DE102015108815B3 - High-current cable for the electrically conductive contacting of a Elektrodentragarms an electrically operated furnace and feeding device for electrically operated stoves - Google Patents

Abstract

The invention relates to a high-current cable for the electrically conductive contacting of an electrode support arm of an electrically operated furnace for electroslag remelting and reduction, with a high-current conductor, an insulating jacket surrounding the high-current conductor and a cable head connected to the high-current conductor at at least one cable end and a feed device for electrically operated ovens. In order to provide a high current cable for electrically conductive contacting an electrode support arm of an electrically operated furnace for electroslag remelting and reduction furnaces which has good conductivity but is nevertheless stable and inexpensive to manufacture, it is provided that the high current conductor and the cable head are formed of aluminum or an aluminum alloy are.

Description

• – einem Hochstromleiter,
• – einer isolierenden, den Hochstromleiter umgebenden Ummantelung und
• – einem an mindestens einem Kabelende mit dem Hochstromleiter verbundenen Kabelkopf.

The invention relates to a high-current cable for the electrically conductive contacting of a Elektrodentragarms an electrically operated furnace for electroslag remelting and reduction ovens, with

• A high current conductor,
• - An insulating, surrounding the high current conductor sheath and
• A cable head connected to the high current conductor at at least one end of the cable.

Furthermore, the invention relates to a feeding device for electrically operated furnaces for electroslag remelting and reduction furnaces.

Hochstromkabel are in a variety of configurations from the prior art, such as the DE 196 21 672 A1 , of the DE 34 43 574 A1 , of the DE 36 29 310 C2 and the EP 1 958 725 A1 known. In this case, corresponding high-current cables are used, in particular, for connecting the secondary side of a transformer of a corresponding high current system to an electrode or a support arm for an electrode of a ladle or electric arc furnace or another component operated with high current. Smaller ladle furnaces typically have three phases and are connected with two high current cables per phase. Larger ovens usually use four or more high current cables per phase.

The well-known from the prior art high-current cable of the type mentioned, such as in the DE 36 29 310 C2 typically have a copper or copper alloy conductor due to their good conductivity and ductility. Also, the cable head and the electrode support arm are at least partially formed of copper or a corresponding alloy.

The disadvantage here is on the one hand, the relatively high weight, which is associated with a difficult handling of relatively massive cables and leads due to the high tensile forces to increased susceptibility to wear of heavy, free-hanging cable especially at the head ends.

In addition, however, the rising copper prices in particular make the development of new possibilities of alternative conductor materials especially for material-intensive applications, such as energy supply devices for electric arc furnaces, desirable.

The invention has for its object to provide a high current cable for electrically conductive contacting an electrode support arm of an electric arc furnace, which has a good conductivity, but is stable and inexpensive to produce.

The invention achieves the object by a device according to claim 1. Advantageous developments of the invention are specified in the dependent claims.

According to the invention, the high-current cable surrounding an insulating sheath for the electrically conductive contacting of an electrode support arm of an arc furnace has a high-current conductor made of aluminum or an aluminum alloy. A cable head connected to the high-current conductor at at least one cable end is also formed according to the invention from aluminum or an aluminum alloy.

Although aluminum conducts electricity less well than copper, aluminum is much lighter and less expensive. In order to achieve the required conductivity, with the transition from the copper conductor to an aluminum conductor, therefore, although a cross-sectional increase of the high-current cable is required. Due to the much lower specific weight of aluminum, the high-current cable according to the invention is nevertheless characterized by a low overall weight. In addition to a simplified handling, this factor leads to a reduction in the tensile forces of the cable at the head ends, resulting in an improved creep strength of the high-current line. Also priced the high current cable with aluminum conductor is superior to the copper cable.

In addition, the inventive design of the cable head made of aluminum or an aluminum alloy contributes significantly to reducing the susceptibility to wear. Thus, in the connection between the cable end and the cable head to a pairing of metals of different electronegativities deliberately omitted and thus advantageously avoided electrochemical contact corrosion.

Under a high-current cable is basically understood any cable that is suitable to conduct a heavy current. In this case, the high-current cable can initially be configured in any desired manner. Thus, the high-current cable can be formed from only one electrical line element. In a preferred embodiment of the invention, however, the high-current conductor has at least two or more individual conductors, which are formed from aluminum or an aluminum alloy.

In principle, the high-current conductor or the individual conductors can have any desired shape and, in particular, any desired cross-section. Preference is given to the high-current conductor or the individual conductors however, formed with a round cross section. In total, the high current conductor has a cross section of 100 to 7,500 mm ² , preferably 1,000 to 6,000 mm ^2, and / or the individual conductors have a cross section of 10 to 1,000 mm ² , preferably 100 to 600 mm.

The individual conductors can be arranged arbitrarily to one another. They may abut each other and / or be twisted or spaced apart. Preferably, each individual conductor is surrounded by a coaxially arranged sheathing, wherein the sheath is formed from any material or composite material that does not conduct electricity, in particular a plastic, a rubber compound or a lacquer. The sheath is u. a. for spacing the individual conductors from each other and reducing their friction to each other.

The high-current cable can be used uncooled, that is without a cooling medium surrounding the conductor. In a preferred embodiment of the invention, the cable is cooled, in particular liquid-cooled. In this case, the high-current conductor is arranged within a cooling liquid arranged in the jacket. As coolant any fluids or fluid mixtures can be used, which ensure improved heat dissipation. Furthermore, the fluids may also be provided with additives, for example with corrosion protection additives.

In the high-current cable according to the invention, the connection of the at least one cable end of the high-current conductor to a cable head can be carried out as desired. Thus, the connection can be made cohesively, for example by soldering or welding. In a preferred embodiment of the invention, the cable head is positively connected to the high-current conductor and more preferably compressed. In a further development of the invention, the sheath can also be included in compression. In the case of a liquid-cooled high-current cable, the jacket in the compressed area is also sealed against leakage of the cooling liquid.

During operation, the high-current cable follows the lowering, lifting and pivoting of the electrode support arm. As a result, in particular, the connecting portion between the high current conductor and the cable head is exposed to strong tensile, compression and torsional stresses.

To meet these demands, the non-positive connection between high-current conductor and cable head is amplified according to a preferred embodiment of the invention by a positive and / or cohesive connection.

In a preferred embodiment, the cable head for this purpose in the direction of the high-current conductor protruding projections, which are further preferably formed by mandrels and / or rings. These projections dig into the surface of the high-current conductor in a form-fitting manner during pressing. Optionally, a pressure-induced flow of the aluminum also lead to a cohesive connection between the cable head and high-current conductor.

The sheath of the high-current cable can be formed of any material. In a liquid-cooled high-current cable, the sheath is designed such that no liquid can escape. Thus, the sheath can be formed in one layer from, for example, a plastic or rubber material. However, the sheath may also consist of a multi-layer composite, wherein at least one layer is liquid-tight and at least one other layer other functional properties, such as a reinforcement for protection against external influences exercises.

In a preferred embodiment, the sheath is formed by a flexible hose. The flexible design of the hose improves the mobility of the high-current cable. In addition, there is an increase in the pressure and fatigue life stability of the hose.

As a rule, such hoses need not be specially made, but can be selected in accordance with their requirement profile in terms of cross-section, compressive strength and material cost of the wide range available on the market hoses.

To manufacture the flexible hose must therefore be pulled only coaxially over the high-current conductor and then connected to the hose ends with this possibly liquid and pressure-tight. The connection between hose and high-current conductor can be made as desired. Thus, the tube cohesively, z. B. by gluing, and / or non-positively, for. B. be connected by means of a hose clamp to the high current conductor. Preferably, the tube is crimped at least at one end together with the high current conductor and / or the cable head.

• – Dauerbruchfestigkeit an der Verbindungsstelle zwischen Kabelkopf und Hochstromleiterende (resultierend aus den geringeren Zugkräften des leichteren Hochstromleiters)
• – Korrosionsfestigkeit an der Verbindungsstelle zwischen Kabelkopf und Hochstromleiter (Material mit gleicher Elektronegativität)
• – Dauerbruchfestigkeit der Ummantelung durch Ausführung in Form eines flexiblen, den Bewegungen des Elektrodenarms folgenden und auch der Druckbelastung durch die Kühlflüssigkeit standhaltenden Schlauchs.

Against the background of lower than the copper prices raw material price for aluminum, the essentially commercially available components on the market and the relatively simple manufacturing process, the high-current cable according to the invention stands out by low production costs. The inventive design of the high-current cable also preferably ensures a high-current cable with an improved stability with respect to

• - fatigue strength at the connection point between the cable head and the high current conductor end (resulting from the lower tensile forces of the lighter high current conductor)
• - Corrosion resistance at the junction between cable head and high current conductor (material with the same electronegativity)
• - Durability of the sheath by execution in the form of a flexible, the movements of the Elektrodenarms following and also the pressure load by the cooling liquid holding hose.

According to the invention, in addition to the high-current conductor and the at least one cable head, the electrode arm made of aluminum or an aluminum alloy is also formed in a feed device for an electric arc furnace with a high-current cable connected to the electrode support arm.

After the electrode arm constitutes a not insignificant proportion of the feed device, on the one hand the weight and not least the material costs for the entire feed device are significantly reduced. By choosing the same material for cable head, high current cable and electrode arm, the susceptibility to contact corrosion at the feeder and in particular at the electrical contact points between high current conductor and cable head on the one hand and cable head and electrode arm on the other hand is also significantly reduced.

Hereinafter, an advantageous embodiment will be explained with reference to a drawing. It shows

1 a perspective view of a first embodiment of a high current cable for electrically conductive contacting an electrode support arm of an electric arc furnace.

In the 1 illustrated embodiment of the high current cable 1 has a high current conductor 2 on that by several individual conductors 5 made of aluminum, of which three are single conductors 5 are shown as examples. The individual leaders 5 are in the process of isolation 6 surrounded coaxially.

At the in 1 illustrated embodiment is a liquid-cooled high current cable 1 , These are an insulation 6 having individual leaders 5 spaced apart within one with a cooling liquid 7 filled or of coolant 7 flowed through sheathing 3 arranged. The jacket 3 is with connections for the supply and discharge of the cooling liquid 7 Mistake.

At the end of the cable has the high-current cable 1 in the illustrated embodiment, a cable head 4 made of aluminum, with the high current conductor 2 and the sheath 3 connected is.

Claims (10)

High-current cable for the electrically conductive contacting of an electrode support arm of an electrically operated furnace for electroslag remelting and reduction furnaces, comprising a high-current conductor, an insulating jacket surrounding the high-current conductor and a cable head connected to the high-current conductor at at least one cable end, characterized in that the high-current conductor 2 ) and the cable head ( 4 ) are formed of aluminum or an aluminum alloy. High-current cable according to Claim 1, characterized in that the high-current conductor ( 2 ) at least two individual conductors ( 5 ) having. High-current cable according to claim 1 or 2, characterized in that the individual conductors ( 5 ) a coaxially arranged insulation ( 6 ) exhibit. High-current cable according to one of the preceding claims, characterized in that the high-current conductor ( 2 ) is liquid-cooled, in particular within one in the sheath ( 3 ) arranged cooling liquid ( 7 ) is arranged. High-current cable according to one of the preceding claims, characterized in that the cable head ( 4 ) with the high-current conductor ( 2 ) positively connected, in particular is pressed. High-current cable according to one of the preceding claims, characterized in that the cable head ( 4 ) in the direction of the high current conductor ( 2 ) has protruding projections. High-current cable according to one of the preceding claims, characterized in that the projections are formed by mandrels and / or rings. High-current cable according to one of the preceding claims, characterized in that the sheath by a flexible hose ( 3 ) is formed. High-current cable according to one of the preceding claims, characterized in that the High current conductor ( 2 ) in total a cross section of 100 to 7500 mm ² , preferably 1000 to 6000 mm ² and / or the individual conductors ( 5 ) has a cross section of 10 to 1000 mm ² , preferably from 100 to 600 mm ² . Feed-in device for electrically operated furnaces for electroslag remelting and reduction furnaces with an electrode support arm, wherein the electrode support arm is formed of aluminum or an aluminum alloy and connected to a high current cable according to one or more of claims 1-9.

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