Sliding Closure for a Metallurgical Vessel, Preferably a Distributor Vessel for a Continuous Casting Facility

Abstract

Slide closure for a metallurgical vessel, with two compensation units I and II for equalizing overloads, which may result from the thermal extension and spreading of the fire-proof closure plate thicknesses conditional on manufacturing, and/or from the upper inner shell, wherein the inner shell can also be reduced during operation. The compensation unit I consists of a spring arrangement with fastening screws which can be moved away between the housing and a cover of the housing. The compensation unit II consists, for its part, of a spring arrangement with an insertion frame pressing against the lower closure plate, which insertion frame is fixed to the bottom of the housing with fastening screws.

Description

The invention relates to a slide closure for a metallurgical vessel, preferably a tundish for a strand casting system, according to the preamble of claim 1.

Slide closures of this type are known in advance, for example from document EP 0 891 829. They are characterized in that, with them, the flow restriction or closing of the outlet is caused by the longitudinal movement of the slide plate. They thus serve in particular as a positioning member for controlled casting of the quantity of molten material from the metallurgical vessel.

For uninterrupted functioning of the slide closure, the plate tension is set such that it ensures both the free movability of the slide plate and the tightness of the slide closure required to prevent air from being sucked in. However, in operation, plate tension is subjected to additional stresses which result especially due to the thermal extension of the fire-proof plates. There are also stresses due to the likewise fire-proof upper inner shell in the vessel due to its thermal extension or reduction.

The object of the invention is to produce a slide closure of the type named at the outset which absorbs, in optimal manner, the operational stresses of the plate tensioning due to the thermal extension of the closure plates and/or the extension or reduction of the upper inner shell.

This object is achieved according to the invention by the features of claim 1.

An optimal absorption of the fire-proof extensions can be achieved with this first compensation unit with spring arrangements for tightening the closure plates against one another, as well as this second compensation unit with spring arrangements for tightening the closure plates against the upper inner shell with an additional insertion frame, adjustable in the housing, which frame can be pressed against the lower closure plate.

By making the two compensation units interact with one another, both overloads due to the thermal extension of the fire-proof plates and also due to the extension or reduction of the fire-proof inner sleeve are minimized. Unlike the slide closure according to EP 0 891 829, such overloads are thus not limited initially by the rigidity of the fire-proof parts and the metallic slide housing. This is advantageous for the operability or the lifespan of the fire-proof parts of the slide closure.

The invention provides that the spring arrangement of the first compensation unit is composed of plate springs, the pretension of which can be set preferably using a stroke limiting stop of the fastening screws. The plate tensioning can thus be adapted to a broad range of extension of the fire-proof parts which results for thermal reasons or spreading of the fire-proof closure plate thicknesses conditional on manufacturing. The starting pretension of the springs can also be set, in precise and repeatable manner, with the stroke limiting stop.

In so doing, it is expedient if the plate springs transmit the spring stroke via swivel pins, the guides of which are provided with inserts. Wear of these parts is minimized as a result.

The invention also provides that the insertion frame of the second compensation unit is fixed on the bottom of the housing by means of fastening screws arranged in pairs on both sides of the outlet, with plate springs inserted between the screw head thereof and the insertion frame, which springs form the spring arrangement of the second compensation unit. In this way, a uniform load of the insertion frame and thus the lower closure plate can be achieved using means which are simple in design.

In order to ensure that the lower closure plate abuts tightly against the insertion frame satisfactorily, it is expedient to provide a sealing element comprising the outlet between the insertion frame and the housing, which element is inserted preferably in a groove in the housing and/or in the insertion frame.

The slide closure is advantageously provided with a replaceable casting tube which is pressed against the lower closure plate with spring-loaded pressing elements. The pressing elements are expediently arranged such that they are effective independently of the two compensation units of the slide closure. They thus remain operational in all operational phases, both with and without the casting tube.

The invention is explained in more detail below using an embodiment example, with reference to the drawings. There are shown in:

FIG. 1 is a partial longitudinal section of a slide closure according to the invention,

FIG. 2 is a perspective top view of the slide closure according to FIG. 1 on the top thereof which can be fastened to the vessel,

FIG. 3 is a section of a spring arrangement with a tensioning screw, which can be moved away, of the slide closure,

FIG. 4 is a partial view of the slide closure with an insertion frame,

FIG. 5 is a spring member of the slide closure, represented in section,

FIG. 6 is a pictorial schematic of the compensation units in the slide closure according to FIG. 1 with a section of the closure plates and partially of the inner sleeve or of the casting tube, and

FIG. 7 is a perspective top view on a clamping device for clamping a closure plate in a metal frame of the slide closure according to FIG. 1.

The slide closure according to FIG. 1 can be mounted on the outlet of a metallurgical vessel. The vessel is designed preferably as a tundish of a strand casting system, wherein the slide closure serves to regulate the quantity of molten material supplied to the strand casting ingot mould during the casting process. A casting tube 3 arranged on the bottom of the slide closure makes possible a covered casting of the molten metal into the ingot. However, this slide closure could also be used on a socket, a tap of a converter or the like.

The slide closure according to FIG. 1 and FIG. 2 comprises a housing 4 with a seal 4′ arranged all around its upper end surface, in order that it is sealed in encircling manner on its top, at the vessel. Fixed, fire-proof closure plates 5, 6 and a slider plate 8, which can be moved back and forth therebetween by a drive mechanism 7, can be inserted in the housing 4, with the longitudinal movement of which an opening, restricting or closing of the outlet 9 is brought about. The upper closure plate 5 is arranged in a cover 11 of the housing 4, rotatably housed about an axis 10, whereas the lower closure plate 6 is fixed in an insertion frame 25 of the housing 4 and the movable closure plate 8 is fixed in a metal frame 12 coupled to the drive mechanism 7. The casting tube 3 is pressed against the lower closure plate 6 with spring-loaded rockers 33. The housing 4 has supports 13 projecting on the top which abut against the outer steel casing of the tundish 2 when in operation.

As illustrated in FIG. 3, a spring arrangement 23 has a base 16 guided in the housing 4 with a screw thread 17 and a crossways bolt 18, about which a swivel pin 20 provided with a screw 19 can be swivelled, wherein the swivel pin is guided into a recess 21 of the cover 11 and is screwed into a nut 22 above the cover. In order to make possible access to the closure plates 5, 6 and 8, the nuts 22 can be loosened and the swivel pins 20 swivelled out of the recesses 21 of the cover. The swivel pins 20 are provided with a stroke limiting stop 20a with which the initial pre-stressing of the plate springs 23 acting on tensile load can be set in precise and repeatable manner. Inserts 24 in the cover 11 are allocated to the nuts 22 of the fastening screws, which inserts minimize wear as a consequence of the frequent assembly and disassembly of the screw connections during operation.

During operation, the nuts 22 are screwed so far onto the swivel pins 20 that the closure plates of the slide closure lying between the insertion frame 25 and the cover 11 are tensioned against one another with the respectively provided contact pressure. This contact pressure is such that, during operation, it ensures the uninterrupted movability of the slider plate 8 when the slide closure is fully impermeable to metal or gas from the outside.

During operation, the fire-proof closure plates 5, 6, 8 experience a dispersive mechanical extension of up to 3 millimetres due to heating or manufacturing tolerances, whereby plate tensioning is subjected to an additional stress. According to the invention, this is compensated by a first compensation unit I, because the plate springs 23′ of the spring arrangement 23 more or less yield due to the additional stress. The stress compensation is very uniformly distributed over the closure plates in effective manner due to the paired arrangement of the fastening screws 15a to 15d on both sides of the outlet 1.

According to FIG. 4 and FIG. 5, an insertion frame 25 with a spring arrangement 30 is arranged on the bottom of the housing 4 for tensioning the closure plates 5, 6, 8 against the upper inner shell 1 of the outlet. This additional insertion frame 25 is fixed to the housing 4 with fastening screws 26 arranged in pairs on both sides of the outlet.

For its part, the spring arrangement 30 consists of plate springs 30 which are inserted between the screw head 28 of the fastening screws 26 and the insertion frame 25 and have the function of pressing the insertion frame against the lower closure plate 6 abutting against same, and thus tensioning the three closure plates 5, 6, 8 together against the upper inner shell 1 of the outlet.

The additional stress caused by an extension or reduction of the inner shell 1 is compensated with this second compensation unit II formed according to the invention, by the plate springs 30 more or less yielding due to this stress. It is advantageous if these plate springs 30 are produced such that they are provided with a steep characteristic curve in respect of its stroke in relation to the spring force, in order to bring about a relatively high change in force with little lift. This is matched to the corresponding characteristic curves of the plate springs 23′ of the compensation unit I, in order that an optimal tensioning is always achieved. In so doing it is intended to be avoided that, depending on the position of the movable closure plate 8, a tipping of the closure plates could take place, wherein this could occur due to an external application of force primarily through the casting tube.

Furthermore, to improve the support between the housing 4 and the insertion frame 25, a last, comprehensive sealing element 31 in a groove 32 is approximately half in the housing 4 and approximately half in the insertion frame 25. A labyrinth effect is thus achieved which additionally improves the tightness. The groove could also be designed only in the housing or in the insertion frame.

FIG. 6 shows, schematically, the arrangement of the two compensation units I and II in the slide closure. The first compensation unit I is formed by spring arrangements 23 between the cover 11 and the housing 4 acting on tensile load for flexibly tensioning the closure plates 5, 6, 8, because the second compensation unit II is effective due to the spring arrangements 30 between the insertion frame 25 and the housing 4 acting on pressure for tensioning the closure plates 5, 6, 8 against the inner shell 1.

These compensation units can be set independently of one another and are also effective independently of one another, with the result that they can carry out their function both individually and also in combination with one another. As a result, they protect the fire-proof parts of the slide closure against overloads which can result from thermal extension and spreading of the fire-proof closure plate thicknesses conditional on manufacturing and/or of the upper inner shell, wherein the inner shell can also be reduced in operation.

Also, a choice is made to fix the central slider plate 8 in its metal frame 12 with a clamping device 34 such that the function of the compensation units I and II is not impaired by the arrangement thereof in the housing 4.

The clamping device 34 according to FIG. 7 is composed of a clamping jaw 38 which can be adjusted against the closure plate 8 in the metal frame 12, two adjusting elements 35, 36 arranged on both sides of the central axis M of the slider plate 8, as well as a threaded spindle 37 abutting against the adjusting elements. The threaded spindle 37 is rotatably housed transverse to the central axis M in the metal frame 12 and provided with thread sections going in opposite directions. By manually rotating this threaded spindle 37, the adjusting elements 35, 36 are adjusted outwards or inwards, symmetrically to one another, and by corresponding wedge surfaces 35′, 36′ in the adjusting elements 35, 36 or the clamping jaw 38, the latter is pressed against the closure plate 8, with the result that a self-locking wedging is created in order that these do not become loose during operation.

The invention is displayed sufficiently using the above explained embodiment example. Self-evidently, other variants can also be provided. Other springs, such as helical springs or the like, could thus also be used instead of these plate springs 23′, 30′.

Claims

1. A slide closure for a metallurgical vessel, preferably a tundish for a strand casting system, with a housing (4) which can be fastened on to the bottom of the vessel, an upper closure plate (5) arranged in a cover (11) of the housing (4), a lower closure plate (6) and a closure plate (8) which can be longitudinally displaced therebetween, wherein these closure plates (5, 6, 8) are tensioned against one another with spring arrangements extending between the housing (4) and the cover (11), characterized in that the slide closure is provided with a first compensation unit I with spring arrangements (23) for tensioning the closure plates (5, 6, 8) against one another and a second compensation unit II with spring arrangements (30) for pressing the closure plates (5, 6, 8) against the upper inner sleeve (9) with an additional insertion frame (25) arranged in the housing (4), which frame can be pressed against the lower closure plate (6).

2. The slide closure according to claim 1, characterized in that the respective spring arrangement (23) of the first compensation unit I is allocated a fastening screw (15a-15d) which can be moved away from the cover (11).

3. The slide closure according to claim 2, characterized in that the respective spring arrangement (23) has several plate springs (23′), the pretensioning of which can be set preferably with the help of a stroke limiting stop (20a-20d) in the respective fastening screw (15a-15d).

4. The slide closure according to claim 3, characterized in that the plate springs (23) transfer their spring stroke via swivel pins (20) of the fastening screws (15a-15d), the guides of which are provided with inserts (24).

5. The slide closure according to claim 1, wherein the insertion frame of the second compensation unit is fixed on a bottom of the housing by means of fastening screws arranged in pairs on both sides of an outlet, with plate springs of the spring arrangement inserted between a screw head thereof and the insertion frame.

6. The slide closure according to claim 5, characterized in that a comprehensive sealing element (31) is inserted in a groove (32) of the housing and/or of the insertion frame (25), between same and the housing (4).

7. The slide closure according to claim 1, further comprising a replaceable casting tube configured to be pressed against the lower closure plate with spring-loaded pressing elements, and wherein the pressing elements are arranged such that they are operative independently of the two compensation units of the slide closure.

8. The slide closure according to claim 1, wherein the central, longitudinally-displaceable closure plate is configured to be tensioned in a metal frame with a clamping device integrated in the metal frame, which clamping device comprises a clamping jaw configured to be adjusted in the metal frame against the central, longitudinally-displaceable closure plate, two adjusting elements arranged on both sides of a central axis of the central, longitudinally-displaceable slide plate and a threaded spindle in active connection with the slide plate, wherein the adjusting elements are adjusted symmetrically to one another by a manual rotation of the threaded spindle and the clamping jaw is configured to be pressed against the central, longitudinally-displaceable closure plate in a self-locking manner by wedge surfaces.

9. The slide closure according to claim 8, characterized in that the threaded spindle (37) is rotatably house transverse to the central axis (M) in the metal frame (12) and is provided with thread sections in opposite directions for the one or the other adjusting element (35, 36).