KR102354371B1 - The burner structure for the incineration for the toxic gas combustion included in the combustion gas - Google Patents

Abstract

The present invention relates to a burner structure which is able to rapidly detect if a fire from a burner burning combustion gas including hazardous gas introduced from an electric furnace to a combustion tower is extinguished by wind pressure of the relevant combustion gas, and safely burn the combustion gas. More specifically, the present invention relates to a burner structure which comprises: a body in a pipe shape having an entrance side and an exit side, which are opened, and having a large number of space units independent from each other formed inside, and inserted into and fastened with a penetrating member placed in a radial shape along a longitudinal direction of the combustion tower by matching the shape; an ignition supply pipe connected to the body's entrance side to communicate with the inside of the body, and mixing the air and the gas needed for combustion, and igniting the air and the gas by a plug, and supplying the fire toward the body's exit side; a first sensor placed outside the ignition supply pipe and detecting the presence or absence of the ignition of the ignition supply pipe, and transmitting the detected information to a control unit; and a combustion unit formed in the body to react to the ignition of the ignition supply pipe, burn the gas in the combustion tower, and burn the hazardous substances included in the combustion gas existing in the combustion tower. The first sensor is able to detect so that the ignition supply pipe can be maintained being ignited all the time.

Description

The burner structure for the incineration for the toxic gas combustion included in the combustion gas

The present invention relates to a burner structure capable of safely burning after a burner that burns combustion gas containing noxious gas flowing from an electric furnace to a combustion tower is extinguished by the wind pressure of the combustion gas, after quickly detecting it will be.

In general, harmful substances such as smoke, odor, and fine dust generated in the production facility process, and nitrogen oxides ( NOx), carbon monoxide (CO), unburned carbon, sulfur oxides (SOx), and the like organic gases, such as the air is seriously polluted problem occurs.

In recent years, in order to solve the above problems, at least one burner that allows incomplete combustion harmful gas or smoke, odor, dust, etc. discharged from production facility processes, electric furnace system, etc. A combustion device using

In particular, in a column-shaped combustion tower, which is a large-scale facility having the same shape as a chimney, in order to burn harmful gases generated from the electric furnace system, fuel is supplied and burned to the combustion tower to efficiently decompose harmful gases due to heat Therefore, a number of devices and methods having a structure for realizing the complete combustion of the harmful gas have been devised.

However, the burner installed to combust the harmful gas generated in the electric furnace using such a large-scale facility is exhausted with a high pressure discharge pressure inside the electric furnace, and this discharge pressure causes the combustion gas generated in the electric furnace to burn. In the process of moving to the tower, the combustion gas rises along the inner wall of the combustion tower in a whirlpool method and exhaust occurs. In this process, the combustion flame of the burner is extinguished by the exhaust pressure (ie, wind pressure). When fuel gas is continuously supplied because the unburned state of such a burner cannot be detected in advance, this causes energy wastage, as well as a safety accident that can cause explosion and ignition by other burners in combustion. It turns out to be a problem with potential.

Domestic Registration Utility No. 20-0288709 (Announcement Date: 2002.09.11.) Domestic Registered Patent No. 10-0418810 (Announcement Date: 2004.02.14.) Domestic Registered Patent No. 10-1727627 (Announcement Date: 2017.05.02.)

In order to solve the above-mentioned problems of the prior art, the present invention is a process in which the combustion gas including the harmful gas introduced into the combustion tower from the electric furnace moves upward in the combustion tower in order to burn the combustion gas provided in a large-scale electric furnace system. A number of burners are installed radially so that combustion occurs step by step in the The purpose is to provide a burner that can make this happen.

In order to solve the above technical problem, the incineration burner structure for the combustion of harmful gases contained in the combustion gas according to the present invention has an inlet side and an outlet side open. PIPE) in the shape of a body 100 that is inserted and fastened by shape matching with a penetrating member 120 provided in a radial shape along the longitudinal direction of the combustion tower 500, and communicates with the inside of the body 100 The ignition supply pipe 200 connected to the inlet side of the body 100, the air and gas necessary for combustion are mixed with each other, and then ignited by the plug 210 and supplied in the direction of the outlet side of the body 100, and the ignition supply pipe ( 200) The first detection sensor 300 provided outside to detect whether the ignition supply pipe 200 is ignited and transmit the detection information to the control unit 600, and the combustion tower in response to the ignition of the ignition supply pipe 200 and a combustion unit 400 formed in the body 100 to burn harmful substances contained in the combustion gas existing in the combustion tower 500 by combustion in the combustion tower 500, wherein the first detection sensor Reference numeral 300 is characterized in that the ignition supply pipe 200 detects to be able to maintain an ignited state at all times.

In addition, the combustion unit 400 includes a plurality of connection pipe members 410 and a cooling water circulation pipe 415 that individually communicate with the space part 110 from the outside of the body 100, but the connection pipe member ( 410) is a first connection pipe 411 to which fuel gas necessary to combust the combustion gas existing in the combustion tower 500 is supplied, and the combustion gas supplied through the first connection pipe 411 for combustion. a second connection pipe 413 for supplying necessary oxygen, and the cooling water circulation pipe 415 is provided to surround the outer surface of the body 100 so that the combustion unit 400 burns the body The fuel gas and oxygen that are emitted toward the outlet side of the body 100 through the first connecting pipe 411 and the second connecting pipe 413 so that the heat generated in the air can be cooled by the circulating cooling water. It is preferable that combustion is made by the ignition of the ignition supply pipe 200 .

In addition, the penetrating member 120 is made in the shape of a pipe (PIPE) having an opening width widened in the direction from the inlet side to the outlet side, and is inserted into the through hole 510 perforated in the combustion tower 500 and fixedly fastened to the cone. 121 and a viewing window 123 and a control unit ( 600) is provided on the cone 121 so as to be electrically connected to the tube that detects whether normal combustion occurs at the exit side of the cone 121 through the combustion unit 400 and transmits the detection information to the control unit 600 and a second detection sensor 125 in the shape of (PIPE), wherein the control unit 600 controls the combustion unit if combustion is not performed at the outlet side of the cone 121 through the detection information of the second detection sensor 125 It is preferable to control so that the supply of oxygen and fuel gas supplied to 400 can be temporarily blocked by the on-off valve (B).

In addition, the penetrating member 120 is further provided with an air supply pipe 127 for supplying air from the outside of the cone 121 toward the outlet side. It is preferable that the air is discharged and the fuel gas remaining on the outlet side of the cone 121 is controlled by the controller 600 so that the fuel gas is forcibly exhausted through the outlet of the combustion tower 500 .

In addition, the outer surface of the cone 121 further includes a cooling water circulation port 129 communicating with the inside but through which the cooling water circulates, and the cooling water circulation port 129 forms the through hole 510 in addition to the cone 121 . The combustion tower 500 is installed in the shape of a pipe (PIPE) up to the inside of the combustion tower 500 to allow cooling water to circulate through the cone 121 as well as the combustion tower around the through hole 510 ( It is desirable to allow the heat of 500) to be cooled.

In addition, the penetrating member 120 is made in the shape of a column tube, the flame burned in the combustion unit 400 by the wind power of the combustion gas moving in a tornado from the lower part of the combustion tower 500 to the upper side. It is preferable that the exit end of the combustion unit 400 is installed so as not to protrude further than the exit end of the cone 121 mounted in the through hole 510 of the combustion tower 500 in order to prevent it from being turned off. do.

In addition, the penetrating member 120 is made in the shape of a column tube, the flame burned in the combustion unit 400 by the wind power of the combustion gas moving in a tornado from the lower part of the combustion tower 500 to the upper side. In order to prevent turning off, the through hole 510 is formed in an oblique shape to have a predetermined inclination angle upward to correspond to the moving direction of the corresponding combustion gas, and the combustion unit 400 is inserted into the oblique shape and shape matching It is desirable to be able to

According to the present invention, differently from the prior art, after ignition of the air and fuel gas supplied into the body through the ignition supply pipe, the first detection sensor detects the ignition by the control unit so that the ignition can be maintained at all times. When the flame of the combustion unit burning in the combustion tower is turned off by the wind power of the combustion gas moving upward in the combustion tower by supplying other fuel gas and oxygen, the second detection sensor quickly detects this, and the control unit controls By temporarily opening/closing the supply of fuel gas through the ignition supply pipe to re-ignite and burn, it has the effect of providing a burner with secured safety.

In addition, differently from the prior art, the angle of the through hole formed in the combustion tower is formed to have an oblique angle in accordance with the direction of the combustion gas rising in a tornado inside the combustion tower, and then the body is inserted into the through hole. By allowing the combustion to take place through the combustion unit, it has the effect of preventing the flame of the combustion unit from being extinguished by the wind power of the combustion gas.

1A and 1B are views showing a burner structure for incineration for combustion of harmful gas contained in combustion gas according to the present invention.
2 is a view showing a penetrating member for a burner structure for incineration for combustion of harmful gas contained in combustion gas according to the present invention.
3 is a view showing an ignition supply pipe for a burner structure for incineration for combustion of harmful gas contained in combustion gas according to the present invention.
4 is a view showing a body in which a combustion part is formed for a burner structure for incineration for combustion of harmful gas contained in combustion gas according to the present invention.
Fig. 5 is a cross-sectional view of Fig. 4;
6 is an enlarged view of a use state in which a burner structure for incineration for combustion of harmful gas contained in combustion gas according to the present invention is installed in an electric furnace.
7A and 7B are views showing the movement of combustion gases in an electric furnace in which a burner structure for incineration for combustion of harmful gases contained in combustion gases according to the present invention is installed.
8A and 8B are another embodiment of a burner structure for incineration for combustion of harmful gas contained in combustion gas according to the present invention.

Hereinafter, other objects and features of the present invention in addition to the above object will become apparent through the description of the embodiments with reference to the accompanying drawings, and unless otherwise defined, all terms used herein, including technical or scientific terms, are It has the same meaning as commonly understood by those of ordinary skill in the art to which the invention pertains. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

Hereinafter, a burner structure for incineration for combustion of harmful gas contained in combustion gas according to the present invention (hereinafter, simply referred to as a 'burner structure') will be described in detail with reference to the accompanying drawings.

First, as shown in FIGS. 1A and 1B , the burner structure 1 according to the present invention largely consists of a body 100 , an ignition supply pipe 200 , a first detection sensor 300 , and a combustion unit 400 . includes

2, 3, and 5 will be described in more detail, the body 100 through the combustion unit 400 from the inside of the combustion tower 500 using the flame burned in the ignition supply pipe 200. It includes a plurality of space portions 110 and the penetrating member 120 in a configuration for enabling another combustion to be performed.

For example, the body 100 is a tube with both sides open in the direction from the inlet to the outlet in which the ignition supply pipe 200 is installed using a material having a durability against heat generated during combustion is mixed or coated on its outer surface ( PIPE).

The first detection sensor 300 is coupled to one side of the body 100 so that the outlet side faces in the horizontal direction, but the mixing tube 220 and the plug communicating with the inside of the body 100 symmetrically to each other in the horizontal direction on the outer surface ( An ignition supply pipe 200 including 210 is installed.

As shown in the figure, the mixing pipe 220 includes air and fuel gas (eg, LNG) for igniting in response to a spark, which is a spark due to electrical discharge of the plug 210 , in the mixing pipe 220 . ) after mixing with each other, so that combustion is made inside the body 100 .

At this time, when combustion is made in the body 100 through the ignition supply pipe 200 , the first detection sensor 300 provided on one side to communicate with the inside of the body 100 detects this and then transmits it to the control unit 600 . so that it can be determined that ignition has been made, and the control unit 600 may block the supply of fuel gas and air supplied to the mixing tube 220 if no detection information is input from the first detection sensor 300 . It is desirable to control the valve (B) so that

In addition, the control unit 600 opens the valve (B) of the air for a certain period of time after blocking the valve (B), and then releases the fuel gas present in the body 100 into the combustion tower 500 by any chance. Thereafter, another valve (B) for supplying the corresponding fuel gas is opened to safely ignite.

As shown in the figure, the body 100 is supplied with fuel gas and oxygen supplied to the combustion unit 400 for performing combustion in the combustion tower 500 through first and second connection pipes 411 and 413 to be described later. It is provided independently and has a structure of a double tube having space portions 110 independent from each other so that they can be discharged in the exit direction of the body 100 , and the space portion 110 formed in the first connection tube 411 is described below. ) is referred to as a first space portion 111 , and the space portion 110 formed inside the second connection pipe 413 is referred to as a second space portion 113 to clearly understand the gist of the present invention.

In addition, the first and second space portions 111 and 113 may be opened in a band shape on the outlet side of the body 100, but a plurality of radially perforations are each based on the center of the body 100 made of a circular tube shape. Smooth combustion by minimizing interference with the discharge of fuel gas and oxygen by the wind power of combustion gas (C-GAS) that is formed in a shape and moves in a tornado within the combustion tower 500 is possible to obtain.

In addition, the penetrating member 120 is configured to prevent the body 100 from being fixedly installed in the combustion tower 500 under the above to prevent deterioration of durability due to vibration and airtightness of heat generated during combustion. , a sight window 123 , a second detection sensor 125 , an air supply pipe 127 , and a coolant circulation port 129 .

For example, the cone 121 has a shape in which the opening width is gradually widened in the direction from the inlet side to the outlet side as shown, and the outer surface of the cone 121 is a through hole 510 formed in the outer surface of the combustion tower 500 having a columnar shape. It has a structure that can be fixed to the combustion tower 500 by being fastened to each other after being inserted in a shape-fitting manner.

In addition, the inside of the cone 121 is inserted through the body 100 so that airtightness with the outer surface of the body 100 can be maintained so that heat due to combustion of the combustion unit 400 to be described later or harmful substances moving in the combustion tower 500 are included. To prevent the emission of combustion gases.

At this time, as shown in the figure, the exit end of the body 100 inserted into the cone 121 is formed in a plurality in the longitudinal direction of the combustion tower 500 so as to form a right angle with respect to an arbitrary central point P. By inserting the cone 121 so as not to protrude further than the exit end of the cone 121 so that combustion is made through the combustion unit 400, the combustion unit is driven by the wind power of the combustion gas moving in a tornado within the combustion tower 500. It is desirable to prevent the flame burning in (400) from being extinguished. (See FIGS. 7A and 7B)

The cone 121 may be made of the same material as the above-described body 100 and may have a hollow interior shape, and a plurality of cooling water circulation holes 129 communicating with the interior are formed on the outer surface of any one of the above By having a circulation structure by a circulation pump in which cooling water is supplied into the cone 121 through the cooling water circulation port 129 and then the cooling water is discharged to the other cooling water circulation port 129, the body 100 is burned It is heated through combustion of the part 400 to prevent heat from being transferred to the combustion tower 500 .

On the other hand, as shown in the figure, the cooling water circulation hole 129 has a plurality of curved pipes to be connected to each other in the cross section of the combustion tower 500 close to the through hole 510 through which the cone 121 is inserted. It is installed in communication with the inside of the cone 121 to allow cooling of the cone 121 as well as cooling of the combustion tower 500 to be performed in parallel. (See Fig. 6)

On the outer surface of the cone 121, in addition to the coolant circulation port 129 described above, a PIPE-shaped sight through which the operator visually checks whether combustion by the combustion unit 400 is normally executed from the outside of the burner structure 1 according to the present invention. 123 is formed, and as shown in the figure, the see-through window 123 is made of a flame-retardant material (eg, castable) on the inlet side and a transparent glass film is formed inside the combustion tower 500 through the glass film. Check the combustion state of the combustion unit 400 that burns.

A second detection sensor 125 having the same function as the above-described first detection sensor 300 is further provided on the outer surface of the cone 121 to check whether the combustion unit 400 is burned together with the viewing window 123 by the sensor. To this end, the second detection sensor 125 is electrically connected to the control unit 600 so that the control unit 600 can receive the detection information.

Thus, when it is detected through the second detection sensor 125 that combustion of the combustion unit 400 is not performed, the control unit 600 opens and closes the supply of fuel gas constituting the combustion unit 400, the valve (B) After checking whether ignition is made in the first detection sensor 300 described above, the closed valve B is controlled to be opened again to prevent a safety accident, and the safety accident here is the combustion unit ( 400), continuous fuel gas is released into the combustion tower 500 due to non-combustion, which means an accident such as an explosion inside.

In addition, on the outer surface of the second detection sensor 125 formed on the outer surface of the cone 121 in the shape of a tube (PIPE), an air supply pipe 127 for discharging air in the combustion tower 500 inward direction through the control of the controller 600 is provided. It may be further provided, and the purpose of the air supply pipe 127 is that the second detection sensor 125 detects that combustion of the combustion unit 400 is not performed, and the valve B for supplying fuel gas is closed. After that, by the discharge pressure of the air discharged through the air supply pipe 127 before controlling the valve (B) to open for re-supply of the corresponding fuel gas, the inside of the body 100 or the cone 121 In a state in which the remaining fuel gas is discharged into the combustion tower 500, the re-opening of the corresponding valve (B) is made to maximize the advantage of safety accident prevention.

Meanwhile, the first and second detection sensors 300 and 125 described above use a flame detector capable of detecting light or heat generated during combustion, and the controller 600 controls the first and second detection Depending on whether the sensors 300 and 125 are detected, the first and second detection sensors 300 and 125 are provided in a control box (not shown), etc., and the operation of the first and second detection sensors 300 and 125 is checked through a plurality of lamps (not shown) that emit light by the applied power. It is also possible to make it visually identifiable by an operator or administrator.

In addition, the combustion unit 400 responds to the flame (combustion) generated by the ignition supply pipe 200 described above in the exit direction of the body 100, another fuel gas (LNG) and oxygen (OXYGEN) required for combustion. ) to supply the first connection pipe 411, the second connection pipe 413, and the cooling water circulation pipe in a configuration so that harmful substances contained in the combustion gas moving in the combustion tower 500 can be completely combusted. 415 is included, and as shown, the arrangement of the first connection pipe 411 , the second connection pipe 413 , and the cooling water circulation pipe 415 is sequential in the direction from the inlet side to the outlet side of the body 100 . formed to be

For example, the first connection pipe 411 is pipe-connected to the body 100 so as to communicate with the first space part 111 of the outer surface of the body 100 having a double pipe structure so that a plurality of space parts 110 are formed to form fuel gas. is supplied, and whether the fuel gas supplied through the first connection pipe 411 is supplied to the openable/closable valve B under the control of the control unit 600 is determined.

In addition, the fuel gas supplied to the first space 111 through the first connection pipe 411 can be discharged into the combustion tower 500 through a radially perforated through hole on the output side of the body 100 . do.

In addition, the second connecting pipe 413 is pipe-connected to communicate with the second space 113 formed inside the body 100 independently of the first space 111, so that oxygen required for combustion together with fuel gas is provided. to be supplied.

In addition, oxygen supplied to the second space 113 through the second connection pipe 413 is supplied to the combustion tower 500 through another through-hole formed radially on the output side of the body 100 in the same manner as the fuel gas described above. ) after being discharged to the inside, they are mixed in the combustion tower 500, and the mixed fuel gas and oxygen are combusted by the ignition supply pipe 200 supplied as flame or high-temperature heat through the body 100 output side. will lose

In addition, the cooling water circulation pipe 415 is configured to improve the durability of the body 100 by cooling the heat transferred to the body 100 due to the combustion of the combustion unit 400 by the circulating cooling water.

For this, the cooling water circulation pipe 415 is installed to form a third space through which the cooling water can circulate between the outer surface of the body 100 and the inner surface of the cooling water circulation pipe 415, as shown, the outer surface of the pipe It is formed to protrude in a shape and has a structure in which cooling water necessary for cooling the body 100 can be supplied from the outside.

Meanwhile, the burner structure 1 according to the present invention is another method for solving the problem that the flame of the combustion unit 400 is extinguished while the combustion gas is burned through the combustion unit 400 as described above. The penetrating member 120 inserted and installed in the through hole 510 of the tower 500 may be installed to have an inclination angle (preferably, an inclination angle of 10 to 20 degrees) in the combustion tower 500 .

That is, as shown in FIGS. 8A and 8B , harmful substances that move upward in the direction of perforation of the through-hole 510 formed on the outer surface of the combustion tower 500 from the lower inner side of the combustion tower 500 to the upper side tornado direction. The through-hole 510 is perforated to have the same oblique angle as the direction of movement of the included combustion gas, but the body 100 is inserted at the same angle to the combustion unit 400 through the combustion tower 500 By allowing combustion to take place within, the interference of the combustion gas by wind power is minimized to prevent the combustion flame from being extinguished.

At this time, the through-holes 510 are formed in a number of radial perforations around the central portion along the longitudinal direction of the column-shaped combustion tower 500 having a predetermined diameter, and the combustion moves from the lower part of the combustion tower 500 to the upper direction. It is preferable that the combustion of the gas be made over a plurality of times.

In conclusion, in the burner structure 1 according to the present invention having the organic coupling relationship of the above-described components, the control unit 600 detects whether the flame of the ignition supply pipe 200 is always activated by the first detection sensor 300 . In this state, when the flame of the combustion unit 400 for burning the combustion gas containing harmful substances inside the combustion tower 500 is turned off by the wind power, it is quickly detected by the second detection sensor 125 After that, the combustion unit 400 is re-ignited through the ignition supply pipe 200 in a state where safety is maintained and can be used.

As described above, the burner structure 1 according to the present invention ignites (combusts) the air and fuel gas supplied into the body 100 through the ignition supply pipe 200 differently from the prior art, and then the first detection sensor The flame of the combustion unit 400 that burns in the combustion tower 500 by supplying another fuel gas and oxygen in a state to be detected by the control unit 600 so that the ignition can be maintained at all times through 300 When power off occurs by the wind power of the combustion gas moving upward in the combustion tower 500 , the second detection sensor 125 detects this quickly, and the supply of fuel gas is temporarily stopped through the control of the control unit 600 . By opening and closing and re-igniting by the ignition supply pipe 200 to achieve combustion, it has the effect of providing a burner with secured safety.

In addition, differently from the prior art, the angle of the through hole 510 perforated in the combustion tower 500 is aligned with the direction of the combustion gas rising in a tornado form inside the combustion tower 500 to have an oblique angle of inclination After the perforation is formed, The effect of preventing the flame of the combustion unit 400 from being extinguished by the wind power of the combustion gas by inserting the body 100 into the through-hole 510 to cause combustion through the combustion unit 400 . will have

As described above, in the present invention, specific matters such as specific components, etc., and limited embodiments and drawings have been described, but these are only provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , various modifications and variations are possible from these descriptions by those of ordinary skill in the art to which the present invention pertains.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and not only the claims to be described later, but also all those with equivalent or equivalent modifications to the claims will be said to belong to the scope of the spirit of the present invention. .

1: Burner structure for incineration for combustion of harmful gas contained in combustion gas according to the present invention
100: body
110: space part 111: first space part
113: second space 120: penetrating member
121: cone 123: sight window
125: second detection sensor 127: air supply pipe
129: coolant circulation port
200: ignition supply pipe
210: plug 220: mixing tube
300: first detection sensor
400: combustion unit
410: connector member 411: first connector
413: second connector 415: cooling water circulation pipe
500: combustion tower
510: through hole
600: control unit

Claims (7)

The inlet side and the outlet side are opened, and it is made in the shape of a pipe (PIPE) in which a plurality of space portions 110 independent from each other are formed, and a penetrating member 120 provided in a radial shape along the longitudinal direction of the combustion tower 500 . The body 100 is inserted and fastened to the shape fit;
The ignition is connected to the inlet side of the body 100 so as to communicate with the inside of the body 100, and after air and gas necessary for combustion are mixed with each other, the ignition is ignited by the plug 210 and supplied to the outlet side of the body 100 supply pipe 200;
a first detection sensor 300 provided outside the ignition supply pipe 200 to detect whether the ignition supply pipe 200 is ignited and transmit the detection information to the control unit 600; and
Combustion is formed in the body 100 in response to the ignition of the ignition supply pipe 200 to be combusted in the combustion tower 500 to combust the harmful substances contained in the combustion gas existing in the combustion tower 500 . part 400; including,
The first detection sensor 300 detects that the ignition supply pipe 200 can always maintain an ignited state,
The first detection sensor 300 is coupled to one side of the body 100 so that the outlet side faces in the horizontal direction, and the mixing tube 220 communicates with the inside of the body 100 symmetrically to each other in the transverse direction on the outer surface and The ignition supply pipe 200 including the plug 210 is installed,
The mixing tube 220 is the body ( 100) so that combustion takes place inside,
When combustion is made in the body 100 through the ignition supply pipe 200, the first detection sensor 300 provided on one side to communicate with the inside of the body 100 detects this, and then to the controller 600 transmission so that it can be determined that ignition has been made, and the control unit 600 stops the supply of fuel gas and air supplied to the mixing tube 220 if no detection information is input from the first detection sensor 300 . configured to control the valve (B) to be shut off;
After the control unit 600 opens the valve (B) of the air for a certain period of time after blocking the valve (B), by any chance, after discharging the fuel gas present in the body 100 to the inside of the combustion tower 500 A burner structure for incineration for combustion of harmful gases contained in combustion gases, characterized in that by opening another valve (B) for supplying the corresponding fuel gas to safely ignite.
According to claim 1,
The combustion unit 400 is
A plurality of connecting pipe members 410 and a cooling water circulation pipe 415 communicating individually with the space part 110 from the outside of the body 100;
The connecting pipe member 410 includes a first connecting pipe 411 to which fuel gas necessary for combusting the combustion gas existing in the combustion tower 500 is supplied, and the combustion supplied through the first connecting pipe 411 . It includes a second connection pipe 413 for supplying oxygen necessary for combustion together with the gas,
The cooling water circulation pipe 415 is provided to surround the outer surface of the body 100 so that the heat generated in the body 100 when the combustion unit 400 is burned can be cooled by the circulating cooling water,
The fuel gas and oxygen emitted toward the outlet side of the body 100 through the first connection pipe 411 and the second connection pipe 413 are combusted by the ignition of the ignition supply pipe 200 . Incineration burner structure for the combustion of harmful gases contained in the combustion gas, characterized in that.
According to claim 1,
The penetrating member 120 is
a cone 121 formed in a pipe (PIPE) shape with an opening width widening from the inlet side to the outlet side and inserted into the through hole 510 perforated in the combustion tower 500 to be fixedly fastened;
a viewing window 123 provided so as to be able to see through from the outside of the cone 121 in communication with the inside of the cone 121 so as to visually check whether or not combustion occurs at the outlet side of the cone 121; and
It is provided in the cone 121 to be electrically connected to the control unit 600 , and detects whether normal combustion occurs at the exit side of the cone 121 through the combustion unit 400 , and transmits the detection information to the control unit 600 . Including; a second detection sensor 125 in the shape of a pipe (PIPE) to
If combustion does not occur at the outlet side of the cone 121 through the detection information of the second detection sensor 125, the control unit 600 controls the supply of oxygen and fuel gas supplied to the combustion unit 400 to the on/off valve ( B) Burner structure for incineration for the combustion of harmful gases contained in the combustion gas, characterized in that the control to be temporarily blocked by.
4. The method of claim 3,
The penetrating member 120 is
An air supply pipe 127 for supplying air from the outside of the cone 121 toward the outlet is further provided.
The air supply pipe 127 discharges air for a certain time while the on/off valve is closed so that the fuel gas remaining on the outlet side of the cone 121 can be forcibly exhausted through the exhaust port of the combustion tower 500 . Burner structure for incineration for combustion of harmful gas contained in combustion gas, characterized in that controlled by the control unit (600).
4. The method of claim 3,
The outer surface of the cone 121 further includes a cooling water circulation port 129 that communicates with the interior but through which the cooling water circulates, wherein the cooling water circulation port 129 forms the through hole 510 in addition to the cone 121 . It is installed in the shape of a pipe (PIPE) up to the inside of the combustion tower 500 so that cooling water can circulate through the cone 121 as well as the combustion tower 500 around the through hole 510 . ) Burner structure for incineration for the combustion of harmful gases contained in the combustion gas, characterized in that so that the heat of the cooling.
4. The method of claim 3,
The penetrating member 120 is
The combustion unit ( Noxious gas contained in combustion gas, characterized in that the outlet end of the combustion tower 500 is installed so as not to protrude further than the outlet end of the cone 121 mounted in the through hole 510 of the combustion tower 500 Burner structure for incineration for combustion.
7. The method of claim 6,
The penetrating member 120 is
The through-hole ( Combustion gas, characterized in that the 510) is formed in an oblique shape to have a predetermined inclination angle upward to correspond to the movement direction of the corresponding combustion gas, and the combustion unit 400 is inserted into the oblique shape and shape matching. Burner structure for incineration for the combustion of harmful gases included in

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