KR20180034666A - Refractory assembly, refractory integrated management system using same, and refractory assembly management method - Google Patents

Abstract

 The present invention relates to refractories; A cartridge module in which at least a part is mounted inside the refractory for understanding the state of the refractory; And a metering module disposed outside the refractory and selectively connected to the cartridge module to measure a current signal flowing to the cartridge module, wherein the cartridge module includes a cartridge body, And a cable unit having one or more metal wires, a refractory integrated management system using the refractory assembly, and a refractory assembly management method.

Description

Refractory assembly, refractory integrated management system using same, and refractory assembly management method

The present invention relates to a refractory assembly, a refractory integrated management system, and a refractory assembly management method using the refractory assembly. More particularly, the present invention can efficiently maintain and manage the refractory while grasping the state of the refractory immediately, A refractory integrated management system using the refractory assembly, and a method of managing the refractory assembly.

Generally, refractory materials such as refractory bricks and castables can be installed in various industries such as a heating furnace, a heat treatment furnace, a baking furnace, and a blast furnace, which are used in steelmaking processes.

The refractories may be exposed for a long time under high temperature conditions as the process progresses to the industry, in which case the refractories are damaged by thermal shocks.

However, the refractory is disposed inside the industrial furnace, and thus there are many restrictions to immediately judge whether the refractory is damaged or not.

In addition, such refractory has a problem that it is difficult to grasp the damage position and degree of damage due to thermal shock.

Accordingly, if the refractory is properly repaired and replaced, the damaged refractory will affect the process of the industrial process, resulting in defects in the manufactured product, which adversely affect the quality.

Also, due to the damage of the refractory, dirt flows out, which causes heat loss, damage of external equipment, and safety accident of field workers.

The present invention provides a refractory assembly capable of efficiently maintaining and managing refractories and preventing damage to the measuring module due to heat while instantly grasping the state of the refractory, an integrated refractory management system using the refractory assembly, To provide a method for managing refractory assemblies.

In order to solve the above technical problems, the present invention provides a refractory material, A cartridge module in which at least a part is mounted inside the refractory for understanding the state of the refractory; And a metering module disposed outside the refractory and selectively connected to the cartridge module to measure a current signal flowing to the cartridge module, wherein the cartridge module includes a cartridge body, A refractory assembly comprising a cable unit having at least one metal wire.

Wherein the cartridge body is made of substantially the same material as the refractory and is replaceably mounted on the refractory, and the cable unit includes a first metal wire and a second metal wire that are independently arranged according to a depth of the cartridge body And the first metal wire and the second metal wire are independently connected to the measurement module to form a closed loop, respectively.

The measuring module includes a power supply unit for supplying power to the cable unit, a wire connection unit selectively connected to both ends of the metal wire to supply power to the metal wire, and a sensing unit for sensing a current flowing through the metal wire, Section.

The wire connecting portion may include a rotating disk having a concave / convex region selectively in contact with the metal wire, and a disk driving member for rotating the rotating disk.

The refractory assembly may further include cartridge fixing means that is solidified by being injected into a space between the refractory and the new cartridge module to fix the cartridge module newly mounted to the refractory inside the refractory.

According to another embodiment of the present invention, the present invention provides a refractory assembly as described above; An integrated management module for determining the state of the refractory based on the current signal measured by the measurement module and generating management information on the refractory; Further, the present invention provides a refractory integrated management system including a local terminal receiving management information from the integrated management module.

Wherein the measurement module includes a first communication unit for communicating with the integrated management module, the integrated management module includes a second communication unit for receiving a current signal transmitted from the first communication unit, a second communication unit for calculating a current signal transmitted from the second communication unit, including a management instruction to the transmission data output section, and the management information for the refractory to the local terminal to display to monitor the condition of the refractory material is determined from the data analyzing unit, the data analysis unit determining a state of the refractory can do.

According to still another aspect of the present invention, there is provided a refractory assembly management method for managing a refractory assembly as described above, comprising the steps of: when a cartridge module is damaged due to damage of a first region of the refractory, ; Inserting a new cartridge module into the internal space of the refractory formed as the damaged cartridge module is removed; A refractory repairing step of replacing the first region with a new partial refractory; And fixing the new cartridge module by injecting and fixing the fluid cartridge fixing means into the space between the refractory and the new cartridge module.

The refractory repair step may form the partial refractory by spraying an injection object including the refractory powder so as to correspond to the first area.

The refractory assembly according to the present invention, the refractory integrated management system using the same, and the method for managing the refractory assembly have the following effects.

First, in order to grasp the condition of the refractory, the cartridge module is replaceably installed inside the refractory, so that it is not necessary to replace the entire refractory even if the cartridge module is damaged due to the damage of the refractory.

Second, the measurement module for measuring the current flowing through the cartridge module and the cartridge module are selectively connected to prevent the heat of the cartridge module from being continuously transmitted to the measurement module, thereby preventing damage to the measurement module due to heat There is an advantage.

Thirdly, when the cartridge module is installed inside the refractory, when the refractory is damaged by heat or impact, such as cracking or breakage, the state of the refractory material is immediately determined and the refractory can be efficiently managed.

1 is a schematic view of an integrated refractory management system according to the present invention.
2 is a block diagram of a refractory integrated management system.
3 is a view of a refractory assembly according to the present invention.
4 is a sectional view taken along line II in Fig.
FIG. 5 is a view illustrating a state where a metering module and a cable unit provided in the refractory assembly of FIG. 3 are connected.
6 is a view illustrating a process of repairing a refractory and a cartridge module according to the present invention when the module is damaged.
7 is a view showing a process of mounting a cartridge module on an existing refractory.

Hereinafter, preferred embodiments of the present invention in which the above-mentioned problems to be solved can be specifically realized will be described with reference to the accompanying drawings. In describing the embodiments, the same names and the same symbols are used for the same configurations, and additional description thereof will be omitted in the following.

The refractory assembly and the refractory integrated management system according to the present invention will be described with reference to FIGS. 1 to 5 as follows.

The refractory integrated management system according to the present embodiment includes a refractory assembly, an integrated management module 30, and a local terminal 40.

The refractory assembly includes refractory 10, cartridge module 100 and metrology module 20 and is connected to the integrated management module 30 via wire or wireless for information on managing the refractory assembly, .

The integrated management module 30 also exchanges management information for managing the refractory 10 through wired or wireless communication with the local terminal 40 disposed around the refractory 10.

Specifically, the refractory 10 is installed on a blast furnace, at least a portion of the cartridge module 100 is mounted inside the refractory 10, and the metering module 20 is mounted on the inside of the cartridge module 100 And the current signal flowing through the cartridge module 100 is measured.

 The cartridge module 100 is selectively connected to the metering module 20 and used to determine the state of the refractory 10. The cartridge module 100 may be installed in the process of manufacturing the refractory 10 or may be mounted on a refractory already manufactured and used.

The cartridge module 100 includes a cartridge body 110 and a cable unit 120 having one or more metal wires disposed inside the cartridge body 110.

The cartridge body 110 is made of substantially the same material as the refractory 10 and is replaceably mounted on the refractory 10.

Even if the cartridge module 100 is replaceably mounted in the refractory 10 to grasp the state of the refractory 10 so that the cartridge module 100 is damaged due to the damage of the refractory 10, The entire refractory 10 need not be replaced.

The cable unit 120 is connected to the measurement module 20 so that a current flows and a current flowing in the cable unit 120 is measured by the measurement module 20. The current signal measured by the measuring module 20 changes according to the state of the refractory 10 due to abrasion, erosion, thermal deformation, etc. of the refractory 10.

Specifically, the cable unit 120 includes a first metal wire 121, a second metal wire 123, and a third metal wire 125 that are independently disposed according to the depth of the cartridge body 110 do. Here, the first metal wire 121, the second metal wire 123, and the third metal wire 125 are independently connected to the measurement module 20 to form a closed loop.

The first metal wires 121, the second metal wires 123, and the third metal wires 125 are independently disposed at different positions and heights depending on the shape and size of the cartridge body 110.

For example, as shown in FIG. 4A, the second metal wire 123 is disposed in the center region of the main cartridge body unit 110, and the second metal wire 123 is arranged in the upper direction with respect to the second metal wire 123 The third metal wire 125 may be disposed at a predetermined distance from the first metal wire 121 and the first metal wire 121 may be disposed at a position spaced apart from the second metal wire 123 by a predetermined distance.

The first metal wires 121, the second metal wires 123, and the third metal wires 125 are disposed at different positions to form independent closed loops, so that the first metal wires 121, The position of the damaged region of the refractory 10 can be confirmed based on the current signal measured at the second metal wire 123 and the third metal wire 125.

As a result, the field worker and the person in charge can more promptly and accurately grasp the damage position and damage state of the refractory 10, so that the refractory 10 can be quickly repaired and replaced, thereby minimizing the risk of safety accidents can do. .

4 (b), a second metal wire 1230 is disposed in the center region of the cartridge body 110, and the first metal wire 1210 and the second metal wire 1210 The third metal wires 1250 may be arranged in an 'X' shape. Although the first metal wire 1210, the second metal wire 1230 and the third metal wire 1250 overlap in FIG. 4B, the height of the first metal wire 1210, the second metal wire 1230, They do not come into contact with each other.

Since the first metal wire 121, the second metal wire 123 and the third metal wire 125 shown in FIG. 3 have substantially the same structure, the first metal wire 121, the second metal wire 123, The following is a brief explanation.

5, the first metal wire 121 includes a wire body 121a, a protrusion 121b protruding from at least a part of the outer surface of the wire body 121a, and at least a part of the wire body 121a And a coating layer (not shown) for securing a space for coating the coating layer.

The wire main body 121a may be made of stainless steel (SUS) having excellent heat resistance so that it is not easily melted or expanded by heat. Of course, the material of the wire main body 121a is not limited thereto, but may be replaced with a metal having good heat resistance and good current.

The protrusion 121b protrudes from the surface of the wire body 121a to widen the surface area of the first metal wire 121 contacting the cartridge body 110. [ As a result, the protrusion 121b can hold the cartridge main body 110, so that the first metal wire 121 can be stably coupled to the cartridge main body 110.

 The space-securing coating layer melts when the temperature of the cartridge body 110 rises, thereby securing an expansion space of the first metal wires 121. Here, the space-securing coating layer may be made of paraffin.

When the first metal wire 121 expands according to the temperature rise of the cartridge main body 110, the first metal wire 121 fills at least a part of the expansion space formed by the space-securing coating layer.

2 and 5, the measurement module 20 is disposed outside the refractory 10, and is selectively connected to the cartridge module 100. Also, the measurement module 20 can communicate with the integrated management module 30 in a wired or wireless manner.

Specifically, the measurement module 20 includes a power unit 26, a sensing unit 21, a first communication unit 23, a casing 25, and a wire connection unit.

The power supply unit 26, the sensing unit 21, and the first communication unit 23 are installed in the internal space of the casing 25. A display unit 24 for displaying the communication state and the power state of the measurement module 20 is disposed on an outer surface of the casing 25. [

The power unit 26 may include a rechargeable battery or may be connected to an external power source through a wire. The rechargeable battery may be replaced with a battery, but may be charged by a thermoelectric element that converts the heat of the space in which the refractory 10 is installed into electrical energy.

The sensing unit 21 measures a current flowing through the cable unit, that is, the first metal wire 121.

The first communication unit 23 communicates with the integrated management module 30 and transmits the current signal measured by the sensing unit 21 to the integrated management module 30. [

The wire connecting part is selectively connected to both ends of the first metal wire 121 to supply power to the first metal wire 121.

The wire connecting portion includes a rotating disk 29 having a concavo-convex region selectively in contact with the first metal wire 121, and a disk driving member 27 for rotating the rotating disk 29.

Here, the disk driving member 27 is electrically connected to the power supply unit 26 and the rotating disk 29, and mechanically rotates the rotating disk 29.

For example, the disk driving member 27 includes internal wires for electrically connecting the power supply unit 26 and the rotating disk 29, and an electric wire disposed on one side of the rotating disk 29, As shown in FIG.

The rotating disk 29 includes a first rotating disk 29a selectively connected to the positive electrode of the first metal wire 121 and a negative electrode of the first metal wire 121, And a second rotating disk 29b selectively connected thereto.

The disk driving member 27 includes a first driving member 27a for rotating the first rotating disk 29a and a second driving member 27b for rotating the second rotating disk 29b, .

When the first rotating disk 29a and the second rotating disk 29b are simultaneously connected to the positive electrode and the negative electrode of the first metal wire 121, current flows through the first metal wire 121, respectively.

Here, the flow of the current flowing through the first metal wire 121 will be described. A current starting from the (+) pole of the power supply unit 26 passes through the first rotating disk 29a via the first driving member 27a, and the current passing through the first rotating disk 29a The first metal wire 121 and the second metal wire 121 are connected to each other. The current output from the negative terminal of the first metal wire passes through the second rotary disc 29b and the current through the second rotary disc 29b flows through the second driving member 27b And flows to the power supply unit 26.

At this time, a first terminal drawn out from the first driving member 27a and a second terminal drawn out from the second driving member are coupled to the sensing unit 21, and the sensing unit 21 is connected to the first The current flowing through the metal wire 121 is sensed.

As a result, the measurement module 20 for measuring the current flowing through the cartridge module 100 and the cartridge module 100 are selectively connected to each other so that the heat of the cartridge module 100 is constantly It is possible to prevent the measurement module 20 from being damaged due to heat.

Of course, the present invention is not limited to the above-described embodiment, and the wire connecting portion may be selectively connected to the first metal wire 121 while moving up and down or moving left and right.

The present invention is not limited to the above-described embodiments, and the refractory assembly may be modified to replace the damaged cartridge module so that the cartridge module, which is newly mounted on the refractory, is fixed inside the refractory 10, And cartridge fixing means which is injected into the space and solidifies.

Meanwhile, the integrated management module 30 determines the state of the refractory 10 based on the call, and generates management information on the refractory while performing wired or wireless communication with the refractory assembly.

Specifically, the integrated management module 30 includes a second communication unit 31, a data analysis unit 33, a data storage unit 35, a data output unit 37, and a management instruction unit 39.

The second communication unit 31 receives the current signal transmitted from the first communication unit 23 and transmits the current signal to the data analysis unit 33.

The data analyzing unit 33 calculates the current signal transmitted from the second communication unit 31 to determine the state of the refractory 10 and the related information on the state of the refractory 10 is stored in the data storage unit (35).

The data analyzer 33 analyzes the current signal measured by the measurement module 20 based on a data conversion criterion stored in the data storage unit 35. In the data conversion standard, the state of the refractory is defined according to the current signal.

As a result, the damaged state and position of the refractory 10 are grasped according to the analysis result of the current signal by the data analysis unit 33.

The analysis of the current signal is based not only on the breakage due to cracking and breakage of the refractory 10 but also by the noise generated by the trench penetrating into the cracked space of the refractory 10 and the noise generated by the heat of the refractory 10 Current signal, and the like.

The change in the current signal caused by the heat of the refractory 10 can grasp the degree and position of the refractory 10 so that the crack initiation time and crack progression speed and degree of the refractory 10 can be analyzed .

The data analyzing unit 33 can grasp the management information of the refractory 10 based on the quantity and the history of the refractory 10 stored in the data storage unit 35.

The data analysis unit 33 analyzes the quantity of refractory material damaged in the refractory 10 disposed in the industrial districts and the product name, manufacturer, manufacture and arrival date of the refractory 10, lot number, etc. Can be grasped in real time.

The state of the refractory stored in the data storage unit 35 may be used to identify the replacement period and time of the refractory 10.

Specifically, the integrated management module 30 analyzes the defect rate, the breakage rate, and the usage rate of the refractory 10 based on the information on the state of the refractory stored in the data storage 35, And can be used to manage the damage and breakage history of the refractory.

The data output unit 37 displays the state of the refractory 10, the amount of refractory stocks and product history, and the damage and breakage history of the refractory 10.

The management instruction unit 39 transmits the management information on the refractory 10 to the local terminal 40 so that the field manager and the person in charge can check the state of the refractory 10 in real time.

Accordingly, the on-site manager and the person in charge can immediately repair and replace the refractory 100.

Meanwhile, the local terminal 40 receives the management information from the integrated management module 30, and can display the management information to the manager managing the refractory. The local terminal 40 may display the management information to the administrator by using voice, text, or a screen display method.

The integrated refractory management system including the refractory assembly, the integrated management module 30 and the local terminal 40 may be used to enable integrated management of the refractory 10 and to monitor the state of the refractory 10 in real time So that the refractory 10 can be managed by a minimum number of on-site management personnel.

Referring to FIG. 6, a process of repairing the refractory and the cartridge module when they are damaged will be described.

6 (a) shows a state in which the cartridge module is mounted on the refractory 10.

Next, as shown in FIG. 6 (b), when the cartridge module 100 is also damaged due to damage of the first region 13 of the refractory, the damaged cartridge module 100 is separated from the refractory 10.

At this time, in order to remove the damaged cartridge module 100, the refractory located in the periphery of the damaged cartridge module 100 is removed to form the separation groove 11.

Next, as shown in FIG. 6C, a new cartridge module 200 is inserted into the internal space of the refractory, that is, into the separating groove 11.

Next, as shown in Fig. 6C, a refractory repair step is performed in which the first region 13 is replaced with a new partial refractory 15. In the refractory repair step, the partial refractory 15 may be formed by spraying an injection object including refractory powder so as to correspond to the first region 13.

6 (d), a fluid cartridge fixing means 17 is injected into the space between the refractory 10 and the new cartridge module 200 to solidify the new cartridge module 200, . Here, as the cartridge fixing means 17, a molten refractory may be used.

Referring to FIG. 7, a process of mounting the cartridge module on the existing refractory will be described.

7A shows the state of the refractory 60 that has been used in the past, that is, the refractory 60 in which the cartridge module is not used.

Next, as shown in FIG. 7 (b), the operator forms the cartridge mounting groove 61 for mounting the cartridge module 100.

7 (c), after the cartridge module 100 is mounted, the cartridge fixing means 63 in the fluid state is poured into the mounting groove 61 to solidify the cartridge module 100, Respectively. Likewise, the cartridge fixing means 63 may use a molten refractory.

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

INDUSTRIAL APPLICABILITY The present invention can be widely applied to refractory assemblies capable of promptly grasping and repairing refractory states efficiently, preventing damage to the measuring module due to heat, and an integrated refractory management system using the refractory assemblies.

Claims (9)

Refractory:
A cartridge module in which at least a part is mounted inside the refractory for understanding the state of the refractory; And,
And a metering module disposed outside the refractory and selectively connected to the cartridge module to measure a current signal flowing to the cartridge module,
Wherein the cartridge module comprises a cartridge body and a cable unit having at least one metal wire disposed inside the cartridge body. The method according to claim 1,
Wherein the cartridge body is made of substantially the same material as the refractory and is replaceably mounted on the refractory, and the cable unit includes a first metal wire and a second metal wire that are independently arranged according to a depth of the cartridge body Wherein the first metal wire and the second metal wire are independently connected to the metrology module to form a closed loop, respectively. The method according to claim 1,
The measuring module includes a power supply unit for supplying power to the cable unit, a wire connection unit selectively connected to both ends of the metal wire to supply power to the metal wire, and a sensing unit for sensing a current flowing through the metal wire, Wherein the refractory assembly comprises a plurality of refractory assemblies. The method of claim 3,
Wherein the wire connecting portion includes a rotating disk having an uneven region selectively in contact with the metal wire, and a disk driving member for rotating the rotating disk. The method according to claim 1,
Further comprising cartridge securing means for injecting and solidifying in a space between the refractory and the new cartridge module to fix the cartridge module newly mounted in the refractory inside the refractory. A refractory assembly according to any one of claims 1 to 5;
An integrated management module for determining the state of the refractory based on the current signal measured by the measurement module and generating management information on the refractory; And,
And a local terminal for receiving management information from the integrated management module. The method according to claim 6,
Wherein the measurement module includes a first communication unit for communicating with the integrated management module, the integrated management module includes a second communication unit for receiving a current signal transmitted from the first communication unit, a second communication unit for calculating a current signal transmitted from the second communication unit, including a management instruction to the transmission data output section, and the management information for the refractory to the local terminal to display to monitor the condition of the refractory material is determined from the data analyzing unit, the data analysis unit determining a state of the refractory Wherein the refractory integrated management system comprises: A refractory assembly management method for managing a refractory assembly according to any one of claims 1 to 4,
Separating the damaged cartridge module from the refractory when the cartridge module is damaged due to damage of the first area of the refractory;
Inserting a new cartridge module into the internal space of the refractory formed as the damaged cartridge module is removed;
A refractory repairing step of replacing the first region with a new partial refractory; And,
And fixing the new cartridge module by injecting and solidifying a fluid cartridge securing means into the space between the refractory and the new cartridge module. 9. The method of claim 8,
Wherein the refractory repairing step forms the partial refractory by spraying an injection target including refractory powder so as to correspond to the first area.

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