EP0695590A1 - Method and device for cooling hot-rolled metal plates and strips - Google Patents

Abstract

Hot rolled strip or plate is passed beneath banks of water spray nozzles (26) which each produce a spray pattern (30) on the surface of the strip. As the water leaves the nozzle it is subjected to lateral air or water spray beams (A, B) which periodically deflect the main spray back and forth across the width of the strip.

Description

The invention relates to a method and a device for cooling hot-rolled plates and strips made of metal, in particular of aluminum or an aluminum alloy, a hot-rolled strip being cut into plates or strips immediately after it emerges from a hot rolling mill.

A hot rolling strip usually has a temperature in the range between approximately 300 and 500 ° C. when it exits a hot rolling mill. To produce plates, these are cut immediately after the hot-rolled strip emerges from the hot rolling mill. Since there is no suitable sealing material for vacuum suction cups that can be used at temperatures above 300 ° C, the hot plates must be removed from the roller table for stacking with gripping tools. This handling of the plates is labor-intensive on the one hand, and on the other hand unwanted traces of the gripping tools can remain on the surface of the plates. A rapid cooling of the plates could in principle take place through the roller emulsion when carrying out empty runs without stitch acceptance. The resulting large temperature differences on the hot rolled strip would lead to unacceptable deviations from the flatness of the plates.

It is often also advantageous to cool a hot-rolled strip further when it is introduced into the tandem stand of a finishing train or into a reversing stand. It is important that there are no flatness deviations on the belt.

From EP-A-0 343 103 a method for cooling pressed profiles and rolled strips is known, in which by means of spray nozzles a water mist is generated. However, this method is not suitable for the rapid inline cooling of hot rolled plates with a thickness of more than about 5 mm because of the insufficient heat transfer. This known cooling method using spray nozzles is described in EP-A-0 429 394 for cooling cast metal strands.

EP-A-0 578 607 discloses an inline method for cooling profiles emerging from an extrusion press, in which the spray nozzles known from EP-A-0 343 103 are installed in modules.

In view of these circumstances, the inventors have set themselves the task of creating a method and a device of the type mentioned at the outset, with which plates and strips can be checked and cooled as quickly as possible to a temperature of at most about 250 ° C. without the plates Flatness deviations occur.

To achieve the object according to the invention in the method, the plates or strips continuously pass through a cooling station immediately after being cut to length, and water is directly applied to them in the flat jet nozzles, the water jet emerging from the flat jet nozzles essentially directed towards the plate or strip surface Forms a plane and the water jet is deflected periodically by air or water jets immediately after it emerges from the flat jet nozzle in such a way that the water jet striking the plate or strip surface performs a wiping movement.

Special and further embodiments of the method and device according to the invention are the subject of dependent patent claims.

With the use of flat jet nozzles according to the invention, when the water jet hits the plate, or belt surface a narrow impact surface with high heat transfer. This locally high heat transfer, together with the wiping movement, leads to even heat removal. The inline cooling of the plates or strips to a temperature of less than 300 ° C leads to a significant increase in production. After passing through the cooling station, plates can also be removed from the roller table and stacked using conventional vacuum systems.

To carry out the wiping movement, the water jet emerging from the flat jet nozzle is preferably pivoted through an angle in a range between 30 and 120 °.

The distance from the outlet opening of the flat jet nozzle to the plate or strip surface is preferably set to approximately 100 to 200 mm.

The impact surface of the water jet on the plate or strip surface preferably has a width of approximately 5 to 10 mm, the length: width ratio being between approximately 5: 1 and 100: 1.

A frequency for the wiping movement which is suitable for the method according to the invention is between approximately 0.1 and 20 Hz. The wiping movement is preferably carried out at a frequency of approximately 0.5 to 2 Hz.

In a device preferred for carrying out the method according to the invention with flat jet nozzles, the flat jet nozzles are arranged on nozzle strips running in the running direction of the plates or strips. The nozzle strips preferably comprise a longitudinal water channel and two longitudinal air channels, branch channels branching from the water channel to the flat jet nozzles and the air channels ending in air gaps directed towards the nozzle outlet openings.

The nozzle strips can be separated into water-feedable modules be divided or built up from such modules.

In a preferred embodiment of the device according to the invention, the nozzle strips or modules have a preferably extruded base body, in which the flat jet nozzles are interchangeably inserted. In this case, covers, which form an air chamber, are preferably placed on the base body with an air gap directed at the nozzle outlet openings, and the air chambers are connected to the air channels via connecting channels.

- Fig. 1a

eine Uebersichtsdarstellung eines Warmwalzwerks mit anschliessender Kühlstation;

- Fig. 1b

einen Teil einer Fertigstrasse mit einer Kühlstation;

- Fig. 2

einen Querschnitt durch die Kühlstation von Fig. 1a;

- Fig. 3

eine Schrägsicht auf ein Modul einer Düsenleiste von Fig. 2;

- Fig. 4

eine Ansicht eines Moduls entgegen der Strahlrichtung;

- Fig. 5

einen Schnitt durch Fig. 4 entlang deren Linie I-I;

- Fig. 6

den zeitlichen Verlauf des Luftdrucks in einem ersten Luftkanal;

- Fig. 7

den zeitlichen Verlauf des Luftdrucks in einem zweiten Luftkanal.

Further advantages, features and details of the invention result from the following description of preferred exemplary embodiments and from the drawing; this shows schematically in

- Fig. 1a

a general view of a hot rolling mill with subsequent cooling station;

- Fig. 1b

part of a finishing train with a cooling station;

- Fig. 2

a cross section through the cooling station of Fig. 1a;

- Fig. 3

an oblique view of a module of a nozzle bar of Fig. 2;

- Fig. 4

a view of a module against the beam direction;

- Fig. 5

a section through Figure 4 along the line II.

- Fig. 6

the time course of the air pressure in a first air duct;

- Fig. 7

the time course of the air pressure in a second air duct.

According to FIG. 1 a, a hot rolling strip 12 emerges from a hot rolling mill 10, which is cut into plates 16 by means of scissors or saw 14 and is moved via a roller table 18 in the transport direction x through a cooling station 20. The in the Cooling station 20 cooled plates 16 are temporarily stored as a stack 22 until further processing.

In Fig. 1b a cut hot rolling strip 12a passes through the cooling station 20, which is arranged here in front of the tandem mill stand 21 of a finishing train. Instead of the tandem roll stand 21, a reversing stand could also be used.

According to FIG. 2, lower and upper nozzle strips 24 are arranged inside the cooling station 20 in the plate or tape transport direction x. 3 and 4, modules 26 with three flat jet nozzles 52 are shown. The nozzle outlet openings 53 visible from the flat jet nozzles 52, which are at a distance of, for example, 150 mm from the surface 32 of the plate 16 or the band 12a, are arranged at regular intervals of, for example, 100 to 200 mm. Covers 34, 36 for air chambers 38, 40 are visible on both sides adjacent to the nozzle outlet openings 52. Additional water nozzles 60 are optionally provided. These water nozzles 60 are then switched on when the cooling effect of the flat jet nozzles 52 is inadequate in the case of thicker plates 16 or belts 12a at the predetermined transport speed.

With their end faces 27 directly adjacent to one another or lined up at a short distance from one another, the modules 26 form the lower and upper nozzle strips 24. Each module 26 can be fed separately with water and air. As can be seen in particular from FIG. 5, the module 26 has a preferably extruded base body 42 with a longitudinal central water channel 46 and longitudinal air channels 48, 50 arranged on both sides of the water channel 46.

The air channels 48, 50 are connected to air chambers 38, 40 via connecting channels 62, 64. These air chambers 38, 40 are formed by covers 34, 36 screwed to the base body 42. Between the cover 34, 36 and the by about 45 ° An inclined surface of the base body 42 is an air gap 54, 56 directed toward the nozzle outlet opening 53.

The water channel 46 is connected to the flat jet nozzles 52 via branch channels 58. If required, the additional water nozzles 60 are supplied via a further water channel, not shown in the drawing.

The mode of operation of a module 26 is explained in more detail below with reference to FIGS. 5 to 7.

An essentially flat water jet W emerges from the flat jet nozzles 52. This water jet W is now alternately deflected in its direction with air jets A, B, which emerge from the air gaps 54 and 56, so that a swivel angle α results overall.

The air pressure ratios for the two air jets A, B as a function of time t are shown in FIGS. 6 and 7. The air pressure p is set in each case in the corresponding air duct 48 or 50. The water jet W is first deflected from its normal position by the first air jet A to the maximum and returned to the normal position. Now the water jet W is deflected by the second air jet B in the other direction to the maximum deflection and then back to the normal position. This mutual periodic deflection with a period T takes place, for example, at a frequency of approximately 1 Hz.

The air jets A and B for deflecting the water jet W can in principle be replaced by water jets, in which case the total amount of water composed of the water jet W and the deflecting water jets is preferably kept constant.

As can be seen in particular from FIG. 3, the wiping movement of the water jet W emerging from the flat jet nozzles 52 runs transversely to the transport direction x of the plates 16 or the belt 12a, successive nozzles each carrying out opposite wiping movements.

The length 1 of the impact surface 30 of the water jet W on the surface 32 of the plates 16 or the band 12a is, for example, 200 mm, the width b, for example, 5 mm. The flat jet nozzles 52 are arranged in the nozzle strips 24 or modules 26 in such a way that the impingement surfaces 30 of adjacent water jets W approximately touch during the wiping movement.

Claims (10)

Method for cooling hot-rolled plates (16) and strips (12a) made of metal, in particular aluminum or an aluminum alloy, wherein a hot-rolled strip (12) immediately after it leaves a hot rolling mill (10) to form plates (16) or strips (12a ) is cut to length,
characterized,
that the plates (16) or strips (12a) immediately after cutting to length pass through a cooling station (20) and water is directly applied to them via flat jet nozzles (52), the water jet (W) emerging from the flat jet nozzles (52) in essentially forms a plane (E) directed towards the plate or belt surface (32) and the water jet (W) is periodically deflected by air or water jets (A, B) immediately after it emerges from the flat jet nozzle (52) such that it the water jet (W) striking the plate or belt surface (32) performs a wiping movement. A method according to claim 1, characterized in that for executing the wiping movement the water jet (W) emerging from the flat jet nozzle (52) is pivoted through an angle (α) in a range between 30 and 120 °. Method according to claim 1 or 2, characterized in that the distance (a) from the outlet opening (53) of the flat jet nozzle (52) to the plate or strip surface (32) is 100 to 200 mm. Method according to one of claims 1 to 3, characterized in that that the impact surface (30) of the water jet W) on the plate or belt surface (32) has a width (b) of approximately 5 to 10 mm and a length (1): width (b) ratio of 5: 1 to 100: 1 having. Method according to one of claims 1 to 4, characterized in that the wiping movement is carried out at a frequency of 0.1 to 20 Hz, preferably 0.5 to 2 Hz. Device for carrying out the method according to one of claims 1 to 5 with flat jet nozzles (52), characterized in that the flat jet nozzles (52) are arranged on nozzle strips (24) running in the running direction (x) of the plates (16) or belts (12a) . Apparatus according to claim 6, characterized in that the nozzle strips (24) comprise a longitudinal water channel (46) and two longitudinal air channels (48, 50), branch channels (58) branching from the water channel (46) to the flat jet nozzles (52) and the Air channels (48, 50) end in air gaps (54, 56) directed towards the nozzle outlet openings (53). Device according to Claim 7, characterized in that the nozzle strips (24) are subdivided into modules (26) which can be fed separately with water or are constructed from such modules (26). Device according to claim 7 or 8, characterized in that the nozzle strips (24) or modules (26) have a preferably extruded base body (42) in which the flat jet nozzles (52) are interchangeably inserted. Device according to one of claims 7 to 9, characterized in that the base body (42) air chambers (38,40) forming covers (34,36) with an air gap (54,56) directed towards the nozzle outlet openings (53) and the air chambers (38,40) via connecting channels (62,64) with the air channels (48, 50) are connected.

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