WO2006125543A2

WO2006125543A2 - Sliding closure for metallurgical vessels

Info

Publication number: WO2006125543A2
Application number: PCT/EP2006/004534
Authority: WO
Inventors: Pierre Gerber; Roland BÜHLMANN
Original assignee: Stopinc Aktiengesellschaft
Priority date: 2005-05-25
Filing date: 2006-05-15
Publication date: 2006-11-30
Also published as: US20090134161A1; WO2006125543A3; EP1888274A2

Abstract

Disclosed is a sliding closure for metallurgical vessels, comprising at least two fireproof closing parts that can be braced against each other by means of spring elements (5). At least one measuring apparatus (10) is provided for measuring the distance of the housing parts or the closing parts from each other regarding the displacement thereof transversal to the sliding areas while at least one temperature gauge is provided which is connected to an evaluation unit (20). The apparatus (10) for measuring the position of the closing parts encompasses exploring coils (12, 13) that are mounted next to each other and a core (15) located in a central opening (11a) in said coils, each of which is arranged in one of the two housing parts and which jointly form a differential throttle. The core (15) can be adjusted perpendicular to the sliding areas when the distance between the two housing parts changes, whereby a tension can be generated which can be transmitted to the evaluation unit (20). Said measurement makes it possible to improve the operational safety of such a sliding closure.

Description

Sliding closure for metallurgical vessels

The invention relates to a sliding closure for metallurgical vessels according to the preamble of claim 1.

A sliding closure of this type is disclosed in WO 03/080274. Closures of such sliding closures are known to be exposed to heavy wear and must therefore be replaced frequently. For economic reasons, however, it is endeavored to use these closure plates as long as possible. Nevertheless, in order to ensure a high degree of operational reliability and to detect impending malfunctions at an early stage, it is known from WO 03/080274 that Sliding closure equipped with at least one measuring device with which the position of the sliding surfaces against each other sliding closure plates can be measured and evaluated with respect to their change transversely to the sliding surfaces. With the measurement of the distance between the housing parts receiving the respective closure plate, the changes in the closure plate position, as they occur, for example, when the molten steel penetrates between the closure plates and forms a thin sheet there, can be diagnosed early. Thus it can be prevented that uncontrolled steel melt flows out between the closure plates.

The problem with the measurement of the closure plate position lies in the large temperature range in which the distance or the distance change must be measured. The temperature difference between the start temperature (eg 24 ° C) and the end temperature (eg 345 ⁰ C) is considerable (here 321 ⁰ C). The distance in the cold and hot state may differ by a few millimeters.

The present invention has for its object to provide a sliding closure of the type mentioned, which has a high reliability, and in the unacceptable with little effort deviations in the closure plate position, taking into account temperature-related distance changes can be determined with sufficient accuracy.

This object is achieved according to the invention by a sliding closure with the features of claim 1. Further preferred embodiments of the inventive sliding closure form the subject of the dependent claims.

The slide fastener according to the invention is equipped with a measuring device which comprises two measuring coils mounted side by side on a bobbin mounted in one of the two housing parts and a core which is longitudinally adjustable in the axial direction of the bobbin and forms a differential inductor. In the case of a change in distance of the two housing parts transversely to the sliding surfaces of the closure plates, the core is displaced from a position opposite the measuring coils, thereby generating a voltage which is transmitted to an evaluation unit. With the measuring device good reproducibility of the measurements of distance changes at different temperatures has been achieved. The temperature drift is small due to the compensation of the two measuring coils in terms of their resistance change, which allows the implementation of a formula-based temperature compensation. As a result, distance changes in a measuring range of 8 mm can be determined with an accuracy of less than 0.1 mm. The sliding gate according to the invention thus has a high level of operational reliability. Breakdowns and in particular breakthroughs, in which often the entire sliding closure mechanism and possibly also parts of the continuous casting plant can be destroyed, can be largely avoided. It can also be detected incorrect mounting on the sliding closure and also resulting breakthroughs can be prevented.

The invention will be explained in more detail with reference to the drawing. Show it: 1 shows in cross section a part of a sliding closure according to the invention with a built-in measuring device;

FIG. 2 shows schematically the basic parts of the measuring device according to FIG. 1; FIG. and Fig. 3 is a circuit diagram of the measuring device for measuring and evaluating the shutter plate position.

Fig. L shows a part of a slide fastener having in a known manner at least two mutually bracing refractory closure plates as closure parts, which are each arranged in a housing part and sliding surfaces against each other. It may be, for example, a sliding closure, which corresponds to that according to WO 03/080274, Fig. 2, and a stationary, attached to a vessel, upper housing part with a closure plate and a movable opposite, provided with the other closure plate Having the lower housing part, wherein the movable housing part and with it the other closure plate by a drive member in a closing or open position is displaceable. The closure plates themselves are not apparent from Fig. 1, and of the housing parts, only one housing part 1 is shown, wherein it is the stationary upper housing part in the illustrated embodiment.

In the stationary housing part 1, similar to the slide closure according to WO 03/080274, FIG. 2, a guide unit 2 is installed which has a guide pin 4 accommodated in a housing 3, at the lower end 4a of which at least one guide element, eg a guide roller, preferably two parallel guide rollers, which are not apparent from Fig. 1, is attached. At the periphery of the guide pin 4, a spring element 5 is arranged, on the one hand on a lower shoulder surface 3a of the housing 3 and on the other hand is supported on the guide pin 4 and presses the guide pin 4 upwards and with him the guide roller from below to a guide track of the movable housing part. In the upper part of the housing 3, a support ring 17 is further held, which serves as a stop of the bobbin 11 and the Führunsbolzens 4.

As is known, several such guide units 2 with spring elements 5 are installed in the stationary housing part 1, via which the lower housing part is pushed upwards and the closure plates are braced against one another.

According to FIG. 1, one of these guide units 2 is assigned a measuring device 10 for measuring the closure plate position with respect to its change transversely to the sliding surfaces. The basic parts of this measuring device 10 are also shown in FIG. 2, Fig. 3 shows a corresponding circuit diagram. The measuring device 10 comprises two measuring coils 12, 13 (FIG. 2) mounted on a bobbin 11 and a magnetic core 15 which is longitudinally displaceable in the axial direction of the bobbin via a non-magnetic drawbar 16 and which is located in a central opening 11a of the bobbin 11 Forming a differential throttle. In a bridge circuit, the voltage changes caused by the movements of the magnetic core 15 can be measured from a central position shown in FIG. 2 (middle between the two measuring coils 12, 13). The differential choke can be operated with a commercially available carrier frequency amplifier 19 with integrated phase rectifier 19 (FIG. 3).

According to the invention, the core 15 is associated with the guide unit 2 or its spring-loaded guide pin 4, with the pull rod 16 frontally mounted in the guide pin 4 at its upper end. In the stationary housing part 1, the bobbin 1 1 with the measuring coils 12, 13 (FIG. 2) is installed above the guide unit 2, such that the pull rod 16 projects with the core 15 into the central opening II a.

With the measuring device 10, the changes in the distance of the two sliding closure housing parts or the two closure plates can be measured transversely to their sliding surfaces. For example, if molten steel penetrates between the closure plates, then a thin sheet may form there, which forces the closure plates apart. As a result, the lower housing part is pressed against the force of the spring elements 5 and its guideways and the guide rollers carrying guide rollers 4 down. Also equipped with the pull rod 16 and the core 15 guide pin 4 is moved in the housing 2 against the force of the spring element 5 down and the core 15 from its central position, in which the measuring voltage is zero, adjusted, creating a voltage now, which is transmitted via the phase rectifier 19 of the evaluation unit 20. This voltage is compared with the voltage measured at room temperature of a reference coil 21 (FIG. 3), which is likewise transmitted to the evaluation unit 20.

To the evaluation unit 20, a temperature-measuring device is connected, which comprises close to the closure plates arranged, not visible from the drawing temperature sensor.

As already mentioned, the measured distance between the two sliding closure housing parts or between the two closure plates is temperature-dependent. In order to computationally compensate for the temperature-related deviations, a measuring device had to be found can be achieved with the reproducible measurement results. With the measuring device 10 acting from differential throttle, good reproducibility was achieved in measurements; the temperature drift is due to the compensation of the two measuring coils 12, 13 (in terms of their resistance change) substantially smaller than in other, also proven measuring systems (eg plunger anchor system). Thanks to the good reproducibility, it is possible to perform a formula-based temperature compensation. As a result, distance changes in a measuring range of 8 mm can be determined with an accuracy of less than 0.1 mm.

The sliding closure according to the invention, equipped with the measuring device 10 acting as a differential throttle, has a high level of operational reliability. Breakdowns and in particular breakthroughs, in which often the entire sliding closure mechanism and possibly also parts of the continuous casting can be destroyed, can be largely avoided. It can also be detected incorrect mounting on the sliding closure and also resulting breakthroughs can be prevented.

It would of course quite possible to install the bobbin 1 1 in the spring-loaded guide pin 4 and assign the core 15 to the stationary housing part 1.

For economic reasons, only one of the guide units 2, the measuring device 10 is assigned. However, it could certainly be provided in several places such measuring devices.

The measuring device 10 for measuring the distance or the distance changes between the two sliding closure housing parts could also be attached to a different location of the sliding closure than at One of the guide units 2. It could, for example - are arranged laterally to the housing parts - similar to the sliding closure according to WO 03/080274, Fig. 2, wherein here the displaceability of a housing part would have to be taken into account.

As sliding closure, a casting tube changer would also be conceivable, in which refractory casting tubes can be exchanged as closure parts. Instead of closure plates and closure sleeves or the like could be used.

Claims

1. Sliding closure for metallurgical vessels having at least two mutually bracing refractory closure parts, which are each arranged in a housing part on sliding surfaces against each other displaceable, for the bracing of the closure parts spring elements (5) are included in at least one of the housing parts, wherein at least one measuring device (10) for measuring the distance of the housing parts or the closure parts to each other in terms of their change transverse to the sliding surfaces and at least one temperature measuring device are present, which measuring devices (10) to an evaluation unit (20) are connected, characterized in that the measuring device (10) for measuring the closure parts position side by side mounted measuring coils (12, 13) and in a central opening (I Ia) located in this core (15), which are each arranged in one of the two housing parts and together form a Differentialdr ossel form, wherein the core (15) or the measuring coils (12, 13) at a distance change of the two housing parts transversely to the sliding surfaces adjustable and thereby a to the evaluation unit (20) can be generated transmittable voltage.

2. Sliding closure according to claim 1, characterized in that two on one in the two housing parts built-in bobbin (1 1) juxtaposed measuring coils (12, 13) and in the axial direction of the bobbin (11) longitudinally adjustable core (15) are provided, wherein the core (15) at a distance change of the two housing parts transverse to the sliding surfaces of a relative to the measuring coils (12, 13) central position is adjustable.

3. sliding closure according to claim 2, characterized in that the measuring device (10) for measuring the closure parts position of a stationary housing part (1) built-in guide unit (2) is assigned, which has a spring-loaded guide pin (4) which at least one of on one guideway of the displaceable housing part pressable guide elements carries, wherein one of the two relatively adjustable measuring device parts (bobbin with measuring coils / core) in the guide pin (4) is installed.

4. sliding closure according to claim 3, characterized in that the guide pin (4) carries at its lower end the guide element or the guide elements and is surrounded at its periphery by one of the guide elements to the guideways of the displaceable housing part from below pressureable spring elements (5) , wherein the magnetic core (15) by means of a non-magnetic tie rod (16) mounted on the front side at the upper end of the guide pin (4) and placed in the stationary, above stationary bobbin (1 1).

5. sliding closure according to claim I ₃ characterized in that one of the two housing parts with parallel to the sliding surfaces Füh- rungsbahnen and the other is provided with the guide tracks can be pressed guide elements.