KR100955528B1 - Apparatus for detecting level of molteniron - Google Patents

Abstract

The present invention relates to a molten iron level measuring apparatus, and more particularly, by using a plurality of electromotive force sensors disposed on the outer surface of the molten iron container, the electromotive force generated in the molten iron is measured, and the level of the molten iron is measured using the measured electromotive force. The present invention relates to an apparatus for calculating.

To this end, the present invention, in the molten iron level measuring device for measuring the level of the molten iron contained in the molten iron container by measuring the electromotive force generated in the molten iron, a plurality of electromotive force arranged on the outer surface of the molten iron container with different heights sensor; And receiving a plurality of electromotive force generated between two adjacent electromotive force sensors among the plurality of electromotive force sensors, and identifying a position where the maximum electromotive force is generated among the magnitudes of the input electromotive force. And a signal processor for calculating a level.

Oxidation electromotive force, thermoelectric power, sensor, molten iron, blast furnace

Description

Apparatus for detecting level of molteniron

The present invention relates to a molten iron level measuring apparatus, and more particularly, by using a plurality of electromotive force sensors disposed on the outer surface of the molten iron container, the electromotive force generated in the molten iron is measured, and the level of the molten iron is measured using the measured electromotive force. The present invention relates to an apparatus for calculating.

In the blast furnace process, iron ore, which is a raw material, is charged into the blast furnace, pulverized coal used as a reducing agent and fuel is mixed with a high-pressure gas, blown into the blast furnace through a pipe, and the pulverized coal is burned by using high temperature hot air to melt the iron ore. . The molten iron produced by the melting of the iron ore is collected in the bottom of the blast furnace, and is discharged through the exit of the blast furnace if necessary.

At this time, in order to use the molten iron efficiently under the optimal conditions, it is required to accurately measure the level of the molten iron contained in the molten iron container such as blast furnace. However, since the molten iron is maintained at a high temperature of about 1600 ° C, it is difficult to accurately measure the molten iron level.

That is, the method of attaching the sensor for measuring the level of the molten iron inside the molten iron container is difficult to use for a long time due to the problem of the heat resistance of the sensor, and the molten iron by scanning a signal such as a laser from the molten iron container outside The method of measuring the level of is not available due to the specificity of the material of the molten iron container.

The present invention is to solve the above problems, in measuring the level of the molten iron contained in the molten iron container to measure the electromotive force generated in the molten iron using a plurality of electromotive force sensor disposed on the outer surface of the molten iron container, By using the measured electromotive force to calculate the level of the molten iron to solve the problem of heat resistance of the sensor generated during the molten iron level measurement process and to provide a molten iron measuring device that can accurately measure the level of the molten iron will be.

The molten iron level measuring device for achieving the above object is a molten iron level measuring device for measuring the level of the molten iron contained in the molten iron container by measuring the electromotive force generated in the molten iron, the height of each other on the outer surface of the molten iron container. A plurality of electromotive force sensors arranged while varying; And receiving a plurality of electromotive force generated between two adjacent electromotive force sensors among the plurality of electromotive force sensors, and identifying a position where the maximum electromotive force is generated among the magnitudes of the input electromotive force. And a signal processor for calculating a level.

Preferably, the plurality of electromotive force sensors are disposed on an outer surface of the molten iron container along a vertical direction.

The molten iron level measuring device may further include a temperature measuring device for measuring the temperature at the position where the electromotive force sensor is disposed and transmitting the measured temperature to the signal processor.

At this time, the signal processing unit calculates the electromotive force by using the temperature measured by the temperature measuring device, calculates the electromotive force by subtracting the electromotive force from the electromotive force measured by the electromotive force sensor, and calculates the magnitude of the calculated electromotive force In comparison, it may be configured to calculate the level of the molten iron contained in the molten iron container by identifying the position where the maximum electromotive force of the maximum magnitude is generated.

According to the molten iron level measuring apparatus of the present invention, by using the electromotive force sensor connected to the outer surface of the molten iron container, it is possible to determine the level of the molten iron by measuring the oxidative electromotive force generated on the surface of the molten iron, solving the heat resistance problem of the molten iron In addition, by using a plurality of electromotive force sensors to measure the electromotive force generated in the molten iron bar it is possible to more accurately measure the molten iron level. Furthermore, by calculating the thermoelectric power generated from the molten iron and correct the value measured by the electromotive force sensor it is possible to further increase the accuracy of the measurement.

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

1 is a structural diagram of a molten iron level measuring apparatus according to the present invention, as shown in the electromotive force sensor 4, the amplifier 5, the signal processing unit 6 and the display unit 7 disposed in the molten iron storage container (1) It includes.

The molten iron storage container (1) means blast furnace and other containers that contain molten iron in the steelmaking process and other subsequent processes in the steel mill, and the inner surface of the storage container is made of refractory material, and the outer surface is generally made of iron.

In the present invention, the level of the molten iron contained in the molten iron storage container (1) by calculating the oxidative electromotive force generated in the molten iron contained in the molten iron container (1).

That is, since molten iron contains carbon, oxidative electromotive force is generated during the oxidation of carbon. Oxygen is required in the oxidation process, and the oxidation of carbon occurs intensively on the surface of the molten iron in which the carbon contained in the molten iron is easily in contact with oxygen. do.

Therefore, the position where the maximum magnitude of the oxidative electromotive force is generated varies depending on the level of the molten iron, and the position of the maximum magnitude of the oxidative electromotive force is measured by measuring the oxidizing electromotive force at various positions having different heights and comparing the measured oxidizing electromotive force with each other. In this case, the level of the molten iron in the molten iron container 1 can be known.

Oxidation electromotive force generated in the molten iron is measured using a plurality of electromotive force sensors (4) disposed on the outer surface of the molten iron storage container (1). The electromotive force sensor 4 means a means for measuring the oxidative electromotive force between any two points of the molten iron container 1.

As shown in FIG. 1, the electromotive force sensor 4 generally includes an electrode 2 disposed on an outer surface of the molten iron container 1 and a conductive wire 3 connected to the electrode. However, the electromotive force sensor 4 may be configured in the form of a single conductor such as platinum wire.

The plurality of electromotive force sensors 4 are arranged on the outer surface of the molten iron storage container 1 while varying the height of each other, in this case is arranged in a line along the vertical direction of the molten iron storage container 1 as shown in FIG. desirable.

In the measurement of the electromotive force, two sensors are selected from among a plurality of electromotive force sensors 4 disposed on the outer surface of the molten iron container 1, and the electromotive force between the selected two sensors is measured. That is, the two selected sensors form a channel for electromotive force measurement.

As mentioned above, the present invention measures the level of the molten iron contained in the molten iron container 1 by grasping the position where the maximum magnitude of the oxidative electromotive force is generated. Accordingly, as shown in FIG. 1, it is preferable to select two sensors adjacent to each other to form a channel so that a plurality of channels can be continuously distributed along the vertical direction of the molten iron container.

The number of electromotive force sensors 4 disposed on the molten iron storage container 1 can be adjusted as necessary. If the number of electromotive force sensors 4 is increased to narrow the interval between channels, more accurate measurement of the molten iron level is possible. do.

The electromotive force measured using the electromotive force sensor 4 is amplified by the amplifier 5 for each channel and then input to the signal processor 6. Therefore, the amplifier preferably includes a plurality of input channels to amplify the plurality of input signals for each channel. In particular, it is desirable to remove noise by removing the AC component of the electromotive force to improve the accuracy of the measurement, the amplifier 5 is preferably configured so that the function of the low pass filter can be performed together.

The signal processor 6 receives the signal amplified by the amplifier 5 and performs signal processing to calculate the level of the molten iron contained in the molten iron container 1. That is, the level of the molten iron is calculated by identifying a position where the maximum magnitude of the electromotive force is generated by comparing the magnitude of the electromotive force for each channel input through the amplifier 5.

The level of the molten iron calculated by the signal processing section 6 is presented through the display section 7.

2 is a structural diagram of a molten iron level measuring apparatus capable of thermoelectric power compensation.

In the molten iron, in addition to the oxidative electromotive force generated during the oxidation of carbon, thermoelectric power is generated according to the temperature difference of the upper and lower parts of the molten iron. Therefore, the electromotive force measured by the electromotive force sensor 4 includes not only an oxidizing electromotive force but also a thermoelectric component. Therefore, in order to accurately measure the level of the molten iron by using the oxidative electromotive force intensively generated on the surface of the molten iron, it is desirable to remove the thermoelectric component according to the upper and lower temperature variations of the molten iron.

Since the thermoelectric power appears in proportion to the temperature deviation between the two measuring points, the thermoelectric power can be calculated by measuring the temperature deviation between the two measuring points. The measurement of the temperature for calculating the thermoelectric power is made through a temperature measuring device 8 such as a thermocouple. The temperature measured by the temperature measuring device 8 is transmitted to the signal processor 6, and the signal processor 6 calculates the thermoelectric power using the measured temperature.

The signal processor 6 calculates the precision electromotive force from which the electromotive force component has been removed by subtracting the above electromotive force from the electromotive force measured by the electromotive force sensor.

At this time, the thermoelectric component is preferably removed for each channel. As shown in FIG. 2, the temperature measuring device 8 is configured to measure the temperature at the position where each electromotive force sensor 4 is disposed, and each channel is configured. By measuring the temperature deviation between the positions where the two electromotive force sensors are formed, it is possible to remove the thermoelectric component for each channel.

Thereafter, the signal processor 6 calculates the level of the molten iron by identifying a position where the maximum magnitude of the electromotive force is generated by comparing the magnitude of the precision electromotive force calculated for each channel.

1 is a structural diagram of a molten iron level measuring apparatus according to the present invention.

2 is a structural diagram of a molten iron level measuring apparatus capable of thermoelectric power compensation.

<Description of Major Symbols in Drawing>

1: molten iron container 2: electrode

3: lead wire 4: electromotive force sensor

5 amplifier 6 signal processor

7: display unit 8: temperature measuring device

Claims (4)

In the molten iron level measuring device for measuring the level of the molten iron contained in the molten iron container by measuring the electromotive force generated in the molten iron, A plurality of electromotive force sensors arranged at different heights on the outer surface of the molten iron container; The level of the molten iron contained in the molten iron container by receiving a plurality of electromotive force generated between two adjacent electromotive force sensors among the plurality of electromotive force sensors, and grasping a position where the maximum electromotive force is generated among the magnitudes of the input electromotive force. Signal processing unit for calculating the; And It includes a temperature measuring device for measuring the temperature of the position where the electromotive force sensor is disposed and transmits to the signal processor, The signal processor calculates the electromotive force by using the temperature measured by the temperature measuring device, calculates the electromotive force by subtracting the electromotive force from the electromotive force measured by the electromotive force sensor, and compares the magnitude of the calculated precision electromotive force The molten iron level measuring apparatus for calculating the level of the molten iron contained in the molten iron container by grasping the position where the maximum electromotive force of the maximum magnitude is generated. The method of claim 1, And the plurality of electromotive force sensors are disposed on an outer surface of the molten iron storage container along a vertical direction. delete delete

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