JPH046866B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a molten metal slag removal device equipped with a suction head for sucking slag on top of the molten metal.

In the molten metal slag removal device described above, slag suction is started by lowering the suction head to a set suction height close to the slag above the molten metal, but if the slag surface becomes highly viscous and has a so-called crusty state, There were cases where the slag surface was a hindrance and slag suction could not be started.

Conventionally, the suction head was brought closer to the slag surface and the slag surface was broken by the suction force of the suction head, but the moment the slag surface was broken, a larger amount of slag than the set amount was sucked in. In addition, an extremely large amount of water vapor is suddenly generated when the slag is cooled by the cooling water jet inside the suction head, and this causes a drastic drop in the vacuum level of the suction system and a temporary positive pressure state. There was a problem that the slag suction became unstable and the smoothness of slag suction was impaired.

In view of the above-mentioned circumstances, an object of the present invention is to provide a suction head with a rational improvement so that smooth slag suction can be carried out regardless of the high viscosity of the slag surface on the molten metal.

The characteristic configuration of the present invention is that a bubbling nozzle for breaking the highly viscous slag surface is attached to the suction head that sucks and removes the slag on the molten metal, and that the bubbling nozzle is movable in front of the suction port. The functions and effects are as follows.

In other words, when suctioning slag, a bubbling nozzle is plunged into the slag above the molten metal, and in this state gas is ejected from the bubbling nozzle into the slag to break the highly viscous slag surface and enable the suction head to suction the slag.

That is, by moving the bubbling nozzle attached to the suction head in front of the suction port, it is possible to accurately break the slag surface at the most suitable position for slag suction by the suction head.
Moreover, the suction head itself can be positioned above the set suction height relative to the slag to break the slag surface while being positioned at a height above the set suction height, thereby reliably preventing the suction of a large amount of slag unexpectedly immediately after the slag surface is crushed. It is possible to avoid problems caused by the generation of large amounts of water vapor, and as a result,
It has now been possible to suction the slag as smoothly as when there is no skin covering.

Incidentally, in order to crush the highly viscous slag surface, it is possible to install a stirring blade type crushing device, but if this crushing device is attached to the suction head, the suction head will become larger, and the If the slag is installed at a location, it has the disadvantage that it becomes difficult to crush the appropriate location, and furthermore, the highly viscous slag surface tends to get entangled with the stirring blades, causing operational troubles.

In addition, when using such a crushing device, it is necessary to move the suction head far back to a position where it does not interfere with the rotation of the stirring blades during crushing. It takes time to restore the product, reducing work efficiency, and in the worst case, skinning occurs again during the restoration, making it impractical.

According to the present invention, since the nozzle is simply installed in the suction head, the suction head can be kept compact, and
The crushing location can be set appropriately, and since the nozzle plunges into the slag and blows out gas only during crushing, it has the advantage that operational troubles such as entanglement on the slag surface are less likely to occur. Since the slag is crushed directly below the suction head suction port, it is possible to quickly shift to slag suction after crushing is completed, improving work efficiency and preventing skinning from occurring again during the transition. Another big advantage is that you can definitely avoid this.

In summary, it has been possible to provide a molten metal slag removal device that has excellent slag suction and removal performance and is also extremely practical.

Next, the present invention will be explained in detail based on illustrative drawings.

FIG. 1 shows a suction head in a molten metal slag removal device.The suction head 2, which is configured to be able to move vertically and horizontally via a link mechanism 1, is connected to a slag 5 floating on a ladle 3 or molten metal 4 in a torpedo car. The suction head 2
Cooling water supplied from a cooling water supply pipe 6 is ejected inside the cooling water supply pipe 6 to solidify the sucked slag into powder.

The solidified slag, surplus cooling water, air, and water vapor generated as a result of cooling the slag are vacuum-transferred in a three-phase state through the suction pipe 7, and the solidified slag is separated and recovered in the post-processing section. It has been done.

A long rod-shaped bubbling nozzle 8 is attached to the suction head 2 so that it can be moved in and out in front of the suction head suction port 2a using an air ring 9. 5
At the same time, compressed air is ejected into the slag from the intrusion tip of the bubbling nozzle 8 to crush the highly viscous slag surface, which is in a so-called skinned state.
The structure is such that the slag can be smoothly suctioned and removed without disturbing the skin-like slag surface.

To configure the compressed air supply structure for the bubbling nozzle 8, the bubbling nozzle 8 and the compressor 10 for supplying compressed air are connected by an air conduit 12 in which a first electromagnetic on-off valve 11 is interposed, and a second electromagnetic on-off valve is connected. A bypass pipe 15 is provided for the first electromagnetic on-off valve 11 in which a valve 13 and a variable throttle valve 14 are interposed in series, so that when the bubbling nozzle 8 is injected, the second electromagnetic on-off valve 13
The pressure switch 16 attached to the bypass pipe 15 detects the rise in air pressure in the pipes 12 and 15 due to the entry of the slug into the bubbling nozzle 8. Based on the detection result, the first electromagnetic on-off valve 11 is automatically opened to supply a large amount of compressed air for crushing the slag surface.

In other words, it is possible to prevent a large amount of compressed air from being supplied before the bubbling nozzle enters the bubbling nozzle and prevent slag from scattering due to the compressed air jet, improving safety while automatically supplying a large amount of compressed air at the appropriate timing. In this way, the operability is improved.

In the figure, 17 and 18 are one-way valves for preventing backflow, and 19 is a relief valve for setting compressed air pressure.

To configure the compressed air jetting structure of the bubbling nozzle 8, as shown in FIG. Formed on the outer peripheral side wall part in the circumferential direction,
This prevents the slag from being press-fitted into the nozzle and clogging the nozzle 8 when the bubbling nozzle 8 enters, and also enables compressed air to be effectively ejected into the slag near the tip of the nozzle.
The structure is designed to improve the slag crushing performance.

To explain in more detail the lowering operation structure of the suction head 2 and the compressed air operation structure of the bubbling nozzle 8, as shown in FIGS. 1 and 3, the suction head drive controller 22 is activated by operating the push button 21 of the automatic control device 20. is actuated to lower the suction head 2 at the raised retirement height _H1 , and in conjunction therewith, the operation valve 9a for the air cylinder 9, and
The second electromagnetic on-off valve 13 is automatically operated to project the bubbling nozzle 8 in a state where a small amount of compressed air is ejected, and further,
When the bubbling nozzle 8 enters the molten metal upper slag 5 as the suction head 2 descends, based on the information from the pressure switch 16,
The first electromagnetic on-off valve 11 is opened to start crushing the slag surface, and at the same time, the suction head 2
automatically switches the descending speed V to the set low speed Va,
Moreover, it is configured to operate a timer T for setting the slag surface crushing time ta. Based on the information from the timer T, when the time has elapsed, that is, when the crushing of the slag surface is completed, the air cylinder operation valve 9a is switched to raise the bubbling nozzle 8 and retire the bubbling nozzle 8. After rising, both the first and second electromagnetic on-off valves 11 and 13 are operated to close with a set time delay tb.

The set low speed Va is set so that the height of the suction head 2 at the time of time-up of the timer T is a safe height _H2 at which slag cannot be sucked yet, and a large amount of slag is sucked the moment the slag surface breaks. I've made sure that nothing happens.

After the slag surface is crushed, the suction head 2
is continuously lowered to start slag suction, and when the electrode rod 23 attached to the suction head 2 comes into contact with the slag 5 on the molten metal as it descends,
That is, when the suction head 2 reaches the preset steady suction height _H3 , the suction head 2 is automatically stopped based on information from the electrode rod 23, and the electrode rod 23 is automatically raised and retired, and further, Thereafter, the slag level is periodically detected by the electrode rod 23, and the suction head 2 is controlled downward so that the steady suction height _H3 is maintained, thereby continuing the steady suction of the slag.

The specific shape and structure of the bubbling nozzle 8 can be improved in various ways, and the specific structure for moving in and out of the front of the suction head suction port 2a and the structure for moving in and out can also be improved in various ways.

Furthermore, the device for supplying compressed air or other gas for crushing the slag surface to the bubbling nozzle 8 can be modified in various ways, such as by using the exhaust pressure of a suction device that applies slag suction pressure to the suction head 2 instead of providing a dedicated compressor. These devices are collectively referred to as the air supply device 10.

Furthermore, various configuration changes can be made to the form of linkage between the bubbling nozzle 8 and the suction head 2, as well as the specific linkage operation structure.

[Brief explanation of drawings]

The drawings illustrate an embodiment of the molten metal slag removal device according to the present invention, FIG. 1 is a schematic diagram showing the structure of the suction head, FIG. 2 is an enlarged sectional view of the tip of the bubbling nozzle, and FIG. This is a time sheet for slag suction operation. 2... Suction head, 2a... Suction port, 4
... Molten metal, 5 ... Slag, 8 ... Bubbling nozzle, 10 ... Air supply device.

Claims (1)

[Claims] 1. A bubbling nozzle 8 for breaking the highly viscous slag surface is attached to the suction head 2 that sucks and removes the slag 5 on the molten metal 4 so as to be movable in front of the suction port 2a, and an air supply device 10
Molten metal slag removal equipment connected to.