EP0892073A1 - Funnel-shaped mould with a liner tube for the electroslag remelting as well a process therefor - Google Patents

Abstract

The funnel mould (10) with a funnel insert (12) and a melting electrode (58) has a surrounding cutout (36) which is located in the top region of the insert (12) for an approximately ring-shaped graphite electrode (40). This electrode is insulated from the insert by an element (38). The graphite electrode is located below the slag surface level and is surrounded from above by a contact ring (42) with a limiting annular gap (50). The contact ring is connected to the supply grid (54) by a high-current cable (52). The pressure of the cooling water in the gap (22) produces a force to press the graphite electrode (40) against the contact ring (42).

Description

The invention relates to a funnel mold with a funnel-shaped Insert tube for electroslag remelting at least a melting electrode - especially one Steel electrode in special metallurgy - according to the generic term of claim 1. In addition, the invention covers a Process for electroslag remelting.

There are several types of so-called ESU chillers with water-cooled tube-like copper insert known in one Jacket pipe with corresponding connections for cooling water is housed; in the casing tube or in the copper insert Cooling channels are provided, which serve the cooling water accordingly the shape of the mold and the necessary cooling water speed spread over the circumference of the mold. The copper insert can have different shapes that different consumable electrodes form block formats different cross-section can be remelted.

A mold used in practice is the so-called. Funnel mold, which is the remelting of electrodes with a large diameter to blocks with a smaller one Diameter allows. Such a mold for remelting electroslag with a melting electrode to one arising in the lower tubular mold area as well from this block to be subtracted down is DE-AS 2 328 804. During block construction, a Maintain relative movement between block and mold. The melting electrode is immersed in a slag bath one that is located in the upper area of a support member held funnel mold is located.

In the case of funnel molds, the melt flow is required lead directly from the slag back into the network, because the smaller block diameter does not cover the entire melt flow can return. But since the slag in which the melting process takes place only in the liquid state is conductive, a direct power connection remains on the Mold wall impossible; through the water cooling of the Copper insert forms on the inside of the mold wall a hard, not melted - and therefore not conductive - slag layer. For this reason various additional electrodes used in the slag bath, that remain hot enough during melting to not to let the slag solidify and thereby the Ensure the return of electricity from the liquid slag to the network. Shows non-edible electrodes of this type US-A-4,145,563, for example, as for the consumable electrode axis-parallel stick electrodes or as - also that Slag bath outstanding - hollow cylinder electrodes that surround their consumable electrode at a distance. Be for non-consumable electrodes made of graphite elements or parts Graphite-copper-ceramic mixtures used, results in the problem of proper electrical contact between the electrode and a high-current cable to be connected ensure that the prevailing in the melting range Temperatures the mechanical properties of such Electrodes are severely affected and any type of local mechanical connection - such as Screws or the like - destroy the electrode very quickly.

The invention lies in knowledge of this prior art the task of creating an ESC funnel mold, in which the problems mentioned above do not occur; the for safe electrical contact between the non-consumable Electrode and the forwarding current parts necessary forces should be independent of the ones constantly changing thermal conditions good working conditions ensure for the electrode.

This task is accomplished through the teaching of the independent claims solved; the subclaims give favorable further training on.

According to the invention is in the upper region of the insert tube Funnel mold a circumferential recess for approximately provided annular graphite electrode and this from the insert tube separated by an isolation organ, the Graphite electrode is located below the slag bath level and is overlapped by an insulating element that with the graphite electrode limited an approximately annular gap as well by means of a high-current cable to the electrical network connected is. In addition, it has proven to be cheap Graphite electrode towards the insert tube towards a ceramic insulation ring hang up, being from a water-cooled Contact ring is gripped as an insulating element.

This ESU funnel mold essentially consists of one - placed in a water jacket - funnel-shaped Copper insert tube, which is preferably cylindrical in the upper part is executed and its lower block forming Part of a round, square or even polygonal May have cross-section. The shoulder-shaped Recess in the upper cylindrical part of the insert tube or copper insert takes the ring-shaped graphite electrode ceramic insulation toward the insert tube a ceramic insulation ring - rests as well as towards the melting electrode towards that water-cooled contact ring assigned.

According to the invention, a between the copper insert or Insert tube and a casing tube formed gap for the cooling water in the upper part of the mold through an O-ring sealed, which is preferably in a to the insert tube opening groove in the upper cylindrical part of the casing tube stores. The cooling water gap is in the lower part by another O-ring with a much shorter diameter by another O-ring with a much shorter diameter sealed, which - like that other O-ring in the upper Part of the mold - in a groove open to the insert tube located.

The water-cooled contact ring is advantageously through Stud bolts with a support plate that holds the mold connected so that it encompasses the studs on the one hand Insulation sleeves rests on the other Annular gap between it and the annular graphite electrode remains guaranteed in the rest position.

Because the area covered by the upper O-ring is considerably larger is shorter than the corresponding area of the lower O-ring Diameter, arises thanks to the cooling water pressure a force that pushes the insert tube towards the graphite electrode presses and the latter - while reducing that annular gap - presses the contact ring. The electrical current flow is guaranteed; because according to another feature of the invention is the contact ring with a high current cable electrical network connected.

• eine konstante und gleichmäßig verteilte Kontaktkraft zwischen Graphitelektrode und Kontaktring, dadurch einwandfreie Stromrückführung von der flüssigen Schlacke zurück in das elektrische Netz;
• eine verlängerte Lebensdauer der Graphitelektrode, die auf die konstanten und gleichmäßig über den Umfang der Elektrode verteilten Kraft- und Temperaturbeanspruchungen zurückzuführen ist;
• die Vermeidung des negativen Einflusses aller mechanischen Ausdehnungserscheinungen infolge thermischer Beanspruchung, da sich der Kupfereinsatz und alle anderen thermisch beanspruchten Teile ausdehnen können.

The advantages of the invention are

• a constant and evenly distributed contact force between the graphite electrode and the contact ring, thus perfect current feedback from the liquid slag back into the electrical network;
• an extended life of the graphite electrode due to the constant and evenly distributed force and temperature stresses distributed over the circumference of the electrode;
• avoidance of the negative influence of all mechanical expansion phenomena due to thermal stress, since the copper insert and all other thermally stressed parts can expand.

Thanks to the described measures, all undesirable and incalculable mechanical stresses - the on lead to destruction of the graphite electrode could - minimized or even avoided entirely.

Fig. 1:

einen Längsschnitt durch eine trichterförmige Kokille für das Elektroschlackeumschmelzen;

Fig. 2:

einen vergrößerten Ausschnitt aus Fig. 1 etwa nach deren Pfeil II.

Further advantages, features and details of the invention emerge from the following description of a preferred exemplary embodiment and with reference to the drawing; this shows schematically in

Fig. 1:

a longitudinal section through a funnel-shaped mold for the electroslag remelting;

Fig. 2:

an enlarged section of FIG. 1 approximately according to the arrow II.

A funnel mold 10 for so-called electroslag remelting (ESR) has, according to FIG. 1, an insert tube 12 formed in one piece from copper or a copper alloy, which consists of a cylindrical molded tube 14 - an inside diameter d and an outside diameter d ₁ - one of this upwardly conically expanding funnel section 15 and a cylindrical fir ring 16 adjoining its largest diameter e. The insert tube 12 is surrounded by a jacket tube 18, which in turn offers a lower tube section 19 and a funnel section 20 molded upwards.

The opposing pairings of the cylindrical Pipe sections 14, 19 and the funnel sections 15, 20 run at a gap distance a from each other; the so educated Gap 22 is used for cooling water and is sealed at the top by an O-ring 24. This rests in a groove 25 which face between two inwards Radial ribs 26 of a collar ring 28 extends. The latter sets - in gap distance a to fir ring 16 of Insert tube 12 standing - the casing tube 18, so that Gap 22, continues and is attached to a support plate 30, which contains supply and return lines 31, 32 for the cooling water.

At the lower end of the gap or cooling water gap 22 is sealed by a - compared to the upper O-ring 24 - significantly smaller O-ring 24 _t , which in an inner groove 25 _i - flanged to the casing tube 18 and the insert tube 12 surrounding - Lock ring 34 is seated.

In a shoulder recess 36 through one - from that Firstring 16 molded - angle edge 17 offered is supported on a ceramic insulation ring 38 an annular graphite electrode 40. This is from a that angular edge 17 at a distance overlapping contact ring 42 covers that as a hollow profile with water-bearing cooling channel 44 is formed. The contact ring 42 is by at 46 indicated studs connected to the support plate 30 so that he on the one hand embrace the stud screws 46 Insulation sleeves 48 rests, on the other hand with the annular graphite electrode 40 forms an annular gap 50. In addition, the contact ring 42 is through a high current cable 52 connected to an electrical network 54.

After appropriate preparation of the ESU funnel mold 10 to start a melting process - i.e. after getting in the cooling water in the cooling water gap 22, fill the funnel mold 10 with slag 56 and immersing one melting electrode 58 suspended in the mold axis A under current - the remelting process begins.

Since the area covered by the upper O-ring 24 is significantly larger than the corresponding area on the lower O-ring 24 _t , a force arises - in view of a pressure of the cooling water in the cooling water gap 22 - which acts on the insert tube 12 in the direction F acts to the graphite electrode 40 and the insert tube 12 ejects to the graphite electrode 40 until that annular gap 50 is closed and a reliable electrical contact between the graphite electrode 40 and the contact ring 42 is achieved. Since the cooling water pressure remains constant during the melting process, the force F acts continuously on the copper insert or the insert tube 12. For this reason, a secure and even mechanical and at the same time electrical contact between the graphite electrode 40 and the contact ring 42 is ensured.

The water-cooled contact ring 42 consists of a copper-containing one Alloy, it is not a problem safe electrical contact between it and the high current cable 52 using any mechanical connection type - such as Screws or the like - to be realized. Because the graphite electrode 40 always remains below the slag level 51 and since they are continuously at the temperature of the melted Slag 56 is heated, the electrical contact on the one hand between slag 56 and graphite electrode 40 and on the other hand between the latter and the contact ring 42 constantly received. By lowering the axial melting electrode 58 the melting electrode melts into the slag 56 58 and drips down through the slag 56.

A during the melting process in the lower part of the Funnel mold 10 forming ingot or block 60 is at Lowering one of the funnel molds 10 to limit the bottom Platform or bottom plate 62 from the bottom block-forming Pipe section - the shaped tube 14 - the funnel mold 10 pulled out.

Claims (11)

Funnel mold with a funnel-shaped insert tube for electroslag remelting at least one melting electrode, in particular a steel electrode in special metallurgy with a water-cooled insert tube made of copper or a copper alloy, the funnel mold receiving a slag bath and the melting electrode partially immersed in the slag bath being connected to an electrical network.
characterized,
that in the upper region of the insert tube (12) a circumferential recess (36) is provided for an approximately annular graphite electrode (40) and this is separated from the insert tube by an insulation member (38), the graphite electrode being below the slag bath level (51) and from another insulating element (42) is overlapped, which delimits an approximately annular gap (50) with the graphite electrode and is connected to the electrical network (54) by means of a high-current cable (52). Chill mold according to claim 1, characterized in that the graphite electrode (40) towards the insert tube (12) a ceramic insulation ring (38) rests and / or from a water-cooled contact ring (42) than the other insulating element. Chill mold according to claim 1 or 2, characterized in that the recess (36) for the graphite electrode (40) as a shoulder recess in a circumferential angular edge (17) of the insert tube (12) is formed. Mold on a support member according to one of claims 1 to 3, characterized in that the water-cooled Contact ring (42) by studs (46) with a Support plate (30) is connected as a Tragoran so that it on the one hand on the insulation sleeves comprising the studs (48) rests and on the other hand with the annular graphite electrode (40) the annular gap (50) forms. Mold with a lower shaped tube and a fir ring of larger diameter, which is connected to the shaped tube by a funnel section, according to one of claims 1 to 4, characterized in that between the insert tube (12) and a jacket tube (18) surrounding it, a gap ( 22) is formed for cooling water, which is bounded by at least one O-ring (24, 24 _i ) both in the area of the fir ring (16) and at the lower end of the shaped tube (14) of smaller diameter (d). Mold according to one of claims 1 to 5, characterized in that the O-ring (24, 24 _t ) rests in a groove (25, 25 _i ) which is open to the insert tube (12). Chill mold according to claim 5 or 6, characterized in that that the groove (25) for the O-ring (24) larger Diameter in the fir ring (16) of the insert tube (12) surrounding collar ring (28) runs the in turn delimits a section of the gap (22). Chill mold according to claim 6 or 7, characterized in that the groove (25 _i ) for the O-ring (24 _t ) of smaller diameter (d ₁ ) is provided in a locking ring (34) surrounding the molded tube (14) at the end. Chill mold according to claim 7, characterized in that the collar ring (28) is attached to the support plate (30) is. Chill mold according to one of claims 4 to 9, characterized in that that the support plate (30) inflows and outflows (31,32) for the cooling water of the gap (22) are assigned. Process for the electroslag remelting of a melting electrode in a funnel mold with water-cooled Insert tube, especially a funnel mold with a graphite electrode adjacent to a contact ring over a surrounding the insert tube Gap space for cooling water, according to at least one of the Claims 1 to 10, characterized in that by means of in the gap (22) prevailing pressure the insert tube (12) towards the graphite electrode (40) acting force (arrow F) and the graphite electrode is pressed onto the contact ring (42).

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