SK96793A3 - A door for deslagging of an electric arc furnace - Google Patents

Abstract

The present invention relates to a slag removing door (10) of an electric arc furnace, of the type comprising a panel (11) which in particular is cooled and mounted slidingly vertically in front of a slag removing opening (2) of said furnace. The slag removing door (10) comprises means (20) for forming a curtain of air which is directed towards the threshold (4) of the door and extends essentially over the entire width of this door to ensure the impermeability of the bottom of said door during its closure and its partial opening. <IMAGE>

Description

Technical field

The invention relates to the slag door of an electric arc furnace, such as a scrap iron furnace, in a metallurgical plant.

BACKGROUND OF THE INVENTION

It is known that certain electric metallurgical furnaces currently in use are equipped with doors mounted vertically sliding in front of the blast hole or furnace tunnel. To this end, the door slides in vertical guides mounted on the outer wall of the furnace on both sides of said opening.

When slagging, i. by discharging the slag through this opening, the slag is deposited at the door sill and remains trapped there. As a result, if the door is to be closed again, these deposits constitute an obstacle to obtaining a satisfactory seal between the threshold and the corresponding lower part of the door. This insufficient tightness results in parasitic air inlets inside the furnace, which can lead in particular to a considerable and undesirable absorption of nitrogen and oxygen by the metal bath or, conversely, to the release of combustion gases out of the furnace. In addition, the ingress of parasitic air also occurs during the opening of the door for the passage of the injection tubes or the sampling probes.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a slag door adapted to overcome these drawbacks.

SUMMARY OF THE INVENTION

These drawbacks are overcome by the invention of a slag door of an electric arc furnace, comprising a panel, mainly cooled and mounted vertically slidingly in front of the slag opening, comprising means for generating an air curtain directed towards the door sill and extending over substantially the entire width of the door. providing a tightness to the bottom of the door during closing and partial opening, the aperture means comprising an air guide tube connected to the compressed air supply means and at least one horizontal cooling tube located at the bottom of the door, the conduit The airflow comprises openings oriented towards the threshold of said door. For the sake of simplicity, throughout the description and definition of the invention, the air guide tube is referred to as an air tube.

According to a further feature of the invention, the air tube is incorporated into the cooling tube and the openings of said air tube are in communication with the outside of said cooling tube.

The air tube openings may be in communication with the outside of the cooling tube by a longitudinal outlet formed in the bottom of the cooling tube and provided with sealing means between said air tube and said cooling tube.

The air tube may be and the sealing means may be coaxial with the cooling tube being formed by two deflectors mounted on one side of the openings and connecting the air tube to the longitudinal edges of the outlet. The air tube may also be supported on the longitudinal edges of the outlet, and the surface line of the inner surface of the air tube containing the apertures may be in contact with the outer surface of the cooling tube, the sealing means being formed by two longitudinal welds disposed between the outer surface of the air tube and the walls of the outlet.

According to a further feature of the invention, the cooling tube is fixed to the lower part of the door. The panel comprising a bundle of horizontal cooling tubes extending over substantially the entire width of said door is preferably designed such that the cooling tube is formed by a part of the bundle disposed on the lower part of the bundle.

According to a further embodiment of the invention, the air tube is formed by a housing formed opposite the door from the outside and the air outlet openings are located between the lower tube of the tube bundle and the auxiliary tube arranged parallel to said lower tube and at substantially the same height.

The housing may according to one embodiment be formed by a horizontal wall welded to the tube bundle, and a substantially vertical wall welded to the accessory tube. According to another embodiment, the housing is formed by a U-bent sheet, the arms of which are oriented downwardly, one arm being welded at its lower edge to the auxiliary tube and the other arm extending downwardly to the height level of the auxiliary tube defining the outlet air vents.

According to a further embodiment of the invention, the openings are formed by at least one row of slots. In this case, the end slits of the series are preferably L-shaped.

According to yet another embodiment of the invention, the air tube is connected by at least one of its ends to the supply means for supplying the cooling air, and comprises inside the barrier walls to distribute the flow rate of air over its entire length.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is explained in more detail below with reference to the accompanying drawings, in which:

Fig. 1 a schematic view of a slag door according to a first embodiment of the invention, Fig. 2 a section along line 2-2 of FIG. 1 Fig. 3 a schematic cross-section of a second embodiment slag door, Fig. 4 a partial section along line 4-4 of FIG. 3

Fig. 5 is a schematic longitudinal section through a third embodiment of the slag door; FIG. 6 is a section along line 6-6 of FIG. 5, FIG. 7 is a schematic longitudinal section through a fourth embodiment of a slag door; FIG. 8 is a section along line 8-8 of FIG. 7, FIG. Fig. 9 is a bottom plan view of a slag door according to a fifth embodiment; 10 is a cross-sectional view of the lower portion of the slag door according to a sixth embodiment; and FIG. 11 is a schematic longitudinal section through an air tube provided with a slag door according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

An electric arc furnace whose outer wall 1 is shown schematically in FIG. 1, the door 10 is mounted vertically sliding in front of the furnace slag opening 2. For this purpose, the door 10 slides in vertical guides 3 mounted on the outer wall 1 of the furnace on both sides of the opening 2.

The sliding of the door 10 is controlled by a control device (not shown), for example a working cylinder of the double-acting type, which allows the door 10 to be partially opened so that injection or injection tubes or metal bath removal probes can be inserted.

The door 10 is formed by a metal panel comprising essentially a bundle of cooling tubes 12 (FIG. 2) in which a fluid formed, for example, by water is circulated. The tubes 12 are horizontal and extend substantially over the entire width of said door.

When slagging, when the door is open, slag and metal deposits stick to the door sill 4 and remain trapped there. This has the effect that the door cannot close completely and that these deposits create an obstacle to achieving sufficient tightness between the threshold 4 and the lower part of the door 10. This is also the case when the door is opened due to the insertion of injection or injection tubes or sampling probes. hole 2.

To prevent this, the door 10 is provided with air curtain generating means 20 oriented to the door sill 4 and extending over substantially the entire width of the door to ensure that the lower portion of the door is sealed during closing and opening. The air curtain has an effective height which can reach up to 50 cm.

According to a first embodiment of the invention shown in FIG. 1 and 2, the air curtain forming means 20 comprises a housing forming an air tube 21 of substantially cuboid shape and mounted on the lower part of the door 10. The air tube 21 is connected to a compressed air supply means (not shown) and comprises a wall mounted opposite the threshold 4. the door 22 through openings 22 oriented towards said threshold 4.

The air tube 21 is protected by a refractory material. The refractory material may be in the form of a plate 24 of refractory material, which may be attached to the air tube 21 on the side facing the furnace interior, to protect the tube from thermal radiation of the furnace. The air tube 21 may be mounted directly on the lower part of the cooled panel 11 or on the cooling tube 12 located on the lower part of the bundle in the case where the cooling of the door panel 10 is carried out by such a bundle. In this case, the lower tube 12 forms an additional cooling portion of the air curtain generating means 20.

According to a second embodiment of the invention shown in FIG. 3 and 4, the air tube 21 is housed in a housing forming a cooling tube 23 having an equally substantially cuboid shape in which the cooling fluid is circulated. The wall of the air tube 21 comprising the apertures 22 forms the bottom of said cooling tube 23.

The cooling tube 23 may be mounted directly on the lower part of the panel 11 or on the tube 12 mounted in the lower part of the bundle. The apertures 22 are formed by at least one row of slots 22a, the end slots 22b of which are L-shaped (FIG. 4), one arm of which is oriented towards the furnace wall, allowing to create an air curtain ensuring better lateral tightness.

According to two further embodiments shown in FIG. 5 to 8, the air curtain generating means 20 includes an air tube 30 connected to compressed air supply means (not shown) and embedded in a horizontal cooling tube 13 located at the bottom of the door 10. This cooling tube may be an independent tube attached to the bottom of the door 10. thereby facilitating assembly and disassembly of the assembly, or a portion of the bundle of cooling tubes 12 disposed on the lower portion of the bundle as shown in FIG. 5 to 8.

In FIG. 5 and 6, the air tube 30 is coaxial with the coolant tube 13 and includes openings 31 directed toward the door threshold 10. These openings 31 are connected to the outer coolant tube 13 by a longitudinal outlet 32 formed in the bottom of the coolant tube 13 and provided with sealing means between said. These sealing means are formed by two deflectors 33 mounted on one side of the apertures 31 and connecting the air tube 30 to the longitudinal edges of the outlet 32. The height and spacing of the deflectors 33 are determined to direct the air streams emanating from the air outlet. apertures 31 so that the air curtain is uniform. This tube 30 can also be supplied with compressed air through its two ends to improve air curtain uniformity.

According to the fourth embodiment shown in FIG. 7 and 8, the air tube 30 is supported on the longitudinal edges of the outlet 32 and the surface line of the outer surface of the air tube. including the holes 31 is tangential to the outer surface of the coolant tube 13. In this case, the sealing means are formed by two longitudinal welds 34 lying between the outer surface of the air tube 30 and the edges of the outlet 32.

According to the fifth and sixth embodiments shown in FIG. 9 and 10, using a compressed air-powered housing, the housing 41 is located opposite the door from the outside and includes an additional cooling tube 44 and air outlets 42 are formed between the inner tube 43 of the tube bundle 12 and the additional tube 44 disposed parallel to lower tube and basically the same height ..

In the embodiment of FIG. 9, the housing 41 is formed by a horizontal wall 45 welded to the bundle of tubes 12 and a wall substantially vertical 46 welded to the additional tube 44.

In the embodiment of FIG. 10, the housing 41 is formed by a U-bent sheet 47, the arms of which are oriented downwards. One arm 48 is welded at its lower edge to the auxiliary tube 44 and the other arm 49 is extended down to the height level of the auxiliary tube 44 to define with it the air inlet openings 42. The box body is movably mounted on a door on the outside.

In both last embodiments, the additional tube 44 may be connected directly to the bundle of tubes 12, or may be supplied separately with water. These two embodiments have the advantage that they can be adapted to existing doors without significantly altering them. In addition, the device is protected from thermal radiation from the furnace by the door itself.

In a sixth embodiment, the housing can be easily disassembled for eventual repositioning.

The air tube 21, 30 or 41 may be connected at one of its ends or at its two ends to a supply means for supplying compressed air. When the air tube is fed at one end thereof, the distribution of the air flow rates along the length of the tube is not uniform and is larger at the end of the tube opposite to that which is connected to the supply air supply means. If the air tube is fed at its two ends, the airflow through the apertures is larger in the center of the tube than at its two ends.

In order to avoid this and to obtain it, as shown in FIG. 11, the air curtain is substantially uniform over the entire length of the air tube, and includes an air tube 21 within the barrier wall 50 that breaks the air flow and creates a positive pressure in the region close to the air inlet. A plurality of baffle walls 50 may be located within the tube 21, depending on the width of the furnace door and the desired air curtain uniformity. For a door width of 800 mm, for example, the partition wall 50 is located 150 mm from the end of the tube 21 connected to the air inlet or both ends of the tube 21 when both ends of the tube are connected to the air inlet as shown in FIG. 11th

The air outlet openings may be in the form of discontinuous slots, which makes it possible to prevent these slits from expanding by deforming the air tube under the effect of heat. The constant width of the slots makes it possible to obtain a regular flow rate of air so that the air curtain remains uniform.

The air curtain thus formed at the bottom of the door allows for tightness, even if the door cannot be lowered to the threshold or when the door has been intentionally partially opened to receive the injection or blow tube or sampling probes, or even during the blasting operation.

By way of example, the apparatus of the invention has been tested to produce openings in the form of a slot having a width of 1 mm, which do not connect to a length of 800 mm corresponding to the width of the slag opening. At an air flow rate of 300 Nm ³ / h and a pressure supply of 0.11 MPa, an effective air curtain was obtained at a height of 300 mm, the furnace shell being at a vacuum of about -30 Pa and an air outlet velocity of at least 50 m / s.

Preferably, the air discharge rate at the outlet of the apertures is greater than 50 m / s so that the air curtain is effective at a height of 300 min when the furnace door is opened.

The inlet air flow rate is adjusted depending on the phase of operation of the furnace. For example, the supply air flow rate is 100 m ³ / h when the furnace door is opened by 200 mm to allow passage of the oxygen blowing tube or, for example, when coal is added during batch melting and when the door is opened 300 mm above the slag during refining or slagging.

Claims (13)

PATENT CLAIMS A slag door of an electric arc furnace, comprising a panel, in particular cooled and mounted vertically sliding in front of the slag opening, characterized in that it comprises means (20) for generating an air curtain directed towards the door threshold (4) and extending substantially over the entire width of the door to provide tightness to the bottom of the door (10) during its closing and partial opening, the orifice means (20) comprising an air tube (21, 23, 44) connected to the compressed air supply means and at least one horizontal cooling tube (12, 13, 23, 43, 44) located at the bottom of the door (10), the air tube (21, 30, 41) having openings (22, 31, 42) oriented towards the threshold (4) ) of said door (10). Sliding door according to claim 1, characterized in that the air tube (21, 30) is incorporated into the cooling tube (13, 23) and the openings (22, 31) of said air tube (21, 30) are in communication with the outside. said cooling tube (13, 23). Sliding door according to claim 1 or 2, characterized in that the openings (31) of the air tube (30) are in communication with the outside of the cooling tube (13) by a longitudinal outlet (32) formed in the bottom of the cooling tube (13) and provided. sealing means between said air tube (30) and said cooling tube (13). The door according to claim 3, characterized in that the air tube (30) is coaxial with the cooling tube (13) and the sealing means are formed by two deflectors (33) each arranged on one side of the openings (31) and connecting the air tube (30). 30) with longitudinal edges of the outlet (32). Sliding door according to claim 3, characterized in that the air tube (30) is supported on the longitudinal edges of the outlet (32) and the surface line of the outer surface of the air tube (30) comprising the openings (31) is tangential to the outer surface of the cooling tube. (12), the sealing means being formed by two longitudinal welds (34) located between the outer surface of the air tube (30) and the walls of the outlet (32). Sliding door according to any one of claims 3 to 5, characterized in that the cooling tube (13) is fixed to the lower part of the door (10). Sliding door according to any one of claims 3 to 5, wherein the panel comprises a bundle of horizontal and parallel cooling tubes extending over substantially the entire width of the door, characterized in that the cooling tube (13) is formed by a portion of the bundle disposed on the lower part of the bundle. Sliding door according to claim 1, characterized in that the air tube is formed by a housing (41) located opposite the door from the outside and the air outlet openings (42) are located between the lower tube (43) of the tube bundle (12) and an additional tube (44) arranged parallel to said lower tube and at substantially the same height. Sliding door according to claim 8, characterized in that the housing (41) is formed by a horizontal wall (45) welded to the bundle of tubes (12), and a substantially vertical wall (46) welded to the auxiliary tube (44). Sliding door according to claim 8, characterized in that the housing (41) is formed by a U-shaped bent sheet (47), the arms of which are oriented downwards, one arm (48) being welded at its lower edge to the auxiliary tube. (44) and the second arm (49) extends downwardly to the height level of the auxiliary tube (44) where it defines air outlet openings (42) therewith. Sliding door according to any one of claims 1 to 11 10, characterized in that the openings (22, 31, 42) are formed by at least one row of slots. Sliding door according to claim 11, characterized in that the end slits of said series are L-shaped. Sliding door according to any one of claims 1 to 13 12, characterized in that the air tube (21, 30, 41) is connected by at least one means for supplying cooling air from its ends, to the supply and internally comprising baffle walls (50) for distributing a flow rate of air over its entire length.