KR102074470B1 - Apparatus for measuring state of a heated member and Controlling method thereof - Google Patents

Abstract

The present invention is to stably sense the state of the member to be heated by the hot melt, and to transmit the information including the sensed data to the external devices to monitor the state of the member to be heated A measuring device for measuring the state of and a control method thereof.
To this end, the present invention is a measuring device for measuring the state of the member to be heated heated by a heat source, connected to the member to be heated to measure the state of the member to be heated, the heat source casing is installed A main body unit disposed to be spaced apart from an outer surface of the main body; An insulation flange unit having one end coupled to a casing protrusion protruding from the outer surface of the heat source casing, and the other end coupled to the body unit such that the body unit is disposed in a form suspended from the casing protrusion; And a heat-resistant plate unit coupled to the casing protrusion and disposed between the outer surface of the heat source casing and the body unit to block heat from the heat source casing from being transferred to the body unit. A measuring device for measuring the state of a member and a control method thereof are provided.

Description

Apparatus for measuring state of a heated member and control method method for measuring the state of the member to be heated

The present invention relates to a measuring apparatus for measuring a state of a member to be heated and a control method thereof, which stably senses a state of a member to be heated by a high temperature melt, and externally stores information including the sensed data. The present invention relates to a measuring device for measuring the state of a member to be heated so that the state of the member to be monitored can be monitored by transmitting the same, and a control method thereof.

In general, the molten steel inside the ladle is low in cleanliness due to temperature, nonuniformity of components, etc., and thus, an additional process is required to produce high clean steel.

At this time, the chemical reaction between molten steel and secondary materials is used by refining molten steel to produce inclusions of low melting point compounds such as alumina, and to separate and injure in molten steel.

In addition, by injecting argon or nitrogen gas, which is an inert gas, through the bubbling plug installed at the bottom of the ladle, which is a container containing molten steel, the stirring of the molten steel is increased to achieve uniform temperature, and is produced through a chemical reaction. A method of removing the inclusions by separating the inclusions into a molten steel upper slag layer is used.

In this process, the bubbling plug must be replaced at an appropriate time because the molten steel is damaged by melting. For example, if the service life of the bubbling plug is based on 24 to 25 cycles, whether or not to continue to use it by visually observing the degree of damage caused by melting of the bubbling plug at the bottom of the ladle from the point of use of 20 cycles. The worker judges every time.

However, since the ladle bottom is always coated with molten steel remaining after casting completion, it is difficult to accurately determine the damage caused by melting of the bubbling plug.

In addition, it is necessary to wait for the ladle to cool to the workable temperature after the one-time work for visual confirmation, which causes a decrease in work efficiency.

In addition, if it is not possible to determine the damage state due to over-melting early and can not be replaced at the appropriate time, a large accident may occur that the molten steel flows out through the bottom of the ladle.

On the other hand, if the bubbling plug is replaced early due to concerns, manufacturing cost increases.

Republic of Korea Patent Application Publication No. 10-2014-0123074 (Name of the invention: gas purging plug including a wear indicator, published 21 October 2014)

The problem to be solved of the present invention is to stably sense the state of the member to be heated by the hot melt, and to transmit the information including the sensed data to external devices to monitor the state of the member to be heated To provide a measuring device and a control method thereof for measuring the state of the member to be heated.

In order to solve the above problems, the present invention is a measuring device for measuring the state of the member to be heated by a heat source, connected to the member to be heated to measure the state of the member to be heated, A main body unit spaced apart from the outer surface of the heat source casing in which the member is installed; An insulation flange unit having one end coupled to a casing protrusion protruding from the outer surface of the heat source casing, and the other end coupled to the body unit such that the body unit is disposed in a form suspended from the casing protrusion; And a heat-resistant plate unit coupled to the casing protrusion and disposed between the outer surface of the heat source casing and the body unit to block heat from the heat source casing from being transferred to the body unit. A measuring device for measuring the state of a member is provided.

The main body unit is disposed to surround at least a portion of the main body case, the outer surface of the main body case, the installation frame coupled to the other end of the heat insulation flange unit, the heat-resistant member assembly disposed in the inner space of the main body case, A battery disposed on an inner space of the heat resistant member assembly, a substrate assembly disposed on an inner space of the heat resistant member assembly and connected to the battery, a base plate for installing the substrate assembly, and a front side of the base plate; It may be disposed to include a front cover coupled to the body case.

The body unit may further include an antenna for communicating with an external device, a temperature sensor for sensing a temperature of an internal space of the heat resistant member assembly, and a cooling fan for cooling the battery and the substrate assembly.

The substrate assembly includes a sensing unit for measuring a state of the member to be heated, a communication unit for transmitting integrated information including sensing data sensed by the sensing unit to an external device, and simultaneously analyzing the sensing data. It may include a control unit for controlling the body unit.

The base plate has an inlet for allowing air to flow into the cooling fan, an outlet for discharging air circulated through the internal space of the heat resistant member assembly, and an antenna exposed hole for exposing the antenna to the front of the base plate. Can be formed.

The heat resistant member assembly may include a first heat resistant member disposed in an inner space of the body case, a second heat resistant member disposed in an inner space of the first heat resistant member, and a third disposed in an inner space of the second heat resistant member. It may include a heat resistant member.

The first heat resistant member may be a harder material than the second heat resistant member, the second heat resistant member may be a compressible material, and the third heat resistant member may be a vacuum insulating material.

The front cover may include a perforated network having a plurality of holes, and a front frame disposed in front of the perforated network to be in close contact with a part of the perforated network and coupled with the side protruding frame of the body case to support the perforated network.

The insulating flange unit may include a first flange coupled to the casing protrusion, a second flange disposed to be spaced apart from the first flange, and an upper surface of the insulating flange unit to be in close contact with the first flange, and a lower surface of the insulating flange unit to be in close contact with the second flange. It may include a first intermediate heat resistant material disposed.

In another embodiment of the present invention, the present invention provides a control method of a measuring device for measuring the state of the member to be heated, the temperature sensing step of the temperature sensor senses the measured temperature which is the internal space temperature of the heat-resistant member assembly ; A comparison step of the control unit comparing the measurement temperature with a preset set temperature tolerance range; A cooling fan driving step of driving the cooling fan by the control unit when the measured temperature is out of the allowable temperature range; A state sensing step of sensing, by the sensing unit, the state of the member to be heated if the measured temperature is within the set temperature allowable range; In addition, the sensing unit provides a control method of a measuring device for measuring the state of the member to be heated, comprising the step of transmitting the sensing data sensed in the state sensing step to the control unit.

The control method may further include: receiving, by the control unit, the sensing data; Analyzing, by the control unit, the sensing data; Counting the number of processes for the process performed by the control unit using the heated member; A data classification step of classifying, by the control unit, integrated information including the sensing data and the number of processes; Confirming whether the communication unit can communicate with external devices to which communication is to be performed; The communication unit may further include individually transmitting monitoring information corresponding to each of the external devices to be communicated among the integrated information to the external devices.

The control method may further include transmitting, by the control unit, an aperiodic sensing request signal to the sensing unit so that the sensing unit senses the sensing data at a time point other than the sensing period of the sensing unit.

The measuring device for measuring the state of the member to be heated and the control method thereof according to the present invention has the following effects.

First, by installing a heat insulation flange unit to block the heat transmitted to the main body unit from the casing protrusion for discharging high temperature at the same time to support the main body unit can prevent the substrate assembly of the main unit unit malfunction due to high heat There is an advantage.

Second, by installing a heat-resistant plate unit in the space between the outer surface of the heat source casing and the body unit there is an advantage that can prevent the heat released from the heat source casing to be transferred to the body unit.

Third, the heat-resistant member assembly is disposed outside the first heat-resistant member that does not deform the shape, and by placing the compressible second heat-resistant member in the inner space of the first heat-resistant member, the body unit can withstand external shocks, yet heat-resistant performance There is an advantage to improve.

1 is a view schematically showing a state in which a measuring device for measuring a state of a member to be heated according to the present invention is connected to a member to be heated.
FIG. 2 is a view showing a state where a measuring device for measuring the state of the member to be heated in FIG. 1 is installed in the ladle; FIG.
3 is an enlarged view of A of FIG. 2.
4 is a view showing a detailed configuration of the measuring device of FIG.
5 is a view for explaining the coupling relationship between the main body case and the front cover provided in the measuring device of FIG.
6 is a view for explaining the coupling relationship between the body case and the heat-resistant assembly provided in the measuring device of FIG.
7 is a flowchart illustrating an embodiment of a control method of a measuring device for measuring a state of a member to be heated according to the present invention.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention in which the above-described problem to be solved may be specifically realized. In describing the present embodiments, the same name and the same reference numerals are used for the same configuration and additional description thereof will be omitted below.

1 to 6, the measuring device according to the present embodiment is for measuring a state of a member to be heated heated by a heat source, and the heating member 10 and the measuring device 20 are electrically It is connected.

In the present embodiment, a bubbling plug is used as the member to be heated 10, and the bubbling plug is installed in a heat source casing 1, that is, a ladle, and a hot melt is accommodated in the inner space of the ladle. .

Specifically, the measuring device 20 and the member to be heated 10 are connected through the wire unit 11. One end of the wire unit 11 is embedded in the heated member 10, and the other end of the wire unit 11 is connected to the measuring device 20.

When the member to be heated 10 is damaged by the melt, one end of the wire unit 11 which is not electrically connected is electrically connected to the medium through the melt, so that the measuring device 20 is connected to the member to be heated. The state of (10) will be measured

The measuring device 20 includes a main body unit 1000, a heat insulation flange unit 200, and a heat resistant plate unit 100.

The body unit 1000 is connected to the member to be heated 10 to measure the state of the member to be heated 10. The main body unit 1000 is disposed away from the outer surface of the heat source casing 1 in which the heated member 10 is installed.

One end of the heat insulation flange unit 200 is coupled to the casing protrusion 1a protruding from the outer surface of the heat source casing 1, and the other end is coupled to the main body unit 1000.

As a result, the main body unit 1000 is disposed in a form suspended from the casing protrusion 1a via the heat insulating flange unit 200. Here, one end of the heat insulation flange unit 200 is welded to the casing protrusion 1a, and the other end of the heat insulation flange unit 200 is welded to the installation frame 600 of the body unit.

The insulation flange unit 200 may include a first flange 210 coupled to the casing protrusion 1a, a second flange 230 spaced apart from the first flange 210 by a predetermined distance, and an upper surface of the insulation flange unit 200. The lower surface of the first flange 210 and at the same time the lower surface includes a first intermediate heat-resistant material 220 disposed in close contact with the upper surface of the second flange (230).

Here, the first flange 210 is disposed to be spaced apart from the first top plate 211 and the first top plate 211 to be coupled to the casing protrusion (1a) and the upper surface of the first intermediate heat-resistant material and The first lower surface plate 212 in contact with, and one end is coupled to the lower surface of the first upper surface plate 211 and the other end includes a first connecting rod 213 coupled to the upper surface of the first lower surface plate 212 do. The first top plate 211, the first bottom plate 212 and the first connection rod 213 may be integrally formed, or may be separately manufactured and combined.

Since the second flange 230 has a structure substantially the same as that of the first flange 210, a description thereof will be omitted.

In addition, the heat insulating flange unit 200 is spaced apart by a predetermined distance in the lower direction of the second flange 230, the third flange 250 is arranged spaced apart in the lower direction of the third flange (250). The fourth flange 270, the upper surface is in close contact with the lower surface of the second flange 230, and the lower surface is in contact with the upper surface of the third flange 250, and the upper surface is the second The bottom surface includes a third intermediate heat resistant material 260 in close contact with the top surface of the fourth flange 270 while being in close contact with the bottom surface of the third flange 250.

Of course, the number of flanges and the number of intermediate heat resistant materials may be changed as necessary. In addition, the insulation flange unit 200 may further include a separate coupling member for coupling the two neighboring flanges, and the intermediate heat-resistant material disposed between the two flanges.

In this embodiment, the heat insulation flange units 200 are arranged in pairs while having a predetermined time on the installation frame 600. Of course, the insulation flange unit 200 may be provided with one or more as necessary.

The heat insulation flange unit 200 blocks the heat transmitted to the body unit 1000 from the casing protrusion 1a that supports the body unit 1000 and discharges high temperature heat. It is possible to prevent the substrate assembly of) from malfunctioning due to high heat. For example, when the temperature of the casing protrusion 1a is 250 ° C., the temperature delivered to the main body unit 1000 blocks heat to about 150 ° C.

The heat resistant plate unit 100 is coupled to the casing protrusion 1a, and is disposed between the outer surface of the heat source casing 1 and the body unit 1000 so that the heat released from the heat source casing 1 It is blocked from being delivered to the main body unit 1000.

At this time, the heat-resistant plate unit 100 is coupled to the casing protrusion (1a) in the form of hanging in the lower direction of the casing protrusion (1a), and is spaced apart from the outer surface of the heat source casing (1) by a predetermined distance. At the same time, the heat-resistant plate unit 100 is also spaced apart from the body unit 1000 by a predetermined interval.

Here, the projection area of the heat resistant plate unit 100 is larger than the projection area of the main body unit 1000 when viewed from the front of the main body unit 1000. That is, when viewed from the front of the main body unit 1000, the main body unit and the heat insulating flange unit 200 is located inside the projected area of the heat resistant plate unit 100.

As a result, the heat resistant plate unit 100 prevents the convective heat and radiant heat emitted from the heat source casing 1 from being transferred to the main body unit 1000 and the heat insulating flange unit 200.

The heat resistant plate unit 100 includes a metal frame 110 and a heat resistant plate 120 inserted into and disposed in an installation groove 111 formed in the metal frame 110. The metal frame 110 is coupled to the casing protrusion (1a) by welding.

The main body unit 1000 includes a main body case 320, an installation frame 600, a heat resistant member assembly 380, a battery 700, a substrate assembly 800, a base plate 900, and a front cover 400. , An antenna 550, a temperature sensor 540, a cooling fan 530, a display unit 510, and a switch unit 520.

The body case 320 has a box shape with one surface open, and forms a space in which the heat resistant member assembly 380 is accommodated.

Side protruding frames 321 are formed on both front sides of the body case 320, and the side protruding frames 321 are coupled to the front cover 400.

An upper heat resistant block 310 is disposed on an upper surface of the body case 320. The upper heat resistant block 310 blocks convective heat and radiant heat transmitted from the upper direction of the body case 320.

The installation frame 600 is disposed to surround at least a portion of the outer surface of the main body case 320 is coupled to the other end of the heat insulating flange unit 200.

The installation frame 600 is disposed to surround some of the outer surfaces of the body case 320 and the upper heat resistant block 310.

In detail, the installation frame 600 includes a first installation frame 610 and a second installation frame 620 disposed at a predetermined interval. An upper surface of the first installation frame 610 and an upper surface of the second installation frame 620 are disposed with a predetermined height on the upper surface of the upper heat resistant block 310. The other end of the heat insulation flange unit 200 is simultaneously coupled to an upper surface of the first installation frame 610 and an upper surface of the second installation frame 620.

As a result, a predetermined space is formed between the other end of the heat insulating flange unit 200 and the upper surface of the upper heat resistant block 310, and thus, to the upper heat resistant block 310 through the heat insulating flange unit 200. The conducted heat can be minimized.

The heat resistant member assembly 380 is disposed on an inner space of the body case 320.

In detail, the heat resistant member assembly 380 includes a first heat resistant member 330 disposed in an inner space of the body case 320 and a second heat resistant member disposed in an inner space of the first heat resistant member 330. 360 and a third heat resistant member 370 disposed in an inner space of the second heat resistant member 360.

The first heat resistant member 330, the second heat resistant member 360, and the third heat resistant member 370 all have an open box shape. The heat resistant members may be integrally formed, but may be formed by combining individual blocks.

Here, the first heat resistant member 330 is a harder material than the second heat resistant member 360, the second heat resistant member 360 is a compressible material, the third heat resistant member 370 is a vacuum insulating material Can be.

For example, the first heat resistant member 330 may be provided as a ceramic board, and the second heat resistant member 360 may be provided as cerakool or aerogel.

The second heat resistant member 360 includes a second outer heat resistant member 340 and a second inner heat resistant member 350, and the second outer heat resistant member 340 and the second inner heat resistant member 350 are It may be made of different materials.

As a result, the first heat resistant member 330 is able to withstand external shocks by preventing the deformation of the first heat resistant member 330, and the second heat resistant member 360 is made of a compressible material to maximize the corresponding heat resistant member in a given space. The third heat resistant member 370 may increase the heat insulation effect while reducing the thickness by using the vacuum heat insulating material.

The battery 700 is disposed on an inner space of the heat resistant member assembly, that is, the third heat resistant member 370. The battery 700 supplies power to components in which electricity is used among the detailed components constituting the main body unit 1000.

In addition, the substrate assembly 800 is disposed on an inner space of the heat resistant member assembly, that is, the third heat resistant member 370, and is connected to the battery 700.

Here, the other end of the wire unit 11 is electrically connected to the substrate assembly 800. In this case, the other end of the wire unit 11 is disposed to penetrate the first heat resistant member 330 and the second heat resistant member 360. On the other hand, the other end of the wire unit 11 is connected to the substrate assembly 800 via the open one surface of the third heat resistant member 370 without passing through the third heat resistant member 370.

The substrate assembly 800 is electrically connected to the substrate main body 840, the substrate main body 840, and a sensing unit 810 for measuring a state of the heated member 10, and the sensing unit 810. Communication unit 830 for transmitting integrated information including sensing data sensed by the external device to the external device, and a control unit 820 for analyzing the sensing data and controlling the main body unit 1000 at the same time. .

The substrate body 840 includes two circuit boards stacked on each other, and the two circuit boards are electrically connected to each other. Since the substrate main body 840 is composed of two circuit boards, the internal space of the third heat resistant member 370 may be efficiently used, thereby reducing the cost of manufacturing the main body unit 1000. .

If the circuit board area becomes large, an internal space of the third heat resistant member 370 for protecting the circuit board from heat emitted from the heat source casing 1 is increased, and the third heat resistant member 370 is increased. Increasing the internal space of the) increases the size of the main body unit 1000, there is a problem that the manufacturing cost increases.

The antenna 550 is provided for communication with an external device, and the temperature sensor 540 senses the internal space temperature of the heat resistant member assembly 380, that is, the temperature of the substrate assembly 800.

The cooling fan 530 is controlled by the control unit 820 to suck the outside air into the body case 320 to cool the battery 700 and the substrate assembly 800.

The switch unit 520 is for controlling the operation of the main body unit 1000, and the display unit 510 indicates whether the temperature of the substrate assembly 800 is within or outside the normal range. Done. The display unit 510 may be provided as an LED.

Of course, the present invention is not limited thereto, and the display unit 510 may be provided as a display panel to display information on the state of the member to be heated 10.

The base plate 900 is formed of a metal material, and the substrate assembly 800 is installed on the base plate 900.

In addition, the base plate 900 has an inlet 910 for allowing air to flow into the cooling fan 530, and an outlet 920 through which air circulated through the inner space of the heat resistant member assembly 380 is discharged. An antenna exposure hole 930 may be formed to expose the antenna 550 in front of the base plate 900.

In addition, the base plate 900 has a display unit exposure port 940 for exposing the display unit 510 in front of the base plate 900 and a switch for exposing the switch unit 520. An exposure hole 950 may be formed.

The front cover 400 is disposed in front of the base plate 900 is coupled to the body case 320.

The front cover 400 is disposed in front of the perforated network 410 having a plurality of through holes (not shown), the perforated network 410 is placed in close contact with a part of the perforated network 410 protruding the side of the body case It is coupled to the frame 321 includes a front frame 480 for supporting the perforated network 410.

The front frame 480 includes a first front frame 440 disposed in front of the upper region of the perforated network 410, and a second front frame 470 disposed in front of the lower region of the perforated network 410. .

The first front frame 440 includes a first coupling frame 420 for coupling with the side protruding frame 321 and a first reinforcing frame 430 for reinforcing the strength of the first coupling frame 420. It may include.

The second front frame 470 includes a second coupling frame 450 for coupling with the side protruding frame 321 and a second reinforcing frame 460 for reinforcing the strength of the second coupling frame 450. It may include.

The perforated network 410 is supported by the front frame 480 in a state that both ends are bent. A central area of the perforated network 410 is spaced apart from the base plate 900 to form an open space that is a space between the central area of the perforated network 410 and the base plate 900.

A portion of the antenna 550, a portion of the display unit 510, and a portion of the switch unit 520 that pass through the base plate 900 are disposed on the open space.

As a result, it is possible to protect the substrate assembly of the main body unit from the heat emitted from the heat source casing while having a compact structure.

On the other hand, with reference to Figures 1 to 7, an embodiment of a control method of the measuring device for measuring the state of the member to be heated according to the present invention.

First, the sensing unit 810 determines whether there is an aperiodic sensing request signal from the control unit 820 (S10). Here, the aperiodic sensing request signal is a signal transmitted by the control unit 820 to the sensing unit 810 so that the sensing unit 810 senses the sensing data at a time point other than the sensing period of the sensing unit 810. Means.

As a result, the control unit 820 may transmit the aperiodic sensing request signal to the sensing unit 810 before the signal determination step is performed.

If there is an aperiodic sensing request signal, a temperature sensing step in which the temperature sensor 540 senses a measurement temperature which is an internal space temperature of the heat resistant member assembly 380 is performed (S30).

If there is no aperiodic sensing request signal, the sensing unit 810 determines whether a sensing period, which is an interval for sensing sensing data, has arrived (S20).

If the current time point reaches the sensing period, the temperature sensing step is performed. However, if the current time point does not reach the sensing period, the sensing unit 810 waits until the sensing period is reached or the aperiodic sensing request signal is received.

After the temperature sensing step is performed, a comparison step in which the control unit compares the measured temperature with a preset set temperature allowable range is performed (S40).

Next, when the measured temperature is out of the set temperature allowable range, a cooling fan driving step in which the control unit drives the cooling fan 530 is performed (S50).

After the cooling fan driving step is performed, a comparison step is performed in which the control unit compares the measured temperature with a preset set temperature allowable range.

Next, when the measured temperature is within the set temperature allowable range, a state sensing step of sensing the state of the member to be heated 10 by the sensing unit 810 is performed (S60).

Next, the sensing unit 810 transmits the sensing data sensed in the state sensing step to the control unit 820 (S70).

Next, the step of receiving the sensing data by the control unit 820 is performed (S80).

Next, the control unit 820 analyzes the sensing data is performed (S90).

Next, the control unit 820 performs a step of counting the number of processes for the process performed using the heated member 10 (S100).

Next, a data classification step is performed in which the control unit 820 classifies the integrated information including the sensing data and the number of processes (S110).

Next, the communication unit 830 checks whether communication with the external devices to be communicated is performed (S120).

Finally, the communication unit individually transmits the monitoring information corresponding to each of the external devices to be the communication target of the integrated information to the external devices (S130).

For example, information on whether the battery is charged, internal temperature of the heat-resistant member assembly, and the like may be transmitted to the external device of the administrator, and information on the state of the member to be heated and the number of processes may be transmitted to the external device of the user. Information may be sent. Of course, the information transmitted by the communication unit 830 to the external devices may be variously changed.

As described above, the present invention is not limited to the above-described specific preferred embodiments, and various modifications may be made by those skilled in the art without departing from the gist of the present invention as claimed in the claims. It is possible and such variations are within the scope of the present invention.

1: heat source casing 10: member to be heated
11: wire unit 20: measuring device
100: heat-resistant plate unit 200: heat insulation flange unit
210: first flange 220: first intermediate heat resistant material
230: second flange 320: body case
330: first heat resistant member 360: second heat resistant member
370: third heat resistant member 380: heat resistant member assembly
400: front cover 410: perforated network
480: front frame 510: display unit
520: switch unit 530: cooling fan
540: temperature sensor 550: antenna
700: battery 800: substrate assembly
810: sensing unit 820: control unit
830: communication unit 840: substrate body
900: base plate 1000: main unit

Claims (10)

A measuring device for measuring a state of a member to be heated heated by a heat source,
A main body unit connected to the heating member to measure a state of the heating member, the main body unit being spaced apart from the outer surface of the heat source casing in which the heating member is installed;
An insulation flange unit having one end coupled to a casing protrusion protruding from the outer surface of the heat source casing, and the other end coupled to the body unit such that the body unit is disposed in a form suspended from the casing protrusion; And,
A heat-resistant plate unit coupled to the casing protrusion and disposed between the outer surface of the heat source casing and the body unit to block heat from the heat source casing from being transferred to the body unit,
The insulation flange unit may include a first flange coupled to the casing protrusion, a second flange disposed to be spaced apart from the first flange, and an upper surface of the insulation flange unit to be in close contact with the first flange, and a lower surface of the insulation flange unit to be in contact with the second flange. A first intermediate heat resistant material disposed therein,
The first flange may include a first top plate coupled to the casing protrusion, a first bottom plate disposed at a predetermined distance from the first top plate, and in contact with the top surface of the first intermediate heat resistant member, and one end of the first top surface. The first end of the plate and the other end is coupled to the upper surface of the first lower plate, the first upper plate and the first lower surface of the plate is characterized in that it comprises a first connecting rod having a narrower cross-sectional width than the first lower plate Instrument for measuring status. The method of claim 1,
The main body unit is disposed to surround at least a portion of the main body case, the outer surface of the main body case, the installation frame coupled to the other end of the heat insulation flange unit, the heat-resistant member assembly disposed in the inner space of the main body case, A battery disposed on an inner space of the heat resistant member assembly, a substrate assembly disposed on an inner space of the heat resistant member assembly and connected to the battery, a base plate for installing the substrate assembly, and a front side of the base plate; The measuring device for measuring the state of the member to be heated, characterized in that it comprises a front cover is coupled to the main body case. The method of claim 2,
The main body unit further includes an antenna for communicating with an external device, a temperature sensor for sensing a temperature of an internal space of the heat resistant member assembly, a cooling fan for cooling the battery and the substrate assembly,
The substrate assembly includes a sensing unit for measuring a state of the member to be heated, a communication unit for transmitting integrated information including sensing data sensed by the sensing unit to an external device, and simultaneously analyzing the sensing data. And a control unit for controlling the main body unit. The method of claim 3,
The base plate has an inlet for allowing air to flow into the cooling fan, an outlet for discharging air circulated through the internal space of the heat resistant member assembly, and an antenna exposed hole for exposing the antenna to the front of the base plate. Measuring device for measuring the state of the member to be heated, characterized in that the formed. The method of claim 2,
The heat resistant member assembly may include a first heat resistant member disposed in an inner space of the body case, a second heat resistant member disposed in an inner space of the first heat resistant member, and a third disposed in an inner space of the second heat resistant member. It includes a heat-resistant member,
The first heat-resistant member is a material harder than the second heat-resistant member, the second heat-resistant member is a compressible material, the third heat-resistant member is a measurement for measuring the state of the member to be heated, characterized in that the vacuum insulation material Device. The method of claim 2,
The front cover may include a perforated network having a plurality of holes, and a front frame disposed in front of the perforated network to be in close contact with a part of the perforated network and coupled with the side protruding frame of the main body case to support the perforated network. Measuring device for measuring the state of the member to be heated. delete A control method of a measuring device for measuring a state of a member to be heated according to claim 3,
A temperature sensing step of sensing, by the temperature sensor, a measurement temperature which is an internal space temperature of the heat resistant member assembly;
A comparison step of the control unit comparing the measurement temperature with a preset set temperature tolerance range;
A cooling fan driving step of driving the cooling fan by the control unit when the measured temperature is out of the allowable temperature range;
A state sensing step of sensing, by the sensing unit, the state of the member to be heated if the measured temperature is within the set temperature allowable range;
Transmitting, by the sensing unit, the sensing data sensed in the state sensing step to the control unit;
The control unit receiving the sensing data;
Analyzing, by the control unit, the sensing data;
Counting the number of processes for the process performed by the control unit using the heated member;
A data classification step of classifying, by the control unit, integrated information including the sensing data and the number of processes;
Confirming whether the communication unit can communicate with external devices to which communication is to be performed; And,
And transmitting, by the communication unit, monitoring information corresponding to each of the external devices to be communicated among the integrated information to the external devices individually. Control method of the device. delete The method of claim 8,
And transmitting, by the control unit, an aperiodic sensing request signal to the sensing unit so that the sensing unit senses the sensing data at a time point other than the sensing period of the sensing unit. Control method of measuring device.

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