EP0093070A1 - Sealing system for electrodes - Google Patents

Abstract

A seal for use around a rod electrode passing along an axis through a hole in the wall of a furnace into the interior of the furnace has an annular and at least limitedly flexible seal ring fitted snugly around the electrode in the hole and a holder carrying the seal ring and sealingly engaged with the furnace wall. Thus gas flow through the wall at the hole past the seal ring is substantially blocked. The seal assembly has structure forming with the electrode and seal ring a substantially closed chamber surrounding the electrode axially inward into the furnace from the ring. This chamber is pressurized at superatmospheric pressure with an inert gas and the electrode is cooled inward of the furnace from the seal ring. The seal ring is compressed axially by a packing assembly so it is pressed radially against the electrode. The packing includes rigid split compression rings bearing axially on the seal ring.

Description

The present invention relates to a sealing system for electrodes, in particular on an electric furnace with graphite electrodes working under a controlled atmosphere. A furnace operating in a controlled atmosphere is preferably constructed so as to have a single gas exhaust duct in which an adjustable shutter device is normally installed, eg a valve or a butterfly valve which allows the adjustment of the pressure, independently of the gas insufflation flow rate in the furnace and the evolution of gas from the molten materials.

To seal such an oven outside the gas exhaust pipe, the normally adopted solution provides an etano bell which covers the electrodes with their suspension, drive and power supply systems and makes it difficult to use a classic electrode holder.

This solution has the advantage of allowing the use of O-rings. The disadvantage, however, is that the suspension and drive system of the elotrode must be constructed in a very compact manner to limit the dimensions of the oloohe. In fact, the fragile elements of the suspension system of the electrodes and their electrical supply must be placed near the electrodes and cannot be effectively protected against the heat given off by them.

The object of the present invention is to eliminate this disadvantage, and to propose a sealing system which makes the oven watertight at the place where the electrodes penetrate the furnace and which is capable of adapting to electrodes produced with high tolerances and having pronounced irregularities.

This object is achieved thanks to the system according to the invention which comprises, at the point of penetration of the electrode into the oven, a stuffing, resistant to high temperatures, preferably based on carbon fibers or graphite, tightened by a press. -throat surrounding the eléotrode, a chamber, maintained at a pressure higher than that of the external atmosphere of the furnace, surrounding the electrode and located between said packing and the interior volume of the furnace, and a cooling device surrounding at least in part said chamber, the electrode and the stuffing.

The major advantage of the solution proposed by the present invention lies in the fact that the electrodes can be replaced quickly when hot without risking damage to the mechanical elements of the electrode drive system. The spacing between these elements and the electrode may correspond to a distance representing several times the diameter of an electrode.

The possibility of holding the electrodes by means of electrode arms of conventional construction is also provided, which is practically impossible in known systems.

When changing the electrodes the production downtime of the oven is minimal since the electrodes can be removed without having to wait for them to cool and with the minimum of maneuvers necessary to free the electrode from its claw and the seal where it enters the oven.

The invention will be described in detail using fig.l which shows one of the possible embodiments.

There is shown an electrode 1 at the point of penetration into the oven. The tightness of the oven at this location is obtained by mounting an adequate packing 2 which is maintained by a stuffing box ar elements 3, 4 and 5. The stuffing 2 is constituted in the case resent by two carbon fiber rings with offset joints. The cable gland is wired using the bolts 6. Part 5 of the cable gland is seated in a cooling ring 7. The seal between these two elements is guaranteed by one or two anointed 0 indicated on the fig. 1 with reference 8.

cable gland is fixed to the cooling ring 7 using the keys 9 passing through the support pins 10.

Cooling panel 7 is itself mounted on an insulating ring 11. It is held by the bolts 12, themselves electrically insulated using the insulating rings 13. These bolts 12 attach all of the rings of the electrode to the plate 14, preferably of steel, which constitutes the wall of separation between the furnace atmosphere and the open air. The seal between the last rings described is also achieved using 0 seals identified by the reference 15. The metal plate 14 is itself protected against the heat of the oven, preferably by a mat of ceramic fibers 16.

According to a preferred version of the invention a metal ring in 4 parts 17, is mounted below the elements 3, 4 and 5 constituting the cable gland. It will serve to maintain a minimum seal between the space 18 and the interior of the oven. The space 18 will have the function of an airlock which will preferably be kept under pressure by the injection of an inert gas (such as nitrogen), - through the orifice 19 in the case of fig.l.

Thus, even in the case where the stuffing did not constitute a perfectly tight seal, the danger of air penetration into the oven is practically excluded as long as the airlock pressure is higher than that of the outside atmosphere of the oven. The neutral gas in contact with the carbon stuffing eliminates any oxidation thereof in the presence of an overheated electrode.

To limit the temperature of the elotrode at the level of the cable gland, it is preferable to install a cooled sheath around the elotrode. This sheath 20 will preferably be cylindrical and concentric with the electrode. In the present case, it consists of two concentric cylindrical sleeves between which passes a spiral which serves to guide the cooling water supplied by line 21 and discharged through line 22.

In a preferred version of the present invention, a third ring 23 around the electrode 1 protects the upper rings against radiation from inside the oven. This ring 23 consists of several segments 24, six in this case, which pivot about axes 25 to which they are suspended. The center of gravity of each segment will be further from the axis of the electrode than its tilting axis so that it is pushed towards the electrode by its own weight.

This solution has the advantage of allowing these segments to best match the shape of the electrode without preventing a slight misalignment thereof.

To prevent, however, that an electrode, mounted slightly oblique to its theoretical axis 26, does not come into contact with parts of the furnace which are not intended to guide it and keep it in position, it is advantageous to provide cleats 27 which limit the tilting angle of the segments 24. Thus the electrode is held, on the one hand, by the electrode-carrying arm and, on the other hand, by the ring 23, such as the angle between the effective axis and the theoretical axis of the elentrode may not exceed a determined maximum value.

This is especially important in the case where the oven is rotatable, i.e. when the theoretical axis of the electrode is not always vertical.

With, at the top, a well-guided electrode holder arm and at the bottom, the ring 23, we will indeed be able to limit the lateral movement of the electrode inside the packing, this in order to guarantee the effectiveness of the latter and in order to reduce its wear following the vertical movement of the electrode.

According to a preferred version of the invention, the rings 3, 4 and 5 constituting the cable gland are each split into two equal halves in the direction of the axis of the electrode. They will however be mounted so that the axis of the cut is moved from one ring to the other, which means that the cable gland assembled with the bolts 6 forms a practically rigid whole.

By adopting this type of cable gland it is possible to detach all of its elements 2, 3, 4 and 5 from the spent electrode without having to slide them along the electrode to remove them, which has a serious advantage in convenient.

Claims (9)

1. A sealing system for electrodes, in particular for electrodes mounted on an electric oven operating in a controlled atmosphere, characterized in that it comprises, at the point of penetration of the electrode (1) in the oven, a stuffing (2) clamped by a cable gland (3, 4, 5) which surrounds the electrode (1), a chamber (18), maintained at a pressure higher than that of the external atmosphere of the furnace, surrounding the electrode (1) and located between said stuffing and the interior of the oven, and a cooling element at least partially surrounding said chamber (18), the electrode (1) and the stuffing (2). 2. A sealing system according to claim 1, characterized in that the stuffing (2) consists of two superimposed rings, which bear against the electrode (1). 3. A sealing system according to claims 1 or 2, characterized in that the stuffing (2) is based on carbon or graphite fibers. 4. Sealing system according to one of claims 1 to 3, characterized in that the cable gland consists of rings (3, 4, 5) each split into two parts, preferably equal. 5. A sealing system according to claim 1, characterized in that the chamber (18) in which prevails a pressure greater than that of the external atmosphere is determined in particular by the stuffing (2), the body of the electrode ( 1), a metal ring (17) in at least two parts and a wall belonging to the cooling element. 6. A sealing system according to claim 1, characterized in that the cooling element comprises a ring (7), surrounding the electrode, in which is seated a part (5) of the cable gland as well as a sheath (20) surrounding the electrode. 7. A sealing system according to claim 6, characterized in that the sheath (20) is constituted by two concentric cylindrical sleeves between which. passes a spiral which serves to guide the coolant and in that it is located between said chamber (18) and the active part of the electrode (1). 8. A sealing system according to claim 1, characterized in that a ring (23), almost entirely surrounding the electrode (1) and constituted by at least two segments (24), is located between the active part of the electrode (1) and the cooling element. 9. A sealing system according to claim 8, characterized in that each segment (24) can pivot around an axis and has a center of gravity different from its tilting axis, so that the center of gravity of the segments (24) is further from the theoretical axis of the electrode (1) than said tilting axis.

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