KR100993268B1 - Bin - Google Patents

Abstract

The raw material storage bin of the present invention includes a container having an open top to store raw materials charged to the blast furnace, and a moisture measuring unit installed at one side of the container to measure moisture in the raw material.

The invention as described above has an effect of optimizing the content of the fuel charged in the blast furnace by installing a moisture measuring unit that can measure the moisture of the raw material in a raw material storage bin in real time.

Blast furnace, container, raw material, fuel, moisture measuring device

Description

Raw material storage bin {BIN}

The present invention relates to a raw material storage bin, and more particularly to a raw material storage bin for measuring the moisture content of the raw material.

In general, the blast furnace for re-emission is a furnace for supplying iron ore, coke and limestone processed into sintered ore to reduce the iron oxide of the iron ore to discharge molten iron, the iron content of the raw iron ore is not constant, the reduction reaction is Since it has a structure that cannot be made smoothly, sintered ore processed by sintering iron ore powder in the form having a certain particle size is used to secure uniform quality and sufficient porosity.

The sintered ore as described above is manufactured in a sintering plant and then stored in a raw material storage bin and charged with coke in the blast furnace.

The raw material storage bin stores a large amount of sintered ore transferred from the sinter plant to the blast furnace in the middle, and discharges a certain amount of sintered ore to the blast furnace at regular intervals, thereby storing all the sintered ore that continuously passes from the sintering plant. There are a number of hazardous storage bins, depending on the size of the blast furnace.

However, since the moisture content of the raw material, such as sintered ore is transported to the blast furnace fluctuate according to the moisture of the atmosphere, the fuel content, which is a heat source for dissociating moisture in the heat source, must be changed according to the moisture content of the raw material. Is generated.

In order to solve this problem, conventionally, the operator adjusts the fuel content based on intuition or experience, but a large amount of fuel is charged more than necessary to raise the cost.

In order to solve the above problems, an object of the present invention is to provide a storage bin for preventing the raw material is wasted to increase the cost by measuring the moisture contained in the raw material in real time.

In order to achieve the above object, the raw material storage bin of the present invention includes a container having an upper portion open to store raw materials charged into the blast furnace, and a moisture measuring unit installed on one side of the container to measure moisture in the raw material. .

The moisture measuring unit includes a first terminal connected to one side of the container, a conductive member immersed in the raw material, a second terminal connected to the conductive member, and a power supply unit for applying power to the first terminal and the second terminal. It may include.

The conductive member is fixed to the container, and an insulating member for insulating between the conductive member and the container may be further provided between the conductive member and the container.

The upper portion of the conductive member is bent toward the outside of the container, an insulating member may be provided between the bent conductive member and the container.

The positive terminal of the power supply unit may be connected to one terminal of the first terminal and the second terminal, and the negative terminal of the power supply unit may be connected to the other terminal.

The present invention has an effect of optimizing the content of the fuel charged in the blast furnace by installing a moisture measuring unit that can measure the moisture of the raw material in a raw material storage bin in real time.

In addition, the present invention has the effect of reducing the manufacturing cost of the molten iron by reducing the waste fuel.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view showing a raw material storage bin provided with a moisture measuring unit according to the present invention, Figures 2 and 3 are cross-sectional views showing a modification of the raw material storage bin provided with a moisture measuring unit according to the present invention.

Referring to Figure 1, the raw material storage bin according to the present invention is a container 200 for storing the raw material 100, the moisture measuring unit is installed on one side of the container 200 to measure the moisture of the raw material 100 300.

The container 200 serves to temporarily store a raw material such as iron ore to be charged into the blast furnace, and is formed in a cylindrical shape with an upper portion open to contain the raw material 100. Here, the lower surface of the container 200 may be formed in a centered shape so as to project toward the lower side. The shape of the container 200 is not limited thereto and may be formed in various shapes.

The container 200 may be formed of a conductive material such as aluminum or stainless steel to allow electricity to flow. Of course, the container 200 may be formed of an insulating material, and may be formed by coating a surface of the container 200 with a conductive material.

One side of the container 200 is connected to the moisture measuring unit 300 for measuring the moisture of the raw material 100 contained in the container 200, the moisture measuring unit 300 is the first connected to the container 200 The terminal 310, the conductive member 320 immersed in the raw material 100 inside the container 200, the second terminal 330 connected to the conductive member 320, and the first terminal 310. ) And a power supply unit 340 for applying power to the second terminal 330.

The first terminal 310 is connected to one side of the container 200, specifically, the upper surface of the container 200, and the conductive member 320 to be immersed in the raw material 100 in the raw material 100 in the container 200. Is prepared. Here, the conductive member 320 may be fixed to the inner surface of the container 200, the conductive member 320 may be formed of a stainless or iron component well current and strong corrosion resistance.

An insulating member 370 may be further provided between the conductive member 320 and the inner surface of the container 200 to fix the conductive member 320 to the container 200, and the insulating member 370 may be a conductive member. It serves to insulate between the 320 and the inner surface of the container 200. Of course, a separate support (not shown) may be installed on the upper portion of the container 200, and the conductive member 320 may be connected to a separate support so as to be immersed in the raw material 100.

The second terminal 330 is connected to the upper portion of the conductive member 320, the first terminal 310 and the second terminal 330 to apply power to the first terminal 310 and the second terminal 330. The power supply unit 340 is connected through a cable 380.

The first terminal 310 is connected to the (-) pole of the power supply unit 340, the second terminal 330 is connected to the (+) pole of the power supply unit 340. As a result, a negative polarity flows through the first terminal 310 and a positive polarity flows through the second terminal 330. Of course, the present invention is not limited thereto, and the first terminal 310 may be connected to the (+) pole of the power supply unit 340, and the second terminal 330 may be connected to the (−) pole of the power supply unit 340. .

The voltmeter 360 and the ammeter 350 may be further connected between the power supply unit 340 and the first terminal 310, and the voltmeter 360 and the ammeter 350 may include the first terminal 310 and the second terminal ( The current and voltage flowing through 330 may be measured. Of course, the voltmeter 360 and the ammeter 350 may be connected between the power supply unit 340 and the second terminal 330.

When a minute current flows from the power supply unit 340 to the second terminal 330, the minute current flows to the container 200 to which the first terminal 310 is connected via the conductive member 320 and the raw material 100. A constant voltage is measured through the voltmeter 360 through the first terminal 310 connected to the 200.

The voltage measured by the voltmeter 360 will vary depending on the moisture content of the raw material 100. That is, when the raw material 100 has a high moisture content, the raw material 100 has a stronger conductive property, so that the voltage drop in the raw material 100 is weakened, thereby increasing the magnitude of the voltage induced in the voltmeter 360. On the other hand, if the moisture content is low in the raw material 100, the raw material 100 is weakened in the conductive property through the electricity is reduced the voltage magnitude induced in the voltmeter 360.

By comparing the change in the voltage measured in the voltmeter 360 as described above, it is possible to predict the relative moisture content in the raw material (100). Therefore, when the water content in the raw material 100 rises, it is possible to secure a heat source by increasing the amount of fuel used, and when the water content is reduced in the raw material 100, it is necessary to reduce the amount of fuel used to heat the unnecessary source. Can be reduced.

The invention as described above can predict the amount of water contained in the raw material 100 in real time, thereby optimizing the amount of fuel 100 used, thereby reducing the fuel 100 wasted, thereby reducing the manufacturing cost.

In the above, the conductive member 320 immersed in the raw material 100 is fixed to the inner side surface of the container 200, but is not limited thereto and may be configured as shown in FIGS. 2 and 3.

As shown in FIG. 2, the conductive member 320 fixed to the container 200 may form a vertical part immersed in the container 200 and a flat part to be bent toward the outside of the container from an upper end of the vertical part. The lower surface of the flat portion is fixed to the container 200. Here, the insulating member 370 may be further provided between the lower surface of the flat portion and the upper surface of the container 200.

In addition, as illustrated in FIG. 3, a through hole may be formed in the sidewall of the container 200, and the through hole may be disposed in the through hole so as to pass through the planar portion of the conductive member 320. Here, the insulating member 370 may be provided in the through hole of the container 200, and the insulating member 370 may be formed to be disposed along the outer side of the planar portion of the conductive member 320. Of course, the coupling method of the conductive member 320 is not limited thereto and may be fixed to the container 200 in various ways.

As described above, the upper surface of the conductive member 320 is bent to form the upper surface of the conductive member 320 toward the outside of the container 200, whereby the conductive member 320 is formed on the upper portion of the container 200. There is an effect to reduce the interference with other components mounted on the.

Although described above with reference to the drawings and embodiments, those skilled in the art that the present invention can be variously modified and changed within the scope without departing from the spirit of the invention described in the claims below I can understand.

1 is a cross-sectional view showing a raw material storage bin provided with a moisture measuring unit according to the present invention.

2 and 3 are cross-sectional views showing a modification of the raw material storage bin provided with a moisture measuring unit according to the present invention.

               <Description of the code | symbol about the principal part of drawings>

100: raw material 200: container

300: moisture measurement unit 310: first terminal

320: conductive terminal 330: second terminal

340: power supply unit 350: ammeter

360: voltmeter 370: insulating member

Claims (5)

A container 200 having an open top such that the raw material 100 charged in the blast furnace is stored; And And a moisture measuring unit 300 installed at one side of the container 200 to measure moisture in the raw material 100. The moisture measuring unit 300 includes a first terminal 310 connected to one side of the container 200, a conductive member 320 immersed in the raw material 100, and a second connected to the conductive member 320. A terminal 330 and a power supply unit 340 for applying power to the first terminal 310 and the second terminal 330, wherein the conductive member 320 is fixed to the container 200, and the conductive member An insulating member 370 is provided between the 320 and the container 200 to insulate the conductive member 320 from the container 200. delete delete The method according to claim 1, The upper portion of the conductive member 320 is bent toward the outside of the container 200, the raw material storage bin is provided with an insulating member 370 between the bent conductive member 320 and the container 200. The method according to claim 1, Raw material storage in which a positive terminal of the power supply unit 340 is connected to one terminal of the first terminal 310 and the second terminal 330, and a negative terminal of the power supply unit 340 is connected to the other terminal. Dragon bin.

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