DE2550671A1 - FUSION CONTACT ELECTRODE FOR A DIRECT CURRENT ARC FURNACE - Google Patents

Description

Allmänna Svenska Elektriska Aktiebolaget Västeras / Sweden

Melt contact electrode for a DC powered one Arc furnace

Addendum to patent ... (patent application P 25 25 720.9)

The present invention relates to a fusible contact electrode according to the patent ... (patent application P 25 25 720.9).

The main patent relates to such a fusible contact electrode as mentioned in the preamble of claim 1. The invention is based on the object of further developing the fusible contact electrode - also called the ground contact electrode - in such a way that that the cooling thereof can be carried out and varied in various ways, depending, for example, on the Environment, the available space and the furnace dimensions,

To solve this problem, a fusible contact electrode is proposed according to the preamble of claim 1, which according to the invention has the features mentioned in the characterizing part of claim 1.

The transition blank is obtained, for example, when using the electrode. It usually arises from the fact that the furthest to the furnace

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inner reaching end of the solid blank melts, while the remainder of this blank on the unmelted one Part of the blank is stuck. This transition blank can be fully integrated with the fixed steel or iron blank be and consist of one part, the blank partially melts during operation of the ground contact electrode.

The invention is to be explained in more detail on the basis of the exemplary embodiments shown in the figures. Show it:

Pig. 1 a ground contact electrode with a blank made of several metals,

Fig. 2-5 different spatial arrangements of the ground contact electrodes,

6 shows an electrode with a conical shell,

7 shows a section through the electrode according to FIG. 6,

8 shows an air-cooled electrode,

9 shows a water-cooled electrode with a conical shell,

FIGS. 10-12 show the solidification conditions at different Electrode types,

Fig. 13-14 a mounted in an extension of the stove Ground contact electrode,

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15 shows a side view of a furnace with two ground contact electrodes,

16-18 further embodiments of the ground contact electrode.

Fig. 1 shows a bottom contact electrode arranged under the melt surface, which consists of a solid blank .1 made of copper or other electrically conductive material, to which an intermediate blank 2 made of iron or steel is attached, which at its end protruding farthest into the furnace is a Melt zone 3 at the transition to melt 4 in the furnace. This blank thus consists of a part that is fused to the rest of the blank, and when it is attached, a part of this blank is melted and taken up by the melt in the furnace. The connection between the blanks 2 and 1 preferably consists of a soldered seam 5, but other conventional types of connection are also conceivable. The electrode is embedded in a ramming compound 6 of the usual refractory type, which is surrounded by bricks 7. The food mass is connected to a metallic shell 8, which is provided with cooling water passages 9 for the liquid cooling of the ground contact electrode, thereby | rerhindert is that the enamel border 3 too far piece for connecting the electrode 10 moves.

Of course, you also want to prevent the iron or steel blank 2 is completely absorbed by the melt and the melt comes into contact with the copper piece, which never

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has a lower melting point and thus, if this happened, would be destroyed quickly. The iron and steel blank 2 thus also serves as protection for the copper blank. the In the case shown, the ground contact electrode is characterized by a transition zone from molten iron to solid iron, however, a transition zone from molten iron to copper is also conceivable if the cooling is sufficiently intensive. But normally you want to have a solidified part of the melt content on the copper blank. The electrode thus forms a transition from molten material 4 to solid material 1-2, and the cooling can be done at least partially by air. Liquid cooling can also be provided on the outer part of the electrode. As mentioned earlier, relates the invention relates to a DC-fed arc furnace with one or more working electrodes that are connected as a cathode, In such furnaces, an arc is formed between the negative Working electrode and the melt. There is no arc between the melt and the positive electrode desirable because most of the arc energy is released at the anode and this would then be quickly consumed. This is the reason for using the ground contact electrode connected as an anode arranged according to the invention. The problem that is solved by the invention is therefore electricity in a way other than an electric arc to the melt. According to the invention, the current is passed through the ground contact electrode, which is a transition from electrical Contains conductive solid material to melt.

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The ground contact electrode is in a through that Lining going opening channel 4. The cross-section of this channel can be circular or some other suitable shape to have. The cross-section can be constant, decrease or increase outwards from the melt, and the channel can be straight or be curved. The opening channel 4 can be arranged at any point in the lining where it is in Comes into contact with the melt.

FIGS. 2-5 show examples of different placements of an opening channel with a constant cross section. The opening channel 12 in FIG. 2 widens somewhat at its end located towards the inside of the furnace. As mentioned above, the channel is with filled with one or more metallic conductive materials, and the melt penetrates a certain distance into the interior Part of the channel. This is followed by the transition zone from the liquid to the solid material, which the latter denotes Fills the rest of the channel. As already mentioned, there are three alternatives for the solid material, namely 1. only iron or Steel from the melting zone to the outside or just another metallic material with a higher thermal conductivity than Iron, for example copper, 2. a material with a higher melting temperature than iron or 3. solidified iron directly on the melt and behind it material with a higher thermal conductivity than iron, for example copper. Of course Cooling is important here to protect the copper part. In Fig. 3, two ground contact electrodes 13 »14 shown, which are arranged to the side of the axis of symmetry of the furnace.

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In Pig. 4 these opening channels 15, 16 are in the vicinity of the Arranged melt level, but open below the same. Figo 5 shows an alternative embodiment with straight lines Opening channels for the ground contact electrodes 17, 18, the empty under the melt level in the furnace.

Fig. 15 shows a side view of a furnace in which the Soil contact electrodes 19, 20 are arranged under the inner part of the pouring nozzle 21 and under the slag hatch 22, respectively are what can prove beneficial. The furnace is also equipped with a stirrer 23.

Figures 13 and 14 show an embodiment of a ground contact electrode 24, which is arranged in an extension of the furnace, which is in communication with the main interior of the furnace. The fixed blank 25 lies here in a curved opening channel, and the cooling consists to a substantial extent a water cooling system 26 which is arranged outside the casting compound 27. The pouring spout is located on the designated 28 Job.

6 shows an embodiment of indirect cooling in which the feed mass 29 is accommodated in a conical casing 30 is. The shell consists of a surrounding electrode 31 Sheet. The solidified transition zone between the solid and the molten part of the electrode is designated by 32. the Heat is conducted through the lining 29, which is tamped or cast, and the highest possible thermal conductivity Has. Due to the conicity of the sheet, the cooling

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intensity to the outer end of the electrode Mn continuously, to.

FIG. 7 shows a section through the electrode according to FIG. 6, the central blank 31 within the feed mass 29

/ ^{in is} recognizable. The cross-section is circular in this exemplary embodiment, but other cross-sectional shapes are also possible.

FIG. 8 shows direct air cooling of the electrode in the area indicated by the arrows 33. In a similar way it is also, direct water cooling is possible, however preferably the combination of liquid and air cooling will choose. The cooling takes place on the outer part 34 of the electrode outside the furnace crucible or in direct contact with material that is in contact with the electrode.

9 shows an electrode consisting only of copper, at least on its outer part 35, with the conical shell 36 liquid-cooled conductors 37 are arranged. The electrode can also consist only of iron and be arranged in the ground, with direct and indirect water cooling, possibly also or only with air cooling.

FIGS. 10-12 show three embodiments of ground contact electrodes with associated temperature curves. The temperature T is plotted on the ordinate as a function of the axial location of the ground contact electrode. The temperature in the bathroom is T, and the temperature in the solidification section is T. the

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The solidification zone lies in Pig. 10 at 38, -and the melted one Part is denoted by 39. In Fig. 11, the molten part 40 has the temperature T 1. The part 41 of the electrode is made made of any material other than iron. As already mentioned, there is a transition zone between the molten material at the point 42 and solid material. Fig. 12 shows an electrode made from Copper or other non-ferrous material 43 is made, wherein this part is followed by a part 44 made of iron or steel, the end facing the furnace interior in the same way as described above has a transition zone made of solidified material 45, which consists of iron or steel and corresponds essentially to the melt content. T, is the temperature of the furnace melt, while T is the melting temperature and T is the temperature in the solid part of the electrode

In summary, it can be said that the transition from the molten to the solid material consists of a solidification zone, and that the position of this zone depends on the temperature of the melt and the degree of cooling, which, as mentioned, a water and / or air cooling, the cross section of the ground contact electrode can be constant or variable, and their placement in the crucible can be chosen arbitrarily as long as they only opens below the melt level. As mentioned, these electrodes can be on the pouring spout or on the slag hatch and also extend along the crucible. You can also attach a separate attachment to the crucible and the bottom contact electrodes place there. The water cooling can be direct and / or indirect. Also is a different coolant than

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Water is conceivable, such as air, steam or the like. The lining of the ground contact can, as mentioned, be conical, however also cylindrical, just like the electrode blank.

In the case of a copper part, a steel rod must be soldered or otherwise attached to this, which is directed towards the melt or is provided with a solidification zone on the melt, which is obtained when starting up for the first time. the The solidification zone can of course also consist of copper or the blank that belongs to the solid part.

In FIGS. 16 and 17, two further alternative embodiments are shown the ground contact electrode shown. The ground contact electrode here consists of an inwardly narrower one metal piece 46 made of copper or another material with good thermal conductivity, the one with cast cooling tubes 47 and is provided with a solidified transition zone 48 on the melt. Pig. 17 shows an oblique downward one Ground contact electrode that opens below the melt level and with recesses 49 for the water supply at 50 and the water drain is provided at 51. The connection contact piece 52 is arranged here to the side of the ground contact electrode. Such a ground contact electrode is break-through-proof because it with its outer part lies above the melt level. ο

oo Figure 18 shows an alternative embodiment with a ro

^ J horizontal plate 53 of copper or some other metal, ver

^ see with organs 54 for water or air cooling. The floor-

<o contact electrode 55 has a solid and a liquid one Part, and the outer liner 56 can be water or air cooled

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be. Power is applied at 57 and the distance 58 can be very short or very long.

The invention can be varied in many ways within the scope of the general inventive concept disclosed.

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Claims (8)

- 11 claims: 1.7 Fusible contact electrode for a DC powered one Arc furnace according to patent ... (patent application P 25 25 720.9), consisting of at least one blank Steel or iron, which is embedded in lining material and surrounded by a shell, the outside of which is at least partially can be cooled, and which extends into a channel for melt which is in communication with the furnace chamber, characterized in that that for the fusible contact electrode a blank made of copper or iron or a composite made of iron and copper Belonging to the blank, the iron being at the end facing the melt, and that a transition blank is attached to this solid blank in the direction of the melt or is attached to it Application of the electrode is attached, which consists of solidified material of steel or iron. 2. fusible contact electrode according to claim 1, characterized in that that the part of the shell facing the furnace crucible is provided with water cooling elements, while the remaining parts are wholly or partially water-cooled. 3 melting contact electrode according to claim 1, characterized in that that the outer part of the sheath or electrode is air-cooled. 4. Melt contact electrode according to one of claims 1-3 » characterized in that the feed mass on the electrode is tapered within a conical shell, the 609822/0 289 - 12 - conical shell preferably with tubes for liquid cooling is provided. 5. Melt contact electrode according to one of claims 1-4 » characterized in that the fusible contact electrode is on the underside of the furnace, essentially below the inner one Part of the pouring spout and / or under the slag hatch or is arranged in an attachment connected to the furnace. 6. fusible contact electrode according to one of claims 1-5, characterized in that the blank in the electrode Provided at least on its outer parts with recesses (51) for water cooling pipes or with cast-in cooling pipes is. 7. fusible contact electrode according to one of claims 1-6, characterized in that the blank in the electrode is horizontal (Ed. 16) or obliquely (5Ig. 17) from an external higher Level is arranged to an inner lower level, which the latter is below the melting level in the furnace. 8. fusible contact electrode according to one of the preceding claims, characterized in that the cross sections of the metallic Parts melted and / or solid in the electrode, in the direction from the inside of the furnace to the outside over the entire length or partially decrease. 6098 22/0289