KR20220089480A - Apparatus for measuring molten iron temperature of blast furnace - Google Patents

Abstract

Disclosed is an apparatus for measuring the temperature of molten iron in a blast furnace. The measuring device according to an embodiment of the present invention is coupled to a long high heat-resistant metal heat conductor with one end immersed in molten iron in the runway and the other end exposed to the outside of the runway, and the other end of the heat conductor It includes a protective tube positioned to be exposed to the outside of the runway, and a thermocouple disposed inside the protective tube and connected to the other end of the heat conductor.

Description

Blast furnace molten iron temperature measuring device

The present invention relates to a device for measuring the temperature of molten iron in a blast furnace, and more particularly, to a temperature measuring device for continuously measuring the temperature of molten iron in a blast furnace.

In general, iron ore and coke are charged in a blast furnace, and high-temperature hot air sent from a hot stove facility is blown in to cause a reduction and melting reaction, and molten iron and slag are made and stagnated inside the blast furnace. The molten material, including molten iron and slag, is discharged out of the blast furnace by opening the outlet installed in the lower part of the blast furnace, and this is called churning.

When the outlet is opened, the train will run for about 2 to 3 hours. The molten iron is discharged together with the slag and the specific gravity of the slag is lower than that of the molten iron, so the slag is located in the upper part of the molten iron. A wall called a skimmer separates the molten iron from the slag, and only the molten iron exists after the skimmer. However, in a high-temperature environment, molten iron is exposed to the atmosphere and the surface is oxidized and exists in the form of FeO.

In order to determine the thermal state of the blast furnace furnace, the temperature of the molten iron discharged to the outside is measured to determine the thermal over-deficiency state.

As a method of measuring the temperature of molten iron, a method of measuring the temperature by inserting a thermocouple into the refractory material disclosed in KR 10-2065063 and KR 10-1797740 is disclosed, but FeO in the surface of the molten iron forms a compound with the refractory material Because it melts the refractory material by making a low-melting-point compound, damage occurs within a few days and the response speed is slow, so it is not economical enough to replace the molten iron temperature measurement method using a disposable thermocouple.

As another method, the method of estimating the molten iron temperature by inserting a thermocouple into the refractory material of the runway disclosed in KR 10-1998740 is disclosed. It is difficult, and there is a problem in that accurate temperature calculation is difficult because the state of the refractory material is non-uniform.

On the other hand, in addition to contact temperature measurement, a non-contact temperature measurement method using the wavelength of light is disclosed, but not only the durability problem of the sensor due to the high temperature and dust environment around the outlet, but also the disturbance between the molten iron, which is the measurement target, and the measuring device during outgoing. There is a problem in that accurate temperature measurement is difficult due to factors.

Korean Patent Registration No. 10-2065063 Korean Patent Registration No. 10-1797740 Korean Patent Registration No. 10-1998740

SUMMARY Embodiments of the present invention provide an apparatus for measuring the temperature of molten iron in a blast furnace that can prevent damage to a thermocouple when continuously measuring the temperature of molten iron in a blast furnace in real time.

According to one aspect of the present invention, one end is located in a state immersed in the molten iron in the runway, the other end is exposed to the outside of the runway, the length of the long high heat-resistant metal heat conductor; and a thermocouple located outside the runway and connected to the other end of the heat conductor.

It is coupled to the other end of the heat conductor, the protective tube is positioned to be exposed to the outside of the runway surrounding the thermocouple; further includes.

a compensating wire having one end connected to the thermocouple and transmitting the thermoelectric power sensed by the thermocouple to the thermoelectric temperature converter; Display unit for outputting the temperature of the molten iron; and a controller for determining the temperature of the molten iron based on the temperature transmitted through the thermoelectric temperature converter and the thermal conductivity of the thermal conductor, and outputting the determined temperature through the display unit.

The heat conductor may have a relatively higher melting point than the temperature of the molten iron.

The heat conductor includes tungsten or tungsten carbide.

The heat conductor may be immersed in the molten iron inside the runway after the skimmer.

The protective tube may be fixedly installed on a frame located outside the tang.

The protective tube may be composed of a refractory material having a hollow hole therein.

The thermocouple may be positioned in the hollow hole so as not to contact the refractory material of the protective tube.

The shape of the cross-section of the heat conductor may be streamlined.

It further includes an inert gas supply unit connected to the hollow hole to supply the inert gas to the hollow hole.

It further includes an inert gas supply unit disposed adjacent to the heat conductor to supply an inert gas to the vicinity of the heat conductor so that the inert gas surrounds the heat conductor.

In the embodiments of the present invention, when the temperature is continuously measured while being immersed in the molten iron of the blast furnace, the high-temperature molten iron temperature is measured indirectly by a thermal conductor to prevent damage to the thermocouple, thereby ensuring continuous and stable measurement data, thereby increasing productivity. will be improved

1 is a view of a blast furnace in which a molten iron temperature measuring device according to an embodiment of the present invention is installed.
Figure 2 is a control block diagram of the molten iron temperature measuring apparatus according to an embodiment of the present invention.
Figure 3 shows a molten iron temperature measuring apparatus according to an embodiment of the present invention.
FIG. 4 is a cross-sectional view taken along line II of FIG. 3 .
Figure 5 shows a molten iron temperature measuring apparatus according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments introduced below are provided as examples in order to sufficiently convey the spirit of the present invention to those of ordinary skill in the art to which the present invention pertains. The present invention is not limited to the embodiments described below and may be embodied in other forms. In order to clearly explain the present invention, parts irrelevant to the description are omitted from the drawings, and in the drawings, the width, length, thickness, etc. of components may be exaggerated for convenience. Like reference numerals refer to like elements throughout.

1 is a view of a blast furnace in which a molten iron temperature measuring device according to an embodiment of the present invention is installed, FIG. 2 is a control block diagram of a molten iron temperature measuring device according to an embodiment of the present invention, and FIG. 3 is the present invention shows a molten iron temperature measuring device according to an embodiment, and FIG. 4 is a cross-sectional view taken along line I-I of FIG. 3 .

1 to 4, the melt discharged through the outlet 2 of the blast furnace 1 is separated into molten iron 4 and slag 5 by the specific gravity difference while passing through the tangent 3 . That is, the molten iron (4) having a high specific gravity is stored on the bottom side of the runway (3), and the slag (5) having a low specific gravity is floated on the molten iron. The molten iron (4) passes through the lower hole of the skimmer (6), is repaired in a racing barrel or a repair car (7), and then sent to the steel mill, which is the next process, and the slag (5) passes through the evacuation port (8). It is sent to the process and the scum process for subsequent processing.

In the runway after the skimmer 6, the molten iron temperature measuring device 10 of this embodiment may be installed. Hereinafter, the configuration in which the molten iron temperature measuring device 10 is installed in the runner after the skimmer 6 will be described, but the molten iron temperature measuring device 10 is the skimmer 6 before the runner, between the sweeping road and Gyeongju Tong, or Of course, it may be installed on a slag runner or the like through which only slag flows.

This molten iron temperature measuring device 10 is positioned with one end immersed in the molten iron 4 in the runway 3, and the other end is exposed to the outside of the runway 3 and is a long high heat resistant metal thermoelectric material. The conductor 20 and the protective tube 30 coupled to the other end of the heat conductor 20 and positioned to be exposed to the outside of the runway 3, and disposed inside the protective tube 30, at the other end of the heat conductor 20 A thermocouple 40 is connected, one end is connected to the thermocouple 40 and a compensation wire 50 that transmits the thermoelectric power sensed by the thermocouple 40 to the thermoelectric temperature converter 60, and a display unit that outputs the temperature of the molten iron (70) and the temperature transmitted through the thermoelectric temperature converter 60 and the control unit 80 for determining the temperature of the molten iron based on the thermal conductivity of the thermal conductor 20, and outputting the determined temperature through the display unit 70 includes

The thermal conductor 20 is always immersed in high-temperature molten iron and is made of a metal material having excellent heat resistance, abrasion resistance, high conductivity, and chemical resistance (especially FeO, H2S, CO, CO2, etc.).

The heat conductor 20 may be made of a metal material having a relatively higher melting point than the temperature of molten iron (eg, 1600° C.), and may include, for example, tungsten or tungsten carbide having a relatively high melting point.

The heat conductor 20 may have a long rod or rod shape, and transfer the heat of the molten iron to the thermocouple 40 disposed outside the runway 3 in a state where one end is immersed in the molten iron.

The shape of the cross section of the heat conductor 20 may be streamlined as shown in FIG. 4 . This is in order not to interfere with the flow of molten iron by the heat conductor 20 immersed in the molten iron.

The protection pipe 30 is positioned to be exposed to the outside of the runway 3 so as not to come into direct contact with the molten iron inside the runway 3, and can be fixedly installed on the frame 12 located outside the runway 3 .

The protective tube 30 may be formed of a refractory material having a hollow cylindrical shape for fixing the other end of the heat conductor 20 . Since the fixing flange 21 formed at the other end of the heat conductor 20 is seated and supported on the step formed inside the protection tube 30 , the heat conductor 20 may be fixedly coupled to the protection tube 30 .

The protective tube 30 is to protect the thermocouple 40 disposed therein from the effects of radiant heat of molten iron and slag, and a hollow hole 31 may be formed inside the protective tube 30, and the thermocouple 40 is In order to block the transfer of heat from the protective tube 30 to the thermocouple 40 , the hollow hole 31 may be positioned so as not to contact the refractory material of the protective tube 30 .

In addition, the protective tube 30 may be made of at least one insulating material of ceramic fiber, carbon fiber, and Inconel, which can be used as a high-temperature insulating material with high heat resistance and high melting point to reduce the effect of radiant heat of molten iron and slag.

The thermocouple 40 may be formed of a platinum wire. Platinum has a measurement temperature range of 1500°C or higher, has good stability, is strong in an oxidizing atmosphere, and has a small thermal conductivity error.

The thermocouple 40 may have one end connected to the other end of the thermal conductor 20 , and the other end connected to the compensating wire 50 .

The thermoelectric power of the thermocouple 40 may be transferred to the thermoelectric temperature converter 60 through the compensating wire 50 , converted into a temperature value through the thermoelectric temperature converter 60 , and then transferred to the controller 80 .

The control unit 80 may determine the actual temperature of the molten iron in consideration of the temperature transmitted through the thermoelectric temperature converter 60 and the thermal conductivity of the thermal conductor 20, and output the determined temperature through the display unit 70. .

That is, the controller 80 may calculate the actual temperature of the molten iron by correcting the difference in the heat loss temperature according to the thermal conductivity of the heat conductor 20 based on the temperature measured through the thermocouple 40 .

The temperature compensation value according to the thermal conductivity of the thermal conductor 20 may be previously calculated according to the length and thickness of the thermal conductor 20 and stored in advance in the storage unit 90 . Measurement and calculation of such thermal conductivity may utilize known measurement and calculation methods in the art related to thermal conductivity, and specific methods will be omitted. In addition, if necessary, the temperature of the molten iron is measured 1-2 times using a disposable thermocouple, and the temperature value of the molten iron calculated in consideration of the measured temperature value and the thermal conductivity of the thermal conductor 20 in the control unit 80 is compared. It may be determined and the correction data for the temperature difference value may be stored in the storage unit 90 .

The control unit 80 may be implemented by a processor or controller such as a central processor unit (CPU), a micro controller unit (MCU), a micro processor unit (MPU), and the like, and the storage unit 90 is a ROM, a RAM It may include at least one of (RAM), an IC memory such as a flash memory, a magnetic memory such as a hard disk, a diskette drive, and an optical memory such as an optical disk. In addition, the display unit 70 is an LCD (Liquid Crystal Display) that performs a function of outputting information corresponding to the user's request on the screen under the control of the control unit 80, including various function menus executed in the molten iron temperature measuring device 10 ) or a touch screen may be used.

Through this configuration, the temperature of the molten iron is continuously measured while the heat conductor 20 is always immersed in the molten iron of the runway 3, so that the furnace can be controlled in real time and controlled by a measurable standardized model. It is possible to improve the productivity by reducing the temperature deviation of the molten iron depending on experience and intuition.

In addition, the heat conductor 20 made of a high heat-resistant metal material (tungsten, tungsten carbide) immersed in the molten iron in the runway 3 has a high melting point that is much higher than the temperature of the molten iron and does not react with FeO or blast furnace slag, By having a property of good heat conduction, the reliability of temperature measurement can be improved by increasing durability compared to a conventional temperature measuring device in which heat conduction is arranged inside a refractory material.

Figure 5 shows a molten iron temperature measuring apparatus according to another embodiment of the present invention. Hereinafter, the same reference numerals are given to components having the same function, and detailed descriptions thereof are omitted.

5, the molten iron temperature measuring device of this embodiment is an inert gas supply unit 100 for supplying an inert gas into the hollow hole 31 in order to effectively block the heat transferred from the protective tube 30 to the thermocouple 40. may include more.

In addition, the inert gas supply unit 100 injects the inert gas to surround the periphery of the heat conductor 20 exposed to the air through the nozzle 101 disposed close to the heat conductor 20, so that the heat conductor 20 It can inhibit the formation of oxides by reacting with oxygen.

In the above, specific embodiments have been shown and described. However, it is not limited to the above-described embodiment, and those of ordinary skill in the art to which the invention pertains will be able to make various changes without departing from the spirit of the invention described in the claims below.

1: Blast furnace, 4: Dragon boat,
6: skimmer, 10: temperature measuring device,
12: frame, 20: heat conductor,
30: protection tube, 31: hollow hole,
40: thermocouple, 50: compensating wire,
60: thermoelectric temperature converter, 70: display unit,
80: control unit, 90: storage unit,
100: inert gas supply unit.

Claims (11)

a heat conductor made of a long high heat-resistant metal material having one end positioned in a state immersed in molten iron in the runway, and the other end exposed to the outside of the runway; and
The molten iron temperature measuring device of a blast furnace comprising a; a thermocouple located outside the runner and connected to the other end of the heat conductor. According to claim 1,
The molten iron temperature measuring device of a blast furnace is coupled to the other end of the heat conductor, and is positioned to be exposed to the outside of the runway and further comprises a protective tube surrounding the thermocouple. According to claim 1,
a compensating wire having one end connected to the thermocouple and transmitting the thermoelectric power sensed by the thermocouple to the thermoelectric temperature converter;
Display unit for outputting the temperature of the molten iron; and
The molten iron temperature measuring device of a blast furnace further comprising; a control unit that determines the temperature of the molten iron based on the temperature transmitted through the thermoelectric temperature converter and the thermal conductivity of the thermal conductor, and outputs the determined temperature through the display unit. According to claim 1,
The heat conductor has a relatively higher melting point than the temperature of the molten iron temperature measuring device of the blast furnace. The method of claim 1,
The heat conductor is a blast furnace molten iron temperature measuring device comprising tungsten or tungsten carbide. According to claim 1,
The molten iron temperature measuring device of the blast furnace in which the heat conductor is immersed in the molten iron inside the sump after the skimmer. 3. The method of claim 2,
The protection pipe is a temperature measuring device for molten iron in a blast furnace that is fixedly installed in a frame located outside the tang. 3. The method of claim 2,
The protective tube includes a refractory material,
A hollow hole is included in the inside of the protective tube,
The thermocouple is a blast furnace molten iron temperature measuring device that is positioned in the hollow hole so as not to come into contact with the refractory material of the protective tube. The method of claim 1,
The shape of the cross section of the heat conductor is a streamlined blast furnace molten iron temperature measuring device. 9. The method of claim 8,
The apparatus for measuring the temperature of molten iron in a blast furnace further comprising an inert gas supply unit connected to the hollow hole to supply an inert gas to the hollow hole. According to claim 1,
The apparatus for measuring the temperature of molten iron in a blast furnace further comprising an inert gas supply unit disposed close to the heat conductor and supplying an inert gas around the heat conductor so that the inert gas surrounds the heat conductor.

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