KR101614547B1 - Apparatus for measuring sample temperature of hot stove - Google Patents

Abstract

It is possible to measure and detect the sample temperature only at the time of the correction of the emissivity of the radiation thermometer 30 without being fixed to the hot air dome 41, And a hot air furnace sample temperature detecting device capable of drastically reducing the maintenance cost is introduced.

The hot air furnace sample temperature detecting device includes a dome opening / closing valve 100 installed at the upper end of the hot air dome 41 so as to open or close the hot air dome 41, Descending device 200 which is provided so that the dome opening / closing valve 100 is opened and the dome opening / closing valve 100 descends into the hot air dome 41 when the hot air dome 41 is opened, A converter 400 for converting a temperature measurement signal of the sample temperature measured by the sample temperature detector 300 into a current signal, And a temperature indicator (500) for displaying the current signal converted by the converter (400) at a temperature measured so as to be read by an operator.

Hot air furnace, sample temperature, thermocouple, detection

Description

[0001] APPARATUS FOR MEASURING SAMPLE TEMPERATURE OF HOT STOVE [0002]

The present invention relates to a hot air furnace sample temperature detecting apparatus, and more particularly, to a hot air furnace sample temperature detecting apparatus which can be used only at the time of emissivity correction of a radiation thermometer provided in a hot air furnace.

Referring to FIG. 1, the temperature of the hot air paths 20 and 40 for supplying hot air to the tuyere 11 of the blast furnace 10 should be maintained at a constant temperature. To this end, a pyro-meter 30, which is a kind of a noncontact type thermometer, is installed in the hot air dome 21, and the temperature of the hot air dome 21 is measured by the radiation thermometer 30.

The temperature of the hot air dome 21 measured from the radiation thermometer 30 is compared with the set temperature preset in the temperature controller 60 from the temperature controller 70. At this time, The combustion air flow control valve 80 is operated to adjust the flow rate of the air supplied to the hot air paths 20 and 40 so that the temperature of the hot air paths 20 and 40 is adjusted.

On the other hand, since the radiation temperature can be changed due to the wavelength of the diffused reflection light from the environment, the radiation rate can be changed periodically (once / three months) in order to accurately measure the internal temperature of the hot dome 21 do.

Therefore, the correction thermometer 50 is installed in the hot air dome 41 of the adjacent hot air path 40 connected to the hot air path 20 provided with the radiation thermometer 30 so that the hot air dome 50 periodically (once / Is compared with the measured temperature measured by the radiation thermometer (30) by detecting the sample temperature of the sample (41). At this time, the measured sample temperature is displayed on the operation screen 90 of the work room, and the operator compares the displayed sample temperature with the measured temperature measured by the radiation thermometer 30, and if a certain deviation occurs, .

Here, the detection of the sample temperature of the hot air dome 41 measured by the calibration thermometer 50 may be performed periodically (once / three months) once. The life of the calibration thermometer 50 is It took about 1 ~ 3 months to continue to replace, and it required a lot of replacement cost (2.5 million won / one) for this continuous replacement, and the time and manpower for the replacement work had to be continuously increased, There is a problem that it takes.

The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus for measuring a sample temperature of a radiation thermometer, So that it is possible to remarkably reduce the cost of maintaining the hot air path.

According to an aspect of the present invention, there is provided an apparatus for detecting a hot air furnace sample temperature, the apparatus comprising: a dome opening / closing valve installed at an upper end of a hot air dome to open or close a hot air dome; A sample temperature detector for detecting and detecting a sample temperature of the hot air dome when the dome opening / closing valve is opened to open the hot air dome when the dome opening / closing valve is opened; A converter for converting a temperature measurement signal for a sample temperature measured by the sample temperature detector into a current signal and a temperature indicator for displaying the current signal converted by the converter at a measured temperature so that an operator can read it .

Wherein the sample temperature detector comprises: a temperature measurement holder fixed to the lifting / lowering device and connected to the transducer by a pair of compensating conductors; and a pair of the pair of compensating conductors coupled to the temperature measuring holder, And a holder thermocouple equipped with a thermocouple element of the thermocouple.

The pair of compensating conductors are separated from each other at an end of the temperature measuring holder, and the pair of thermocouple elements are separated from each other at an inner side of the holder thermocouple. When the temperature measuring holder is coupled with the holder thermocouple, It is preferable that the lead wire and the thermocouple element are in contact with each other.

The elevating device preferably includes a cylinder operating in a vertical direction, a cylinder drive line connected to the cylinder, and a control panel connected to the cylinder drive line to control operation of the cylinder.

Preferably, the cylinder drive line is provided with a pulley for assisting smooth movement of the compensating wire when the sample temperature detector ascends and descends.

According to the hot-air furnace sample temperature detecting apparatus as described above, the sample temperature can be measured and detected only when the emissivity of the radiation thermometer is corrected without being fixed to the hot air dome. So that the maintenance cost of the hot air can be remarkably reduced.

Hereinafter, an apparatus for detecting a hot air furnace sample temperature according to a preferred embodiment of the present invention will be described in detail with reference to FIG. 2 through FIG. 5, but partially with reference to FIG.

The hot air furnace sample temperature detecting apparatus according to an embodiment of the present invention includes a dome opening / closing valve 100, a sample temperature detector 300, a converter 400, and a temperature indicator 500.

The dome opening / closing valve 100 is installed at the upper end of the hot air dome 41 so as to open or close the hot air dome 41, and may be manually or automatically opened and closed. However, It is preferable to be configured to be manually opened and closed to reduce the maintenance and installation cost.

The sample temperature detector 300 is installed in an ascending / descending device 200 disposed above the hot air dome 41. The hot air dome 41 is connected to the sample temperature detector 300 by the dome opening / Descends the inside of the hot air dome 41 by the ascending / descending device 200 to measure and detect the sample temperature of the hot air dome 41. When measurement and detection of the sample temperature is completed , And is lifted again by the lifting / lowering device (200) and is released to the outside of the hot air dome (41).

The lifting and lowering apparatus 200 includes a cylinder 210 operating in a vertical direction, a cylinder drive line 220 connected to the cylinder 210, and a cylinder 210 connected to the cylinder drive line 220, And a control panel 230 for controlling the operation of the control panel 230.

Since the lifting apparatus 200 is used for measuring the sample temperature only at the time of correcting the emissivity of the radiation thermometer 30, it can be normally located or kept at a certain place around the hot air path 40, It can be moved and fixed to be positioned above the hot air dome 41. At this time, the end of the driving line 220 may be fixed to the support 270 to fix the lifting device 200. The ascending / descending device 200 may be continuously installed at a predetermined position above the hot air dome 41.

The driving line 220 is entirely made of a metal pipe. When the driving line 220 is positioned above the hot air dome 41, a part of the driving line 220 is made of a flexible hose 221 for smooth movement desirable. A pressure supply valve 240 and a pressure release valve 250 are installed on the driving line 220 with the cylinder 210 interposed therebetween.

The cylinder 210 may be actuated by hydraulic or pneumatic pressure, but is preferably configured to be actuated by pneumatic pressure in view of frequency of use. In this case, the drive line 220 is filled with air as a driving fluid.

4, the cylinder 210 includes a piston 211 operated by the pressure of the driving fluid and a spring 212 connected to the piston 211 to assist the operation of the piston 211. [ And a stopper 213 for restricting the movement of the piston 211 is provided.

The control panel 230 is provided to allow the operation of the cylinder 210 to be controlled by an operator and the operation of the pressure supply valve 240 and the pressure release valve 250 is controlled by the control panel 230 A sample temperature measurement button 231 for controlling each sample temperature and a sample temperature measurement completion button 232 are provided in the control panel 230. A flow meter 233 for controlling the operation speed of the cylinder 210, (234).

The sample temperature detector 300 is mounted on the piston 211 of the cylinder 210 of the ascending / descending device 200 and connected to the transducer 400 by a pair of compensating wires 280. [ And a holder thermocouple 320 coupled to the temperature measurement holder 310 and having a pair of thermocouple elements 290 connected to the pair of compensating wires 280 when coupled.

Referring to FIG. 5, the pair of compensating wire 280 is separated from the end of the temperature measuring holder 310. Specifically, the first wire 281 of the compensating wire 280 is connected to the temperature measuring holder 310, And the second lead wire 282 contacts the inner terminal 312 spatially separated from the protrusion protrusion 311. The second lead wire 282 contacts the protrusion terminal 311 formed at the end of the temperature measurement holder 310, More specifically, the first element 291 of the thermocouple element 290 is connected to the inner side of the holder thermocouple 320. The first thermocouple element 290 is connected to the inner side of the holder thermocouple 320, And the second element 292 is in contact with the second terminal 322 which is spatially separated from the first terminal 321. The first terminal 321 is connected to the groove 321a of the first terminal 321,

When the temperature measuring holder 310 and the holder thermocouple 320 are coupled as described above, the first lead wire 280 and the second lead wire 282 of the separate contact compensating wire 280 are connected to the thermocouple element A temperature measurement loop is formed by the thermocouple element 290 and the compensating wire 280 so that the temperature of the sample temperature Measurement and detection becomes possible.

The converter 400 converts the temperature measurement signal for the sample temperature measured by the sample temperature detector 300 into a current signal. The converter 400 is connected to the sample temperature detector 300 and the pair of compensation wires 280 Lt; / RTI >

A pulley 260 that winds the compensating wire 280 may be installed on the driving line 220 so that the compensating wire 280 can move smoothly when the sample temperature detector 300 ascends and descends .

The temperature indicator 500 is used to display the current signal converted by the converter 400 at a measured temperature for the operator to read, and is electrically connected to the converter 400.

Hereinafter, the operation of the hot air furnace sample temperature detecting apparatus according to the embodiment of the present invention will be described.

In order to correct the emissivity of the radiation thermometer 30 installed in the hot air dome 21 and continuously measure the temperature of the hot air dome 21, The hot air path sample temperature detecting apparatus according to the embodiment of the present invention is positioned above the hot air dome 41 of the adjacent hot air path 40 connected thereto and the sample temperature detector 300 is disposed above the hot air dome 41 Vertically. At this time, the driving line 220 of the ascending / descending device 200 is fixed to the supporting table 270.

Thereafter, the handle 110 of the dome opening / closing valve 100 installed at the upper end of the hot air dome 41 is turned to open the hot air dome 41 and the sample temperature measurement button 231 of the control panel 230 When the pressure supply valve 240 is opened, the pressure of the working fluid is applied to the cylinder 210 and the piston 211 is lowered. As a result, the sample temperature detector 300 installed in the piston 211 is driven by the hot air dome 41 ) To measure the sample temperature.

When the operator presses the sample temperature measurement completion button 232 of the control panel 230 after the measurement of the sample temperature is completed, the pressure supply valve 240 is closed and the pressure release valve 250 is opened, The pressure of the working fluid applied to the pressure reducing valve 210 is released to the atmosphere through the pressure relief valve 250. At this time, the piston 211 rises due to the action of the spring 212 installed on the cylinder 210, so that the sample temperature detector 300 installed on the piston 211 is released to the outside of the hot air dome 41 do.

When the measurement of the sample temperature by the sample temperature detector 300 is completed, the temperature measurement signal for the measured sample temperature is converted into a current signal through the converter 400, and the temperature indicator 500 is read by the operator The sample temperature is displayed so that the sample temperature detection is completed.

When the sample temperature detection is completed, the operator turns the handle 110 of the dome opening / closing valve 100 to close the hot air dome 41, compares the detected sample temperature with the temperature measured by the radiation thermometer 30, And corrects the emissivity of the radiation thermometer 30 when the deviation exceeds a certain limit. At this time, since the holder thermocouple 320 which has been used once is disposable, it is separated from the after-use temperature measurement holder 310 and discarded, and a new holder thermocouple 320 is coupled to the temperature measurement holder 310 when measuring the next sample temperature. Here, since the replacement cost of the holder thermocouple 320 is about 1,400 won per unit, the maintenance cost by the hot air can be remarkably reduced in comparison with the replacement cost (2.5 million won / one) of the conventional thermometer 50 for correction .

While the invention has been shown and described with respect to the specific embodiments thereof, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the following claims It is to be understood that the invention may be modified and changed without departing from the scope of the invention.

1 is a view showing a conventional hot air furnace sample temperature detecting process.

2 is a diagram illustrating a hot air furnace sample temperature detecting apparatus according to an embodiment of the present invention.

3 is a view illustrating operation of a hot air furnace sample temperature detecting apparatus according to an embodiment of the present invention.

FIG. 4 is a view showing a sample temperature detector applied to the hot air furnace sample temperature detecting apparatus according to the embodiment of the present invention; FIG.

5 shows a temperature measurement holder and a holder thermocouple of a sample temperature detector.

Description of the Related Art

100: dome opening / closing valve 200: ascending / descending device

210: cylinder 220: drive line

230: control panel 300: sample temperature detector

310: Temperature measurement holder 320: Holder thermocouple

400: Transducer 500: Temperature indicator

Claims (5)

A dome opening / closing valve 100 installed at the upper end of the hot air dome 41 to open or close the hot air dome 41; Descending device 200 disposed above the hot air dome 41 so that when the hot air dome 41 is opened by the dome opening / closing valve 100, the hot air dome 41 A sample temperature detector 300 for measuring and detecting a sample temperature of the hot air dome 41; A converter 400 for converting a temperature measurement signal for a sample temperature measured by the sample temperature detector 300 into a current signal; And And a temperature indicator (500) for displaying the current signal converted by the converter (400) at a temperature measured so as to be read by an operator, The sample temperature detector 300 includes a temperature measurement holder 310 fixed to the lifting apparatus 200 and connected to the transducer 400 by a pair of compensating wires 280, And a holder thermocouple (320) having a pair of thermocouple elements (290) coupled to the pair of compensating wires (280) when coupled to the thermocouple (310). delete The method according to claim 1, The pair of compensating wires 280 are separated from each other at the end of the temperature measuring holder 310 and the pair of thermocouple elements 290 are separated from each other inside the holder thermocouple 320, Wherein the compensating wire (280) and the thermocouple element (290) are in contact with each other when the holder (310) and the holder thermocouple (320) are coupled. The method according to claim 1, The lifting apparatus 200 includes a cylinder 210 operating in the vertical direction, a cylinder drive line 220 connected to the cylinder 210, and a cylinder drive line 220 connected to the cylinder drive line 220, And a control panel (230) for controlling operation of the hot air furnace. The method of claim 4, Wherein the cylinder drive line (220) is provided with a pulley (260) for assisting smooth movement of the compensating wire (280) when the sample temperature detector (300) ascends and descends.

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