AT510292B1 - DETERMINATION OF THE POSITION OF A CONTACT TABLE TO A PROBE HOLDER OF A HORIZONTAL PROBE - Google Patents

Description

Austrian Patent Office AT510 292 B1 2012-03-15

description

TABLE OF THE INVENTION

Determining the position of a contact rod on a probe holder of a metallurgical probe

FIELD OF TECHNOLOGY

The present invention relates to a method for determining the position of the free end of a contact rod on a probe holder of a metallurgical probe.

The present invention further relates to an apparatus for carrying out the method according to the invention.

STATE OF THE ART

In the production of iron, steel and other metals samples of the liquid metal are removed, there is a temperature detection, etc. For such tasks, metallurgical probes are used which have a probe longitudinal axis and are open at one end face. At the other end they are closed. The probes are usually used only once and then disposed of.

In the prior art, the probes are plugged onto the probe holder of a measuring lance, or the probe holder inserted into the probe. This has at its end a so-called contact rod, which connects the signal lines in the attached probe with the signal lines in the probe holder. The contact rod forms a straight extension of the contact rod end portion of the probe holder. The signal lines in the probe holder are subsequently connected to the signal lines in the body of the measuring probe. Through these signal lines, the information measured by the probe, such as temperature of the liquid metal to signal processing devices are passed. When the probe is mounted on the probe holder, the probe is immersed in the molten metal of the liquid metal, thus supplying the probe to its intended use. Thereafter, the probe is pulled out of the molten metal by moving the sublance. Thereafter, the probe is removed from the probe holder.

In the prior art, it is known that a worker removes each probe to be used from a reservoir and manually aufsteckt on the probe holder with contact rod. This is cumbersome, tedious and due to the harsh operating conditions in metallurgical plants as possible to avoid. It is therefore an automated solution to strive for. For the realization of an automated solution, however, there are essentially two problems in the prior art.

On the one hand, the probe holder is often plastically bent when the probe is immersed in the molten metal. The extent of plastic deflection can vary. The probe holder of the measuring probe with the end of the contact rod to be inserted into the probe and the probe must be positioned very precisely when inserting the probe in order to avoid breaking off the contact rod when attaching the probe. The relatively thin-walled contact rod breaks easily when exposed to forces. The probe should therefore be positioned when plugging so that it forms as possible a straight extension of the contact rod end portion of the probe holder - and thus the contact rod -. With such a positioning, the probe can be pushed over the contact rod onto the probe holder without exerting any appreciable forces on the contact rod. Even slight bending of the probe holder makes an automated insertion of the probe onto the probe holder difficult. This is because a position of the probe and a plug-in movement, which would allow trouble-free plugging without force from the probe to the contact rod in an unenforced probe holder, with a bent probe holder can lead to force of the probe on the contact rod. In order nevertheless to be able to realize an automated solution, it is known in the prior art to use a centering device which has a contact-rod-side funnel region and a probe-side funnel region, which are attached to their Passing bottlenecks into each other. By inserting the probe holder with contact rod into the contact rod side funnel region and inserting the probe into the probe side funnel region, the contact rod end portion of the probe holder and the open end of the probe are centered relative to each other so that the probe can be slid over the contact rod onto the probe holder without appreciable To exert forces on the contact rod.

The known centering device must be forcibly obvious, since otherwise the probe holder with contact rod after insertion into the probe could indeed be pulled out of the probe again, but could not be removed together with the plugged probe from the centering device. The known centering device must therefore comprise a corresponding actuator, corresponding moving parts, a power supply and a control device. It is therefore on the one hand relatively complex and expensive and on the other hand due to the harsh operating conditions in metallurgical plants relatively susceptible to interference.

The probe holder or provided with the probe holder end of the measuring lance, hereinafter also referred to as the probe holder supporting measuring lance, is often contaminated during the test drive, for example, by slag and molten metal. This makes it difficult or impossible to attach fresh probes to the probe holder. If the probes are changed manually, the operator may have to manually remove the contamination from the probe holder. As already mentioned, since the probe holder is often plastically bent and the extent of the plastic bending can vary, an accurate automated supply of a cleaning device to the probe holder is made more difficult. Automated delivery requires knowledge of the spatial position of the contact rod end of the probe holder.

SUMMARY OF THE INVENTION TECHNICAL TASK

The object of the present invention is to provide a way by which the position of the end of the contact rod can be determined easily and safely. This allows automated manipulations at the end of the contact rod end of the probe holder, such as automated insertion of the probe holder into the probe or feeding a cleaning device to the probe holder.

TECHNICAL SOLUTION

The object is achieved by a method for determining the position of the free end of a contact rod on a probe holder, wherein the probe holder is held movably by means of a holding and moving device, characterized in that it comprises the steps: [0014] in that the free end of the contact rod is set with the setting of the holding and moving device in a surveying starting position of the holding and moving device in a measuring range of a measuring device, wherein the measuring device is in a surveying starting position and then the movement of the probe holder and / or the measuring device takes place in three spatial directions relative to each other until [0019] - either in each of the three spatial directions through the contact rod, a detector of the

Surveying device was triggered, or in at least one of the three spatial directions a preset maximum Aus measure of movement is exceeded without a detector of the surveying device was triggered, [0021] FIG each of the three spatial directions is determined the extent of the movement of the probe holder by means of the holding and moving device and / or the extent of the movement of the measuring device [0024] until the triggering of the detector.

The contact rod has two ends. One of these ends is connected to the probe holder. The other end of the contact rod is referred to as the free end of the contact rod.

ADVANTAGEOUS EFFECTS OF THE INVENTION

By this procedure it is achieved that the probe holder can be reliably automated inserted into the probe, or automated supply of a cleaning device can be done to the probe holder.

The contact rod breaks off relatively easily when forces act on him, especially when the forces do not act in the direction of its longitudinal axis. It is therefore generally not bent when forces are applied, but breaks off. Therefore, it can be assumed that if a contact rod is present -so it has not broken off -this contact rod is unbent. In that case, the contact rod forms a straight extension of the contact rod end portion of the probe holder. Accordingly, from the position of the free end of the contact rod, it is easy to close the position of the contact-rod-side end portion of the probe holder. On this contact rod end portion of the probe holder, the probe is plugged or attacks a cleaning device.

By the method according to the invention, the distance of the free end of a contact rod from the detectors - or to the boundaries of the space areas, upon entering the detectors are triggered - the measuring device determined. The positions of the detectors - or the areas of space upon which the detectors are triggered - are known. Likewise, the spatial position of the surveying device in the surveying start position of the surveying device to the holding and moving device in the surveying start position of the holding and moving device is known.

The detectors can be triggered, for example, when touched by the contact rod - for example, provided with electrical contacts limitations of Vermessungsbereiches-, or they can be triggered when the contact rod enters a monitored area of them space - for example, in detectors with light barriers or ultrasonic barriers.

To illustrate the following example serve: when the holding and moving device holds an unobstructed contact rod, the end of the contact rod - in positioning the holding and moving device in the surveying start position of the holding and moving device, and positioning the surveying device in the surveying start position of the surveying device - in the direction of the x-axis of a three-dimensional Cartesian coordinate system a cm from a detector - or to the boundary of the spatial region upon which the detector is triggered - removed, in the direction of the y-axis of the three-dimensional Cartesian Coordinate system b cm of a detector - or to the boundary of the space area, upon entering the detector is triggered - removed, and in the z-axis direction of a three-dimensional Cartesian coordinate system c cm of a detector - or to the boundary of the space area, b when it enters the detector is triggered - removed. In case of immovable surveying 3/17 Austrian Patent Office AT510 292 B1 2012-03-15

Device, the contact rod must be moved by means of the holding and moving device of the probe holder to a certain extent in the three spatial directions, so that in each spatial direction, a detector is triggered. The amount of movement in this example is a cm in the x-axis direction, b cm in the y-axis direction, and c cm in the z-axis direction. The fact that the determination of the extent of the movement until the detection of the detectors gives these values, it can be deduced that the tip of the contact rod - when positioning the holding and moving device in the survey start position of the holding and moving device, and positioning the Measuring device in the surveying start position of the surveying device - with these distances from the detectors -beziehungsweise to the limits of the area where they enter the detector are triggered - is removed.

With a probe holder that is bent in one or more spatial directions, the detectors are triggered to a greater or lesser extent of motion.

To trigger the detectors, the contact rod can be moved by moving the probe holder while the surveying device remains stationary. The surveying device can also be moved while the probe holder remains stationary with the contact rod. It is also possible to move both the probe holder with the contact rod and the measuring device.

The movement of the probe holder with contact rod and / or the measuring device relative to one another takes place so far in three spatial directions until the detectors were triggered in all three spatial directions. In this case, probe holders with contact rod and / or measuring device can be moved one after the other in a respective spatial direction until a detector is triggered in the respective spatial direction. It is also possible for probe holders with contact rod and / or measuring device to be moved simultaneously in two or three spatial directions.

The movement of the probe holder and / or the measuring device is limited to a presettable by the operator of the method maximum extent. If this preset maximum amount of movement is exceeded without a detector being triggered, the movement will be stopped. The lack of triggering of a detector indicates that either the probe holder or the contact rod is bent beyond an acceptable level, or is bent such that the contact rod is out of range, or that the contact rod is not present at all, for example he broke off. In these cases, replacement of the probe holder with contact rod and / or contact rod is necessary.

The maximum amount of movement can be selected and preset by the operator of the method according to the invention. It is, for example, chosen so that the measuring probe can still be introduced even with bent probe holder through the opening provided for this purpose in a vessel with liquid metal. If the probe holder is bent so much that the measuring lance would no longer be able to pass through this opening, this bending beyond the acceptable extent can be determined by moving the probe holder and / or the measuring device to the maximum extent preset by the operator of the method the movement no detector is triggered. In this way, the absence of the contact rod can be determined.

By the method according to the invention, the spatial position of the free end of a contact rod on a sample holder, which is held by a holding and moving device in surveying start position defined. If this holding and moving device is moved from the survey start position to a new position that is spatially precisely defined relative to the survey start position, the new position of the free end of the contact bar is also defined. Accordingly, an automated supply of probes or cleaning devices is possible. In this case, either the probe can be automatically brought to the free end of the contact rod, or the contact rod is automatically brought to the probe, or probe and contact rod are approached each other 4/17 Austrian Patent Office AT510 292B1 2012-03-15 leads; The same applies mutatis mutandis to the introduction of cleaning device to the probe holder.

According to one embodiment of the present invention, after determining the position of the free end of the contact rod on the probe holder, the probe holder is subjected to a predetermined degree of bending. Since the position of the contact rod-side end of the probe holder is known before the bending, and the bending itself takes place to a defined extent, the position of the contact rod-side end of the probe holder is also known after the bending. Accordingly, an automated supply of probes or cleaning devices is just as possible as if no bending takes place. The advantage of defined deflection, for example, is that the holding and moving device, automated probe delivery devices, or automated device delivery devices need to be moved less widely to interact with the probe holder - plugging the probe, cleaning the probe holder enable.

Another object of the present invention is an apparatus for carrying out the method according to the invention. Such a device comprises a holding and moving device for a probe holder with contact rod, and is characterized in that it also comprises - a measuring device with measuring range with detectors which can be triggered by the contact rod, [0040] - as well as a device for determining a triggering [0041] - and a device for determining the extent of movement of the probe holder [0043] by means of the holding and moving device until the triggering of a detector of the measuring device by the contact rod, [0044] starting from a defined survey Start position of the holding and moving device and from a surveying start position of the surveying device.

The holding and moving device for the probe holder with contact rod is used in the case of movement, of course, for the defined movement of the probe holder with contact rod, that is, the extent of movement in all spatial directions is controllable and detectable. Accordingly, defined movement is to be understood in the device for the defined movement of the measuring device.

The holding and moving device for a probe holder with contact rod can be designed, for example, as a movable robot arm with gripper system. It may also be, for example, the measuring lance held by a manipulator or movable by the manipulator, to which the probe holder is fastened.

The measuring device can be made stationary.

Another object of the present invention is a further device for carrying out the method according to the invention. Such a device comprises a holding and moving device for a probe holder with contact rod, and is characterized in that it also comprises - a surveying device with measuring range with detectors which can be triggered by the contact rod, [0050] - as well as a device for determining a triggering of a detector, as well as a device for defined movement of the measuring device and a device for determining the extent of a movement of the measuring device [0054] up to the triggering a detector of the surveying device by the contact rod, starting from a defined survey start position of the holding and moving device and from a survey start position of the surveying device.

The measuring device can be designed, for example, as a tool for a movable robot arm with or without a gripper system.

Another object of the present invention is a further device for carrying out the method according to the invention. Such a device comprises a holding and moving device for a probe holder with contact rod, and is characterized in that it also comprises - a measuring device with measuring range with detectors which can be triggered by the contact rod, [0059] - as well as a device for determining a triggering of a detector, [0060] - as well as a device for the defined movement of the measuring device [0061] - and a device for determining the extent of a movement of the measuring device until the triggering of a detector of the measuring device by the contact rod, [0063] and determination [ 0064] of the amount of movement of the probe holder by means of the holding and moving device - starting from a defined measuring start position of the holding and moving device and from a surveying starting position of the surveying device.

The holding and moving device for the probe holder with contact rod is used in the case of movement, of course, for the defined movement of the probe holder with contact rod, that is, the extent of movement in all spatial directions is controllable and detectable. Accordingly, defined movement is to be understood in the device for the defined movement of the measuring device.

A detector is understood to mean a device which emits a signal through the contact rod when it touches the contact rod or upon entering the area monitored by the device for changes in a prevailing state, that is to say it is triggered. The detectors can be, for example, light barriers, for example with laser or infrared light. Such detectors are triggered when the contact rod at least partially interrupts the beam of the laser or infrared light.

The detectors may also be ultrasonically sound barriers, or they may be capacitive or inductive detectors, which can detect changes in the area of space detected by their field by entering the contact rod in this area of space.

It may also be electrical switching contacts, which are triggered directly or by means of mechanical deflection, such as flag end switch act. Such detectors are mounted, for example, on a measuring range limiting walls and are triggered by the contact rod contact.

The device for determining the triggering of a detector can be selected from the repertory known to the person skilled in the art of determining the triggering of a detector within the meaning of the present invention. For example, the detectors can emit electrical signals that are received by a remote station with evaluation electronics, such as a control and regulating device. Delivery of radio signals or other types of signals may also be provided.

The holding and moving device for a probe holder, for example, be designed as a movable robot arm with gripper system, or as a manipulator for the measuring probe. The measuring device can be designed, for example, as a tool for a movable robot arm, with or without a gripper system. It can also be made stationary.

According to one embodiment, the device according to the invention also comprises a bending device for the controlled bending of the probe holder.

By means of such a bending device, the probe holder, after determining the position of its intended to receive a metallurgical probe end of a deflection in a defined extent be subjected. For controlled bending, the bending device can be held immobile after insertion of the probe holder, while the holding and moving device and thus the probe holder is moved to a defined extent. It is also possible to hold the holding and moving device and thus the probe holder immobile after insertion of the contact rod in the bending device and to move the bending device in a defined extent. In principle, both holding and moving device - and thus the probe holder - and bending device can be moved relative to each other in a defined extent.

The bending device can be embodied, for example, as a movable tool for a robot arm, with or without a gripper system. It can also be made stationary. According to one embodiment of the device according to the invention, there is a tool for a robot arm which has both the bending device and the measuring device.

According to one embodiment of the device according to the invention, the bending device is designed as a tool graspable by a gripper system of a tool containing the measuring device for a robot arm.

According to one embodiment, the device according to the invention also comprises a cleaning device for cleaning the probe holder and / or the measuring lance head carrying the probe holder.

For cleaning, the cleaning device can be held immobile after partial or complete insertion of the probe holder, while the holding and moving device and thus the probe holder is moved to a defined extent. It is also possible to hold the holding and moving device and thus the probe holder immobile after introduction of the probe holder in the cleaning device and to move the cleaning device in a defined extent. In principle, both holding and moving device - and thus the probe holder - and cleaning device can be moved relative to each other to a defined extent. During the relative movement between the cleaning device and the probe holder, the probe holder is cleaned by mechanical action. The relative movement may, for example, be circular, or a forward and backward movement within a certain angular range about the longitudinal axis of the probe holder, or rectilinear - for example, forward and backward movement in the direction of the longitudinal axis of the probe holder, or hybrid forms of such movements.

These remarks also apply mutatis mutandis to the cleaning of the measuring lance head carrying the probe holder.

The cleaning device has cleaning agents that act on the contamination of the probe holder and / or the probe holder bearing measuring lance - for example, a teeth-equipped cleaning crown, in the opening of the probe holder and / or the probe holder bearing measuring lance is introduced. The cleaning agents may have their own drive units, so that in addition to the relative movement between the cleaning device and the probe holder and / or the measuring lance head carrying the probe holder, a relative movement between the cleaning agent and the probe holder and / or the measuring probe head carrying the probe holder can take place.

The cleaning device can be designed, for example, as a tool for a movable robot arm. It can also be made stationary.

According to one embodiment of the device according to the invention, the cleaning device is designed as a gripper system of a tool containing the measuring device for a robot arm tangible tool.

When the cleaning device and the bending device are designed as components graspable by a gripper system of the surveying device, it is advantageously possible to combine either the bending device or the cleaning device with the measuring device as needed. This reduces the expenditure on equipment for providing a bending function and a cleaning function.

BRIEF DESCRIPTION OF THE DRAWINGS

Further advantages and details emerge from the following description of exemplary embodiments in conjunction with the drawings. FIG. 1 shows, in a sequence of 3 figures 1a, 1b, 1c, how it is bent

Probe holder can come.

Figure 2 shows a section of a device according to the invention in schemati shear representation, in which the probe holder is moved to determine the position of the free end of the contact rod.

FIG. 3 shows a detail of a device according to the invention, in which a bent probe holder is subjected to a defined bending.

FIG. 4 shows a detail of a device according to the invention, in which a soiled probe holder is cleaned by means of a cleaning device.

DESCRIPTION OF THE EMBODIMENTS

1a shows a longitudinal section through the lower portion of the body of a measuring lance 1, on the probe holder 2 a hüttentechnische probe 3 is attached. For clarity, only the shell of the probe 3 is shown, but not in the probe existing measuring equipment. Attached to the probe holder 2 is a contact rod 4, via which signals of the measuring apparatuses in the probe 3 are forwarded into the probe holder 2 and subsequently into the body of the measuring probe 1. In a metallurgical vessel 5, in this case a converter, liquid metal 6 and scrap 7 is present. The measuring lance 1 is moved by means of a manipulator, not shown, in the direction of molten metal 6 downwards. Figure 1 b shows how the probe 3 impinges on a piece of scrap 7 during the downward movement, the impact being represented by a serrated star. The inclusion of not essential for the presentation of this situation reference numerals has been omitted for reasons of clarity. Figure 1c shows that the probe holder 2 was bent by the impact.

FIG. 2 shows part of a holding and moving device 8 for the probe holder 2 with contact rod 4. In this case, this holding and moving device 8 is provided by a manipulator acting on the measuring lance. By means of the holding and moving device 8, the measuring lance 1 and thus also the probe holder 2 can be moved defined with contact rod 4, for example, in the surveying start position of the holding and moving device. Shown is the holding and moving device 8 in its survey start position. The defined movement is controlled and, with the appropriate design, can be used by the Austrian Patent Office AT510 292B1 2012-03-15

Moving device 8 done in all three spatial directions of a Cartesian coordinate system. The amount of movement is detectable by means of a device for determining the amount of movement by means of the holding and moving device 9, which is connected to the holding and moving device 8 by means of signal line 10. The signal line 10 is designed as physically present line, but it could also be designed as a radio signal transmission.

The measuring device 11 is arranged on a tool 15 graspable by a robot arm 14. By means of the robot arm 14, the tool 15 and thus the measuring device 11 can be moved in all three spatial directions of a Cartesian coordinate system until detectors of the measuring device 11 are triggered. To determine the extent of such movement, a device for determining the extent of movement of the surveying device until the triggering of a detector of the surveying device by the contact rod is present. In the illustrated case, this device for determining the extent of movement of the measuring device until the triggering of a detector of the measuring device by the contact rod is at the same time the device for determining the extent of a movement taking place by means of the holding and moving device 8. The robot arm is connected via signal line 16 to the device for determining the extent of movement of the measuring device until the triggering of a detector of the measuring device by the contact rod. The signal line 16 is designed as physically present line, but it could also be designed as a radio signal transmission.

By the movement of the tool 15 and thus of the measuring device 11 in the direction of the three spatial directions of the Cartesian coordinate system outlined by arrows, the contact rod 4 strikes the walls 11a, 11b, 11c, which bound the surveying area in the dashed rimmed surveying device 11. The walls 11a, 11b, 11c are provided with switching contacts and thus act on contact by the contact rod 4 as detectors, which are triggered by the touch. Via signal line 12, the triggering is reported to a first control and regulating device 13. In Figure 2, signal line 12 is shown connected only to wall 11b, but it also serves to signal tripping of detectors on walls 11a and 11c, which has not been shown in the drawing for clarity. The signal line 12 is designed as physically present line, but it could also be designed as a radio signal transmission. The first control and regulating device 13 also serves as a device for detecting a triggering of a detector. To determine the position of the free end of the contact rod 4, the holding and moving device 8 and the measuring device 11 are first brought into a surveying start position of the holding and moving device 8 or in a surveying start position of the surveying device 11.

By a second control and regulating device 17, the device for determining the extent of a movement by means of the holding and moving device 9, which at the same time a device for determining the extent of movement of the surveying device to the triggering of a detector of the surveying device through the Contact rod is connected to the first control and regulating device 13 via signal lines 18 and 19. Each of the signal lines 18 and 19 is designed as physically present line, but they could also be designed in each case as a radio signal transmission. The second control and regulating device receives information about the movements of the tool and could also receive information about their movements when moving the measuring lance. It also receives information about the triggering of the detectors of the measuring device 12 and the necessary amount of movement. Based on this information, the movements are controlled and regulated. Links of the second control and regulating device 17 with the drives for the motions are not shown separately for the sake of clarity.

In the method shown in Figure 2, the measuring lance 1 and the probe holder 2 is not moved to determine the position of the free end of the contact rod. The 9/17 Austrian Patent Office AT510 292B1 2012-03-15

Position of the free end of the contact rod is determined by movement of the arranged on the tool 15 measuring device 11 by means of the robot arm 14.

However, the position of the free end of the contact rod could also be determined by means of a defined movement of the measuring lance or of the probe holder 2, without the measuring device 11 arranged on the tool 15 being moved by means of the robot arm 14. In principle, defined movement of the measuring device 11 arranged on the tool 15 by means of the robot arm 14 and the measuring lance 1 or of the probe holder 2 could also take place for determining the position of the free end of the contact rod.

FIG. 3 shows a detail of a device according to the invention, while a bent probe holder 2 is subjected to a defined bending. Robot arm 14 engages a tool 20, is arranged on the measuring device 11. As in Figure 3, the walls 11a, 11b, 11c are provided with switching contacts and thus act on contact by the contact rod 4 as detectors, which are triggered by the touch. Via signal line 12, the triggering is reported to a first control and regulating device 13. The analogous to Figure 2 parts of the device act as described in Figure 2. The tool 20 has a gripper system with two gripper fingers 21 a, 21 b, which comprises a bending device 22 for the controlled bending of the probe holder 2. In the case shown, as a result of a determination as described in FIG. 2, information about the position of the free end of the contact rod 4 and thus also about how strongly the probe holder 2 is bent in which directions exists in the second control and regulation device 17. The second control and regulation device 17 is now not signal cables shown to the robot, not shown, on which the robot arm 14 is movably mounted, that a movement of the robot arm and thus the bending device 22 for controlled bending of the probe holder 2 should be such that the probe holder is bent in a predetermined by the second control and regulating device 17 in a direction predetermined by the second control and regulating device 17 direction. In the case shown, this is done by driving the robot arm 14 to the left after introduction of the probe holder 2 into the hole 23 of the bending device 22 for controlled bending of the probe holder 2. At the beginning of the process of bending to a defined extent, the position of the probe holder 2 in the hole 23 is known, since the probe holder 2 has only been moved in a defined manner after determining the position of the free end of the contact rod in the measuring range of the measuring device 11. Due to the knowledge of this position, the hole 23 of the bending device 22 for controlled bending of the probe holder 2 is pushed by the robot arm on the probe holder 2, wherein this movement is defined. Accordingly, the position of the probe holder 2 in the hole 23 is known. With this information, the second control device 17 calculates to what extent the robot arm 14 must be moved to the left to achieve a certain degree of deflection of the probe holder. Crosses with double arrows indicate in Figure 3, in which directions the movement of the robot arm 14 and thus of the bending device 22 for controlled bending of the probe holder 2 can take place.

FIG. 4 shows a detail of a device according to the invention, while a cleaning device 24, which is designed as a tool graspable by a gripper system of a tool that holds the measuring device for a robot arm, cleans a soiled probe holder and the measuring lance head carrying the probe holder. The device is up to the presence of the cleaning device 24 instead of the bending device 22 for controlled bending of the probe holder 2, and except for a different embodiment of the measuring device 11, analogous to the device described in Figure 3. Accordingly, the representation of analog device parts was omitted for the sake of clarity. Just as in the description of FIG. 3, the bent device 22 for controlled bending of the probe holder 2 is pushed over the probe holder in a defined manner, in FIG. 4 the cleaning device 24 is pushed over the probe holder 2. In the illustrated case, the probe holder 2 is not bent. While not moving, the robotic arm performs a forward and backward movement in the direction of the longitudinal axis of the probe holder represented by straight and curved double arrows, and a forward and backward movement within a particular one Angular range around the longitudinal axis of the probe holder. The probe holder 2 is thereby freed of these contaminants 26 by a cleaning agent, in this case a teeth-equipped cleaning crown 25, by mechanical action of the teeth on contaminants 26 of the probe holder. It is shown how scrapings scraped off by the teeth 26 fall off the probe holder 2.

In FIG. 4, the measuring range of the measuring device 11 is limited by light barriers 27 whose light beams are shown in dashed lines.

LIST OF REFERENCE SIGNS 1 2 3 4 5 6 7 8 9 10 11 11a, 11b, 11c 12 13 14 15 16 17 18 19 20 21a, 21b 22 23 24 25 26 27

measuring probe

probe holder

probe

Contact staff

Metallurgical vessel

Liquid metal

scrap metal

Holding and moving device 8 for the probe holder 2 with contact rod Device for determining the extent of a movement / device for determining the extent of movement of the measuring device by means of the holding and moving device 8 until a detector of the measuring device is triggered by the contact rod Signal line measuring device wall

signal line

First control and regulating device

robot arm

Tool

signal line

Second control device

signal line

signal line

Tool

gripping fingers

Verbiegevorrichtung

hole

cleaning device

cleaning crown

pollution

Photocell 11/17

Claims (9)

Austrian Patent Office AT510 292 B1 2012-03-15 Claims 1. A method for determining the position of the free end of a contact rod (4) on a probe holder (2), said probe holder (2) being movably held by a holding and moving device (8) characterized in that it comprises the steps of: - inserting the free end of the contact rod (4) into a surveying area of a surveying device (11), setting the holding and moving device (8) in a surveying starting position of the holding and moving device with the surveying device (11) in a surveying start position of the surveying device, and then movement of the probe holder (2) and / or the surveying device (11) so far in three spatial directions relative to each other, until - in either of the three Spaces through the contact rod (4) a detector of the surveying device (11) was triggered, - or in the in any one of the three spatial directions a preset maximum amount of movement is exceeded without triggering a detector of the measuring device (11), wherein for each of the three spatial directions the extent of movement of the probe holder (2) by means of the holding and moving device (8) and / or the extent of movement of the surveying device (11) is determined until the triggering of the detector. 2. The method according to claim 1, characterized in that the probe holder (2) after determining the position of the free end of the contact rod (2) on the probe holder (2) is subjected to a deflection taking place to a defined extent. 3. A device for carrying out a method according to claim 1 or 2, comprising a holding and moving device (8) for a probe holder (2) with contact rod (4), characterized in that it comprises - a surveying device (11) with surveying range with the detector rod triggerable detectors, - and a device for detecting a triggering of a detector, - and a device for determining the extent of a means of the holding and moving device (8) movement of the probe holder (9) to the triggering of a detector of the surveying device (11 ) by the contact rod (4), starting from a defined survey start position of the holding and moving device (8) and from a survey start position of the surveying device (11). 4. A device for carrying out a method according to claim 1 or 2, comprising a holding and moving device (8) for a probe holder with contact rod (4), characterized in that it comprises - a surveying device (11) with survey area with by the contact rod ( 4) triggerable detectors, - and a device for detecting a triggering of a detector, - and a device for defined movement of the surveying device (11) and a device for determining the extent of movement of the surveying device (9) until the triggering of a detector of the surveying device the contact rod (4), starting from a defined survey start position of the holding and moving device (8) and from a survey start position of the surveying device (11). 12/17 Austrian Patent Office AT510 292 B1 2012-03-15 5. The device according to claim 4, characterized in that it comprises a device for determining the extent of taking place by means of the holding and moving device movement (9) of the probe holder (2) until the triggering of a detector of the surveying device (11) by the contact rod (4 ), starting from a defined survey start position of the holding and moving device (8) and from a survey start position of the surveying device (11). 6. Device according to one of claims 3 to 5, characterized in that it comprises a bending device (22) for the controlled bending of the probe holder (2). 7. The device according to claim 6, characterized in that the bending device (22) as by a gripper system of the surveying device (11) containing tool (20) for a robot arm (14) tangible tool is executed. 8. Device according to one of claims 3 to 7, characterized in that it comprises a cleaning device (24) for cleaning the probe holder (2) and / or the probe holder (2) carrying the measuring lance head. 9. The device according to claim 8, characterized in that the cleaning device (24) is designed as a gripper system of a surveying device containing tool for a robot arm tangible tool. 4 sheets of drawings 13/17