DE2844951C2 - Use of a refractory ceramic material molded under pressure in a metal frame as a slide for a shut-off device for regulating the flow of molten metal - Google Patents

Description

Slide plates for slide closures on containers containing molten steel using refractory mixtures which are bonded to refractory concrete with an alumina cement as a binder are from the DE-OS 26 24 299 known

Usually gate valves are used as shut-off devices to regulate the flow of Metal melts are used in such a way that plates made of a refractory material are placed in a metal frame, e.g. B. plates of the type described in DE-OS 26 24 299. A pre-fired plate made of refractory Material is pressed into a metal frame, using a refractory mortar as a connecting material between the refractory plate and the metal frame. One disadvantage of the prior art is see therein: that the preformed refractory panels must be designed precisely and properly and that the connection between the the metal frame is not permanent, especially after prolonged use. By using a Mortar between the refractory plate and the metal frame can also result in uneven stress distributions in the arrangement. In addition, the manufacture of the slide is also according to the prior art The technology is expensive, because the refractory panels placed in a frame have to be of the correct shape beforehand pressed, then dried at low temperatures and finally fired at high temperatures and further firing is required when joining the fired refractory panels by means of a cement to the metal frame.

The object of the invention is to provide a metal frame integrally connected to a refractory ceramic material as a slide for a shut-off device for regulating the flow of molten metal.

This task is accomplished through the use of a chemical bond in a metal frame made from a mixture of ceramic particles and a chemical bond at lower, below conventional firing temperatures Binder formed under pressure between the ceramic particles, in direct contact with the metal frame standing refractory ceramic material as a slide for a shut-off device to regulate the The flow of molten metal dissolved

Preferably, the binder binds the ceramic particles of the mixture together to form a coherent, refractory Materia !, in which a chemical bond occurs at a temperature below the conventional one Firing temperature is, for example, at a temperature of less than 371 ⁰ C. A particularly preferred one The binder for the present invention contains a starting material for phosphorus pentoxy? preferably Phosphoric acid.

The refractory material is preferably made of clay or magnesia. The gate valve of the shut-off device may furthermore also comprise means for securing the refractory material, and these means consist preferably from protrusions in the metal frame.

A preferred method of manufacturing the slide for the shut-off element is to use it

a container for receiving the refractory material, in the subsequent filling of a

Mixture of ceramic particles and binder in the frame. The mixture is then made by applying Pressure molded inside the frame. The mixture is then heated to within the frame

to achieve a chemical setting of the ceramic particles, so that a coherent, refractory material In addition, this process causes the refractory material to be attached to the inner surface of the frame

so attached.

It is preferred that for the case that the mixture contains a raw material of phosphorus pentoxide to form the chemical setting time, the mixture was subjected to a heat treatment at a temperature in the range from 204 ⁰ C to 315 ° C.

Further details, features and advantages of the invention emerge from the following description of the exemplary embodiments shown purely schematically in the drawings. It shows P i g. 1 shows a cross section through part of a slide, FIG. FIG. 2 shows a detailed view of part of the embodiment according to FIG. 1 and

3 shows a cross section through a mold arrangement for producing the embodiment according to FIG Invention.

As shown in Fig. 1, the slide part 10 has a shaped metallic frame 12, which surrounds the refractory ceramic material 14. The metallic frame has several functions.

According to the present invention, in contrast to the prior art, the frame initially forms one Part of the casting mold that forms the ceramic material of the refractory layer 14.

The shape of the frame depends on the mechanism used to operate the sliding part of the Shut-off device is used.

The refractory ceramic material 14 is not connected to the frame 12 by means of a refractory mortar, but lies directly on the frame 12. The direct bonding of the refractory material to the frame by using low-fire, refractory materials represents another significant aversion

from the conventional prior art arrangements. The immediate touch of the refractory Layer with the metal frame allows the use of mechanical means to make the refractory Attach layer 14 to the inner surface of the metal frame.

As in Fig. 2, projections 18 are disposed on the inside of the frame 12. The protrusions 18 (Fig. 2) form the edge of the frame 12 which is bent so that it protrudes inward. These Embodiment is to be regarded only as an example of a protrusion or protrusions that are the same Function. The function of the protrusions is to keep the refractory layer 14 within the Set frame 12 to improve the hold of the refractory layer 14 in the frame 12. Because a detachment the refractory layer of the frame can lead to a catastrophic leakage of the molten metal, soft held back by the shut-off device or the discharge of which is controlled by the shut-off device, The refractory ceramic material 14 consists of ceramic particles, which by pressing and then Heating to a temperature below conventional firing temperatures.

The refractory material depends on the type of molten metal that is controlled by the gate target. For example, basic refractory materials such as dead-burned magnesite or synthetic Periclase, or magnesium oxide, can be used. The refractory material can be made by adding a refractory is solid chrome ore. Acid or neutral refractory materials, such as alumina or aluminum oxide, Alumina silicate, mullite, zirconium oxide, or zirconium silicate, can then be used if there is the given situation requires. The selection of the properties of the ceramic components of the refractory Materials is at the discretion of those skilled in this area of technology.

The determining criterion as to whether a ceramic material can be used in connection with the invention is its ability to produce an unfired, coherent, refractory material! with a N:?. drig temperature bond and to maintain a Dimens ^: -MisstaDilität when it is exposed to the operating temperature of the valve.

The chemical setting of the ceramic material is brought about by adding a binder

Suitable inorganic materials for the chemical setting of ceramic materials are silicates, Sulfates, nitrates, chlorides and phosphates.

The addition of phosphorus pentoxide to refractory compositions to achieve good chemical Binding at low temperatures, making ceramic particles into a coherent, refractory material are formed is known per se. This setting takes place at temperatures in the range of 204 ° C to 315 ° C. This temperature corresponds to the temperature that is necessary for warping or melting of the Avoid metal frame surrounding the refractory material. The strength of the phosphate setting produced refractory mixture, measured by the breaking strength, is sufficient for the Tied molded body can be handled and subjected to a grinding process, the ground Surface forms the sealing surface 16 of the slide valve part. Higher temperatures that the device in Suspending service will not normally change the dimension of the preformed refractory layer. The additional heating further solidifies the setting between the ceramic particles, which are the refractory Form layer.

In addition to inorganic binders, organic binder systems such as lignosulfates can also be used or tar- or pitch-bound refractory materials can be used.

B e i s ρ i e ■

A refractory mixture of nearly 85% alumina was incorporated into a standard dry pan mixer Made using phosphoric acid. The composition of the mixture was as follows:

Material weight%

Calcined bauxil with a grain size of - 1.19 mm 35

CalcinicrtL-r bauxite with a grain size of - 0.105 mm 55

Caicinierie clay with a grain size of - 0.044 mm 5

Plastic kaolin 5

About 5% by weight of a 75% concentrated phosphoric acid was added to this mixture and the moisture content was adjusted to almost 5 to 7% by weight. The composition of the mixture and the particle size of the components were determined in such a way that a pressed product with a pressed density of 2.99 g / cm ^{3 was} obtained. The hydraulic impact press equipment normally used in the manufacture of prefired refractory gate plates has been modified to accommodate the metal frame as shown in FIG. 3 is shown to accept or take up. The metal frame was inserted into the press. A weighed amount of the refractory mixture described above was then poured into the metal frame. The mixture poured into the metal vessel was weighed for size and density control. A volume-related input of the mixture would also be possible.

The ceramic mixture is then pressed. The effect of a hydraulic impact press allows a maximum density, which is achieved even at moderate press pressures. The use of screw presses, hydraulic or mectonic presses also allows a sufficient refractory shape to be obtained with sufficient density. After pressing, the assembly made of ceramic and metal is removed from the press and the surrounding mold as an integrated metal frame / refractory plate assembly. An inspection and test of this pressed assembly showed a pre-density of 2.98 g / cm ³ . One

visual inspection of the assembly reveals clean, sharp edges, particularly around the bore area, and intimate contact between the metal frame and the ceramic material. The order could be easily handled without damaging the assembly or without the refractory material separating from and falling out of the metal vessel.

s The assembly was then placed directly into a dryer where the assembly at a temperature of 82 ° C to 260 ⁰ C for 12 hours and was fired. The low-burn arrangement was examined again. Visual inspection revealed a hard, well-defined refractory shaped body in intimate contact with the metal frame. The low-fired refractory material showed no shrinkage. Likewise, there was no excessive expansion of the metal frame due to the drying temperature

Breaking or loosening the connection between the refractory material and the metal frame.

The test results on the low-fire assembly (see Table I) indicate that the assembly has the desired properties.

15th Table I. apparent porosity Volume weight Kaltbicpcicsligkcil HeiUbicgc
strength
(1482 "C) 20th Refractory component 17% £, O-f K / lfll- IV ₁ U IlMHItl 7 Π Kl / mm2 S5% clay

Conventional gate valves that use pre-burned refractory panels! will show the following Features on:

25th Table Il apparent porosity Space weight Cold resistance
N / mm ² Hot bending
strength
(1482 ° C) Ceramic material 17%
15%
16% 2.82 g / cm >
2.90 g / cm '
2.87 g / cm ' 21.1
14 "0
16.1 7.0 N / mm ²
14.7 N / mm *
133N / mm ^J JO 85% clay
90% clay
96% MgO

A comparison with these conventional refractory plates shows that a slide produced in the previous manner or the refractory ceramic material contained therein has the same or better properties than the known materials, but according to the invention a significantly simplified method of manufacture takes place ar.d the bonding of the refractory Material on the metal frame is done without using a refractory cement.

1 sheet of drawings

Claims (1)

Claim: Using one in a metal frame made from a mixture of ceramic particles and one at lower, below the conventional firing temperatures, a chemical bond between the ceramic particles creating binder under pressure, in direct contact with the metal frame, refractory ceramic material as a slide for a valve to regulate the flow of Metal smelting.