JPS5850946B2 - Repair material for plate bricks in sliding nozzle equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a plate brick repair material that is supplied from the outside to a damaged portion of a sliding surface that occurs near a nozzle hole of a sliding nozzle device.

Japan and the U.S. also published Special Publication No. 11121 of 1972, Publication of Actual Publication No. 4.7 of 1973.
As described in Japanese Patent No. 42523, in a sliding nozzle device, etc., before setting the plate bricks,
It was common practice to apply lubricant to the sliding surface, or to create recesses in the sliding surface of the plate and load lubricant there.
In this conventional method, the lubricant is burnt out in a short time due to the heat generated when the molten metal flows out, which not only greatly reduces the sliding lubricity but also causes tar, pitch, etc. to enter the pores in the plate brick surface. Even when impregnated or coated with organic matter, even the filled carbon material disappears, weakening the structure of the plate surface. There was a problem in that damage to the plugs, etc. occurred, resulting in loss of damper performance.

This invention was completed in order to solve the above-mentioned conventional problems, and damage is most likely to occur between the nozzle holes above and below the sliding movement, during operation after assembly of the sliding nozzle device, or during operation of the sliding nozzle device after assembly. The object of the present invention is to provide a repair material for repairing the damaged surface by the sliding of the sliding plate itself by supplying the repair material for the damaged part to the sliding surface of the sliding plate during the downtime.

As the aggregate of the repair material of the present invention, oxide-based refractories such as mullite, quartz, alumina, and magnesia are used.

Aluminum chlorohydrate, aluminum oxyhydroxide, aluminum chloride, aluminum hydroxide, aluminum sulfate, aluminum nitrate, and other aluminum compounds.

Magnesium sulfate and other magnesium compounds.

Zirconium chloride and other zirconium compounds.

Optionally, refractories such as those with graphite added can be used.

In order to maintain the smoothness of the sliding surface and slide into damaged areas by sliding the sliding plate, it is necessary to have a particle size of 50 microns or less.

In order to improve the adhesion of the aggregate to the damaged area, it is effective to use a thermosetting resin such as epoxy resin or phenol resin as a bonding material between the repair aggregate and the plate.

Further, in order to disperse the sliding surface, grease such as silicone grease or paraffin which becomes liquid at the operating temperature and is in an ideal fluid state at the operating temperature of the sliding nozzle device is added.

Any exothermic agent or foaming agent such as silicon, aluminum magnesium, titanium, or obsidian can be added to the repair material according to the present invention, and the effect of actively preventing insertion due to solidification of molten metal can be expected.

The repair material of the present invention may be used in the form of a paste, plate, cream, grease, semi-solid, or solid.

Furthermore, when the fluid contains solids in the usage form, the solids content is preferably 70% or less (particularly preferably 5 to 65%), and when it is semi-solid, the solids content is preferably 50% or more.

The accompanying drawings show an embodiment of a sliding nozzle spray F suitable for externally supplying the repair material of the present invention.

In FIG. 1, reference numeral 1 denotes an upper fixing plate of a sliding nozzle which is connected and fixed to a nozzle 4 attached to the lower part of the tundish.

2 is a lower sliding plate connected and fixed to the lower nozzle.

The upper and lower plates 1 and 2 are provided with supply holes 10 for supplying a repair material in the form of a liquid or grease connected to a suitable force pressure source.

The tips of the supply holes 10 are opened in the vicinity of the respective nozzles 4 and 5 in order to supply the damage repair material to the sliding surface.

Of course, it is also possible to fix the repair material supply hole 10 in the plate, provide a reservoir there, and supply the repair material to the sliding surface from the reservoir.

4 to 6 show the arrangement of the tip openings of the damage repair material supply holes 10 on the sliding surface.

4 and 5 show the case of a type in which the lower plate moves linearly with respect to the upper plate, and FIG. 5 shows the case of a type in which the lower plate moves rotationally with respect to the upper plate.

As seen in each figure, a plurality of tip openings of the supply holes 10 are preferably provided in the width direction of the sliding surface in order to uniformly supply the repair material throughout the sliding surface wheel.

In addition, not only in the width direction of the sliding surface, but also in the sliding direction, especially in the front and rear of the nozzle, for example, on both the upper and lower plates in the area mainly based on the sliding locus created when the nozzle part slides. A supply port for repair material may also be provided.

Alternatively, as shown in FIGS. 4 and 5, it is desirable to make the opening of the upper plate larger than that of the lower plate to adjust the state of supply of the repair material to the sliding surface.

In a forced supply device for repair materials with this structure, for example,
A mixture of boron nitride and synthetic oil, or a liquid mixture of tungsten disulfide and graphite with synthetic oil,
A grease-like material is suitable.

On the other hand, in the case of a mixture of graphite and A1203-8102 series refractories, or a solid repair material consisting of aluminum oxide, sodium nitrate, sodium silicofluoride, refractory brick scraps, pitch, organic binder, binder clay, etc. for,
It is also possible to use the means for continuous feeding shown in FIG.

That is, a spring press-fitting device 8 is attached below a repair material supply port provided on the lower plate and opening to the sliding surface, and the above-mentioned solid repair material 7 is filled thereon.

The solid repair material 7 is always actively slid and supplied onto the sliding surface by the action of the spring means.

In addition, as shown in FIG. 3, a repair material is supplied from the tip of the blow-off pipe 10 guided from the shell onto the sliding plate 2, and is applied to the sliding plate 2 from the notch 9 under the stationary plate 1. A method of introducing it into a gap is also possible.

When the plate is in the closed state, open state, or sliding state, the repair material is supplied to the sliding surface to fill the sliding surface with a film or the damaged part, and as a result, the next opening will be in the closed state. In some cases, this film or filling part acts as a damage prevention film, which prevents direct penetration and contact with molten metal and also reduces the penetration speed.

These damage protection membranes may be washed away by the molten metal flow, but they protect the membrane until it is washed away, and cushion the shock of the initial impact of the molten metal flow.

A similar effect can also be obtained by actively rinsing away after each sliding movement.

Furthermore, the repair material in the filled portion is baked into this area by the heating action, making it possible to completely repair the sliding surface.

Next, the damage prevention film that is not formed when opening is formed when it is closed or due to the movement of the position due to sliding.1.
The formation of this damage-preventing film is repeated and performed continuously, and the damage is effectively prevented.

Appropriate repair materials are selected and operated depending on operating conditions, firebrick material and other conditions, and damage behavior.

Further, even if the repair material disappears due to the first opening/closing operation, for example, new repair material is supplied as described above, so that the lubricating effect can be maintained.

As mentioned above, repair materials are used not only in the above example but also in accordance with the damage situation.

In addition, multiple effects can be achieved, such as using damage prevention methods that have a lubricating effect.

The combined effects are listed below, and by adding an optional additive to the repair material according to the purpose, the sealing or connection effect of the sliding surface is improved.

The joint surface between the upper nozzle and the plate is an important point because it can lead to accidents involving water leakage.

Another condition is that the upper nozzle should be easily and quickly attached to and detached from the container, and connected to and detached from the plate.

Furthermore, if the repair material is constantly supplied around the nozzle hole of the plate, it is possible to prevent leakage of metal or hot water due to a drop in surface pressure, and furthermore, failure of the device due to inability to close the nozzle hole.

It also prevents gas leakage caused by gas blowing to prevent solidification of molten metal or degas it, and also prevents damage to the plate due to the bubbling effect that accompanies this.

Cooling of the sliding surface can also be achieved by supplying repair material.

Since the repair material is supplied from outside, there is no need to cover the sliding surface of the plate with a sliding layer or apply lubricant during plate assembly. In addition, there is no need to make something with such high precision, which extends the life of the sliding plate.

By containing a heating agent or a bubbling agent in the repair material, the molten metal in the nozzle hole is heated or bubbled to prevent the molten metal from solidifying.

In addition, sliding opening/closing devices for passages such as pans, tundishes, converters, and other containers and gutters that contain molten metal, or opening/closing sliding parts and sliding connections for blowing fluids (including powder and granules). It has many effects, such as a wide range of applications.

[Brief explanation of the drawing]

The accompanying drawings show an embodiment for supplying a sliding nozzle plate with a repair material according to the present invention, and FIGS.
FIG. 3 shows a vertical cross section of each embodiment, and FIGS.
The figure shows the open state of the aeration material supply hole on the sliding surface. 1... Upper plate, 2... Lower plate, 4... Upper nozzle, 5... Lower nozzle,
3,10...For supply of repair materials

Claims (1)

[Claims] 1 A plate repair material to be supplied externally to the sliding surface of a plate brick during the operation of a sliding nozzle device, which contains refractory particles of 50 microns or less, graphite, thermosetting resin, grease and/or paraffin. A repair material for plate bricks in a sliding nozzle device, characterized by containing the following.