KR101062013B1 - Multi thermocouple for multipoint measurement and its manufacturing method - Google Patents

Abstract

The present invention relates to a multi-thermocouple for multi-point measurement that can make the position of the temperature-contacting contact point of each sheath thermocouple installed in the probe when the temperature is measured at a plurality of points.

The multi-thermocouple for multi-point measurement according to the present invention includes a measuring unit formed by combining a plurality of sheath thermocouples having different lengths so that one end thereof is positioned at the same position, a cover tube surrounding the measuring unit, and each of the sheath thermocouples; Compensation wires are provided between the connectors connected to the control circuit, wherein the sheath thermocouple is inserted into the protective tube, the protective tube and each end is non-ground welded in a position spaced a predetermined distance from the end of the protective tube And an inorganic insulator filled in the first and second thermocouple small wires and the protective tube, and the compensation wire is installed to connect the first and second thermocouple small wires of the sheath thermocouple to the connector.

Multipoint Measurement, Thermocouple, Equal Interval

Description

Multi thermocouple for multipoint measurement and its manufacturing method {Multi thermocouple for multi point measuring and manufacturing method of that}

The present invention relates to a multi-thermocouple for multi-point measurement, and more particularly, multi-therm for multi-point measurement, which can uniformly position the temperature-contacting contact point of each sheath thermocouple installed in the probe when the temperature is measured at a plurality of points. It's about couples.

In general, blast furnaces of general steel mills that make pig iron using iron ore, coke, and flux are raw materials, and therefore, it is difficult to grasp the temperature and gas loss in each part of the inside because the height is more than several tens of meters.

Therefore, the multi-point sensor for blast furnace detection enables the development of smelting technology by exploring the temperature and reaction state of each part up to the lower stage where iron ore reacts and smelts inside the blast furnace, as well as improving product quality and cost. Promote

The multi-point sensor for blast furnace probes can be equipped with multiple sheath thermocouples for temperature measurement inside the receiving pipe to measure the temperature at each point in a wide horizontal range at the same time. In order to accurately measure the temperature at each point, it is of utmost importance that the positions of the temperature measuring contacts of the sheath thermocouples at which the temperature is measured are equally spaced.

However, the length of the receiving pipe and each sheath thermocouple must be several tens of meters or more in order to explore each part from the inner portion to the inner portion of the blast furnace having a height of several tens of meters or more. Since it is difficult to uniformly adjust the position of the thermocouple side contact point, the conventional blast furnace probe multi-point sensor was not spaced at equal intervals between the sheath thermocouples, and thus there was a problem in that the measurement efficiency was deteriorated.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a multi-thermocouple for multi-point measurement in which the temperature measuring contact points at which the temperature is measured during the temperature measurement for each point in the horizontal direction of the blast furnace are separated by an equal distance.

Multi-point thermocouple for measuring multi-point according to the present invention for achieving the above object is a measuring unit formed by combining a plurality of sheath thermocouples of different lengths, each end is located in the same position, a cover tube surrounding the measuring unit and And a compensating wire installed between the respective sheath thermocouples and the connector connected to the control circuit, wherein the sheath thermocouple is inserted into the protective tube and the protective tube and each end thereof is spaced a predetermined distance from the end of the protective tube. And an inorganic insulator filled in the inside of the protective tube and the first and second thermocouple wires which are ungrounded welded in position, wherein the compensating wire is configured to connect the connectors to the first and second thermocouple wires of the respective sheath thermocouples. Is installed.

According to the present invention, a method of manufacturing a multi-thermocouple for multi-point measurement includes two temperature-contacting contacts spaced apart by a predetermined distance by non-ground welding the first and second thermocouple small wires from the end of the protective tube to each end of the first and second thermocouple small wires. Sheath thermocouple forming step of forming a sheath thermocouple having a measurement unit, and a measurement unit forming step of manufacturing a measuring unit by welding the plurality of sheath thermocouples of different lengths to each other so that the temperature-contacting contact in each sheath thermocouple are mutually spaced; A tube insertion step of attaching the traction line to any one of the combined sheath thermocouples and inserting the measurement unit into the cover tube, a tube drawing step of drawing the cover tube into which the measurement unit is inserted to a predetermined diameter, and the drawn cover One end of the tube is cut off at a point spaced apart from the sheath thermocouple, and the other end of the tube is And a tube closing step of cutting the exposed tube and connecting the first and second thermocouple wires of the sheath thermocouples exposed through the other end of the cover tube to a connector connected to the control circuit using a compensation wire. .

The multi-thermocouple for multi-point measurement according to the present invention can efficiently measure the temperature at each point inside the blast furnace because the temperature measuring contact points in the blast furnace are evenly spaced and spaced apart, thereby increasing the accuracy of the data. .

Hereinafter, with reference to the accompanying drawings will be described in more detail the multi-point thermocouple for multi-point measurement according to the present invention.

1 to 4 illustrate a preferred embodiment of the multi-point thermocouple 100 for multi-point measurement according to the present invention.

Referring to the drawings, the multi- thermocouple for measuring multi-point 100 according to the present invention is a measurement unit 10 is formed with a plurality of the temperature measuring contact 19 for measuring the temperature, and surrounding the measurement unit 10 It includes a cover tube 20, the compensation wire 30 for connecting the measuring unit 10 and the connector 31.

The measuring unit 10 is formed by first to third sheath thermocouples 12 to 14 having different lengths from each other.

The first sheath thermocouple 12 has the longest length and the third sheath thermocouple 14 is formed to have different lengths. The first to third sheath thermocouples 12 to 14 have different lengths. Since the structure is the same, the structure of the sheath thermocouple 11 will be described at a time.

The sheath thermocouple 11 includes a protective tube 15, first and second thermocouple wires 16 and 17 inserted into the protective tube 15, and an inorganic insulator 18 filled in the protective tube 15. Include.

The protective tube 15 has a cylindrical shape having a predetermined diameter and has an inner space extending in the longitudinal direction therein.

The first and second thermocouple wires 16 and 17 are non-ground welded to the inside of the protective tube 15, and the temperature-contacting contacts 19 of the first and second thermocouple wires 16 and 17 are spaced apart from each other. have. Accordingly, since one of the sheath thermocouples 11 is provided with two thermocouple small wires so that the positions of the temperature-contacting contacts 19 are spaced by a predetermined interval, temperature measurement at two points is possible.

An inorganic insulator 18 is filled in the protective tube 15.

In general, since the protective tube 15 is formed of a metal material such as stainless steel, it is preferable to fill the inorganic insulator 18 for insulation between the protective tube 15 and the first and second thermocouple wires 16 and 17.

In the present embodiment, magnesium oxide (MgO) is applied as the inorganic insulator 18 and filled in the protective tube 15. In addition, the inorganic insulator 18 is made of aluminum oxide (Al ₂ O ₃ ) and zinc oxide (ZnO). May be used.

Since the sheath thermocouple 11 is thin and small in size and light in weight, the sheath thermocouple 11 has little restriction in installation, and can be measured in a small place or in a small heat capacity, and can be easily measured due to easy workability and fast response speed. have.

The measuring unit 10 is formed by combining three first to third sheath thermocouples 12 to 14 having different mutual lengths and having first and second thermocouple wires 16 and 17, respectively, as described above. The first to third sheath thermocouples 12 to 14 are welded so that one end of the protective tube 15 is located at the same point.

Accordingly, the first and third sheath thermocouples 14 are positioned at different ends of the protective tube 15 from each other, and the first and second thermocouple wires 16 and 17 have respective ends of the protective tube 15. Since sixth temperature measuring contact point 19 having different measurement positions is formed in the entire measuring unit 10 because the distance is installed so as to be spaced apart from each other.

In this embodiment, three first to third sheath thermocouples 12 to 14 having different lengths are installed because six temperature-contacting points 19 need to be formed. Alternatively, the sheath thermocouple 11 is required. Accordingly, two or four or more may be coupled to each other so that each of the temperature-contacting points 19 are spaced at equal intervals.

The cover tube 20 surrounds the measurement unit 10.

The cover tube 20 protects the measuring unit 10 formed by combining a plurality of sheath thermocouples 11. After forming the measuring unit 10, the cover tube 20 is formed inside the cover tube 20 having a tube shape. Since it is easy to insert the measuring unit 10, the cover tube 20 has an inner diameter relatively larger than the outer diameter of the measuring unit 10.

The cover tube 20 reduces the inner and outer diameters by drawing so that the measuring unit 10 can be fixed after the measuring unit 10 is inserted, and one end thereof is from the end of the first sheath thermocouple 12. Cut and finish at points spaced apart.

The other end of the cover tube 20 is such that one end of the sheath thermocouple 11 is exposed to a predetermined length to the outside so as to easily connect the thermocouple element wires installed in each of the first to third sheath thermocouples 12 to 14 with a reinforcement wire. Is cut.

The sleeve 21 is welded to the other end of the cover tube 20, and the inside of the sleeve 21 is filled with epoxy.

The reinforcing wire is connected to the thermocouple element wire one end before the sleeve 21 is installed, the other end is connected in order to the connector 31 installed in the control circuit.

Therefore, in the control circuit, the temperature is measured through the electromotive force due to the temperature difference between the reference contact point and the temperature contact point 19 through the compensation lead 30.

Hereinafter, the manufacturing method of the multi-point thermocouple 100 for multi-point measurement according to the present invention will be described in detail.

① Sheath thermocouple formation stage

First, the sheath thermocouple 11 having a heat conducting wire for measuring temperature is formed.

As described above, the sheath thermocouple 11 is installed by non-ground welding two first and second thermocouple wires 16 and 17 so that the positions of the temperature-contacting contacts 19 are spaced apart from each other inside the protection tube 15. It is formed by filling magnesium oxide, which is an inorganic insulator 18, inside (15).

The end distances of the first and second thermocouple small wires 16 and 17, that is, the separation distance between the RTDs 19 may be selectively set according to the measurement position at which the measurement is made.

The sheath thermocouples 11 are provided with three different lengths, that is, the first to third sheath thermocouples 12 to 14.

② Formation Unit

In this step, the prepared first to third sheath thermocouples 12 to 14 are bonded to each other by welding.

By allowing one end of the first to third sheath thermocouples 12 to 14 to be located at the same point, the other ends of the first to third sheath thermocouples 12 to 14 are coupled to each other. Are different, and the positions of the temperature-contacting contacts 19 of the first and second thermocouple wires 16 and 17 installed therein are also spaced apart from each other, so that the first to third sheath thermocouples 12 to 14 are coupled to each other. In the measuring unit 10 formed therein, six temperature-contacting points 19 spaced apart from each other are formed.

Each of the RTDs 19 may be spaced at equal intervals as necessary, or may be different from each other so that temperature measurements may be made at a specific location in the blast furnace.

③ Tube Insertion Step

In this step, the measuring unit 10 is inserted into the cover tube 20.

The cover tube 20 is in the form of a tube having an inner diameter somewhat larger than the outer diameter of the measuring unit 10 so that the measuring unit 10 can be easily inserted, and an end of the first sheath thermocouple 12 of the measuring unit 10. After the traction line 23 is welded to the traction line 23 through the cover tube 20 and pulls the traction line 23 to insert the measuring unit 10 into the cover tube 20. .

④ Tube drawing step

In this step, the traction line 23 is cut, and the cover tube 20 into which the measurement unit 10 is inserted is drawn out.

As described above, since the cover tube 20 is a tube material having a large diameter to facilitate the insertion of the measuring unit 10, the cover tube 20 is fixed to fix the position of the measuring unit 10 to the inside of the cover tube 20. ) To draw the measuring unit 10 is fixedly coupled to the inside of the cover tube (20).

⑤ Tube finishing step

After drawing the cover tube 20, both ends of the cover tube 20 are cut and finished. The other end of the cover tube 20 adjacent to the other end of the first sheath thermocouple 12 is a first sheath thermocouple. Cut at a point spaced a predetermined distance from the end of (12) and weld the end to prevent foreign matter from entering.

One end of the cover tube 20 is cut so that one end of the sheath thermocouples 11 may be exposed to a predetermined length for connection with the compensation wire 30 to be described later.

⑥ Compensation lead connection step

When the closing of the cover tube 20 is completed, the first and second sheath thermocouples 12 to 14 are connected to the first and second thermocouple wires 16 and 17 through the compensation wire 30 through the connector 31. Connect with

First, each of the first and second thermocouple wires 16 and 17 is connected to one side of the compensation wire 30, and then the sleeve 21 is welded to one end of the cover tube 20, and the inside The epoxy resin is filled to protect the connection point between the first and second thermocouple wires 16 and 17 and the compensation wire 30.

The other side of the compensating lead 30 is connected to the connector 31 installed in the control circuit in an order so that the temperature value measured at each of the temperature measuring contacts 19 is detected.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1 is a perspective view showing an embodiment of a multi-thermocouple for multi-point measurement according to the present invention;

2 is a partially cutaway perspective view of FIG. 1;

3 is a cross-sectional view showing a sheath thermocouple installed in the cover tube of FIG.

4 is a partially cutaway perspective view illustrating a state in which the measuring unit of FIG. 1 is inserted into a cover tube using a traction line.

<Explanation of symbols for the main parts of the drawings>

100; Multi Thermocouple for Multipoint Measurement

10; Measuring unit

11; Sheath thermocouple

15; Sheriff

16,17; First and second thermocouple wires

18; Inorganic insulator

20; Cover tube

23; Towboat

30; Compensation Lead

Claims (2)

A measuring unit formed by combining a plurality of sheath thermocouples having different lengths such that one end thereof is positioned at the same position; A cover tube surrounding the measuring unit; Compensation lead is provided between each of the sheath thermocouple and a connector connected to the control circuit; The sheath thermocouple may include a protective tube and first and second thermocouple wires which are inserted and installed inside the protective tube and are non-ground welded at each end spaced apart from each other by different distances from the ends of the protective tube so that the positions of the temperature-contacting points are different. And an inorganic insulator filled in the protective tube, The compensation wire is a multi-thermocouple for multi-point measurement, characterized in that installed to connect the first and second thermocouple small wire and the connector of each sheath thermocouple. A sheath thermocouple forming step of forming a sheath thermocouple having two side-temperature contact points spaced apart from each other by non-ground welding such that the first and second thermocouple small wires of the protective tube have different end distances from the ends of the protective tube; A measuring unit forming step of manufacturing a measuring unit by welding the plurality of sheath thermocouples having different lengths to each other so that the temperature-contacting contacts in the respective sheath thermocouples are spaced apart from each other; A tube insertion step of attaching a traction line to any one of the coupled sheath thermocouples and inserting the measurement unit into the cover tube; A tube drawing step of drawing the cover tube into which the measuring unit is inserted to a predetermined diameter; A tube closing step of cutting one end of the drawn cover tube at a point spaced apart from the sheath thermocouple at a predetermined distance, and the other end of the cover tube to cut the sheath thermocouple to expose a predetermined length; And a compensation wire connection step of connecting the first and second thermocouple elements of each of the sheath thermocouples exposed through the other end of the cover tube with a connector connected to the control circuit using a compensation wire. How to make a couple.

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