Slide closure for a vessel containing molten metal includes a slide housing and a slide unit that can be displaced longitudinally towards the slide housing, at least one refractory closure plate can respectively be inserted into the slide housing. The closure plates can be pressed against one another by the slide unit being braced against the slide housing. The closure plates can respectively be fixed or centered therein by a placement device having a displaceable positioning element. These placement devices are respectively designed such that upon bracing the slide unit against the slide housing, placing of the positioning element and clamping or centering of the respective closure plate is brought about therein. Therefore, despite easier operation, increased operating reliability is guaranteed because the closure plates are clamped and centered mechanically.

A robotized system for fixing a sliding gate valve plate to a sliding gate valve or removing a sliding gate valve plate from a sliding gate valve comprises a sliding gate valve plate, a metallurgic vessel provided with a sliding gate valve comprising a plate support frame comprising a receiving cradle suitable for receiving and locking the sliding gate valve plate, and a robot comprising a handling interface provided with gripping clamps for gripping the sliding gate valve plate. The sliding gate valve plate comprises gripping holds mating the gripping clamps of the robot, such that the robot can securely hold and handle the sliding gate valve plate.

A robotized system for fixing a sliding gate valve plate to a sliding gate valve or removing a sliding gate valve plate from a sliding gate valve comprises a sliding gate valve plate, a metallurgic vessel provided with a sliding gate valve comprising a plate support frame comprising a receiving cradle suitable for receiving and locking the sliding gate valve plate, and a robot comprising a handling interface provided with gripping clamps for gripping the sliding gate valve plate. The sliding gate valve plate comprises gripping holds mating the gripping clamps of the robot, such that the robot can securely hold and handle the sliding gate valve plate.

Slide gate for a metallurgical vessel, in particular a ladle, including a slide gate housing attachable to a metallurgical vessel, a head plate accommodated in the slide gate housing and having a passage opening for a metallic melt, a slide frame mounted in the slide gate housing so as to be displaceable in a direction relative to the head plate, and a slide plate accommodated in the slide frame and having a passage opening, characterized in that a device for compensating the contact pressure of the slide plate against the head plate is arranged between the slide gate housing and the slide frame, wherein the compensating device includes at least one carrier body mounted in the slide gate housing so as to be rotatable about at least one axis of rotation, and at least one spring element, via which the carrier body is coupled to the slide frame.

Slide gate for a metallurgical vessel, in particular a ladle, including a slide gate housing attachable to a metallurgical vessel, a head plate accommodated in the slide gate housing and having a passage opening for a metallic melt, a slide frame mounted in the slide gate housing so as to be displaceable in a direction relative to the head plate, and a slide plate accommodated in the slide frame and having a passage opening, characterized in that a device for compensating the contact pressure of the slide plate against the head plate is arranged between the slide gate housing and the slide frame, wherein the compensating device includes at least one carrier body mounted in the slide gate housing so as to be rotatable about at least one axis of rotation, and at least one spring element, via which the carrier body is coupled to the slide frame.

A steel ladle drainage method, is achieved by using a steel ladle structure. Vacuum interlayers are provided within an upper nozzle, an upper fixed plate, alower fixed plate and a sliding plate of the steel ladle structure respectively. In the steel ladle drainage method provided by the present invention, a metal drainage agent is used to replace the drainage sand in the prior art, the metal drainage agent is melted by the liquid steel and deposited in the upper nozzle, the sliding plate with the vacuum interlayer and the upper nozzle with the vacuum interlayer have the insulation effect on the melted metal drainage agent, agent falling. Moreover, through moving the sliding plate, the two pouring holes of the upper and lower fixed plates are connectedwith each other, the metal drainage agent enters the tundish through the pouring holes and the lower nozzle under the action of gravity.

A steel ladle drainage method, is achieved by using a steel ladle structure. Vacuum interlayers are provided within an upper nozzle, an upper fixed plate, alower fixed plate and a sliding plate of the steel ladle structure respectively. In the steel ladle drainage method provided by the present invention, a metal drainage agent is used to replace the drainage sand in the prior art, the metal drainage agent is melted by the liquid steel and deposited in the upper nozzle, the sliding plate with the vacuum interlayer and the upper nozzle with the vacuum interlayer have the insulation effect on the melted metal drainage agent, agent falling. Moreover, through moving the sliding plate, the two pouring holes of the upper and lower fixed plates are connectedwith each other, the metal drainage agent enters the tundish through the pouring holes and the lower nozzle under the action of gravity.

A gate valve system includes a base plate and a gate valve plate, a casting plant includes the gate valve system, and a casting process manufactures workpieces, particularly from metal materials. The base plate has an opening and the gate valve plate has a first opening and at least a second opening. The separating gate valve system is set up so that the separating gate valve system can be brought into casting, pressing, and closure positions. In the casting position, the first opening is arranged to align with the opening of the base plate, at least to the greatest possible extent; in the pressing position, the second opening is arranged to align with the opening of the base plate, at least to the greatest possible extent; and in the closure position, the gate valve plate closes off the opening of the base plate.

A gate valve system includes a base plate and a gate valve plate, a casting plant includes the gate valve system, and a casting process manufactures workpieces, particularly from metal materials. The base plate has an opening and the gate valve plate has a first opening and at least a second opening. The separating gate valve system is set up so that the separating gate valve system can be brought into casting, pressing, and closure positions. In the casting position, the first opening is arranged to align with the opening of the base plate, at least to the greatest possible extent; in the pressing position, the second opening is arranged to align with the opening of the base plate, at least to the greatest possible extent; and in the closure position, the gate valve plate closes off the opening of the base plate.

A sliding gate valve of a metallurgic vessel comprises a carriage. The carriage comprises a plate frame for supporting a first refractory plate and the plate frame is slideably mounted on a carriage support structure for sliding along a first axis. The carriage comprises a selecting device for selecting between a first stroke ΔX1 and a second stroke ΔX2 by moving a blocking member between a blocking and a non-blocking position. When the blocking member is located in the blocking position a first bumper portion of the plate frame is bumping into the blocking member if the plate frame is to slide beyond a nominal end-position. When the blocking member is located in the non-blocking position the first bumper portion is not bumping into the blocking member if the plate frame is to slide beyond a nominal end-position, thereby allowing the plate frame to slide beyond the nominal end-position to a service end-position.