KR20060063405A - Probe capable of measuring temperature inside of blast furnace - Google Patents

Abstract

Disclosed is a probe for measuring a multipoint temperature of a blast furnace. Probe for multi-point temperature measurement of such a blast furnace is a tube, and a thermocouple provided inside the tube to measure the temperature of a plurality of points inside the blast furnace, and to prevent heat transfer by filling the refractory around, And when the thermocouple descends from the inside of the blast furnace includes a spring that can prevent the bending by an external force. The blast furnace probe for temperature measurement has the advantage of being able to measure the temperature of the high temperature region by filling the refractory around the thermocouple element wire, thereby improving the reliability of the temperature measurement. In addition, when the thermocouple element is inserted, a larger number of thermocouple element elements may be inserted into the tube by not using a separate wire, thereby providing a more accurate temperature measurement.

Blast furnace, temperature, measurement, probe, thermocouple, refractory

Description

PROBE CAPABLE OF MEASURING TEMPERATURE INSIDE OF BLAST FURNACE}

BRIEF DESCRIPTION OF THE DRAWINGS The figure which shows schematically the state which measures the temperature inside a blast furnace by the probe for measuring the temperature of a general blast furnace.

2 is a view showing the internal structure of the probe for measuring the temperature of the blast furnace according to the prior art.

Figure 3 is a perspective view showing a probe for measuring the multi-point temperature of the blast furnace according to a preferred embodiment of the present invention.

4 is a side view of FIG. 3;

5 is a perspective view showing a thermocouple of the multi-point temperature measuring probe shown in FIG. 4.

6 is a side view showing the internal structure of FIG.

The present invention relates to a multi-point probe that can measure the temperature inside the blast furnace, and more particularly, it is possible to measure the temperature inside the blast furnace that can easily and accurately measure the temperature inside the blast furnace by improving its structure. It is about a multipoint probe.

In general, a blast furnace is a high-temperature, high-pressure reactor for producing molten iron by reducing the iron ore charged from the top of the furnace by hot air supplied from the bottom.

The interior of this blast furnace exhibits a pattern within the temperature range of 500 ° C. to 1500 ° C. from the top of the furnace to the bottom where the molten iron is discharged.

As shown in Fig. 1, the inside of the blast furnace 1 is iron ore from the top of the ore layer (G) and the solid zone (C) of the coke layer, the soft melting zone (W) of the semi-melt state, It is made of molten iron layer (Y).

In the layer structure inside the blast furnace, the operation efficiency of the blast furnace (1) greatly varies depending on the structure of the soft fusion zone (W). Therefore, grasping the shape and position of the soft fusion zone W is a very important factor in the operation.

In order to investigate the shape and location of the softening fusion zone (W), the temperature inside the blast furnace should be measured, and various methods have been developed for measuring the temperature inside the blast furnace.

Among these methods, a method of measuring temperature by inserting the multi-point temperature measuring probe 3 into the blast furnace 1 is widely known.

That is, the multi-point temperature measurement probe measurement method by dropping the probe (3) accumulated in the protective tube in the upper part of the blast furnace (1) with a charge, the probe is controlled along the interior of the blast furnace in the process of falling along the inside of the blast furnace ( It is a system which can measure a temperature by sending out to 7), and can measure a temperature until the probe 3 melts by an impact or high temperature.

Therefore, there is an advantage that the temperature of the charge can be directly measured during the operation in such a way that the point where the probe 3 is melted with the charge is recognized as the soft fusion zone W.

FIG. 2 discloses a Korean Patent Registration No. 0,373,067, which is filed under the name of a blast furnace surveying multipoint sensor and a manufacturing method thereof as an example of a probe for measuring a multipoint temperature.

As shown, the multi-point temperature measuring probe is composed of a tube 4 having a length of several tens of meters or more, and a thermocouple 13 provided in the tube 4 and capable of measuring the temperature inside the blast furnace.

In addition, the thermocouple 13 is inserted into the tube 4 to prevent the transfer of high temperature heat to the thermocouple 13, and inserted into the inside of the protective tube 9 and therein An inner tube 15 and 16 into which the thermocouple wires 18 and 19 are inserted, and a wire 17 connecting the thermocouple 13 to each other.

At this time, the thermocouple element wire (18, 19) is composed of a positive electrode 19 and a cathode ray 18, by being connected to a plurality of contacts provided in the tube (4) can measure the temperature of a plurality of places at the same time.

However, as the number of thermocouple probes having such a structure is accurate, the more the number of thermocouples inserted into the tube, the more precise the temperature can be measured. However, the diameter of the tube is limited to a certain size, which limits the number of thermocouples to be inserted. Precise temperature measurement is difficult.

In addition, in order to insert a larger number of thermocouples in a limited space, the outer diameter of the thermocouple needs to be reduced. In this case, since the element wire of the thermocouple becomes thinner, the measuring resistance is increased by the square power with respect to the ratio of the loop resistance. There is a problem that a measurement error occurs due to the influence on the input impedance (Input Impeadance).

Furthermore, in the case of blast furnaces, the temperature is measured while the multi-point temperature measuring probe is strongly pressed by the load of the upper charges, and as the diameter of the inner pipe becomes thinner, the gap between the anode wire and the cathode wire and the inner surface of the inner pipe is reduced. Since the wire may be narrowed and cut, there is a problem that it is difficult to measure the temperature of the high temperature.

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem, and an object of the present invention is to provide a multi-point temperature measuring probe capable of measuring temperature even in a high temperature region by placing a thermocouple element wire by filling a thermocouple with refractory.

In addition, another object of the present invention is to insert a thermocouple element wire does not use a separate wire by inserting a larger number of thermocouple element wires inside the tube body for more accurate temperature measurement multi-point temperature measurement probe To provide.

Further, another object of the present invention is to reduce the temperature measurement error by maintaining the input impedance stable by lowering the reciprocation resistance (Loop Resistance) by maintaining the wire of the thermocouple above a certain diameter even when a large number of thermocouples are inserted To provide a multipoint temperature probe.

In order to realize the above object of the present invention, an embodiment of the present invention is a tube; A thermocouple provided inside the tubular body to measure temperature at a plurality of points in the blast furnace, and to prevent heat from being transferred by filling a refractory around; And it provides a multi-point temperature measuring probe including a spring that can prevent the thermocouple to bend by the external force when descending from the inside of the blast furnace.

Hereinafter, with reference to the accompanying drawings will be described in detail the structure of the multi-point temperature probe according to a preferred embodiment of the present invention.

As shown in Figure 3 to 5, the multi-point temperature probe (Probe) 20 proposed by the present invention is provided in the tube body 21 and the tube body 21, the temperature of a plurality of places in the blast furnace The thermocouple 27 that can measure the, and the thermocouple 27 includes a spring 25 to prevent the bending by the external force when the charge into the blast furnace.

In the multi-point temperature measuring probe having such a structure, the tube 21 has a structure in which an empty space is formed therein so that the thermocouple 27 may be inserted.

Therefore, high temperature heat can be prevented from being transferred to the thermocouple 27.

At this time, the tube 21 is preferably formed in a telescopic (telescopic) structure can be adjusted to stretch the length.                     

And, the thermocouple 27 is connected to a plurality of contacts (P1, P2, P3, P4, P5, P6) provided on the tube 20 can efficiently measure the temperature inside the blast furnace.

The thermocouple 27 is a protective tube 30 provided in the inside of the tubular body 20, a plurality of thermocouple elements 32, 34 that can be inserted into the protective tube 30 to measure the temperature, and Filled inside the protective tube 30 includes a refractory 36 that can prevent heat from being transferred to the plurality of thermocouple elements 32, 34.

Since the protective tube 30 has a structure in which an empty space is formed therein, a plurality of thermocouple wires 32 and 34 may be inserted therein.

The thermocouple element wires 32 and 34 form a pair of anode lines 32 and cathode lines 34, and the anode lines 32 and cathode lines 34 are formed of a plurality of contacts formed on the tubular body 214. Respectively.

Therefore, when the multi-point temperature measuring probe 20 of a predetermined length falls inside the blast furnace, the temperature measured at the plurality of contacts P1 ... P6 is transmitted to the thermocouple element wires 32 and 34, so that The temperature of multiple points can be measured efficiently at the same time.

At this time, the diameter of the anode wire 32 and the cathode ray 34 may be preferably formed within the range of 0.3 to 0.5mm.

In addition, the refractory 36 is filled in the protection tube 30 to surround the thermocouple element wires 32 and 34.

Therefore, the high temperature heat transmitted through the tubular body 21 and the protective tube 30 is minimized from being transferred to the thermocouple element wires 32 and 34.

In this case, the refractory 36 may be applied to various kinds of refractory, but preferably includes magnesium oxide (MgO) which is a compound of oxygen and magnesium.

The refractory 36 is charged inside the protective tube 30 to protect the thermocouple wires 32 and 34 from high temperature heat and to fix the thermocouple wires 32 and 34. do.

That is, the plurality of thermocouple wires 32 and 34 may be fixedly disposed at a predetermined position by the solidification of the refractory 36.

At this time, each of the thermocouple elements 32 and 34 needs to maximize their spacing to avoid contact with each other as much as possible.

Therefore, the thermocouple elements 32 and 34 may be arranged in a zigzag shape.

As described above, the probe for measuring the multipoint temperature of the blast furnace according to the preferred embodiment of the present invention has the advantage that the reliability of the temperature measurement can be improved by enabling the temperature measurement in the high temperature region by filling the refractory around the thermocouple element wire.

In addition, when the thermocouple element is inserted, a larger number of thermocouple element elements may be inserted into the tube by not using a separate wire, thereby providing a more accurate temperature measurement.

In addition, even when a larger number of thermocouples are inserted, there is an advantage in that the input impedance is kept stable by reducing the loop resistance by maintaining the element wires of a predetermined diameter or more, thereby reducing the temperature measurement error.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. In addition, it is natural that it belongs to the scope of the present invention.

Claims (7)

Tube body; A thermocouple provided inside the tubular body to measure temperature at a plurality of points in the blast furnace, and to prevent heat from being transferred by filling a refractory around; And Probe for measuring the multi-point temperature comprising a spring that can be prevented from bending by the external force when the thermocouple is lowered in the blast furnace. The method of claim 1, The tube has a telescopic structure, the length of the multi-point temperature measurement probe is variable. The method of claim 1, The thermocouple may include a protective tube provided inside the tube, a plurality of thermocouple element wires inserted into the protective tube to measure a temperature, and filled in the protective tube to prevent heat from being transferred to the plurality of thermocouple element wires. Probe for multipoint temperature measurement, containing refractory. The method of claim 3, wherein The plurality of thermocouple element wires each of the multi-point temperature measurement probe consisting of a cathode wire and a cathode wire. The method of claim 4, wherein The plurality of thermocouple element wire is a multi-point temperature measurement probe having a diameter within the range of 0.3 ~ 0.5mm. The method of claim 3, wherein The plurality of thermocouple element wire is a multi-point temperature measurement probe is arranged in a shape that can be maximized each other. The method of claim 3, wherein The refractory is magnesium oxide (MgO) probe for multi-point temperature measurement.

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