EP1711292A1

EP1711292A1 - Slide plate

Info

Publication number: EP1711292A1
Application number: EP05791426A
Authority: EP
Inventors: Reinhard Ehrengruber; Carl Hoffmann; Robert Sherriff
Original assignee: Refractory Intellectual Property GmbH and Co KG
Current assignee: Refractory Intellectual Property GmbH and Co KG
Priority date: 2004-10-18
Filing date: 2005-09-16
Publication date: 2006-10-18
Anticipated expiration: 2025-09-16
Also published as: EG25557A; CN1968772B; DE102004050702B3; MXPA06014446A; EP1711292B1; US20070241486A1; UA80793C2; CA2567598C; WO2006042596A1; CA2567598A1; CN1968772A; EA200602261A1; AR051220A1; DE502005004395D1; ZA200609392B; ATE397987T1; ES2308547T3; US7703644B2; BRPI0512324A; EA009962B1

Abstract

The invention relates to a slide plate for a sliding closure on metallurgical melting crucibles.

Description

slide plate

Description

The invention relates to a slide plate for a slide closure on metallurgical melting vessels.

Slide plates, which are understood to mean both plates for linear slides and rotary valves, have been used for decades to control the outflow of metallurgical melting vessels, for example pans or so-called intermediate containers (tundish).

Such slide closures (slide systems) consist for example of two plates, a fixed and a movable plate. Both Plates have at least one flow passage for an associated molten metal, the opening being perpendicular to the main surfaces of the plates. The plates are movable relative to one another so that corresponding apertures of the plates can be offset, partially overlapping or aligned with each other to adjust the mass of the melt passed therethrough or to interrupt the melt flow.

Lock systems with more than two plates are also known.

In particular, the wall portion of the flow openings wears in the course of use. To improve the wear resistance (but also for repair purposes), it is known to arrange around the flow opening in the base body of the plate an annular insert made of a particularly wear-resistant material. The problem is the "connection" of the insert with the surrounding refractory material of the base plate.

From DE 100 06 939 C l it is known to einzumörteln the annular insert into a corresponding recess of the main body of the plate. For this purpose, it is necessary to mechanically prepare the base plate accordingly, for example to drill it out. This causes additional costs. In addition, only rotationally symmetric inserts can be used.

DE 100 06 939 C1 also mentions the possibility of using the ring-shaped insert by co-pressing it with the surrounding material refractory matrix material to be pressed. In this case, for example, a prefabricated insert is inserted into a mold and surrounded by mass, which is to form the body later. The mass is then pressed. This method is in principle applicable to any insert forms and easy to perform. However, it has the disadvantage that insert and surrounding body after the release from the press solve each other and creates a small gap between the insert and the base plate. Thus, the insert can later solve when using the slide plate in a slide closure of the surrounding body or even fall out.

A commonly used method is to encase a prefabricated insert body with a refractory hydraulic mass (a concrete). In this way, almost any use Geo¬ metrics can be used. During the heating, however, the hydraulic bond of the matrix material of the main body loses at least part of its strength. Only at temperatures well above 1000 ° C, a solid ceramic bond is generated. In this context, a "strength hole" is used, usually around 900 ° C. When using the slide plate, a strong temperature gradient forms between the area of the passage opening and the edge of the plate At the edge of the plate, the temperature is much lower, inevitably resulting in areas within the plate that are heated only to the "strength hole" (about 900 ° C). The wear of these plates is correspondingly high. Based on this prior art, the present invention seeks to provide a slide plate for a slide closure on a metallurgical melting vessel, which has a wear-resistant insert in the region of the passage opening for the molten metal, wherein the slide plate is to be produced in a simple process and on her total volume as constant as possible high strength (wear resistance) has.

To solve this problem, the invention is based on the cited prior art, in which the use is fixed in situ during compression of a refractory matrix material surrounding the insert for the base body in this. As far as the insert is described below as "annular" this may be "exactly annular", resulting in a circular shape of the outer peripheral portion of the insert. The term also includes forms in which the insert, stepped in the axial direction of its opening between opposite end faces, outside, that is designed with different outer diameters or designed with a conical peripheral surface. "Ring-shaped" furthermore also includes asymmetrical peripheral shapes and an off-center arrangement of the opening, in this respect ring-shaped only relies on the insert having an opening for passing the molten metal.

As described, however, during molding, a space (distance) is formed between the insert and the base body, usually in the form of an annular gap between the circumferential surface of the insert and the corresponding surface of the base body, which at least partially prevents frictional connection between the two. This space (gap) can also be multi-part.

According to the invention, this problem is solved by filling the space between the insert and the base body with an impregnating agent, which binds the base body to the insert in a force-locking manner. In its most general embodiment, the invention relates to a slide plate for a slide closure on a metallurgical melting vessel, having the following features:

a) the slide plate has a base body (2) of a refractory ceramic material, b) the base body (2) has at least one passage opening which is perpendicular to main surfaces of the base body (2), c) the base body (2) surrounds one annular insert (1) made of a refractory ceramic material, d) the insert (1) surrounds the passage opening on all sides at least in the area of a main surface of the main body (2) and aligns with this main surface, e) between insert (1) and base body (2 ) existing space (3) is filled with an impregnating agent, which connects body (2) and insert (1) non-positively.

The mentioned sections between insert and body, in which there is no positive connection between the two parts, are usually extremely narrow and have a width of usually <100 microns, often <10 microns. Such a narrow space (gap) can obviously not be filled with a mortar or the like. However, the use of a (liquid) impregnating agent makes it possible to fill this cavity (these cavities) and in this way to connect the two parts together.

In this case, the space can be filled with a carbonaceous impregnating agent. Such an impregnating agent may be, for example, a substance from the group: coal tar pitch, petrol pitch, phenolic resin.

After removal from the press, the slide plate is impregnated (impregnated) with such a substance and then tempered on the plate Temperatures between 200 and 700 ° C, so cokoes the impregnation agent and solidifies, creating the desired frictional Ver¬ bond between annular insert and surrounding body. The gap or gaps between the two components are thus connected by means of a continuous carbon layer.

In this case, the impregnation can be limited to the aforementioned transition region between insert and body. But it is also possible to choose the impregnation range larger, up to the impregnation of the entire plate.

The impregnation has the additional advantage that the tightness of the plate as a whole in the impregnated region is increased and its sliding properties are improved.

The impregnation can be optimized if both the use and the material of the main body before impregnation have an open porosity between 5 and 20% by volume. The open porosity of the body will usually be higher than that of the insert, since the insert is already used as a preformed, usually pre-pressed part.

The choice of material as well as the pressing technique can be selected so that the space to be filled between the insert and the base body has a width < _. 70 microns, for example between 20 and 70 microns has. This can be adjusted, for example, by selecting the grain size for the insert or the base body.

While the use is usually used as a pre-pressed part, the base body can optionally also be created by casting. The gap is then usually slightly higher, so that the width of the space (gap) between the insert and the base plate before impregnation and after any drying of the plate may be greater than the mentioned 100 microns. Moreover, the features described in the prior art with regard to material selection can also be transferred to the slide plate according to the invention. Thus, the insert will generally have a higher wear resistance than the main body. This can be used for the body cheaper material qualities, which reduces the price of the slide plate as a whole.

Usually insert and body are made of different refractory ceramic materials.

A suitable material for use is a material based on ZrO ₂ . For example, materials based on Al ₂ O ₃ can be used for the base body.

Although the slide plate can be produced by different methods, as explained above, a method has proven to be advantageous in which a pre-pressed, annular insert made of a fireproof ceramic material in a pressing process in a base made of a refractory ceramic material, demoulded and the slide plate thus formed is then impregnated and tempered in the transition region between the insert and the base body with an impregnating agent.

Such a method was tested in the following experiment:

A fired annular insert of MgO stabilized zirconia was placed in a press mold. The insert was then surrounded with an alumina-based molding compound, in such an amount that the molding compound (for the formation of the body) projects beyond the upper end surface of the insert, to an extent such that after the subsequent pressing operation upper end surface of the base body is aligned with the upper end face of the insert. After removal of the thus pressed slide plate, this was impregnated in the range of a few millimeters on both sides of the transition region between the insert and the base body with liquid coal tar pitch and then tempered at 500 ° C.

As the attached Figure 1 shows, in the sharp transition between insert 1 and base 2 an approximately 5 microns wide layer 3 of coked coal tar pitch is microscopically detectable.

This filling layer creates a frictional connection between the insert and the envelope (main body). The insert is thus securely and reliably fixed relative to the body. In a follow-up field test, the slide plate could be tested together with a slide plate of the same construction to form a slide closure system. Six batches of steel were cast without the insert losing its non-positive connection in the main body.

The improved anchorage of the insert in the slide plate was tested in the following experiment, as shown in Fig. 2:

The plate 10 is placed horizontally on a ring 12, wherein the insert 14 does not rest. The insert 14 has an outer diameter of 130 mm, an inner diameter of the bore of 80 mm and is 15 mm thick. From above, the plate is drilled at six points 16, which lie at a uniform angular distance on an imaginary circle, to the top 14o of the insert 14. A punch 18 with six corresponding pressure cylinders 20 is now inserted into the holes. The force was measured at which the insert 14 is destroyed or breaks out of the plate 10.

In each case 5 experiments were carried out on a inventively designed, annealed at 500 ° C slide valve plate (E) and on a similar slide plate without impregnation (S) and determines the average for each plate. For S, a value of 2 ± 1 kN was determined, for E, however, a value of 18 ± 3 kN.

The insert can extend over the entire height of the slide plate (perpendicular to the main surfaces). Likewise, it is also possible to graduate the outer diameter of the insert ring, corresponding to a corresponding gradation of the surrounding body. In this way, an additional mechanical security is provided that the ring rests reliably in use on a corresponding collar of Grund¬ plate and can not solve in the flow direction of the molten metal.

Claims

"Slide plate" P atentanspr che

Sliding plate for a slide closure on a metallurgical melting vessel, having the following features: a) the slide plate has a base body (2) made of a refractory ceramic material, b) the base body (2) has at least one passage opening perpendicular to main surfaces of the C) the base body (2) surrounds an annular insert (1) made of a refractory ceramic material, d) the insert (1) surrounds the passage opening on all sides at least in the area of a main surface of the base body (2) and aligns with it This main surface, e) a between insert (1) and body (2) existing space (3) is filled with an impregnating agent, which body (2) and insert (1) connects non-positively.

2. slide plate according to claim 1, the space (3) is filled with a carbon impregnant impregnated.

3. slide plate according to claim 1, whose space (3) is filled with an impregnating agent from the group: coal tar pitch, petrol pitch, phenolic resin.

4. slide plate according to claim 1, whose space (3) is a gap with a width <100 microns.

5. slide plate according to claim 1, which was tempered at temperatures between 200 and 700 ⁰ C.

6. slide plate according to claim 1, the base body (2) is pressed.

7. slide plate according to claim 1, the insert (1) is pressed.

8. slide plate according to claim 1, whose use (1) has a higher wear resistance than the main body (2).

9. slide plate according to claim 1, in the insert (1) and base body (2) consist of different refractory ceramic materials.

10. slide plate according to claim 1, whose use (1) consists of a material based on ZrO ₂ .

1 1. slide plate according to claim 1, whose base body (2) consists of a material based on Al ₂ O ₃ .

12. A method for producing a slide plate according to claim 1, wherein a pre-pressed, annular insert made of a refractory ceramic material in a pressing process in a base made of a refractory ceramic material, demolding and the slide plate thus formed then in the transition region between insert and body with a Impregnating agent is soaked and tempered.