KR900006568Y1 - Slag sampler - Google Patents

Abstract

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Description

Slag sampler

1 is a perspective view of the present invention.

2 is a perspective view of a sublance probe to which the present invention is attached.

3 is a perspective view of a conventional sub-lance probe.

4 is a state of use of the present invention.

* Explanation of symbols for main parts of the drawings

1: sub lance probe 4: slag sampler

5: annular protrusion ring 6: concave groove

The present invention relates to a slag sampler that is used to sample slag in a converter during drilling.

In general, the purpose of sampling the slag in the converter for refining pig iron out of the blast furnace with the steel of the required component is well described in the known art.

In other words, it is impossible to analyze the reaction state of slag-metal at the same time without grasping the time-dependent change of the composition of slag that has a great influence on the reaction in the converter. Slag sampling is required during drilling for the control system, and there are many problems with this slag sampling method.

Conventional slag sampling is performed by dropping a chain from the top of the converter to the slag layer in the furnace to remove a small amount of slag attached to the chain due to the difference in thermal conductivity, and to obtain a sample. There is a sampling method in which a slag is sampled by a slag sampler pocket having a semi-conical pocket attached to one side of a sub-lance probe. As there is a time difference from the metal sampling, it is difficult to grasp the change over time, and it is cumbersome to collect the slag separately, and the slag sampler with the pocket is timely as shown in Utility Model No. 85-366. Is easy to sample, but the slag sampling failure rate is irregular due to fluctuation And the sub-lance is projected is attached to the probe in the pocket sampler had a difficult to automate the process inconvenient because it is not possible to mount the sub-lance probe mechanically.

The present invention devised an improved slag sampler coupled to a sub-lance probe tube containing a metal sampler and a molten steel temperature measuring probe in a converter to solve the above problems. Referring to the drawings in detail as follows.

Attached by replacing the slag sampler (4) with a slag sampler (4) attached to the molten steel temperature measuring probe (2) for measuring the metal temperature in the converter and the metal sampler (3) embedded in the converter. However, the slag sampler is characterized in that the ring-shaped protruding ring 5 is formed on the outer circumference to form the concave groove 6 and a diameter smaller than the outer diameter of the sub-lance probe (1).

In the accompanying drawings, reference numeral 7 denotes a converter, 8 denotes an oxygen lance 9 a slag layer, and 10 denotes a molten steel layer.

Since the slag sampler 4 of the present invention is configured to be smaller than the outer diameter of the sublance probe 1, there is no difficulty in automating since there is no defect that protrudes from the sublance probe like the conventional pocket-attached slag sampler. The outer periphery of the slag sampler 4 constituting a part of the lance probe (1) formed a ring-shaped protruding ring (5) to increase the difference in thermal conductivity, and the concave groove (6) between each protruding ring (5) Not only to facilitate the collection of slag, but also to prevent the slag layer from easily collapsing.

At this time, the coupling portion of the sub lance probe 1 and the slag sampler 4 is manufactured by reinforcing with a castable so that molten steel does not penetrate.

When explaining the operation and effect of the present invention configured as described above, in the refining molten steel as a target component by charging molten iron, scrap, various auxiliary materials, etc. in the converter (7) and blowing oxygen into the oxygen lance (8). The slag is generated as the blowing time elapses, and the reaction between the slag metals occurs. At this time, the molten steel layer in the converter 7 is connected to the sub-lance probe 1 to measure the metal sampling and the molten steel temperature for dynamic control of the converter blow. When it is immersed in (10), the molten steel temperature measurement and metal sampling can be performed by the molten steel temperature measuring probe (2) and the built-in metal sampler (3) mounted on the tip of the sub-lance probe (1), and the sub-lance probe (1). The slag sampler 4, which is a part of), is coupled to a position that can be locked to the slag layer 9 in the converter 7, so that the slag is attached to the concave groove 6 formed between the several annular protrusion wheels 5. Be Which will be collected slag.

Therefore, the use of the sub-lance probe (1) combined with the slag sampler (4) of the present invention can be carried out at the same time the molten steel temperature measurement and metal and slag sampling, the risk of the operation in the method of collecting slag by dropping the conventional chain And it solved the disadvantage that simultaneous sampling of metal and slag was difficult, and solved the work difficulties that required additional equipment when using a slag sampler with a pocket, which was inexpensive, and which had to be manually mounted without automating the sub lance. To give.

Since the slag sampler 4 of the present invention is configured in an integrated state with the sub-lance probe 1, the metal and slag sample can be secured by the automation without any obstacle to the converter blow operation.

Claims (1)

Attached by replacing slag sampler (4) with a part of the conventional sub-lance probe (1) attached with a molten steel temperature measurement probe (2) for measuring the metal temperature in the converter while the converter is blown. The slag sampler, characterized in that formed in the outer periphery of the ring-shaped protruding ring (5) to form a concave groove (6) and a diameter smaller than the outer diameter of the sub-lance probe (1).