WO2011009622A1 - Electrode carrier arm with locally fastened current conductor - Google Patents

Abstract

The invention relates to an electrode carrier arm, an electrically conductive layer (100) being formed on at least one outer side of the electrode carrier arm (4), wherein the electrically conductive layer is a sheet metal made of a first material with an electrical conductivity of ≥ 30⋅10⁶ S/m and a heat conductivity of ≥ 200 W/(m⋅ K), fastened via a plurality of connecting regions (110, 120) on the outside of the electrode carrier arm and in thermally conductive contact with the electrode carrier arm.

Description

 Electrode support arm with locally fixed conductor

The present invention relates to an electrode support arm for a metallurgical furnace, in particular an electric arc furnace.

EP 0 184 140 A2 discloses an electric arc furnace in which the electrode arm is provided, at least on part of its outside, with a layer of good electrical conductivity, e.g. made of copper or aluminum. This layer is plated and serves as a high current conductor for the electrode current.

Such electrode support arms serve both to hold an electrode and to conduct current to the electrode. They experience on the one hand a mechanical load by the weight of the electrode and the electrode support arm itself and on the other hand a thermal load. Therefore, electrode support arms are usually designed as a hollow profile in which coolant channels are provided, so that the electrode support arm can be cooled.

From DE 1 565 382 an electrode arm is known in which the current supply to the electrode is ensured by a sleeve completely surrounding the electrode arm. The sleeve may be insulated or in conductive connection with the electrode arm.

From EP 1 901 585 A1, DE 42 36 158 C1, EP 0 061 612 A1 and DE 10 2006 027 648 A1 further electrode support arms are known.

The preparation of such Elektrodentragarm is expensive.

It is an object of the present invention to improve the adaptation of an electrode support arm for a metallurgical furnace such as an arc furnace.

This object is achieved by a Elektrodentragarm according to claim 1 or 3. Further developments of the invention are specified in the dependent claims. It is a power line adaptation of individual components, such as sheet steel and copper sheet, without the disadvantages of busbars, etc. possible. At the same time, production becomes more flexible and less expensive. Due to the plurality of first connecting regions, a good contact between outer side and sheet metal, which consists for example of steel or copper and thus ensures good heat conduction.

The costly and expensive plating can be replaced, in particular by applying inexpensive standard copper plates.

The electrically conductive layer fixedly connected to the support structure by the plurality of first connection portions is cooled by the cooled electrode support arm via the first connection portions.

Further features and expediencies will become apparent from the description of embodiments with reference to FIGS. From the figures show:

Fig. 1 is a cross-sectional view of a portion of a Elektrodentragarms after a first

 Embodiment perpendicular to the longitudinal direction;

 Fig. 2 is a plan view of the part of an electrode support arm of Fig. 1;

 Fig. 3 is a cross-sectional view of a portion of a Elektrodentragarms after a second

 Embodiment perpendicular to the longitudinal direction;

 4 is a perspective view of an electrode support arm according to the first embodiment;

 Fig. 5 is a side view, partly in section, of an electric arc furnace; and

 6 is a plan view of the electrode support arms of the furnace of FIG. 5.

5 and 6 show an electric arc furnace 1 with three approximately parallel to each other arranged Elektrodentragarmen 2, 3, 4, of which in the sectional view of FIG. 5, only the electrode support arms 3 and 4 are shown. The electrode support arms 2, 3, 4 are liftable and lowered by lifting columns 5 in a known manner and by means of a portal 6, in which the lifting columns 5 are guided, pivotable about an axis 7 to the side. Each of the electrode arms 2, 3, 4 has an Elektrodeneinspannvorrichtung 8, which includes a contact jaw 9, which is supported on the Elektrodenarm, and by which an electrode 10 is clamped to the electrode support arm and is powered. The electrodes 10 are formed as so-called combination electrodes with a metallic upper part and a screw-on, the combustion underlying lower part.

The electrode support arms 2, 3, 4 have a box-shaped profile 18 (see FIG. 4) and, in addition to cooling channels for a cooling liquid, such as water, may have a device for actuating the electrode clamping device. Details of a corresponding exemplary construction of the electrode arms 2, 3, 4 and of the clamping device 8 can be found in EP 0 184 140 A2.

In the example of FIGS. 5, 6, the electrode support arms 2 and 4 over their entire length, the middle electrode support arm only on a portion of its length on a plurality of outer sides of the box profile from the electrode end with a highly electrically conductive layer 100 of copper or Aluminum provided, which is shown hatched in Figures 5 and 6 only at the end of the respective layer. The electrically conductive layer 100 is applied by plating copper. On the middle electrode support arm 3, a high-current tube 14 is fastened by means of support arms 13, which is electrically connected to the region of the electrode support arm 3 provided with the electrically highly conductive layer 12. At the end of the electrode support arms 2 and 4 and the high-current tube 14, which faces away from the respective electrode, connection terminals 15 are provided for high-current cables 16, which are connected to a transformer, not shown, and feed the current for the electrodes 10. The electrode support arms 2 to 4 are each secured electrically isolated on the associated lifting column 5 by means of bolts. The insulation is indicated in Fig. 5 by an insulating plate 17.

For the invention it does not depend on the exact configuration of the internals of the electrode support arm and the power supply to the electrode support arm.

The electrode support arm 4 in the embodiment shown in FIGS. 5 and 6 has an electrically conductive layer 100 on a plurality of the four outer sides in the longitudinal direction. But it would also be sufficient if the electrically conductive layer 100 is formed only on an outer side (preferably the upper), or 2 or 3 of the outer sides. Under an outside should be understood in each case the side of a wall of a profile body, which faces away from the interior in the profile body. A profile body with a rectangular cross-section therefore has four outer sides which extend in the longitudinal direction.

An electrode support arm in which an electrically conductive layer 100 is formed on the upper outer side 102 will be described below by way of example.

In the embodiments shown in FIGS. 1 to 4, the electrode support arm is formed by a rectangular box profile 19 extending in a longitudinal direction z having a length a7. The rectangular box profile 19 has a bottom wall 18a and a top wall 18d and two side walls 18b, 18c connecting the bottom and top walls 18a, 18d. The box profile 19 has a length a7 in the longitudinal direction z, a width c7 in a transverse direction y, which is perpendicular to the longitudinal direction z, and a height h7 in a vertical direction x, which is perpendicular to the longitudinal direction z and senkecht to the transverse direction y on. The walls 18a, 18b, 18c, 18d each have a thickness hl, but may also have different thicknesses.

The upper wall 18d has an inner side 101, which is disposed opposite to the lower wall 18a, and an outer side 102.

Also, the two side walls 18b, 18c and the lower wall 18a each have an inner side facing the opposite wall, and an outer side facing away from the opposite wall, respectively.

The walls 18a to 18d of the box profile element 18 are formed of sheet steel and form the supporting structure of the electrode support arms.

The box profile 19 can preferably be formed from one or a plurality of box profile elements 18, 18 ', which are connected in the longitudinal direction z and have the above construction. The box profile elements 18, 18 'can be formed with different lengths in the longitudinal direction z. On the upper outer side of the electrode support arm 2, 3, 4, that is to say the outer side 102 of the upper wall 18d of the first box profile element 18, an electrically conductive layer 100 is formed.

Referring to Figs. 1, 2 and 4, the structure of supporting structure and current conducting layer will be described in more detail.

The electrically conductive layer 100 extends in the transverse direction y, preferably with substantially the same width c7 as the electrode support arm. The electrically conductive layer 100 has a thickness h2 in the height direction x.

In the embodiment, the electrically conductive layer 100 consists of a plate-shaped copper sheet 100. The copper sheet 100 bears against the outer side 102 of the upper wall 18d of the first box profile element 18. The copper sheet 100 is arranged on the first box profile element 18 such that the right and left edges in the transverse direction y are preferably flush with the edges of the outer side 102 of the upper wall 18d of the box profile element 18. The copper sheet 100 has an outer surface 104, which faces away from the outer side 102 of the wall plate 18d.

At the two ends in the longitudinal direction z, the copper sheet 100 has an end face 134 each.

The copper sheet 100 has a plurality of first connection portions 110, or rather, is connected to the upper wall sheet 18d by means of the connection portions 110. As shown in the figures, the first connection portions 110 are substantially distributed over the entire copper sheet 100. The first connection regions 110 each have a circular, continuous opening 112 with a diameter d 1.

Each through opening 112 of a first connection region 110 has at the lower edge of the openings an inner edge which faces the outer side 102 of the box profile element 18. The copper sheet 100 is connected at the inner edges of the openings 112 in each case by a cohesive connection 111 with the upper wall 18 d of the box profile element 18. The cohesive connection is preferably a weld 111. The weld 1 11 each extends along the inner peripheral edge of the opening, which faces the outer side 102 of the Kastenpro fϊlelements 18. The openings 112 are completely filled in the remaining areas with a material that conducts heat well, preferably copper or aluminum.

Each of the first connection regions 110 is arranged with a minimum distance z from the closest adjacent connection region 110. The connecting portions 1 10 on the copper sheet 100 are arranged in a grid. The grid consists of a rectangular, preferably square grid, in which additionally a central first connecting area 110 is arranged on the intersection of the diagonals.

The rectangular grid of the grid has in the longitudinal direction z a distance al of the grid points. That Two adjacent first connection regions 110 have an edge distance a2 in the longitudinal direction z.

The rectangular grid of the grid has a distance cl of the grid points in the transverse direction y. That two adjacent first connecting regions 1 10 have an edge distance c2 in the transverse direction y.

In the diagonal direction of the rectangular grid, the centers of two adjacent first connection regions 110 are spaced apart by a distance zl. That two adjacent first connection regions 1 10 have an edge distance z2 in the diagonal direction.

The centers of the lying in the transverse direction y closest to the edge of the copper sheet 100 connecting portions 1 10 have a distance c5 from the edge. That the edge distance between a first connection portion 110 and the edge of the copper sheet 100 is the distance c6 in the transverse direction y.

4 shows an enlarged cross-sectional view of a portion of the electrode support arm 2, 3, 4. The portion is formed by two interconnected box profile elements 18, 18 '. The first Kastenpro filelement 18 has a length a8 in the longitudinal direction z. The second box section element 18 'has a length a9 in the longitudinal direction z. The first box section element 18 and the second box section element 18 'are connected to each other by a peripheral weld 133.

As can be clearly seen in Fig. 1, the copper sheet 100 is formed and arranged so that the end face 134 before welding the adjacent box profile elements 18, 18 'each have a distance a5 in the longitudinal direction z from a first end of the upper wall 18d in the longitudinal direction z has. This distance allows easy welding of the adjacent box profile elements 18, 18 'by means of the weld 133, since the corresponding part of the outside 102 of the top wall 18d of the box profile element 18 is not covered by the copper sheet 100.

The centers of the first connection regions 110 are arranged at a distance a3 in the longitudinal direction z to the end face 134 of the copper sheet 100. That the edge distance from a first connection region 110 to the end face 134 of the copper sheet 100 is the distance a4 in the longitudinal direction z.

The copper sheet 100 is preferably materially bonded along the inner edge of the end face 134, preferably by a weld in a second connection region 130 with the outer side 102 of the box profile element 18.

The arrangement and construction of the first and second connection regions 110, 130 on the second box profile element 18 'takes place analogously to the first box profile element 18.

The first box section element 18 and the second box section element 18 'are connected by the substantially V-shaped weld seam 133, which extends along the circumference. The greatest width b2 of the weld 133 lies between the outer side 102 of the upper wall 18d of the first box profile element 18 and the outer side 102 of the upper wall 18d of the second Kastenpro filelements 18 '.

The end surfaces 134 of the copper sheets 100 are spaced from each other by a distance bl in the longitudinal direction z, which results from the double distance a5 and is greater than the width b2 in the longitudinal direction z. The gap 132 between the second connection regions 130 is filled with a material that conducts both heat as current comparable or as good as the material of the electrically conductive layer, eg, copper or aluminum.

To produce such an electrode support arm, box-section elements 18, 18 'are preferably first produced with electrically conductive layer 100 and then welded. Alternatively, first box profile elements 18, 18 'can also be produced and welded without electrically conductive layer 100. Then, the electrically conductive layer 100 may be independently and fastened with other lengths in the z-direction and regardless of the position of the welds 133 over the first connection regions.

Fig. 3 shows a second embodiment of the electrode support arm. The same components and sizes as in the first embodiment are denoted by the same reference numerals and will not be described again.

The plate-shaped copper sheet 100 is not welded in contrast to the first embodiment, but connected to the outside 102 by a plurality of connecting elements forming the first connecting portions 120. As connecting elements nails 121 are preferably used, as they are known for example from DE 10 2004 040 701 B3. The nails 121 have an overall height h5 in the height direction y. The nail head has a height h.3 in the height direction y and the nail shaft has a height h4 in the height direction y. The nail shank 122 has a diameter d10, the nail head has a diameter d11. The nails are durably pressed into the top wall 18d of the box profile member 18 and firmly connect the copper sheet 100 to the outside 102. According to the embodiment shown, the nails 121 do not penetrate the walls of the box profile elements 18, 18 'completely. It is further shown that the connecting elements are distributed substantially over the entire copper sheet 100.

The nails 121 are arranged in a grid that corresponds to the grid of the first embodiment.

For producing a Elektrodentragarms according to the second embodiment, the copper sheets 100, unlike the first embodiment, by shooting nails with connected to the box section 18, 18 '. The nails penetrate the copper sheet 100 and penetrate into the box profile element 18, 18 '.

In the second embodiment, no openings 1 12 must be provided in the copper sheets 100, so that this processing step can be omitted. In addition, the nails 121 can be shot in easily and at a fast speed.

To improve the thermal conductivity, nails 121 with high thermal conductivity are preferably used.

As fasteners, for example, screws or pins could be used. Furthermore, different nails 121, in particular different lengths and different thickness nails 121 in different areas of the electrode support arm 4 can be used.

The arrangement of the individual first connection regions 1 10, 120 to each other can also be done in other raster forms. For example, the individual connection regions 110, 120 may be arranged in rhomboidal patterns relative to one another. The first connection regions 110, 120 can also be arranged in a random pattern relative to one another without screening.

The longitudinal edges of the copper sheet 100 may be welded to the box profile element 18, 18 'and / or an adjacent copper sheet 100. The edges on the edges of the electrode support arm and / or those of the copper sheet 100 should be rounded to avoid voltage spikes.

The end face 134 of the copper sheets 100 may also be formed bevelled.

The electrode support arm can also be designed as a T-carrier or as a carrier designed in any other way.

As connecting elements preferably nails are used. The nails are preferably with special impact or Eintreibmaschinen, as for example from DE 10th 2007 000 25 Al, driven or shot into the electrically conductive layer 100 and the wall 18d.

The thickness h1 of the wall of the box profile element 18, 18 'of the electrode support arm in the height direction x or the transverse direction y is <30 mm, preferably between 5 and 20 mm, more preferably between 10 and 16 mm, e.g. 11 mm, 13 mm or 15 mm.

The thickness h2 of the electrically conductive layer 100 in the height direction x is between 1 and 15 mm, preferably between 3 and 6 mm, more preferably between 4 and 5 mm, e.g. 4 mm, 4.5 mm or 5 mm.

The height h3 of the nail head 123 in the height direction x is <6 mm, preferably between 1 and 5 mm, more preferably between 2 and 3 mm, e.g. 2 mm, 2.5 mm or 3 mm.

The height h4 of the nail shank in the height direction x is 10 to 35 mm, preferably 10 to 20 mm, e.g. 12 mm, 15 mm or 17 mm.

The total height h5 of the nail in the height direction x is 1 1 mm to 41 mm, preferably 15 mm to 35 mm, e.g. 15 mm, 19 mm or 21 mm or 23 mm.

The height h7 of the electrode support arm in the height direction x is between 600 and 1500 mm, preferably between 800 and 1000 mm, e.g. 800 mm, 900 mm or 1000 mm.

The diameter d10 of the rod shank is preferably between 3 mm and 10 mm, more preferably between 3.5 mm and 6 mm, e.g. 4 mm.

The width bl in the longitudinal direction z between two end surfaces 134 of the electrically conductive layer 100 is preferably between 10 mm and 70 mm, more preferably between 20 mm and 40 mm, such as e.g. 30 mm.

The distances a1, cl of two first connection regions 110 in the longitudinal direction z are between 60 and 220 mm, preferably between 70 and 150 mm, more preferably between 80 and 120 mm, such as 90 mm, 100 mm or 110 mm. It follows that on and the same copper plate 1 OO in the longitudinal direction z preferably at least every 220 mm, a first connection portion 1 10 is provided. Next, it follows that at least one connecting area per circa 200 10 ³ mm ² copper sheet 100 is provided, and that are even with the use of several copper plates 100 of the preferred maximum distance in the longitudinal direction z between two first connection portions 110 on various copper plates 100 , 510 mm.

The distance a3 of a first connecting portion 110 to the edge of the second connecting portion 130 is between 60 and 220 mm, preferably between 70 and 150 mm, more preferably between 80 and 120 mm, such as e.g. 90 mm, 100 mm or 1 10 mm ..

The lengths a8 and a9 of a box profile element 18, 18 'are between 500 mm and 4000 mm.

The diameter d 1 of a circular opening in the electrically conductive layer 100 is between 10 mm and 40 mm, preferably between 15 mm and 30 mm, more preferably between 15 and 25 mm, e.g. 20 mm.

The edge lengths of a rectangular opening in the electrically conductive layer 100 are between 10mm and 25mm for the short side and between 30mm and 80mm for the long side, such as the long side. 18mm x 50mm.

The area of a first connection region is between 78 mm ² and 2000 mm ² , preferably between 200 mm ² and 400 mm ² , such as 314 mm ² .

A ratio of the area of the first connection regions 110, 120 to a total area of the electrically conductive layer 100 is greater than 1% and less than 20%, preferably greater than 3% and less than 15%, more preferably greater than 5% and less than 10 %, such as 6%, 7%, 8% or 9%.

A ratio of an area of the first connection areas 110, 120 together with the second connection areas 130 to a total area of the electrically conductive layer 100 is greater than 2% and less than 40%, preferably greater than 3% and less than 30%, more preferably greater than 4% and less than 15%, such as 6%, 9%, 10% or 13%.

The thermal conductivity of the electrically conductive layer 100 and the filler material for the first and second connection regions 110, 130 is> 200 W / (mK), preferably> 300 W / (mK), more preferably> 350 W / (mK), such as eg 350 W / (m K) and 380 W / (m-K).

The electrical conductivity of the electrically conductive layer 100 and the filler material for the first and second connection regions 110, 130 is> 30 10 ⁶ S / m, preferably> 35-10 ⁶ S / m and more preferably> 50- 10 ⁶ S / m, such as 56 10 ⁶ S / m or 58-10 ⁶ S / m.

It is expressly stated that all features disclosed in the specification and / or claims are intended to be separate and independent of each other for the purpose of original disclosure and also for the purpose of limiting the claimed invention, regardless of the composition of the features in FIG the embodiments and / or claims to be disclosed. It is expressly stated that all ranges of values or indications of groups of entities disclose every possible intermediate value and every intermediate entity for the purpose of original disclosure and also for the purpose of limiting the claimed invention.

LIST OF REFERENCE NUMBERS

1 electric arc furnace

 2 electrode support arm

 3 electrode support arm

 4 electrode support arm

 5 lifting columns

 6 portal

 7 axis

 8 electrode clamping device

 9 contact jaw

 10 electrode

 18 first box profile element

 18 'second box profile element

 18a lower wall of a box profile element

18b side wall of a box profile element

 18c side wall of a box profile element

 18d upper wall of a box profile element

19 box profile

 100 copper sheet

 101 inside of the first box profile element

102 outside of the first box profile element 104 outer surface of the copper sheet

 1 10 first connection area

 1 1 1 weld

 112 filled with heat conductive material opening

120 first connection area

 121 nail

 122 nail stock

 123 nail head

 130 second connection area

 131 weld

132 electrically and heat conductive filling 133 weld

134 face of the copper sheet

Claims

claims

1. Electrode support arm for a metallurgical furnace, with

 an electrically conductive layer (100) on at least one outer side of the electrode support arm (4),

 in which

the electrically conductive layer (100) is a metal sheet of a first material with an electrical conductivity> 30 10 ⁶ S / m and a thermal conductivity> 200 W / (m K), which is distributed over a plurality of first connecting regions (1 10, 120) is attached to the outside of the electrode support arm (4) and in heat conductive contact therewith.

2. An electrode support arm according to claim 1, wherein the ratio of an area of the first connection areas to a total area of the electrically conductive layer is greater than 1% and less than 20%.

3. Electrode support arm for a metallurgical furnace, with

 an electrically conductive layer (100) on at least one outer side of the electrode support arm (4),

 in which

 the electrically conductive layer (100) is fixed to the outside of the electrode support arm (4) via a plurality of first connection regions (1, 10, 120) and in heat conductive contact therewith, and the ratio of a surface area of the connection regions to a total area of the electrically conductive layer increases than 1% and less than 20%.

4. An electrode support arm for a metallurgical furnace according to claim 3, wherein

the electrically conductive layer (100) is a plate-shaped sheet of a first material having an electrical conductivity> 30-10 ⁶ S / m and a thermal conductivity> 200 W / (mK).

An electrode support arm according to any one of claims 1 to 4, which extends in a longitudinal direction z and a height (h7) in a height direction (x) which is perpendicular to the longitudinal direction (z) and a width (c7) in a transverse direction (y ) which is perpendicular to the height direction (x) and to the longitudinal direction (z),

 wherein the outside is formed by an outside of a metal sheet having a first thickness (hl) perpendicular to the longitudinal direction (z) which is <30 mm.

6. electrode support arm according to one of claims 1 to 5, wherein the electrode support arm (4) and the electrically conductive layer (100) in one or more of the plurality of first connecting portions (110, 120) penetrating through the conductive layer connecting elements (121). are connected.

7. Electrode support arm according to one of claims 1 to 6, wherein the electrically conductive layer (100) in one or more of the plurality of first connecting portions (110, 120) has a through opening, at the edge of the electrode support arm (4) and the electrically conductive layer (100) are integrally connected.

8. An electrode support arm according to claim 7, wherein the electrode support arm (4) and the electrically conductive layer (100) are welded to the edge of the through hole.

9. electrode support arm according to claim 7 or 8, wherein the opening in the electrically conductive layer (100) with material (112) having a thermal conductivity> 200 W / (m-K) is filled.

10. Elektrodentragarm according to any one of claims 1 to 9, wherein the first connecting portions (110, 120) have a distance (cl, a2, z) from the respective proximate first connecting portion of 40mm to 200mm.

1 1. Elektrodentragarm according to one of claims 1 to 10, wherein the electrically conductive layer consists of a plurality of sheets (100) which are interconnected.

12. Elektrodentragarm according to any one of claims 1 to 11, wherein the Elektrodentragarm (4) is modular.

13. Elektrodentragarm according to any one of claims 1 to 12, wherein between the electrically conductive layer (100) and the outside of the electrode support arm (4) in the areas between the first connecting portions (110, 120) is provided a heat conducting means.

14. Elektrodentragarm according to one of claims 1 to 13, wherein

 the electrically conductive layer (100) has a second thickness (h2) of 1 to 15 mm.