KR101345705B1 - A speedy response thermocouple preventing decrease of insulation resistance at high temperature - Google Patents

Abstract

The present invention relates to a high-temperature insulation resistance degradation suppression fast response thermocouple, more specifically, a pair of (+) wire in one sheath thermocouple, the (-) wire removed in the other sheath thermocouple The present invention relates to a high temperature insulation resistance suppression fast response thermocouple that is manufactured to significantly reduce shunt error while utilizing existing thermocouple products by making a new sheath thermocouple.
The high temperature insulation resistance lowering fast response thermocouple of the present invention comprises: a pair of sheath thermocouples in which + wires are removed from one sheath thermocouple and -sheaths are removed from another sheath thermocouple;
A sheath fixing insulating tube interposed between the pair of sheath thermocouples; A metal protective tube which inserts the sheath fixing insulating tube and fills a space with an insulating material to fix the insulating tube; The wires of opposite poles drawn out from the pair of sheath thermocouples may be formed of an on-contact point formed by forming a closed circuit at the end of the insulated tube.
The sheath thermocouple of the present invention can be used in places where various constraints exist, for example, heat treatment furnaces such as annealing furnaces in steel mills, and can effectively prevent shunt errors caused by an ambient temperature higher than the surface temperature of the heat treated product. have. In addition, the high-temperature insulation resistance suppression fast response thermocouple put in the cover located on one side of the furnace, it is possible to measure and recover the surface temperature of the heat-treatment product with a quick response, by the heat-treatment product moving at high speed Wear of thermocouples can also be effectively prevented. In addition, since a thermocouple having a shunt error prevention structure can be manufactured by using an existing sheath thermocouple product, it is easy to manufacture and use.

Description

A speedy response thermocouple preventing decrease of insulation resistance at high temperature}

The present invention relates to a high-temperature insulation resistance suppression fast response thermocouple, and more specifically, in a pair of thermocouples, (+) wire in one sheath thermocouple, (-) wire in another sheath thermocouple By using a pair of sheath thermocouples without the use of a pair of sheaths, the sheath thermocouples of the present invention can be fabricated so that the high-temperature insulation resistance can be reduced while using the existing thermocouple products and having a quick response and significantly reducing shunt errors. Relates to the response thermocouple.

In general, thermocouples are used in various industrial fields such as annealing furnaces in steel mills. As sheath thermocouples are widely used in industrial sites, many problems of use of sheath thermocouples have appeared in various situations. Especially in high temperature environments, the output value of thermocouples includes errors due to unknown causes. Due to the structure of the sheath thermocouple, insulation degradation at high temperatures is inevitable.

The sheath thermocouple is largely composed of a metal shell, an insulator, and a wire. In order for the sheath thermocouple to have a fast response, the measuring object and the sheath thermocouple must be quickly thermally balanced. In order to quickly reach thermal equilibrium, the smaller the volume of the measuring body is, the more advantageous it is. As the volume of the measuring body decreases, the volume occupied by the insulator inside the sheath thermocouple also decreases, and as the volume of the insulator decreases, errors due to insulation degradation occur.

1 is a cross-sectional view for comparing the volume of the sheath thermocouple. When comparing the sheath thermocouple having a diameter of 8.0 mm and the sheath thermocouple having a diameter of 4.8 mm, as shown in FIG. 1, FIG. 1A shows a diameter of only insulator 13 having a diameter of 6.0 mm and a cross-sectional area of about 28 mm ² , and FIG. 1B shows an insulator 13. ) The diameter of the bay is 3.6mm and its cross section is about 10 mm ² Therefore, it can be seen that the cross-sectional area of the insulators of both is about three times different.

If it is used at a relatively low temperature, there is no big cause of error, but at a high temperature, it may cause an error. The sheath cable, which is a raw material of the sheath thermocouple, mostly uses magnesium oxide (MgO) as an insulator. This is because it is inexpensive and has a melting point of about 2800 ° C., which is suitable as a high temperature insulator. However, magnesium oxide has a property of lowering the insulation resistance by about 1/10 as the temperature rises in the high temperature region by 100 ° C. For this reason, when using the sheath thermocouple at high temperature, many causes of error appear. Among them, the most prominent one is the shunt error and shows a very large error.

2 is a view for explaining the relationship between the general thermocouple and the temperature distribution. When the thermocouple of FIG. 2 (a) is given a temperature distribution such that the middle part becomes a high temperature as shown in (b), the temperature measurement output of the thermocouple shows a significant error. Therefore, when the RT is located in the high temperature region, positive or negative errors are generated by the relationship between the temperature of the middle part of the sheath thermocouple and the magnitude of the magnitude.

The main cause of shunt error is the insulation degradation between thermocouple wires, and the resistance of thermocouple wires is also related. The shunt error is closely related to the electromotive force generation principle of the thermocouple. In principle, the shunt error is output from zero. When a temperature difference ΔT is given to a specific portion of one thermocouple element wire, an electromotive force ΔE is generated at both ends of the section. The magnitude is the product of the element's intrinsic thermoelectric coefficient S and the temperature difference ΔT.

ΔE = S · ΔT

That is, thermoelectric power corresponding to the temperature difference is generated. The electromotive force of a practical thermocouple is also derived from this principle.

3 is a view for explaining a temperature distribution of a general thermocouple. When the temperature at both ends of the thermocouple wires A, B is T ₁ , T ₂ as shown in FIG. 2, the thermoelectric power E is expressed using the thermoelectric powers S _A and S _B of each wire, as follows.

4 is a diagram for explaining the relationship between the potential distribution and the temperature distribution of a general thermocouple. In the above, the potential distribution in the longitudinal direction of the element wire is as shown in FIG. 4 when the K type thermocouple is assumed. The potential does not change where the temperature is constant, but the potential changes where there is a temperature gradient.

FIG. 5 is a diagram for explaining the potential distribution when the middle portion of the thermocouple overcomes high temperature and maintains insulation. FIG. The potential distribution in the case where insulation between element wires is maintained in the high temperature distribution at which the intermediate portion becomes high temperature is as shown in FIG. 5. In this case, the output is zero when the reference contact point and the temperature contact point are at the same temperature, but the potential difference occurs between the element wires at the portion where the intermediate temperature increases.

6 is a diagram for explaining a shunt error generation potential distribution when an intermediate portion of a thermocouple is insulated at a high temperature. Magnesia (MgO) and alumina (Al ₂ O ₃ ), which are insulators, have a lower insulation resistance by about 1/10 as they rise by 100 ° C in the high temperature region. Therefore, at the temperature of the intermediate hot portion, a leak current flows in the portion. This leak current flows through the closed circuit including the element wires and the temperature-contacting point and increases the resistance of the element wires, so that the potential gradient of the D1 portion in FIG. 5 becomes small and changes to the potential gradient as shown in D1 'in FIG.

Usually, the potential gradient D2 is changed in size so that no current flows, and it is a shunt error that a change in magnitude is displayed as an output. Therefore, since the magnitude of the shunt error is related to the resistance of the element wire, the higher the temperature region is, the larger the distance from the temperature-contacting point becomes. Alternatively, the smaller the sheath diameter, the easier it is to relate to the resistance of the insulator and the resistance of the wire.

Such a shunt error is more likely to occur as the sheath outer diameter is thinner, and more likely to occur when the heating temperature of the middle portion is 800 ° C or higher, and when the heating length of the middle portion is long. In addition, when the heating position of the intermediate part is far from the temperature contact point, the lower the insulation resistance, the easier it is to occur. Depending on the thermocouple type, K type thermocouples are easier to generate than R type thermocouples, and thinner wire diameters are more likely to occur at the same sheath diameter.

Prior art document JP2008-90742 is a cis-type K thermocouple patent, which solves the problem of so-called shunt error in which the thermocouple core wire of the thermocouple used for a long time at high temperature drops and the thermoelectric power decreases, resulting in measurement error. In a sheath-type K thermocouple in which a (+) side thermocouple core wire of an alloy mainly containing nickel and chromium and an nickel mainly contains a (-) side thermocouple core wire through an insulator in a metal sheath for the purpose. In order to solve the problem of long-term use at high temperature, thermocouple core drop, decrease in thermal power and error in measurement value, the positive side thermocouple core diameter is 15 ~ 22% of the sheath outer diameter, and the negative side thermocouple core Sheath type K thermocouples or positive (+) thermocouple cores with wire diameters of 23-27% of the sheath outer diameter 23-27% of the sheath outer diameter and (-) thermocouple core diameters with 15-22% of the sheath outer diameter One sheath K thermoelectric The table is presented.

However, such a method requires a separate production of the sheath thermocouple, making it difficult to produce a small amount, and as the core wire becomes thick, a problem arises that the response is inferior.

7 is a cross-sectional conceptual view for explaining the structure of the sheath thermocouple 10 of the prior art which is widely used. If the non-metallic protection tube cannot be used due to shock and vibration at high temperature, if the thermocouple shape is not straight, the metal thermocouple cannot be used and the sheath thermocouple is suitable.

Referring to FIG. 7, in the conventional sheath thermocouple 10, a thermocouple element 12 of positive and negative poles is positioned inside a sheath 11 that is a steel, and magnesia, which is an insulator 13, is formed. It is charged, and the structure is such that the (+), (-) element wire forms a closed circuit through the on-contact point 14 of the same material as the sheath 11, so that the other end not shown may be connected to a separate measuring device. The element wire 12 is a structure protruding out of the sheath.

However, the sheath thermocouple 10 as described above has a problem that the shunt error can not be effectively prevented, and as a countermeasure against the shunt error until now, the sheath 11 has a relatively large outer diameter. Increasing the size of the diameter), shortening the length of the intermediate portion to be heated, or introducing a cooling device for lowering the temperature.

However, when the size of the wire diameter is increased, it is difficult to use in a place where the response is low and the measurement must be completed quickly, and the shortening of the length of the intermediate portion to be heated cannot be used in a situation where the measurement position is fixed. The introduction of the cooling device has a problem that requires a large investment cost.

The present invention was devised to solve the problems of the prior art as described above, and an object of the present invention is to provide a sheath thermocouple having a structure that effectively prevents shunt error while utilizing an existing sheath thermocouple product.

It is another object of the present invention to provide a sheath thermocouple capable of effectively preventing shunt errors caused by an ambient temperature higher than the surface temperature of a heat-treated product while being used in a heat treatment furnace in which various constraints exist, such as an annealing furnace in a steel mill. It is done.

In addition, an object of the present invention is to provide a sheath thermocouple capable of measuring the surface temperature of the heat treated product with a quick response, and can effectively prevent wear of the thermocouple.

In order to achieve the above object, the high-temperature insulation resistance suppression fast response thermocouple of the present invention, a pair of sheath thermocouples in which + wires from one sheath thermocouple and -sheath from another sheath thermocouple; A sheath fixing insulating tube interposed between the pair of sheath thermocouples; A metal protective tube which inserts the sheath fixing insulating tube and fills a space with an insulator to fix the insulating tube; The wires of opposite poles drawn out from the pair of sheath thermocouples may be formed of an on-contact point formed by forming a closed circuit at the end of the insulated tube.

In the present invention, the extra wires forming the closed circuit of the pair of sheath thermocouple is characterized in that the end is finished with an insulator and a refractory cement, and the insulator tube interpolating the pair of sheath thermocouple is made of a ceramic material In addition, the insulator is characterized in that the heat-resistant cement or magnesia.

In addition, in the present invention, the pair of sheath thermocouples are protected by a protective cap formed at the tip of the metal protective tube, and the pair of sheath thermocouples is further protected by a tip cap formed by protruding from the tip of the metal protective tube. In addition, the sheath fixing insulating tube for interpolating the pair of sheath thermocouple is characterized in that two or more insertion holes are formed.

The sheath thermocouple of the present invention can be used in places where various constraints exist, for example, heat treatment furnaces such as annealing furnaces in steel mills, and can effectively prevent shunt errors caused by an ambient temperature higher than the surface temperature of the heat treated product. have.

In addition, the high-temperature insulation resistance suppression fast response thermocouple put in the cover located on one side of the furnace, it is possible to measure and recover the surface temperature of the heat-treatment product with a quick response, by the heat-treatment product moving at high speed Wear of thermocouples can also be effectively prevented.

In addition, since a thermocouple having a shunt error prevention structure can be manufactured by using an existing sheath thermocouple product, it is easy to manufacture and use.

1 is a cross-sectional view for comparing the volume of a typical sheath thermocouple.
2 is a view for explaining the relationship between the general thermocouple and the temperature distribution.
3 is a view for explaining a temperature distribution of a general thermocouple.
4 is a diagram for explaining the relationship between the potential distribution and the temperature distribution of a general thermocouple.
FIG. 5 is a diagram for explaining the potential distribution when the middle portion of the thermocouple overcomes high temperature and maintains insulation. FIG.
6 is a diagram for explaining a shunt error generation potential distribution when an intermediate portion of a thermocouple is insulated at a high temperature.
7 is a schematic cross-sectional conceptual view of a sheath thermocouple according to the prior art.
8 is an embodiment of a high-temperature insulation resistance degradation suppression fast response thermocouple according to the present invention.
FIG. 9 is a conceptual view of a portion B (body) in front of FIG. 8.
10 is a perspective conceptual view of the sheath fixing insulator tube embedded in FIG. 8, (a) is a shape before the sheath thermocouple is inserted, (b) is a shape in which the sheath thermocouple is inserted into a single type, and (c) Is a perspective conceptual view showing a shape in which two single type thermocouples inserted in a sheath fixing thermocouple are coupled in series.
11 is another embodiment of the high-temperature insulation resistance degradation suppression fast response thermocouple according to the present invention.
12 is another embodiment of the high-temperature insulation resistance degradation suppression fast response thermocouple according to the present invention.

Hereinafter, a specific embodiment of the present invention will be described in detail with reference to the accompanying drawings.

8 is an embodiment of the high-temperature insulation resistance degradation suppression fast response thermocouple according to the present invention. FIG. 9 is a conceptual view of a portion B (body) in front of FIG. 8.

First, the gist of the present invention, the thermocouple of the present invention is a method of manufacturing one thermocouple using two sheath thermocouple (10). One sheath thermocouple 10 uses a positive wire, and the other sheath thermocouple 10 uses a negative wire to form one closed circuit. Unused wires were removed and finished with MgO and zirconia cement. In addition, two sheath thermocouples were fixed with an insulated tube.

8 and 9, the high temperature insulation resistance suppression fast response thermocouple according to the present invention removes a positive wire from one sheath thermocouple 10 and a negative wire from another sheath thermocouple 10. It is made using a pair of sheath thermocouples 10. The pair of sheath thermocouples 10 is interposed between the sheath fixing insulator tube 20 and interposed between the pair of sheath thermocouples 10 and the sheath fixing insulator tube 20. In the very narrow space, there is an air layer.

10 is a perspective conceptual view of the sheath fixing insulator tube embedded in FIG. 8, (a) is a shape before the sheath thermocouple is inserted, (b) is a shape in which the sheath thermocouple is inserted into a single type, and (c) Is a perspective conceptual view showing a shape in which two single type thermocouples inserted in a sheath fixing thermocouple are coupled in series.

Referring to FIG. 10, four insertion holes 21 are formed in the sheath fixing insulating tube 20 of the present invention. One of the gist of the present invention is to prevent the phenomenon that the insulation resistance is lowered at high temperature. If the insulation resistance is weakened at a high temperature and the insulation resistance decreases, the + wire and the-wire may be electrically connected. That is, in the present invention, when there is no insulated tube, the filling of the internal filler is weakened, and if a leakage current occurs between each element and the sheath sheath, it is necessary to exclude the possibility of connecting the + element wire and the-element wire. There is no purpose to connect two sheaths on purpose. Therefore, in the present invention as shown in FIG. 8, an insulating tube is inserted between two sheaths to prevent electrical connection between the two wires even if a leak current occurs.

In addition, the thermocouple can be configured as a single type, double type or multi type. The single type is a thermocouple composed of one on-contact point. In the case of the present invention, since two sheaths are required at one on-contact point, at least two insertion holes 21 of the sheath fixing insulation tube 20 are required. The double type refers to a thermocouple composed of two on-contact points. In the present invention, since four sheaths are required, at least four insertion holes 21 of the sheath fixing insulation tube 20 are required as shown in FIG. .

Multi-type refers to a type in which several sheaths of single or double type are bundled together. For example, if a different length of thermocouple measuring a temperature of one point is required, the length is different from using three thermocouples. Three thermocouples can be bundled together. 10 (c) shows a form in which two thermocouples are connected in series.

In other words, a single type thermocouple requires two insertion holes, but a double type thermocouple requires four sheath insertion holes. Therefore, in the present invention, the sheath fixing insulating tube 20 having two or more insertion holes is required.

In addition, the sheath fixing insulating tube 20 is inserted into the metal protective tube 30, and the space between the metal protective tube 30 and the sheath fixing insulating tube 20 is also filled with insulation to fix the insulating tube. . The wires of opposite poles drawn out from the pair of sheath thermocouples 10-1 and 10-2 form a closed circuit at the end of the sheath fixing insulating tube 20 to form an on-contact point 14. The tip of the metal protective tube 30 is protected by a heat-resistant cement.

In the present invention, the extra wires to be removed while constituting the closed circuit of the pair of sheath thermocouples 10-1 and 10-2 as described above are finished with insulators and refractory cement as shown in FIG. do.

The insulator used in the present invention is a heat-resistant cement or magnesia, and the pair of sheath thermocouples 10-1 and 10-2 protrude to the tip of the metal protective tube 30 to be protected by the protective cap 40.

Although the cap of the present invention can be protected by one cap as in FIGS. 11 and 12, it is also possible to install and use the cap in duplicate as in FIG. 8. In FIG. 8, the protective cap 40 serves as a finishing function of the internal insulation and a mechanical fixing role of each component, and the tip cap 40-1 directly protects the hot contact by mechanical and chemical wear of the hot contact. It serves to prevent. That is, in this invention, it is comprised so that one cap may be used or more caps can be selectively used according to the environment and atmosphere in which a thermocouple is used.

12 is another embodiment of the high-temperature insulation resistance degradation suppression fast response thermocouple according to the present invention. As shown in FIG. 12, the high temperature insulation resistance lowering fast response thermocouple according to the present invention may be equipped with a separate protective cap 40 to improve mechanical wear, and the protective cap 40 may be cobalt alloy (UNCO-50). It is preferable to process and use a product having excellent wear resistance such as).

Increasing the size of the wire diameter (diameter of the wire), which is one of the conventional methods for preventing shunt errors, the response speed is slowed. However, in the structure of the present invention, the wire diameter according to the prior art sheath thermocouple ( As it is maintained in the same manner as in Fig. 7), a response speed similar to that of one sheath thermocouple can be maintained.

In addition, the high-temperature insulation resistance degradation suppression fast response thermocouple according to the present invention, while increasing the outer diameter of the sheath 11, the wire diameter is maintained as it is, the responsiveness is as fast as the conventional sheath thermocouple 10, the volume of the insulating structure can be increased shunt It is a structure that can prevent errors.

The insulation structure of the present invention described above includes a magnesia or alumina insulator in the sheath thermocouple 10, a fine air layer between the sheath thermocouples 10-1 and 10-2 and the sheath fixing insulation tube 20, It is composed of a sheath fixing insulating tube 20 made of alumina or the like, and has superior insulation means compared to the sheath thermocouple 10 of the prior art in which only an insulator of a single material exists.

The sheath fixing insulation tube 20 of the present invention is used for insulation between the insulation means and the sheath thermocouples 10-1 and 10-2 as described above and between the wires, and the metal protective tube 30 is generated in the measurement environment. To protect against shocks.

The high temperature insulation resistance drop suppression fast response thermocouple according to the present invention has a far distance between the element wire and the element wire compared to the conventional general sheath thermocouple 10 according to the prior art, the insulator 13 is thickened to generate a shunt error due to high temperature use In this case, the insulation can be prevented from falling. In addition, the conventional cooling method for reducing the temperature of the thermocouple (cooling water, N ₂ It is much cheaper than gas) and can be easily manufactured since existing sheath thermocouples can be utilized.

10, 10-1, 10-2: sheath thermocouple 11: sheath 12: (thermocouple) element wire
13: Insulator 14: On-contact 20: Insulation tube for sheath fixing
21: insertion hole 30: metal protective tube 40: protective cap
40-1: Tip Cap

Claims (7)

A pair of + sheaths removed from one sheath thermocouple and finished with an insulator, allowing only the wires to be used, and another pair of sheath thermocouples removed with a wire and finished with an insulator, allowing only the + wires to be used. Sheath thermocouples;
A sheath fixing insulating tube surrounding the pair of sheath thermocouples and into which the pair of sheath thermocouples are interpolated;
A metal protective tube which inserts the sheath fixing insulating tube and fills a space with an insulator to fix the insulating tube;
The wires of opposite poles drawn from the pair of sheath thermocouples are composed of a hot contact formed by forming a closed circuit at the end of the insulated tube, so that the distance between the + wire and the-wire becomes farther, and the volume of the insulating structure increases. A high temperature insulation resistance fast response thermocouple, characterized in that it can be prevented. The method of claim 1,
The extra element wire forming the closed circuit of the pair of sheath thermocouple is a high temperature insulation resistance drop fast response thermocouple, characterized in that the front end is finished with an insulator and a refractory cement. The method of claim 1,
The insulating tube for interpolating the pair of sheath thermocouple is a high temperature insulation resistance suppression fast response thermocouple, characterized in that the ceramic material. 3. The method according to claim 1 or 2,
The insulator is a high-temperature insulation resistance drop fast response thermocouple, characterized in that the heat-resistant cement or magnesia. 3. The method according to claim 1 or 2,
And the pair of sheath thermocouples is protected by a protective cap formed at the tip of the metal protective tube. 3. The method according to claim 1 or 2,
And the pair of sheath thermocouples is further protected by a tip cap formed by protruding from the tip of the metal protective tube. The method according to claim 1 or 3,
A high temperature insulation resistance drop fast response thermocouple, characterized in that two or more insertion holes are formed in the sheath fixing insulating tube for interpolating the pair of sheath thermocouples.

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