The invention relates to a sliding closure (10) for a metallurgical vessel comprising a tapping hole (1) for draining metal melt or slag, said sliding closure being provided with a slider housing (3) that can be secured to the vessel (2) and a closure plate (6) that can move therein for opening and closing the tapping hole (1). The sliding closure (10) also has only this moveable closure plate (6), without a stationary closure plate, which is can be moved directly on a sliding surface (7), extending around the tapping hole, preferably of a casing block (9) in the vessel (2) and can be pressed by pretensioning elements. In this way, this sliding closure (10) provides a constructionally simpler structure and user-friendly handling.

The invention relates to a sliding closure (10) for a metallurgical vessel comprising a tapping hole (1) for draining metal melt or slag, said sliding closure being provided with a slider housing (3) that can be secured to the vessel (2) and a closure plate (6) that can move therein for opening and closing the tapping hole (1). The sliding closure (10) also has only this moveable closure plate (6), without a stationary closure plate, which is can be moved directly on a sliding surface (7), extending around the tapping hole, preferably of a casing block (9) in the vessel (2) and can be pressed by pretensioning elements. In this way, this sliding closure (10) provides a constructionally simpler structure and user-friendly handling.

A slide closure (10) for a container containing molten metal is provided with a housing part (1) that can be fastened to the latter and a slider unit (2) that can be displaced longitudinally relative to it, into which a fireproof plate (4 or 5) can respectively be inserted. The slider unit (2) is held by a number of holding means (6a, 6b; 7a, 7b) fastened to the housing part (1) perpendicular to the slider unit such that it can be displaced longitudinally. The holding means (6a, 6b; 7a, 7b) are individually fastened releasably to the housing part (1) such that in the braced state of the slide closure (10) they can be released from the housing part (1) in almost every position of the slider unit (2). In the event of a breakdown opening of the latter is thus made possible without the holding means and/or other parts having to be destroyed. In addition, the housing part (1) has walls (8, 9) running close to the plate (4, 5) in the longitudinal direction and with projections (10a, 10b or 11a, 11b) that protrude to the side, in which walls bearings (12) of the individual holding means (6a, 6b; 7a, 7b) can be accommodated.

In a sliding gate, a flow path vertical angle a between a flow path axial direction and a vertical downstream direction in a flow path hole in each plate is 5° or more and 75° or less, and a flow path axial direction projected on sliding surface in which the flow path axial direction is projected on a sliding surface differs between the plates and is changed clockwise or counterclockwise toward a downstream side. Then, molten metal forms a turning flow in the flow path hole of the sliding gate. Furthermore, the molten metal also forms a turning flow in a ladle shroud on the downstream side of the sliding gate.

In a sliding gate, a flow path vertical angle a between a flow path axial direction and a vertical downstream direction in a flow path hole in each plate is 5° or more and 75° or less, and a flow path axial direction projected on sliding surface in which the flow path axial direction is projected on a sliding surface differs between the plates and is changed clockwise or counterclockwise toward a downstream side. Then, molten metal forms a turning flow in the flow path hole of the sliding gate. Furthermore, the molten metal also forms a turning flow in a ladle shroud on the downstream side of the sliding gate.

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.

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.

The present invention concerns a metal casting installation comprising, (a) a loading platform (20), (b) a tundish (1), (c) a first ladle (11) and a second ladle (12), each of the first and second ladle comprising, a floor provided with an opening (11o, 12o), a collector nozzle (14) and a ladle shroud (13a-13c), a ladle sliding gate (15) configured for moving the collector nozzle and the ladle shroud between a sealed position wherein the opening is sealed, a casting position wherein the opening faces the ladle shroud (13a-13c), and an unclogging position wherein the opening faces the collector nozzle (14), (d) a turret (30) for holding the first and second ladles, configured for moving and holding in place the first and second ladles (11,12) between a loading station and a casting station, over the tundish (1), Characterized in that, the metal casting installation comprises a robot (21) configured for carrying out the following operations on the first or second ladle which is held in the loading station, loading a new ladle shroud (13b) onto the ladle slide gate (15), and coupling a driving device (17) to the ladle slide gate (15).

The present invention concerns a metal casting installation comprising, (a) a loading platform (20), (b) a tundish (1), (c) a first ladle (11) and a second ladle (12), each of the first and second ladle comprising, a floor provided with an opening (11o, 12o), a collector nozzle (14) and a ladle shroud (13a-13c), a ladle sliding gate (15) configured for moving the collector nozzle and the ladle shroud between a sealed position wherein the opening is sealed, a casting position wherein the opening faces the ladle shroud (13a-13c), and an unclogging position wherein the opening faces the collector nozzle (14), (d) a turret (30) for holding the first and second ladles, configured for moving and holding in place the first and second ladles (11,12) between a loading station and a casting station, over the tundish (1), Characterized in that, the metal casting installation comprises a robot (21) configured for carrying out the following operations on the first or second ladle which is held in the loading station, loading a new ladle shroud (13b) onto the ladle slide gate (15), and coupling a driving device (17) to the ladle slide gate (15).

Provided is a casting sliding gate including a plurality of plates, and at least a portion of the plates includes carbon fibers and carbide and is capable of suppressing damage due to a thermal shock.