EP2429741A1

EP2429741A1 - Continuous casting system comprising at least one robot

Info

Publication number: EP2429741A1
Application number: EP10720351A
Authority: EP
Inventors: Dirk Lieftucht; Ina HÜLLEN
Original assignee: SMS Siemag AG
Current assignee: SMS Siemag AG
Priority date: 2009-05-12
Filing date: 2010-05-11
Publication date: 2012-03-21
Also published as: DE102009020857A1; WO2010130405A1; CN102421550A

Abstract

The invention relates to a continuous casting system comprising at least one continuous casting mold (2) and at least one robot (10) for performing process controlled and automated engagements with the continuous casting system, characterized in that the at least one robot (10) comprises means for detecting casting crusting in the at least one continuous casting mold (2).

Description

Continuous casting plant with at least one robot

The invention relates to a continuous casting plant with at least one continuous casting mold and at least one robot for carrying out process-controlled and automated interventions on the continuous casting plant.

The present invention relates to all types of continuous casting, in which a molten metal from a melt container, such as a ladle, is passed through a distribution vessel in a cooled mold, there formed with intensive cooling to an at least partially solidified strand of a desired cross section and from the continuous casting is continuously discharged. The can have a slab, thin slab, strip, billet or billet cross section of any size.

Robots are used on a continuous caster to perform on-going work and to eliminate malfunctions in hazardous areas where operators are exposed to high levels of heat from the liquid metal and cast metal strands, or slag and metal splashes. The robots are already being used on the open continuous casting mold for observing the melt bath surface, for casting powder application, for temperature measurement and for sampling and the like. In addition, robots are used for changing the shade tube, changing the pouring tube, or for changing the closure plates of the slide valve closure and for blowing out the outflow opening on the distribution vessels and ladles. It is known that robots for the inspection of the cast strands and the separated slabs, blooms or billets and for the elimination of errors, for example by flames, are used in the outlet area of the continuous casting plant. EP 0 371 482 A2 discloses the use of a multi-function robot on a continuous casting mold, wherein the robot receives casting-process-related data from measuring devices on the mold and also acquires measured data by an optical detection system, for example, on the mold and on the basis of this information an application plan created and processed with priority assignment. This is a stationary robot whose location is specially chosen for use on the mold.

From JP 03-71959 A the use of two robots on the casting platform of a multi-strand continuous casting plant is known, each robot on the casting platform is assigned a roadway and the robot can take on this one use position to replace at a large trough distributor pouring and on to carry out cleaning work on the outlet openings of the distribution vessel and the pouring pipes. Each robot is assigned a delimited work area, whereby it is not possible to work one robot in the working area of the other robot.

WO 2005 118182 A1 proposes a robot for a continuous casting plant with which different interventions on a continuous casting plant are to be carried out at different working positions which are outside the range of a single operating position of the robot. The continuous caster is associated with a roadway, and the robot has a chassis, which is guided displaceable on the roadway. At least one parking position and at least two deployment positions for the robot are defined on the roadway. Each operating position is assigned to work areas that can only be reached from this operating position at the continuous casting installation, wherein the distance between each operating position of the robot and the assigned work area or service area is defined within the minimum and maximum reach of the robot arm. The robot is equipped with a data transmission and reception device; This is in turn connected to a central control device or a process computer of the continuous casting plant connected by signal technology. By defining a roadway on the continuous casting plant or in subregions of a continuous casting plant, which is guided past a plurality of potential work areas so that these work areas are within the range of predetermined individual positions of a robot that can travel on the roadway, the limited, only singular Possible use of a robot to be resolved.

WO 2007 057061 A1 discloses a continuous casting plant with at least one multifunction robot. At least one working area is defined on the continuous casting plant and at least one multi-function robot is assigned to each working area, which in turn is arranged on a pivoting arm. The multifunction robot is arranged on a swivel arm of a rotary column mounted on the casting platform of the continuous casting plant and pivotable with the swivel arm between a retracted position and a working position.

On the other hand, in continuous casting molds, mold powder crusts are still removed at regular intervals by operating personnel. Here, a wooden rod is inserted approximately ten to twenty centimeters deep into the casting gap between the mold and the partially solidified casting strand and pulled along the mold contour. If an increased formation of Gießpulverkrusten in the narrow side area is found, they must be removed manually.

The quality and quantity of this process depends on the executing staff and varies as they change. There is no automatic data collection on the process of pour crust control or scab removal.

It is the object of the invention to simplify the observation of the Gießpulverkruste and their removal. According to the invention this object is achieved in a continuous casting of the type mentioned fact that the at least one robot comprises means for Gießkrustendetektion in the at least one continuous casting mold.

The use of a robot automates the previously manual process. With the help of sensors unified data on the found encrustations and the forces applied when detecting mold powder crusts are detected. In a second step, these data are incorporated into the existing data structure of the plant.

Automation ensures a very uniform execution of the process. The created database allows statistical surveys on the effects of encrustations and their removal.

A robot can be executed in the form of a permanently installed device, with the robot arm being fastened at a fixed location in the vicinity of the supply and operating units of the mold. As a result, distances of about five meters can be bridged, and the robot can be positioned so that it is located between two inserts in a protected area.

When approaching the mold various geometric data for the robot can be used to maintain the required distances to the individual units. If necessary, the upper contour of the copper plates used in the continuous casting mold can also be used for reference point travel.

The robots used are equipped with heat-resistant protective coverings. Wood rods for scanning the pouring crusts, which can be used several times, are provided in a magazine changing device. In addition, a sensor to protect the operator in terms of the robot.

Advantageous developments of the invention will become apparent from the dependent claims.

It is preferably provided that the robot is arranged in the vicinity of supply or operating units of the at least one continuous casting mold.

Assuming that the continuous casting plant is a multi-strand casting plant with several continuous casting molds and that a distributor gutter carriage movable on rails is provided between the molds, robots can be fastened to the distribution gutter carriage.

Preferably, the robot is arranged on the underside of the Verteilerrinnenwagens. Here, on the one hand, it can be stored to save space and, on the other hand, it is largely protected against cast and slag sprayers.

Advantageously, the contours of the continuous casting mold, in particular the upper Kokillenrand, can be used for the orientation of the robot.

In an advantageous embodiment, the robot is provided with at least one sensor for detecting the pouring crust in the continuous casting molds. The sensor is designed in particular as a force or pressure sensor and preferably not an optical sensor.

With the aid of the force sensor attached to the robot, the thickness of the pouring crust can be determined, for example, in a computing and evaluation unit integrated in the robot or in the computer system of a central control station.

Advantageously, the robot comprises a pivot column, at least one pivot arm and / or at least one articulated arm and an attached, in particular interchangeable, end effector.

Preferably, means for removing the pouring crust are attached or attachable to the end effector.

The invention will be explained in more detail in an embodiment. The single figure shows a side view of a casting platform with a Verteiltrollinnenwagen and attached to this robot.

A distributor gutter car 1 (FIG.) Picks up a molten metal from a ladle (not shown here) and subsequently conveys it to one or more continuous casting molds 2. For this purpose, the tundish car 1 is movably mounted on rails 4 on the casting platform 5 via wheels 3.

On its underside, the distributor trough 1 has a pouring tube 6, from which the melt flows into the mold 2. The mold 2 has on its longitudinal and its transverse sides movable copper plates 7, 8, between which forms a gradually decreasing metal strand 9 from the melt. In order to promote the mobility of the metal strand 7 with respect to the copper plates 7, 8, casting powder is introduced into the area on the inside of the copper plates 7, 8, which can crust together with the upper layer of the melt, so that a casting crust is formed at intervals must be removed.

On the underside of the Verteilerrinnenwagens 1 a robot 10 is fixed, which is equipped with a multi-link articulated and rotary arm 11. At the distal

End of the articulated and rotary arm 11, an end effector is provided on which a removable storage magazine a wooden rod or the like can be attached to scan the inner edge of the mold in the casting crust. According to the determined force, the strength of the pouring crust can be determined. For this purpose, either the robot 9 or a central Control station, to which the robot 9 is connected, equipped with the necessary computing means. Preferably, the determined results for the thickness of the pouring crust can also be displayed on a screen. Then it can be decided whether and at what intervals this has to be removed.

However, it can also be provided that the robot 10 already makes this decision independently. In this case, an end effector attached to the arm 11 exchanges the wooden bar for a tool for removing the slag and the pouring crust. It is understood that various sensors, for example also for temperature measurement, can be attached to the arm 11 of the robot 10.

In the case of a Mehrstranggießanlage the robot 10 can be easily moved in each case with the Verteilerrinnenwagen 1, so that he can check the crusts in each continuous casting mold 2 and optionally remove.

LIST OF REFERENCE NUMBERS

1 distributor gutter car

10 2 continuous casting mold

3 wheels

4 rails

5 casting platform

6 pouring tube

15 7 copper plate

8 copper plate

9 metal strand

10 robots

11 joint and rotary arm

Claims

claims

1. Continuous casting plant with at least one continuous casting mold (2) and with at least one robot (10) for carrying out process-controlled and automated interventions on the continuous casting plant, characterized in that the at least one robot (10) comprises means for the detection of the foundry in the at least one continuous casting mold (2). includes.

2. Continuous casting plant according to claim 1, characterized in that the robot (10) in the vicinity of supply or operating units of the at least one continuous casting mold (2) is arranged.

3. Continuous casting plant according to claim 1, characterized in that the continuous casting is equipped as a Mehrstranggießanlage with several continuous casting molds (2) and a movable between these distributors lerrinnenwagen (1) and that the robot (10) on the

Distributor gutter carriage (1) is attached.

4. Continuous casting plant according to claim 3, characterized in that the robot (10) on the underside of the Verteilerrinnenwagens (1) is arranged.

5. Continuous casting plant according to one of claims 1 to 4, characterized in that contours, in particular the upper mold edge for orientation of the robot (10) are usable.

6. Continuous casting plant according to one of claims 1 to 5, characterized in that the robot (10) comprises at least one sensor for detecting the casting crust in the continuous casting molds (2).

7. Continuous casting plant according to one of claims 1 to 6, characterized in that at least one force sensor for detecting the thickness of the casting crust is attached to the robot (10).

8. Continuous casting plant according to one of claims 1 to 7, characterized in that the robot (10) comprises at least one rotary column, at least one pivot arm and / or at least one articulated arm (11) and attached thereto, in particular interchangeable, end effector.

9. Mehrstranggießanlage according to claim 8, characterized in that attached to the end effector means for removing the casting crust or are attachable.