EP0436813A2 - Shut-off and/or control device - Google Patents

Abstract

A closing and / or regulating member for an elongated spout of a container containing molten metal has a tubular, immovable closure part (6) and a tubular closure part (7) rotatable thereon. Longitudinal slots (8.9) of the closure parts (6.7) are used for casting close to the final dimensions. A radial flow through the inner closure part (6,7) should be avoided. The stability of the closure parts is to be improved. The cavity (11) of the internal closure part (6, 7) is closed on one end face (12). Opposite this, it forms an inlet opening (14). <IMAGE>

Description

The invention relates to a closing and / or regulating member for an elongated spout of a container containing molten metal, with a refractory, tubular, immovable closure part and a refractory, tubular closure part rotatable relative to this metal-tight, the one closure part being mounted in the other closure part and both closure parts are each provided with an outlet opening designed as a longitudinal slot.

Such a closing and / or regulating element is described in DE 38 05 071 A1. At the closure parts there are inlet openings which, like the outlet openings, are slit-shaped and diametrically opposite the outlet openings with respect to the common longitudinal axis of the two tubular closure parts. In the open state of the closing and / or regulating member, the melt flows radially through the cavity of the internal closure part. The cavity does not contribute to a distribution of the melt over the slit-shaped outlet openings. In addition, the longitudinal slots weaken the closure parts, since each closure part is provided with two longitudinal slots.

DE 38 09 071 A1 describes a twist lock in which radial and diametrical openings of the movable closure part are avoided. A recess in the outer surface of this closure part forms the connecting channel between the inlet opening and the outlet opening. However, the outer, tubular closure part is weakened by two slots. The cavity of the tubular inner closure member does not contribute to the distribution of the melt over the outlet opening. The recess is exposed to the sealing surface of the outer closure part, so that it is exposed to wear from the melt. Another control device for a slit-shaped spout is described in DE 35 08 218 A1. There, the melt flow rate can be adjusted by influencing its viscosity. A locking device is not shown.

CH 671 716 A5 describes a device for casting thin strips or foils made of metallic material. A longitudinal slot is provided in a tubular nozzle body. One end of the nozzle body is closed. The melt flows in at the other end. To regulate the The level of the melt in the vessel can be regulated or the melt is pressurized, the nozzle body being arranged above the melt level. The nozzle body does not form a closing and / or regulating element.

The object of the invention is to propose a closing and / or regulating member of the type mentioned, in which it is avoided that the melt flows radially to the longitudinal axis of the tubular closure parts through the internal cavity to the outlet openings and in which the stability of the tubular closure parts is improved is.

According to the invention, the above object is achieved in a closing and / or regulating element of the type mentioned at the outset in that the cavity of the inner, tubular closure part is closed on one end face and open on the other end face and forms an inlet opening thereon, which extends over the cavity of the internal closure part is connected to the slot-shaped outlet opening.

The melt enters the cavity at the end. There is therefore no need for an inlet slot on the inner, tubular closure part parallel to the slot-shaped outlet opening. Likewise, an inlet slot extending parallel to the slot-shaped outlet opening on the outer tubular closure part is superfluous. The stability of the two closure parts is considerably improved. This is In particular, it is essential because the two closure parts, which are mounted one inside the other, must be able to be permanently rotated easily about their common longitudinal axis in order to ensure the desired closing and / or regulating function. It is thus achieved that the thickness of the melt strip leaving the slit-shaped outlet opening of the outer closure part can be sensitively controlled by rotating the two outlet openings relative to one another and, if necessary, the melt outlet can be interrupted. The width of the outflowing melt strip can be controlled by moving the closure parts in the direction of the longitudinal axis.

In the closing and / or regulating member, the molten metal does not pass diametrically or radially through the cavity, but rather flows into it in the longitudinal direction. The cavity thereby forms a buffer which ensures that the melt is under the same pressure practically over the entire length of the slot-shaped outlet openings. It is achieved in that the emerging melt strip leads to metal strips or sheets of uniform thickness, the uniformity of the thickness also existing in the edge regions. The closing and / or regulating element described is therefore suitable for continuous casting close to the final dimensions, in particular strip casting, or thin slab casting, with the otherwise necessary rolling operations being eliminated. Due to the controllability of the emerging melt belt, the need to control the speed of a cooling drum or cooling belt which takes over the melt belt and is arranged downstream of the closing and / or regulating member takes a back seat. It is also favorable that the melt present in the cavity can also be in direct connection with the melt in the vessel when the closing member is closed, since this counteracts a blockage of the cavity. It is also advantageous that the closure parts can be pulled apart and replaced in the axial direction when worn.

In an embodiment of the invention, a flow zone extending in the longitudinal direction of the cavity is provided in the cavity between the inlet opening and the slot-shaped outlet opening of the internal closure part. The flow zone aligns the flowing melt in the direction of the closed end face, that is to say transversely to the slot-shaped outlet openings. This supports the uniform pressure over the entire length of the slot-shaped outlet openings. For the same purpose, a further development of the invention provides that there is a storage space in the cavity between the closed end face and the slit-shaped outlet opening of the internal closure part.

Figur 1

ein Schließ- und/oder Regelorgan außen an einem Schmelzenbehälter,

Figur 2

das Schließ- oder Regelorgan nach Figur 1, dieser gegenüber vergrößert, im Schnitt,

Figur 3

eine Alternative zu Figur 2,

Figur 4

einen Schnitt längs der Linie IV-IV nach Figur 2 bzw. Figur 3,

Figur 5

ein in einem Schmelzenbehälter angeordnetes Schließ- und/oder Regelorgan,

Figur 6

einen Schnitt längs der Linie VI-VI nach Figur 5,

Figur 7

eine Teilansicht einer Alternative zu Figur 5 und

Figur 8

eine Alternative zu Figur 1, in einer Figur 2 entsprechenden Ansicht.

Further advantageous refinements of the invention result from the subclaims and the following description of exemplary embodiments. The drawing shows:

Figure 1

a closing and / or regulating element on the outside of a melt container,

Figure 2

1, the closing or regulating element according to FIG. 1, enlarged compared to it, in section,

Figure 3

an alternative to FIG. 2,

Figure 4

3 shows a section along the line IV-IV according to FIG. 2 or FIG. 3,

Figure 5

a closing and / or regulating element arranged in a melt container,

Figure 6

4 shows a section along the line VI-VI according to FIG. 5,

Figure 7

a partial view of an alternative to Figure 5 and

Figure 8

an alternative to Figure 1, in a view corresponding to Figure 2.

A system for casting sheet metal or thin strips has a container (2) containing molten metal (1). A closing and / or regulating element (3) is arranged at the bottom of this at an outlet (4). A cooling roller (5) or a cooling belt is arranged downstream of the closing and / or regulating element (3) in the outflow direction of the melt. The melt strip emerging from the closing and / or regulating member (3) is drawn off from the cooling roll (5) or the cooling belt.

The closing and / or regulating member (3) has an immovable closure part (6) attached to the container (2). This is tubular and consists of a refractory, ceramic material. In addition, the closing and / or regulating member (3) has a movable closure part (7). This is also tubular and consists of a refractory, ceramic material. The closure part (7) is rotatable relative to the closure part (6) about the common longitudinal axis (L). It can also be axially displaceable in the direction of the longitudinal axis (L).

The immovable closure part (6) has a longitudinal slot (8) as an outlet opening. The closure part (7) is provided with a longitudinal slot (9) as an outlet opening. Both longitudinal slots (8,9) have the same length (A) and the same width (B). The longitudinal slots (8, 9) together form the melt strip emerging on the cooling roll (5).

In the exemplary embodiment according to FIGS. 1 to 4, the closing and / or regulating member (3) is arranged at the bottom, laterally outside the container (2).

In the exemplary embodiment according to FIGS. 5 to 7, the closing and / or regulating member (3) is arranged at the bottom inside the container (2), so that it requires a longitudinal slot (10) which continues the longitudinal slots (8, 9) and which the cooling roller ( 5) is subordinate.

In the exemplary embodiment according to FIG. 8, the closing and / or regulating element (3) is arranged below the container (2).

In all of the exemplary embodiments, the closure part (7 or 6) located within the outer closure part (6, 7) forms an internal cylindrical cavity (11). This is closed on one end (12). There is a storage space (13) between the closed end face (12) and the end of the longitudinal slot (8, 9) near it. If necessary, this can have a vent hole. Opposed to the closed end face (12) in the direction of the longitudinal axis (L), an inlet opening (14) is formed on the inner closure part (6, 7). Between the inlet opening (14) and the end of the longitudinal slot (8 or 9) close to it, the cavity (11) forms a flow zone (15) which directs the melt flowing in through the inlet opening (14) towards the closed end face (12). aligns.

In all of the exemplary embodiments, the movable closure part (7) has an extension (16) which is guided outwards. A control element (not shown in more detail) engages on the extension (16), with which the closure part (7) can be rotated in the direction (D) about the longitudinal axis (L) and, if appropriate, can also be displaced axially to the longitudinal axis (L) in the direction of the arrow (E) is.

In the embodiment of Figure 2, the movable closure member (7) is the internal closure member. Accordingly, the external closure part (6) is on a side connection (17) of the container (2) by means of a flange (18) attached. Since in this embodiment the outer closure part (6) is fixed, its longitudinal slot (8) is firmly assigned to the cooling roller (5).

In the exemplary embodiment according to FIG. 3, the closure part (6) which is fixed to the socket (17) by means of its flange (18) is the inside closure part. In relation to this, the outer closure part (7) is movable.

In the embodiment according to FIG. 5, the closure part (6) attached to the container (2) is the external closure part. It is inside the container (2). The movable closure part (7) is arranged inside the closure part (6).

In the exemplary embodiments according to FIGS. 1 to 6, the outer closure part (6 or 7) is in each case open on the end face in which the open end face or the inlet opening (14) of the inner closure part lies. The outer closure part (6 or 7) does not interfere with the flow of the melt into the inlet opening (14) of the inner closure part (6 or 7).

In order to improve the support of the immovable, external closure part (6) in the embodiment according to FIGS. 5 and 6, support webs (19) can be provided in the container (2).

In the exemplary embodiment according to FIG. 7, the inlet opening (14) of the internal, movable closure part (7) is formed by an edge (20) which is inclined to the longitudinal axis (L). In contrast to this, in the exemplary embodiments according to FIGS. 1 to 6, the edge delimiting the inlet opening (14) runs perpendicular to the longitudinal axis (L). The external, fixed closure part (6) arranged inside the container (2) has an inlet opening (21) corresponding to the inlet opening (14) delimited by the edge (20). This lies radially to the longitudinal axis (L). However, it does not face the longitudinal slots (8.9). The flow zone (15) exists between it and the end of the longitudinal slots (8, 9) near it. The inlet opening (21) allows the outer closure part (6) to be mounted on the container (2) also at its end close to the inlet opening (21). This improves the stability of the arrangement. In addition, it is possible to design the inclined edge (20) in cooperation with the inlet opening (21) so that in the closed position of the closing and / or regulating member (3) the movable closure part (7) also the inlet opening (21) of the Locking part (6) shuts off. The edge (20) could also be stepped.

In the exemplary embodiment according to FIG. 8, the closing and / or regulating element (3) is arranged below the container (2) at its outlet (4). The internal, movable closure part (7) has the inlet opening (14) described in FIG. 7 with the inclined edge (20). The outlet (4) opens into the inlet opening (21). In the embodiment according to FIG. 8, the static pressure of the melt in the closing and / or regulating member (3) is increased compared to the embodiment according to FIG. 1 or 5. This can improve the even pressure distribution over the length (A) of the longitudinal slots (8,9). In addition, a spatially more compact structure is achieved than in the embodiment according to FIG. 1.

In the exemplary embodiments according to the figures, the longitudinal slots (8, 9) are shown as being open at the bottom. It is also possible to provide the slots (8, 9 or 10) laterally.

If the weaknesses which form the longitudinal slots (8.9) on the closure parts (6.7) are significant, it is also possible to bridge the slots (8.9) by means of a plurality of narrow webs which prevent the melt from escaping hardly affect.

In the exemplary embodiments according to FIGS. 1 to 4 and 8, it is also favorable that the closing and / or regulating member is exposed outside the container (2), so that it can be easily heated with a heating device in order to freeze the melt in it prevent.

Claims (14)

Closing and / or regulating member for an elongated spout of a container containing molten metal, with a refractory, tubular, immovable closure part and a refractory, tubular closure part rotatable relative to this in a metal-tight manner, one closure part being mounted in the other closure part and both closure parts with each have an outlet opening designed as a longitudinal slot,
characterized,
that the cavity (11) of the inner, tubular closure part (6 or 7) is closed on one end face (12) and open on the other end face and forms an inlet opening (14) thereon, which via the cavity (11) of the internal closure part (6 or 7) is connected to the slot-shaped outlet opening (8 or 9). Locking and / or regulating element according to claim 1,
characterized,
that in the cavity (11) between the inlet opening (14) and the slot-shaped outlet opening (8 or 9) of the internal closure part (6 or 7) there is a flow zone (15) extending in the longitudinal axis direction (L) of the cavity (11). Closing and / or regulating element according to claim 1 or 2,
characterized,
that there is a storage space (13) in the cavity (11) between the closed end face (12) and the slit-shaped outlet opening (8 or 9) of the internal closure part (6 or 7). Locking and / or regulating element according to one of the preceding claims,
characterized,
that for operating the rotatable closure part (7) an operating part is provided on the end face (12) facing away from the inlet opening (14). Locking and / or regulating element according to one of the preceding claims,
characterized,
that the outer closure part is open at one end and this open end is the Encloses inlet opening (14) of the internal closure part (6 or 7). Locking and / or regulating element according to one of the preceding claims 1 to 4,
characterized,
that the outer closure part (6 or 7) has an inlet opening (21) which is radial to the longitudinal axis (L). Closing and / or regulating element according to claim 6,
characterized,
that the inlet opening (14) of the internal closure part (6 or 7) is bounded by an edge (20) which is inclined to the longitudinal axis (L). Locking and / or regulating element according to one of the preceding claims,
characterized,
that it lies outside the container (2) and is connected in the region of its inlet opening (14) to an outlet (4) provided on the side or bottom of the container (2) at the bottom. Closing and / or regulating element according to claim 8,
characterized,
that the movable closure part (7) is the external closure part. Closing and / or closing member according to claim 8,
characterized,
that the movable closure part (7) is the internal closure part. Locking and / or regulating element according to one of the preceding claims 8 to 10,
characterized,
that a heating device is arranged on the outer closure part (6 or 7). Locking and / or regulating element according to one of the preceding claims 1 to 7,
characterized,
that it is arranged inside the container (2) on the bottom thereof. Locking and / or regulating element according to claim 12,
characterized,
that the movable closure part (7) is the internal closure part. Locking and / or regulating element according to one of the preceding claims,
characterized,
that the movable closure part (7) is displaceable in the direction of the longitudinal axis (L).

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