzle cooling system is arranged in cooling bar 16, 16a and 17, 17a transversely to sheet travel direction 20 and over the entire width of a sheet 22 to be rolled.

[0033] FIG. 3 is a graphic representation showing the control of sheet cooling using cooling system 16, 16a and 17, 17a of FIG. 2, according to the invention. In principle, preliminary information such as primary sheet data 23, target sheet properties 24 and actual sheet properties 25 can be provided to a cooling model 26 for cooling control. This basic data serves to control cooling device 28. Cooling model 26 is controlled by the values sensed by sensors 27, 27a. As such, the actual properties of sheet 22 before cooling can be compared with the target properties after cooling of sheet 22. If the target properties are not reached, this information is transmitted to the cooling model and the cooling device is readjusted accordingly, as shown in FIG. 4.

[0034] This ensures a safe and reliable process. The cooling device can be used with maximum flexibility. Manual interventions by operating personnel are minimized by means of automatic control through the model computer.

[0035] As such, cooling model 26 interacts perpetually and virtually online with cooling device 28. Thus, a cooling model is possible for each section of the machine. Volumetric flow rates and the actual data are also constantly compared and readjusted if necessary.

[0036] This makes it possible to produce maximum uniformity of cooling transversely and longitudinally to the strip travel direction, wherein cooling rates of lowest to very high values can be achieved.

[0037] The control concept can be used to operate a plate mill, a hot strip mill or a thermal treatment line, for example, with maximum flexibility. This means that the desired cooling rate can be freely set at any time and over the entire length of the machine. The model computer (not shown) that controls cooling model 26 autonomously decides which cooling application (cooling rate) is necessary and most economical for the material properties to be achieved.

LIST OF REFERENCE NUMERALS

[0038] 10 Apparatus

[0039] 12 Roller table roller

[0040] 13 Roller table roller

[0041] 14 Roller table roller

[0042] 16, 16a Upper cooling bar

[0043] 17, 17a Lower cooling bar

[0044] 18, 18a Pair of cooling bars

[0045] 19, 19a Full jet nozzles

[0046] 20 Full cone nozzles

[0047] 21 Sheet travel direction

[0048] 22 Sheet

[0049] 23 Primary sheet data

[0050] 24 Target sheet properties

[0051] 25 Actual sheet properties

[0052] 26 Cooling model

[0053] 27, 27a Sensors

[0054] 28 Cooling device

[0055] 29 Cooling medium