RU2798379C2 - Gate valve for metallurgical container, preferably intermediate ladle for continuous casting system - Google Patents

Abstract

FIELD: metal casting.

SUBSTANCE: gate valve for a metallurgical container comprises a housing (4) fixed on the bottom of the container, an upper inner sleeve (1) of the container, an upper locking plate (5), a lower locking plate (6), a locking plate (8) installed between the plates (5, 6) with the possibility of moving in the longitudinal direction, and two compensation blocks I and II. The upper locking plate (5) is located in the cover (11) of the housing (4). The first compensation block I is formed by a spring system (23) that creates tension forces between the cover (11) and the housing (4), and the pressure plate (5, 6, 8) to each other. The second compensating block II, containing the spring system (30), is equipped with an insert frame (25) installed with the possibility of being pressed against the lower locking plate (6), presses the plates (5, 6, 8) against the upper inner sleeve (1).

EFFECT: increased service life of the refractory parts of the slide gate by compensating for thermal expansion of the plates and expansion or contraction of the upper inner sleeve.

9 cl, 7 dwg

Description

The invention relates to a gate valve for a metallurgical container, preferably a tundish for a continuous casting system, according to the preamble of paragraph 1 of the claims.

Sliding gate valves of this type are known, for example, from EP 0 891 829. They differ in that they restrict the flow or close the outlet by moving the movable plate longitudinally. Thus, they serve in particular as a positioning element for the controlled pouring of a certain amount of melt from a metallurgical container.

For the smooth operation of the slide gate, the plate tension is set in such a way that it provides both free movement of the movable plate and the tightness of the movable plate, which is necessary to prevent air intake. However, during operation, the plate is subjected to additional stresses arising, in particular, as a result of thermal expansion of the refractory plates. In addition, it is stressed due to thermal expansion or contraction of the refractory upper inner shell of the metallurgical ladle.

The object of the invention is to provide a gate valve of the type indicated, which optimally absorbs operating stresses arising in the plate due to thermal expansion of the closure plate and/or expansion or contraction of the upper inner sleeve.

This problem is solved according to the invention due to the combination of features included in paragraph 1 of the claims.

Optimum absorption of the expansion of the refractory parts can be achieved with a first compensating block with a spring system for pressing the stop plates against each other, as well as a second compensating block with a spring system for pressing the stop plates against the upper inner sleeve, and with an additional insert frame that moves into housing and can be pressed against the lower striker plate.

By interacting with each other of the two compensating blocks, both overloads resulting from the thermal expansion of the refractory plates and from the expansion or contraction of the refractory inner shell are minimized. Thus, in contrast to the sliding gate valve according to EP 0891829, these overloads are not limited only by the given rigidity of the refractory parts and the metal movable body. This favorably affects the performance and service life of the refractory parts of the slide gate.

The invention provides that the spring system of the first compensation unit consists of disc springs, the pretensioning of which can be set, preferably by means of a stroke limiter of the fixing screws. In this way, the tension of the plate can be adapted to a wide range of expansion of the refractory parts due to thermal or production reasons due to changes in the thickness of the refractory striker plate. The initial preload of the springs can also be precisely and repeatedly adjusted using the stroke limiter.

Advantageously, the disc springs transmit the spring movement through the pivot pins, the guides of which are provided with bushings, whereby the wear of these parts is minimized.

The invention also provides that the plug-in frame of the second compensating block is fixed to the bottom of the housing with the help of fixing screws located in pairs on both sides of the outlet, while between the head of the corresponding screw and the plug-in frame, disk springs are installed, which form the spring system of the second compensating block. In this way, a uniform distribution of the load on the insert frame and consequently on the lower striker plate can be achieved by means of simple structural means.

In order to ensure that the lower striker plate fits snugly enough against the insert frame, it is expedient to provide a sealing element enclosing the outlet opening between the insert frame and the body, this element being preferably inserted into a groove in the body and/or in the insert frame.

The gate valve is preferably provided with a removable gate tube, which is pressed against the lower locking plate by spring-loaded clamping elements. The clamping elements are preferably positioned so that they act independently of the two compensating blocks of the slide gate. Thus, they remain operable at all stages of work, both with and without a sprue tube.

Below the invention is explained in more detail on the example of an embodiment with reference to the drawings, which show:

- in Fig. 1 is a partial longitudinal section of a sliding gate according to the invention;

- in Fig. 2 is a top perspective view of the sliding gate according to FIG. 1, which can be attached to the container with its upper part;

- in Fig. 3 - section of the spring system of the slide gate with a tension screw that can move;

- in Fig. 4 is a partial view of a slide gate with an insert frame;

- in Fig. 5 - spring element of the slide gate, presented in section;

- in Fig. 6 is a schematic representation of the compensation blocks in the sliding gate according to FIG. 1 with a cut of the locking plates and partly of the inner cup or sprue tube;

- in Fig. 7 is a top perspective view of the clamping device for clamping the striker plate on the metal frame of the sliding gate according to FIG. 1.

Slide gate according to Fig. 1 can be mounted on the toe of a metallurgical container. The container is preferably designed as a tundish of the continuous casting system, in which the sliding gate serves to control the amount of melt supplied during the casting process to the mold of the continuous casting system. Gating tube 3, located at the bottom of the sliding gate, provides the possibility of inconspicuous pouring of molten metal into the mold. Alternatively, this gate valve can also be used on a pouring ladle, a converter taphole, or the like.

Slide gate according to Fig. 1 and FIG. 2 comprises a body 4 with a seal 4' located along the perimeter of its entire upper end surface so that it is hermetically attached with its upper part to the container. The fixed refractory stop plates 5, 6 and the movable plate 8, which can be moved back and forth by the drive mechanism 7, can be inserted into the body 4, the longitudinal movement of which opens, restricts or closes the outlet 9. The upper stop plate 5 is located in cover 11 of the housing 4 with the possibility of rotation around the axis 10, while the lower locking plate 6 is fixed in the insert frame 25 of the housing 4, and the movable locking plate 8 is fixed in the metal frame 12 connected to the drive mechanism 7. The sprue tube 3 is pressed against the bottom the locking plate 6 with spring-loaded levers 33. The body 4 has upwardly protruding supports 13, which, in working order, are adjacent to the outer part of the steel body of the tundish 2.

As shown in FIG. 3, the spring system 23 has a base 16 guided into the housing 4 by means of a screw thread 17 and a transverse bolt 18, around which the hinge pin 20, provided with a thread 19, can rotate, while the hinge pin is directed into the groove 21 of the cover 11 and screwed into the nut 22 over the lid. To provide access to the locking plates 5, 6 and 8, the nuts 22 can be loosened, and the hinge pins 20 can be turned from the grooves 21 of the cover. The hinge pins 20 are provided with a stroke limiter 20a, with which the initial preload of the Belleville springs 23, which influences the tension force, can be accurately and repeatedly adjusted. In the cover 11, on the nuts 22 of the fixing screws, inserts 24 are located, due to which the wear caused by frequent assembly and disassembly of threaded connections during operation is minimized.

In operation, the nuts 22 are screwed onto the hinge pins 20 so that the locking plates of the sliding gate, lying between the insert frame 25 and the cover 11, are pressed against each other with a correspondingly given contact pressure. This contact pressure is calculated in such a way that during operation it ensures continuous movement of the movable plate 8 with complete impermeability of the slide gate from the outside for metal or gas.

During operation, the refractory stop plates 5, 6, 8 experience dispersive mechanical elongation of up to 3 millimeters due to heating or manufacturing processes, resulting in additional stresses in the plate. According to the invention, this is compensated for by the first compensation unit I, since the cup springs 23' of the spring system 23 are more or less deformed as a result of the additional load. By arranging the fixing screws 15a-15d in pairs on either side of the outlet 9, the stress compensation is effective and very evenly distributed over the striker plates.

According to FIG. 4 and FIG. 5, at the bottom of the housing 4, an insert frame 25 is installed with a spring system 30 for pressing the locking plates 5, 6, 8 to the upper inner cup 1 of the outlet. This additional insert frame 25 is attached to the housing by 4 fixing screws 26 arranged in pairs on either side of the outlet.

The spring system 30, in turn, consists of Belleville springs 30', which are inserted between the head 28 of the fixing screws 26 and the insert frame 25, and have the function of pressing the insert frame against the adjacent lower striker plate 6, and thus press three locking plates 5, 6, 8 together to the upper inner glass 1 of the outlet.

The additional stress caused by the expansion or contraction of the inner sleeve 1 is compensated, according to the invention, by means of the second compensation block II, due to the fact that the Belleville springs 30' deform more or less under said stress. Preferably, these Belleville springs 30' are manufactured to have steep characteristic curves with respect to their stroke relative to the spring force, in order to provide a relatively large change in force with a small stroke. This is adapted to the respective characteristic curves of the cup springs 23' of the compensation unit I in order to always achieve the optimum tension. In this case, it is necessary to avoid the inclination of the gate plates, which can occur, depending on the position of the movable gate plate 8, due to an external force acting mainly through the gate tube.

In addition, to improve the fastening between the housing 4 and the insert frame 25, a female sealing element 31 is provided in the groove 32, one approximately half of which is located in the housing 4, and the other approximately half in the insert frame 25. This achieves a labyrinth effect, which further increases tightness. Alternatively, the groove can only be provided in the housing or insert frame.

Figure 6 schematically shows the location of the two compensation blocks I and II in the sliding gate. The first compensating block I is formed by a spring system 23 between the cover 11 and the body 4, which exerts a tension force to resiliently tension the locking plates 5, 6, 8, and the second compensation block II is formed by a spring system 30 between the insert frame 25 and the body 4, which exerts pressure for pressing locking plates 5, 6, 8 to the inner sleeve 1.

Said compensation blocks can be installed independently of each other and operate independently of each other, so that they can function both individually and in conjunction with each other. As a result, they protect the refractory parts of the slide gate from overloads that may occur due to thermal expansion and thickness changes of the refractory striker plate due to production reasons and/or thermal expansion or contraction of the upper inner nozzle during operation.

In addition, a clamping device 34 is used to fix the central locking plate 8 in its metal frame 12 in such a way that its location in the housing 4 does not impair the operation of the compensation blocks I and II.

The clamping device 34 according to Fig.7 consists of a clamping jaw 38, which can be adjusted in a metal frame 12 relative to the striker plate 8, and two adjusting elements 35, 36 located on both sides of the central axis Μ of the striker plate 8, as well as the spindle 37 threaded, connected to the adjusting elements. The threaded spindle 37 is rotatably mounted transverse to the central axis Μ in a metal frame 12 and is provided with thread sections extending in opposite directions. By manually rotating said threaded spindle 37, the adjusting elements 35, 36 are adjusted outward or inward, symmetrically to each other, and by means of the corresponding wedge surfaces 35', 36' of the adjusting elements 35, 36 or the clamping jaw 38, it is pressed against the locking plate 8, resulting in a self-locking wedging to avoid loosening during operation.

The invention is sufficiently illustrated by the embodiment described above. It goes without saying that other options are possible. For example, instead of the Belleville springs 23', 30', other springs such as helical springs and the like may be used.

Claims (9)

1. Sliding gate for a metallurgical container, containing a body (4), which is fixed at the bottom of the container, an upper inner sleeve (1) of a metallurgical container protruding from the upper locking plate (5), the lower locking plate (6), the locking plate (8) , installed between them with the ability to move in the longitudinal direction, the first compensation block I with a spring system (23), made with the possibility of pressing the locking plates (5, 6, 8) to each other, and the second compensation block II with a spring system (30) , made with the possibility of pressing the locking plates (5, 6, 8) to the upper inner sleeve (1), characterized in that it is equipped with a cover (11) of the housing (4), in which the upper locking plate (5) is located, the first compensation block I is formed by a spring system (23) configured to create a tension force between the cover (11) and the body (4), and the second compensation block II is provided with an insert frame (25) mounted with the possibility of being pressed against the lower locking plate (6). 2. Slide gate according to claim 1, characterized in that the spring system (23) of the first compensation block I is equipped with fixing screws (15a-15d), which are installed with the possibility of its movement relative to the cover (11). 3. Gate valve according to claim. 2, characterized in that the spring system (23) contains several Belleville springs (23') and travel stops (20a-20d) on the mounting screws (15a-15d), made with the possibility of adjusting the preload of the Belleville springs (23'). 4. Gate valve according to claim. 3, characterized in that the Belleville springs (23') are connected to the spring through the hinge pins (20) of the fixing screws (15a-15d), the guides of which are equipped with inserts (24) to enable the transfer of power from the Belleville springs (23') spring. 5. Slide gate according to any one of paragraphs. 1-4, characterized in that the insert frame (25) of the second compensation block II is installed on the bottom of the housing (4) using fixing screws (26) located in pairs on both sides of the outlet (1), and the Belleville springs (30' ) of the spring system (30) are installed between the heads (28) of the mentioned screws and the insert frame (25). 6. Gate valve according to claim 5, characterized in that a female sealing element (31) is inserted into the groove (32) of the body and/or insert frame (25), between it and the body (4). 7. Slide gate according to any one of paragraphs. 1-6, characterized in that it is equipped with a replaceable sprue tube (3), which is pressed against the lower locking plate (6) using spring-loaded clamping elements (33), while the clamping elements (33) are located with the possibility of acting independently of two compensation blocks I and II of the sliding gate. 8. Sliding gate according to any one of paragraphs. 1-7, characterized in that the central locking plate (8), mounted for movement in the longitudinal direction, is clamped in the metal frame (12) using a clamping device (34) built into it, containing a clamping jaw (38) made with the possibility of regulation in a metal frame (12) relative to the locking plate (8), two adjusting elements (35, 36) located on both sides of the central axis (M) of the locking plate (8), and a threaded spindle (37) connected to adjusting elements, while the adjusting elements (35, 36) are installed symmetrically to each other with the possibility of manual rotation of the said threaded spindle (37), and the clamping jaw (38) is pressed against the locking plate (8) in a self-locking manner by means of wedge surfaces (35', 36'). 9. Gate valve according to claim 8, characterized in that the threaded spindle (37) is installed in a metal frame (12) with the possibility of rotation across the central axis (M) and is provided with opposite threaded sections for one and the other adjusting elements (35, 36 ).

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