EP0283425A1 - Method and apparatus for casting metal strips, particularly steel ones - Google Patents

Abstract

In a method for casting strips of metal, in particular steel, the molten metal (2) is poured from a pouring nozzle (4) corresponding to the strip width onto a continuously moving, cooled conveyor belt (5) and the nozzle mouth (6) becomes level to the thickness (7) of the metal strip to be cast, ie set at an acute angle to the conveyor belt level (5a). In order to maintain the outflow rate (12) at the nozzle mouth (6) also on the conveyor belt (5), i.e. In order to avoid shear forces of the flow layers and thus a speed profile (14) with negative components (16), it is proposed that the inclination of the conveyor belt (5) in a conveyor belt (5) inclined to the horizontal (9) in the casting direction (10) The casting direction (10) is set as a function of the casting speed, which should be equal to the conveyor belt speed (15), and the material parameters of the molten metal (2).

Description

The invention relates to a device for casting strips of metal, in particular steel, consisting of a storage vessel with a pouring nozzle and a shaping device for the casting belt, the storage vessel and shaping device being mounted on a frame which is adjustable in inclination to the horizontal.

Such a device, with a frame adjustable in inclination, is described in DE-AS 21 16 870. It is used for casting non-ferrous metals with metal strip thicknesses of a few millimeters. A practically advantageously applicable embodiment for steel as molten metal is not known.

From DE-OS 35 21 778 and EP-A 0208890 it is known to pour onto a horizontally arranged, flat conveyor belt, the pouring taking place in such a way that taking into account the fact that during casting onto the moving cooling surface of the heat sink (conveyor belt ) in the area of the nozzle wedge-shaped solidification front and by adjusting the speed of the cooling surface, the free gap between the outlet-side nozzle lip and possibly the lateral nozzle lips from an uncontrolled outflow of the melt liquid metal-preventing small initial value is gradually increased to the final value corresponding to the desired strand thickness, which also prevents uncontrolled outflow. Such a method requires a momentary acceleration of the molten metal from the exit direction of the molten metal, starting from the pouring nozzle in the direction of movement of the cooled conveyor belt. The occurring differences in speed cause an unsafe flow, so that the desired thickness is difficult to control and differences in thickness cannot be excluded.

The invention has for its object to improve the casting and continuous casting dynamically and fluidically.

The object is achieved with the features in the characterizing part of claim 1.

With the casting device according to the invention, only a weak deflection of the individual sub-layer flows is achieved with layer-dependent acceleration in the direction of movement of the conveyor belt, so that a largely laminar flow is achieved on the cooled conveyor belt. The discharge speed at the end of the pouring nozzle is almost equal to the conveyor belt speed. The parameters to be observed are in particular the metal strip thickness, the overheating temperature and the properties of the respective steel grades.

The casting process is initiated by gradually tilting the conveyor belt from an approximately horizontal starting position of the impact surface for the molten metal into the inclined operating position for starting. The design of the pouring device has the advantage of a common inclination of the storage vessel and the conveyor belt level as well to be able to adjust like a separate adjustment between the storage container and the conveyor belt level, taking into account the height distance apart from the inclination.

A further improvement provides that a slide guide for an adjustable slide is provided on the frame, on which the storage container and at least lifting devices for the storage container are arranged. In this way, the storage vessel can be set on the one hand to the conveyor belt and on the other hand can be completely removed from the area of the conveyor belt so that the conveyor belt is accessible.

Further improvements in the sense of an inclined conveyor belt for different operating states are achieved in that a support for the cooled conveyor belt is arranged between the drums, that the support has a continuous contour that runs over a tangent to the drum circumference and that at least in the area of Pouring nozzle of the storage vessel is provided with a height that corresponds at least to the thickness of the cooled conveyor belt together with the thickness of the cast belt and is adapted to the course of the continuous contour of the support or the cooled conveyor belt and is arranged laterally. Advantageously, a suitable base for guiding the conveyor belt and for weight absorption, among other things. also created the cast belt and on the other hand created a basis for a basis connected with the inclination adjustment for setting the most favorable flow conditions by the continuous contour. Then the moving seal solves the problem of lateral leakage of the casting material or lateral thickness differences across the cross section of the cast strip.

Looking across the width of the cast belt, it is also advantageous that at the conveyor belt level of the cooled conveyor belt in Distance of the thickness of the cast strip is a cooled smoothing roll. An improved surface quality is thus achieved on the surface of the cast belt facing away from the conveyor belt.

In an embodiment of the invention it is provided that the cooled smoothing roller is arranged in the region of the pouring nozzle of the storage container. Thus, the smoothing takes place in a certain warm area, in which an influence on the surface is advantageous.

An advantageous measure to protect the conveyor belt is that a cooling medium can be introduced under pressure between the curved support and the cooled conveyor belt. This increases the cooling for the conveyor belt, which means that a considerable amount of heat has to be dissipated when the casting belt cools down.

A further embodiment of the invention consists in that a guide for the cooled conveyor belt is assigned to the drum on the casting side, which is arranged in the region of the pouring nozzle. Such a guide reduces possible wear between the laterally arranged, rotating seals at the height of the conveyor belt.

A further improvement is that the drum on the casting side is assigned a cleaning or spraying device for applying size. This advantageously favors the loosening of the cast belt from the conveyor belt.

Further features of the invention provide that the lateral, rotating seal consists of metallic elements forming a flat surface in the operating position.

To protect against reoxidation of the cast strip surface, it is proposed that between the pouring nozzle of the storage container and that on the support guided cooled conveyor belt, the smoothing roller and the side moving seal a casting space is formed, which is filled with inert gas.

The consumption of inert gas can also be limited in that a hood protecting against oxidation is arranged after the smoothing roll in the casting direction.

Further features emerge from the attached drawings.

• Fig. 1 eine das Verfahren erläuternde Querschnittsdarstellung durch die Ausgießdüse,
• Fig. 2 eine Prinzipdarstellung des Transportbandes in der Phase des Angießens,
• Fig. 3 die Prinzipdarstellung gemäß Fig. 2 in der Phase nach dem Angießen,
• Fig. 4 einen senkrechten Querschnitt durch Vorratsgefäß und Ausgießdüse mit Transportband und Glättrolle,
• Fig. 5 eine seitenansicht der gesamten Gießvorrichtung,
• Fig. 6 eine Draufsicht auf die gesamte Gießvorrichtung gemäß Fig. 5 und
• Fig. 7 eine Draufsicht auf die Partie der Gießvorrichtung mit der mitlaufenden seitlichen Abdichtung.

An embodiment of the invention is shown in the drawing and will be described in more detail below. Show it:

• 1 is a cross-sectional view explaining the method through the pouring nozzle,
• 2 is a schematic diagram of the conveyor belt in the casting phase,
• 3 shows the basic illustration according to FIG. 2 in the phase after casting,
• 4 shows a vertical cross section through the storage vessel and pouring nozzle with conveyor belt and smoothing roll,
• 5 is a side view of the entire casting device,
• Fig. 6 is a plan view of the entire casting device according to FIGS. 5 and
• Fig. 7 is a plan view of the lot of the casting device with the accompanying side seal.

The cast strip 1 to be cast is made of molten metal 2 (molten steel), which flows from a storage vessel 3 through a pouring nozzle 4 and arrives at a conveyor belt 5, to which the nozzle mouth 6 with its plane extending over the width 1a has a thickness of 7 mm Casting belt 1 is set at an acute angle to the conveyor belt plane 5a of the conveyor belt 5. An angle adjustment is made in such a way that the nozzle mouth 6 is sealed at its rear part 6a in the direction of movement 8 by the surface tension of the molten metal 2 (meniscus) and at its front part 6b in the direction of movement 8 is at the acute angle, which is the thickness 7 to Conveyor belt level 5a results.

The conveyor belt plane 5a forms an acute angle 11 to the horizontal 9 in the casting direction 10, which is formed by a corresponding curvature or curvature of the course of the conveyor belt plane 5a.

The inclination of the conveyor belt 5 to the horizontal 9 in the casting direction 10 is set as a function of the casting speed and the material parameters of the molten metal (e.g. metal belt thickness 7, superheating temperature, type of steel and the like), so that the outflow speed 12 within the pouring nozzle 4 is equal to the conveyor belt speed 15 . Conversely, of course, the conveyor belt speed 15 can also be regulated to the specified dimensions of the pouring nozzle 4 and the discharge speed 12 in order to bring the discharge speed into line with the conveyor belt speed 15.

To start the conveyor belt 5 (FIGS. 2 and 3), an approximately horizontal starting position of the impact point 13 for the molten metal 2 is assumed. In this position of the conveyor belt 5, the speed profile 14 with a corresponding conveyor belt speed 15 shows a negative speed component 16 in the upper region, which ultimately also leads to an overall smaller speed distribution 17. Here shear forces of the molten metal 2 occur within the flow which can only be overcome because there is already a tendency to incline in the impact point 13. When starting, this state is therefore quickly overcome by tilting the conveyor belt 5 (FIG. 3), so that the speed profile 14 increases rapidly with increased flow speed and causes the new speed distribution 17a.

The thickness 7 of the cast strip 1 is drawn greatly enlarged in FIGS. 2 and 3 in order to make the speed profile 14 more visible. In addition, the speed profile 14 in the front part 6b of the nozzle mouth 6 is advantageously also influenced by a tear-off ring 18 which roughly corresponds to the crushing rings usual in horizontal continuous casting within a horizontal continuous casting mold, i.e. e.g. is made of boron nitride, but causes the metal melt to tear off continuously.

The casting device for cast strips 1 with a thickness 7 of a few millimeters has a storage vessel 3 (FIG. 4) which is provided with a lining 19, an intermediate wall 20, a cover 21 and the pouring nozzle 4. The pouring nozzle 4 is mounted in a pouring stone 22 and held by a sealing ring 24 by means of a retaining ring 23 fastened to the vessel jacket 3a. The pouring nozzle 4 is therefore easy to replace. Either a cooling device 25 or a heating device 26 is arranged around the front area 4a, both of which can also be combined and can be switched on or off depending on the temperature of the molten metal 2. Behind the pouring nozzle 4 in the casting direction 10 there is an adjustable, cooled smoothing roller 27 above the conveyor belt level 5a at a distance of the thickness 7 of the casting belt 1, the length of which is dimensioned in accordance with the width of the casting belt 1. The smoothing roller 27 is also rotatably supported in a pivot bearing 28 (FIG. 5) which is supported on a pair of articulated arms 29 and a pair of columns 30. A (hydraulic) pair of lifting units 31 is used for setting and adjusting the smoothing roller 27.

The storage vessel 3 for the molten metal 2 and the drums 5b and 5c with the conveyor belt 5 are arranged on a frame 32. The frame 32 consists of two parallel beams 32a and 32b (Fig. 6). The frame 32 can be pivoted about the horizontal axis 33 of the bearing block pair 34 by a piston-cylinder engine 36 supported on the corridor 35 and articulated on the frame 32. The storage vessel 3 is, as will be described in more detail below, on the frame 32 adjustable in height and inclination to the conveyor belt level 5a. A slide guide 37 for an adjustable slide 38 is also provided on the frame 32. The carriage 38 carries the storage vessel 3 and a lifting device 39 for the storage vessel 3. The carriage 38 is designed here as a carriage 38a with wheels 40 and can be moved horizontally. For this purpose, the carriage 38 has a drive in the form of a displacement cylinder 41, the cylinder housing 42 of which is articulated on the carriage guide 43 at 43a.

For the cooled conveyor belt 5, a support 44 is arranged between the drums 5b and 5c (FIG. 4), which is provided with a special contour 45 opposite the smoothing roller 27. The contour 45 has a continuous course which runs continuously but arched above a tangent 46 placed on the drum circumferences (FIG. 2). In the area of the pouring nozzle 4 of the storage vessel 3 there is a moving seal 47 which is adapted to the course of the continuous contour 45 and which projects beyond the thickness 7 of the cast strip 1 and is flexible and is guided in each case via pairs of rollers 48 and 49. The axes 50 of the pairs of rollers 48 and 49 accordingly run perpendicular or obliquely to the horizontal 9. The flexible seal 47 consists of metallic elements 52 forming a flat surface 51 in the operating position.

A cooling medium 53 is introduced under pressure between the arched support 44 and the conveyor belt 5. The conveyor belt 5 is also guided laterally in the region of the pouring nozzle 4 by a guide 54 (FIG. 7), to keep wear to the flexible seal 47 low. A cleaning device 55 and a spray device 56 (FIG. 4) are also assigned to the casting-side drum 5b.

A pouring chamber 57 (FIG. 4) is formed between the pouring nozzle 4 of the storage container 3, the cooled conveyor belt 5 guided on the support 44, the smoothing roller 27 and the lateral, rotating seal 47, which is formed by an inert gas, e.g. Argon or nitrogen, is fulfilled and is therefore surrounded by a hood 58 (FIG. 5), into which the inert gas enters through a pipeline 59 and flows out through a gap 60 and thus keeps the atmospheric oxygen away from the cast strip 1 during solidification.

Claims (11)

1. Casting device for casting strips of metal, in particular steel, consisting of a storage vessel with a pouring nozzle and a shaping device for the casting belt, wherein the storage vessel and shaping device are mounted on a frame that is adjustable in inclination to the horizontal,
characterized,
that the shaping device consists of a conveyor belt (5), which is cooled on one side and runs over two spaced, drivable drums (5b, 5c), the nozzle mouth (6), the pouring nozzle (4) and a laterally arranged at least in the region of the pouring nozzle (4), Running seal (47) is that the conveyor belt (5) is supported on a support (44) between the drums (5b, 5c) and that a cooled smoothing roller (27) at a distance of the thickness (7) of the cast belt (1) from the conveyor belt level (5a) is arranged in the region of the pouring nozzle (4). 2. Pouring device according to claim 1, characterized in that on the frame (32) the storage vessel (3) to the conveyor belt level (5a) is adjustable in height and inclination. 3. Casting device according to claim 1, characterized in that on the frame (32) a slide guide (37) for an adjustable slide (38) is provided, on which the storage vessel (3) and at least lifting devices (39) for the storage vessel (3rd ) are arranged. 4. Casting device according to claims 1 to 3, characterized in that the support (44) has a continuous contour (45) which extends over a tangent to the drum circumferences (46). 5. Pouring device according to claim 1, characterized in that the seal (4) is adapted to the course of the continuous contour (45) of the support (44) or the conveyor belt (5) and has a height which is at least the thickness of the cooled conveyor belt (5) together with the thickness (7) of the cast strip (1) corresponds. 6. Pouring device according to one or more of claims 1 to 5, characterized in that a cooling medium (53) can be introduced under pressure between the arched support (44) and the cooled conveyor belt (5). 7. Pouring device according to claims 1 to 6, characterized in that the casting-side drum (5b), which is arranged in the region of the pouring nozzle (4), is assigned a guide (54) for the cooled conveyor belt (5). 8. Casting device according to claims 1 to 7, characterized in that the casting-side drum (5b) is associated with a cleaning or spraying device (55, 56) for applying size. 9. Pouring device according to claims 1 to 8, characterized in that the lateral, rotating seal (47) consists of metallic elements (52) forming a flat surface (51) in the operating position. 10. Pouring device according to claims 1 to 9, characterized in that between the pouring nozzle (4) of the storage container (3), the guided on the support (44), cooled conveyor belt (5), the smoothing roller (27) and the lateral, running seal (47) a casting space (57) is formed, which is filled with inert gas. 11. Pouring device according to claims 13 to 10, characterized in that a protective cover against oxidation (58) is then arranged in the casting direction (10) on the smoothing roller (27).

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