KR101267348B1 - Sampler for preventing inflow of slag - Google Patents

Abstract

The present invention relates to a slag inflow prevention sampler that prevents the slag formed on the top of the molten steel to be collected when the molten steel is collected, for this purpose is fixed by the refractory to the cylindrical tube and the lower end of the branch pipe, A molten steel inlet tube having an opening through which molten steel is formed, and fixedly installed at a lower end of the refractory to communicate with an opening of the sampling mold, and having an inlet through which molten steel is introduced from the outside, and an inlet of the molten steel inlet pipe. It is installed to provide a blocking member to temporarily block the inflow of slag during immersion.

Description

Sampler for preventing slag inflow {SAMPLER FOR PREVENTING INFLOW OF SLAG}

The present invention relates to a sampler, and more particularly, to a slag inflow prevention sampler which prevents the slag formed on the upper end of the molten steel when the molten steel is collected.

The steelmaking process that uses iron ore as a raw material to produce steel as final product starts with a steelmaking process that dissolves iron ore in the blast furnace. A molten steel is prepared by performing preliminary treatment such as talline on a molten iron which is an iron ore-dissolved form. Molten steel is subjected to a primary refining process to remove impurities and then to a secondary refining process to finely adjust the components in the molten steel. When the secondary refining is completed, the components in the molten steel are adjusted. After the secondary refining is completed, the molten steel is moved to the continuous casting process, and a semi-finished product such as slab, bloom, billet and the like is formed through the continuous casting process. The semi-finished product thus formed is manufactured into a desired final product such as a rolling coil and a heavy plate through a final molding process such as rolling.

Ladle Furnace is a device for fine-tuning and desulfurizing molten steel components after melting and scraping of scraps in the converter. In the ladle, secondary refining is performed by adding an auxiliary material, arbu bubbling, and arc heating to adjust molten steel components for deoxidation and desulfurization. At this time, in the converter and ladle, the temperature of molten steel is measured several times, and a part of molten steel is collected and component analysis is performed. Sampling of such molten steel is an essential task in the refining process.

When the molten steel is collected in this way, a large amount of slag flows into the sampling mold of the sampler and is unevenly distributed in the analytical specimen, so that a deviation may occur during component analysis.

Related prior arts include Korean Patent Publication No. 2002-0001001 (published date; January 9, 2002).

The present invention is to provide a slag inflow prevention sampler that prevents the slag formed at the top of the molten steel to enter the sampling mold when the molten steel is collected in the steelmaking process, and also prevents the introduced slag is distributed unevenly.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above.

The sampler of the present invention for achieving the above object is a cylindrical tube; A sampling mold fixed to the bottom center of the branch pipe by refractory and having an opening through which molten steel flows downward; A molten steel inlet pipe fixedly installed at a lower end of the refractory to communicate with an opening of the sampling mold and having an inlet through which molten steel is introduced from the outside; A blocking member installed at an inlet of the molten steel inlet pipe to temporarily block inflow of slag during immersion; And a protective cap which is covered to protect the molten steel inlet pipe from the lower end of the branch pipe and prevents foreign substances from flowing into the sampling mold.

The blocking member may be an aluminum film, and the blocking member may have a thickness of about 1 mm to about 5 mm.

The molten steel inlet pipe is fixed to the surrounding by the refractory may further include a sensing means for measuring the temperature and oxygen concentration of the molten steel, respectively.

As described above, the present invention prevents the slag formed at the top of the molten steel from entering the sampling mold when the molten steel is collected in the steelmaking process, and also prevents the introduced slag from being distributed unevenly, thereby recovering a healthy molten steel sample. There is an advantage to this.

1 is a cross-sectional view showing a part of a sampler according to the present invention.
2 is a view showing an installation example of the blocking member according to an embodiment of the present invention.
3 is a view showing an installation example of a blocking member according to another embodiment of the present invention.
4 is a view for explaining the distribution of slag in the molten steel flow into the sampling mold according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like elements in the figures are denoted by the same reference numerals wherever possible. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

1 is a cross-sectional view showing a part of a sampler according to an embodiment of the present invention, wherein the sampler 100 includes a branch pipe 110, a refractory 120, a sampling mold 130, a molten steel inflow pipe 140, and a blocking member ( 150), the sensing means 160 and the protective cap 170 is configured to include.

Branch tube 110 is a cylindrical tube formed of paper or pulp material. The paper tube 110 is formed by hardly compressing a paper material such as pulp and is manufactured to withstand a predetermined time even in molten steel around 1500 ° C. Branch tube 110 is made of a long cylindrical shape serves as the body of the sampler.

The sampling mold 130 may be inserted into the lower center portion of the branch pipe 110 and fixedly installed by the refractory 120. The sampling mold 130 is a hollow portion made of a ceramic, metal, or refractory 120 material, and has an opening through which molten steel flows downward. Since the sampling mold 130 is inserted into the branch pipe 110, when the branch pipe 110 is introduced into the molten steel, the sampling mold 130 is a container formed such that the molten steel flows through the opening.

The molten steel inflow pipe 140 is fixed to the lower end of the refractory 120 so as to communicate with the opening of the sampling mold 130 is installed to extend downward, the inlet for the molten steel is introduced from the end extending downward.

The blocking member 150 is installed at the inlet of the molten steel inlet pipe 140 to temporarily block the inflow of slag during immersion. Here, the blocking member 150 may be inserted into the inlet of the molten steel inlet pipe 140, as shown in FIG. In addition, the blocking member 150 may not be inserted into the inlet of the molten steel inlet pipe 140, but may be installed in the form of being covered by the inlet of the molten steel inlet pipe 140 as shown in FIG. As the blocking member 150, deoxidation elements such as aluminum, silicon, magnesium, and manganese may be used, and aluminum is suitable in terms of efficiency such as price. Since the melting point of aluminum is about 660 ° C., the aluminum film may immediately change into a liquid state when exposed to a slag layer of about 1000 ° C. or molten steel of about 1500 ° C. or more.

In addition, the thickness of the blocking member 150 is preferably manufactured in consideration of the time (approximately 3 to 5 seconds) and reaction speed for the sampler to pass through the slag layer. Since the sampler may block inflow of the slag into the sampling mold 130 while passing through the slag layer, the thickness may be about 1 mm to about 5 mm. In this case, when the thickness of the blocking member 150 is less than 1 mm, the sampler may be melted before passing through the slag layer, and the slag may be introduced. When the thickness of the blocking member 150 exceeds 5 mm, the sampler is immersed in molten steel. Even after the molten steel is temporarily blocked, it may take a long time to collect the molten steel.

The sensing means 160 is fixedly installed at the lower end of the refractory 120 around the molten steel inlet pipe 140, and is formed to protrude downward to measure the temperature and oxygen concentration of the molten steel, respectively. The sensing means 160 may include a probe 161 for measuring the temperature of the molten steel and an oxygen measuring instrument 165 for measuring the oxygen concentration in the molten steel. The sampler 100 that simultaneously measures the temperature, oxygen and oxygen of the molten steel is called a TOS type sampler. The TOS type sampler is a decarburization process in a converter and a secondary refining process to ladle. Mainly used in Of course, the sampler of the present invention is not limited to the TOS type sampler, but may be applied to a sampler for collecting only molten steel.

The protective cap 170 is formed of a paper or pulp material which is covered to protect the molten steel inlet pipe 140 and the sensing means 160 at the bottom of the branch pipe 110 to prevent foreign substances from flowing into the sampling mold 130. Can be.

As shown in FIG. 1, the refractory 120 serves as a holder for fixing the sampling mold 130, the molten steel inlet pipe 140, the probe 161, the oxygen measuring instrument 165, and the like in the branch pipe 110. . Meanwhile, although not shown, the cable of the sensing means 160 for temperature and oxygen measurement may be inserted into the branch pipe 110. Therefore, the hollow may be formed inside the branch pipe 110. The molten steel temperature and oxygen concentration measured through the probe 161 and the oxygen measuring instrument 165 are transmitted to an external controller via a cable, and the molten steel temperature and oxygen concentration measured according to the control of the controller are displayed on the display. do.

In the steelmaking process, the furnace and ladle furnace processes are refined to adjust the composition and temperature of molten steel to produce clean molten steel. Therefore, it is essential to analyze the composition of molten steel in refining converters and ladles. Collection of such molten steel can be carried out several times during refining.

As such, when the sampler 100 is immersed in the molten steel for analyzing the temperature, oxygen, and components of the molten steel, the protective cap 170 is burned while passing through the slag layer, and the molten steel inflow pipe 140 installed inside the protective cap 170. ) Blocking member 150 also begins to melt. The blocking member 150 is preferably formed to a thickness that all melt when the sampler reaches the molten steel through the slag layer. As such, the blocking member 150 not only temporarily blocks the slag from flowing into the sampling mold 130 through the molten steel inlet pipe 140, but also blocks the slag because the blocking member 150 is a strong deoxidation element even though a small amount of slag is introduced. After reacting with the fluorine, it floats to the top of the sampling mold 130 as shown in FIG. For example, when the blocking member 150 is an aluminum film, the slag introduced into the sampling mold 130 reacts with aluminum to generate alumina (Al ₂ O ₃ ) inclusions, and the generated inclusions are moved upwards in the sampling mold 130. As a result, the slag is prevented from being distributed unevenly in the sampling mold 130.

In general, since the specimen for analyzing the component is an intermediate portion (ⓐ) as shown in Figure 4, the slag (S) floating to the top of the sampling mold 130 does not affect the component analysis.

As such, the sampling mold 130 is immersed in the molten steel for a predetermined time to collect a part of the molten steel therein, and is taken out of the molten steel together with the branch pipe 110. At this time, the branch pipe 110 is burned by the heat of the molten steel, but is manufactured to maintain the appearance of the appearance. The sampling mold 130 may collect molten steel located in the branch pipe 110 in this manner. After the extraction of the molten steel is drawn out together with the branch pipe 110, the operator breaks out the drawn branch pipe 110, take out the sampling mold 130 inserted into the interior and then analyze the composition of the molten steel through the central portion of the specimen Will be implemented.

Such a sampler is not limited to the configuration and manner of operation of the embodiments described above. The above embodiments may be configured such that various modifications may be made by selectively combining all or part of the embodiments.

100: sampler 110: branch tube
120: refractory 130: sampling mold
140: molten steel inlet pipe 150: blocking member
160: sensing means 170: protective cap

Claims (4)

Cylindrical tubes;
A sampling mold fixed to the bottom center of the branch pipe by refractory and having an opening through which molten steel flows downward;
A molten steel inflow pipe fixedly installed at a lower end of the refractory and having an inlet through which molten steel is introduced from the outside so as to communicate with an opening of the sampling mold;
A blocking member installed at the inlet of the molten steel inlet pipe to temporarily block the slag of the upper part of the molten steel from being introduced into the sampling mold through the inlet; And
Included to protect the molten steel inlet pipe from the lower end of the branch pipe to prevent foreign matter from entering the sampling mold; includes;
The blocking member is all melted when the sampler reaches the molten steel through the slag layer during immersion, it is made of a deoxidation element to react with the remaining slag after immersion to produce slag inclusions, the generated inclusions are formed in the inlet and opening downward Slag inflow prevention sampler which floats upwards in the sampling mold through.
The method according to claim 1,
The blocking member is a sampler for preventing slag inflow is an aluminum film.
The method according to claim 1,
Slab inflow prevention sampler having a thickness of the blocking member is 1mm to 5mm.
The method according to claim 1,
Slag inflow prevention sampler further comprises a sensing means for measuring the temperature and oxygen concentration of the molten steel fixedly installed by the refractory around the molten steel inlet pipe.

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