EP4311994A1 - Metallurgical vessel with a tapping device for the controlled tapping of liquid metal - Google Patents

Abstract

The invention is in the field of metallurgical plants, specifically in the field of metallurgical vessels of metals.

The object of the present invention is to provide a simple design of the tapping device in which the solidification of liquid metal in the tapping channel is prevented.

The task is solved by a metallurgical vessel (1) with a tapping device (10) for the controlled tapping of liquid metal, which is located in a lower part of the vessel. A partial area of a vessel wall (3) has, from an inside (3a) of the vessel wall (3) to an outside (3b of the vessel wall (3), a drainage channel (4) which flows into a tapping channel (11) of the tapping device (10). A lower edge (5) of the drain channel (4) on the inside (3a) of the vessel wall (3), measured from a cutting edge of the vessel wall (3) and the vessel bottom (2), is at a height (H) of 50 -300mm The outflow channel (4) extends through at least a portion of the vessel wall (3) essentially at a 90° angle to the vessel wall (3).

Description

field of technology

The invention is in the field of metallurgical plants, specifically in the field of metallurgical vessels of metals.

The metallurgical vessel has a tapping device for the controlled tapping of liquid metal, which is located in a lower part of the vessel.

The lower part of the vessel consists of a fireproof lining with a vessel base and a closed vessel wall. A portion of the vessel wall, from an inside of the vessel wall to an outside of the vessel wall, has a drainage channel.

The tapping device is designed in such a way that the outflow channel on the outside of the vessel wall opens into a tapping channel of the tapping device. When the metallurgical vessel is in a melting position, the tapping channel initially extends upwards - at an absolute angle of 0° to 20° to the force of gravity, preferably at an absolute angle of 0° to 5° to the force of gravity, opposite to the direction of the force of gravity - to an overflow channel - which extends essentially at an angle of 90 ° to the force of gravity - and the overflow channel opens into a tap hole channel which - essentially in the direction of the force of gravity - at an absolute angle of 0 ° to 20 ° to the force of gravity, preferably at an absolute angle from 0° to 5° to the earth's gravity - runs downwards to a tap opening.

State of the art

In the EP1181491 B1 A metallurgical vessel is described with a tapping device for the controlled, slag-free withdrawal of liquid metal.

A tapping device disclosed in this document shows a tendency for the melt to solidify in the channel of the tapping device in phases of processes in which standstills occur between the melts. In the tapping device disclosed, the channel begins at the same level as the bottom of the vessel, which means that the channel is always flooded with liquid steel. It can therefore happen that the liquid metal solidifies during breaks in the process. This solidified metal must then be melted again with liquid metal, which is created when a new process phase starts.

This is additionally supported with a long oxygen lance, which is inserted into the canal from above. This melting process can take several hours. Furthermore, even with the first melt, there is always the risk that the liquid metal will immediately flow into the channel and solidify again there due to a lack of temperature in the channel.

Summary of the invention

The object of the present invention is to provide a simple design of the tapping device in which the solidification of liquid metal in the tapping channel is prevented.

The object is achieved in that a lower edge of the drainage channel is located on the vessel wall, measured on an inside of the vessel wall from a cutting edge of the vessel wall and the vessel bottom, at a height of 50-300mm, with the drainage channel being at least in a partial area of the vessel wall extends through the vessel wall essentially at a 90° angle to the vessel wall.

The height of the step depends, on the one hand, on the size of the vessel and, on the other hand, on the respective process operation of the metallurgical furnace.

This stage allows liquid metal to enter the drain channel with a time delay, even in the melting phase, and thus there is a longer phase in which the drain channel is heated, and thus solidification in the drain channel is avoided due to insufficient temperature of the brick lining in the drain channel .

The outflow channel should be at a 90° angle to the vessel wall at least in a partial area of the vessel wall, preferably over the entire width of the vessel wall, since such a step can be produced particularly easily and inexpensively.

The height of the stage is preferably set so that a defined sump of liquid metal is either below or above the stage. The focus can be either to delay the inflow of the liquid metal sump into the drainage channel or to completely prevent the slag from flowing in by completely covering the drainage channel with liquid metal. The height of the lower edge is determined depending on the percentage of a sump of liquid metal - which remains in the metallurgical melting vessel after tapping - of a tapping weight of the metallurgical vessel, which can be in the range of 15%-70%. The height of the lower edge can be chosen so that in the critical process phases, such as process breaks, the liquid metal remaining in the furnace remains completely in the melting vessel and the drainage channel can run completely empty. The drain channel In addition to a rectangular cross-section, it can also have a vaulted cross-section or a round cross-section. If the lower edge is not a straight line, then the height is always understood to be that which is the shortest distance from the cutting edge of the vessel wall and the vessel bottom.

In a preferred embodiment, the lower edge and/or an upper edge has a chamfer. The chamfer preferably has a dimension in the horizontal and vertical directions or a radius of at least 10 mm, particularly preferably at least 20 mm. The bevel or radius allows for better flow into the drainage channel.

A flow number increases due to the principle of the rounded or chamfered lower edge and/or upper edge and thus increases a flow rate.

In an advantageous embodiment, at least one side edge of the drainage channel has a chamfer or a radius. The chamfer preferably has a dimension in the horizontal and vertical directions or a radius of at least 10 mm, particularly preferably at least 20 mm. The bevel allows for better flow into the drainage channel. Because the liquid metal flows in more evenly from all sides, the inlet speed of the liquid metal is harmonized across a cross section of the outflow channel. The one-sided wear on the top edge is reduced and the abrasion is distributed more evenly across all side parts. This extends the service life of the drain channel.

In a further preferred embodiment, the tapping opening is located above a lower edge on an outer surface of the vessel bottom. Due to the fact that the lower edge of the drainage channel is above the bottom of the vessel, a lower edge of the vessel bottom can be moved upwards in the area of the drainage channel in order to achieve the same thickness of the refractory lining. This allows the tap opening to be moved upwards in order to obtain a shorter length of the tap hole channel to the tap opening. The shorter length reduces the risk of the canal becoming blocked.

In an expedient embodiment, a burner is placed in the middle of the tapping channel, the burner having an output of at least 0.2 MW and a maximum of 1 MW. The central arrangement of the burner reduces wear on the refractory lining in the overflow channel and tapping channel.

An advantageous embodiment provides that a ratio of the hydraulic diameter of the drainage channel to a diameter of the tap opening is at least greater than 0.9.

dh...

hydraulischer Durchmesser

A...

Fläche

U...

Umfang

The hydraulic diameter is calculated by Equation 1. $$d_H=4\frac{\mathrm{A}}{U}$$

ie...

hydraulic diameter

A...

Area

U...

Scope

Brief description of the drawings

The characteristics, features and advantages of this invention described above and the manner in which they are achieved will be more clearly and clearly understood in connection with the following description of an exemplary embodiment which will be explained in more detail in connection with the drawings. Show:
Figs 1 - 4 shows a schematic representation of a metallurgical vessel with a tapping device.

Description of the embodiments

In the Fig. 1 A metallurgical vessel 1 is shown, the lower part of the vessel having a refractory lining with a vessel bottom 2 and a closed vessel wall 3. There is a bottom tap 9 in the vessel bottom 2. There is a drain channel 4 in the vessel wall 3. A lower edge 5 of the drain channel 4 is at a height H, measured from the intersection of the vessel wall 3 and the vessel bottom 2. The bottom edge 5 extends from the bottom edge 5 Outflow channel essentially at an angle of 90 ° through the vessel wall 3. A tapping device 10 is designed such that the outflow channel 4 opens into a tapping channel 11 of the tapping device 1 and the tapping channel 11, when the metallurgical vessel 1 is in a melting position, is initially extends upward - against the direction of gravity Fg - to an overflow channel 12 and then extends downward into a tap hole channel 13 - in the direction of gravity Fg - to a branch opening 14.

In the Fig. 2 A metallurgical vessel 1 is also shown with an inside 3a and an outside 3b of the vessel wall 3. In this preferred embodiment, the lower edge has a chamfer 5a and an upper edge 5d has a chamfer with the dimension a. A side wall 5b of the drainage channel 5 also has a chamfer 5c. The bevels are each attached at the transition from the inner surface 3a of the vessel wall to the drainage channel 4.

This design ensures that the liquid metal flows in particularly well from all sides. The one-sided wear of the upper edge is reduced. The abrasion is distributed more evenly on all four sides of the drain channel 5. This extends the service life of the drain channel.

In the Fig. 3 is in contrast to Fig. 1 the lower edge of the tap opening 13 above a lower edge of the vessel bottom 2b, the lower edge 2b being located on an outer surface 2a of the vessel base 2. The lower edge 2b is the deepest point of the vessel bottom on its outer surface 2a. This design shortens the length of the tapping channel 11 from the overflow channel 12 to the tapping opening 14.

Furthermore, in this embodiment there is a burner 15 in the middle of the tapping channel 11, which extends from the outflow channel 4 to the overflow channel 12.

In the Fig. 4 A top view is shown, indicated by the arrow in Fig. 3 indicated view A of the tapping device 10. In addition to the refractory lining 10a, the tapping device 10 also consists of a steel structure 10b. The vessel wall 3, which also consists of a refractory lining 3c and a steel structure 3d, is shown with the inside 3a and the outside 3b and the drainage channel 4, which extends from the inside 3a to the outside 3b and opens into the tapping channel 11. The tap channel 11 then extends upwards to an overflow channel 12, which then opens into the tap hole channel 13, with a diameter d.

Although the invention has been illustrated and described in detail by the preferred embodiments, the invention is not limited by the examples disclosed and other variations may be derived therefrom by those skilled in the art without departing from the scope of the invention.

Reference symbol list

1

Metallurgical vessel

2

vessel bottom

2a

Outside of the bottom of the vessel

2 B

Lower edge of the bottom of the vessel

3

vessel wall

3a

inside

3b

Outside

3c

Fire - festival lining

3d

steel construction

4

drainage channel

5

Bottom edge

5a

chamfer

5b

Side wall

5c

Chamfer of the side wall

5d

Top edge

9

Bottom tap

10

tapping device

10a

Fireproof - brick lining

10b

steel construction

11

Tap channel

12

overflow channel

13

tap hole channel

14

Tap opening

15

burner

H

Height

A

dimension

d

diameter

Claims (6)

Metallurgical vessel (1) with a tapping device (10) for the controlled tapping of liquid metal which is located in a lower part of the vessel, - wherein the lower part of the vessel comprises a fireproof lining (10a) and a steel structure (3d) with a vessel bottom (2) and a closed vessel wall (3), - wherein a portion of the vessel wall (3), from an inside (3a) of the vessel wall (3) to an outside (3b of the vessel wall (3), has a drainage channel (4), - wherein the tapping device (10) is designed such that the outflow channel (4) on the outside (3b) of the vessel wall (3) opens into a tapping channel (11) of the tapping device (10) and the tapping channel (11), if the metallurgical Vessel (1) is in a melting position, initially upwards - at an absolute angle of 0° to 20° to the force of gravity, preferably at an absolute angle of 0° to 5° to the force of gravity, opposite to the direction of the force of gravity (Fg). an overflow channel (12), - which extends essentially at an angle of 90 ° to the force of gravity (Fg) - and the overflow channel (12) opens into a tap hole channel (13) which - essentially in the direction of the force of gravity (Fg) - in a Absolute angle of 0° to 20° to the force of gravity, preferably at an absolute angle of 0° to 5° to the force of gravity - runs downwards to a tapping opening (14), characterized in that a lower edge (5) of the drainage channel (4) is on the inside (3a) of the vessel wall (3), measured from a cutting edge of the vessel wall (3) and the vessel bottom (2), at a height (H) of 50-300mm, the outflow channel (4) extending through the vessel wall (3) at least in a partial area at a substantially 90° angle to the vessel wall (3). Metallurgical vessel (1) with a tapping device (10) for the controlled tapping of liquid metal according to claim 1, characterized in that the lower edge (5) and / or an upper edge (5d) on the inside (3a) of the vessel wall (3). Chamfer or a rounding, preferably the chamfer should have a dimension (a) in the horizontal and vertical directions or the rounding should have a radius of at least 10 mm, particularly preferably of at least 20 mm. Metallurgical vessel (1) with a tapping device (10) for the controlled tapping of liquid metal according to claims 1 or 2, characterized in that at least one side edge (5b) of the drainage channel (4) on the inside (3a) of the vessel wall (3) has a chamfer or a rounding, preferably the chamfer should have a dimension (a) in the horizontal and vertical directions or the rounding should have a radius of at least 10 mm, particularly preferably of at least 20 mm. Metallurgical vessel (1) with a tapping device (10) for the controlled tapping of liquid metal according to claims 1 - 3, characterized in that the tapping opening (13) above a lower edge (2b) on an outer surface (2a) of the vessel bottom (2) lies when the metallurgical vessel (1) is in the melting position. Metallurgical vessel (1) with a tapping device (10) for the controlled tapping of liquid metal according to claims 1 - 4, characterized in that a burner (15) runs centrally to the intention channel (11), the burner having an output of at least 0. 2 MW and a maximum of 1 MW. Metallurgical vessel (1) with a tapping device (10) for the controlled tapping of liquid metal according to claims 1 - 5, characterized in that a ratio of the hydraulic diameter of the drain channel (4) to a diameter (d) of the tapping opening (14) is at least is greater than 0.9.

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