KR100788909B1 - Voc incineration apparatus designed by module type with large turn down ratio and without backfire occurrence - Google Patents

Abstract

A flame combustion apparatus for processing VOC(Volatile Organic Composition) by a module type with large capacity without backfire occurrence is provided to reduce the backfire possibility by installing backfire prevention nozzles dually and to increase flame stability by mounting a flame holder around the nozzles. A flame combustion apparatus for processing VOC(volatile organic composition) by a module type with large capacity without backfire occurrence comprises an air supply chamber part(1), a VOC supply part(2), a flame generating part(3), and a backfire prevention part(4), second backfire prevention nozzles, and a first mixed air supply pipe. The air supply chamber part has an air supply chamber(13) in which an air(15) for processing a VOC(22) is stored, and an air supply pipe(14) formed to supply the air to a flame generating part(3). The VOC supply part has a VOC supply pipe(21) installed in the air supply pipe by supplying the VOC to the flame generating part. The flame generating part has a flame holder(31) for stabilizing the flame. The backfire prevention part is formed with a first backfire prevention nozzle(41) of a porous structure. The second backfire prevention nozzles are separated from each other toward the lower part of the first backfire prevention nozzles. The first mixed air supply pipe is formed with a path through the VOC supply pipe.

Description

VOC Incineration Apparatus Designed by Module Type with Large Turn down Ratio and without Backfire Occurrence}

1 is a general schematic diagram of a basic combustion apparatus according to the present invention,

FIG. 2 is an overall schematic diagram of a combustion apparatus according to a modification of the basic combustion apparatus of the present invention shown in FIG.

3 is a general schematic diagram of a combustion device according to another modification of the basic combustion device of the present invention shown in FIG.

4 is an overall schematic view of a combustion device including a swing device further included in the combustion device of the present invention according to the modification of FIG. 2,

5 is an overall schematic diagram of a combustion device according to another modification of the basic combustion device of the present invention shown in FIG.

Figure 6 is a schematic diagram showing the flame characteristics of each of the combustion apparatus (burner) of the present invention,

7 is a schematic view showing the flashback nozzle and the flame holder structure of the present invention;

8 is a schematic view showing the structure of the swing device of the present invention,

9 is a schematic view showing the structure of the present invention air / VOC mixing device,

10 is a schematic diagram showing the structure when the module type single combustion device (burner) is composed of a multiple combustion device (burner) structure,

11 is an embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

(1): air supply chamber part (2): VOC supply part

(3): flame generating part (4): backfire prevention part

(5): Drain 6: Appearance

(11): primary mixed air supply pipe (12): secondary mixed air supply pipe

(13): air supply chamber (14): air supply pipe

(15): Air (21): VOC supply pipe

(22): VOC (23): Primary mixed VOC supply pipe

(31): flame holder (32): secondary flame holder

(33): Slewing device (34): Slewing wing

(41): 1st flashback prevention nozzle (42): 2nd flashback prevention nozzle

(43): air and VOC mixer

The present invention relates to a flame-burning apparatus for treating volatile organic compounds having a large processing capacity range and no flame inversion, designed in a modular type. Specifically, the present invention relates to volatile organic compounds generated in the storage and storage of liquefied petroleum gas. Volatile Organic Compounds (hereinafter referred to as 'VOC') relates to a flame combustion device configured to be widely applied to various VOC compositions as well as to develop flame stability and minimize unburned gas generation.

In general, VOC refers to a substance having a vapor pressure of 0.01 kPa or higher at 20 ° C. It reacts with nitrogen oxides to generate photochemical oxidants by receiving sunlight, causing forests to die, causing cancer, etc., and causing considerable damage to the human body. It is a harmful substance that adversely affects the global environment such as warming and destruction of the ozone layer.

As a result, member states, including the United States, Canada, the EC, and Eastern Europe, pledged to reduce their VOC emissions by more than 30% by 2,000 years compared to the base year. To be fulfilled.

In Korea, the amendment of the Air Pollution Conservation Act was established in December 1995. Accordingly, since 1999, VOCs are regulated in the air environment regulation area designated by Article 8-2 of the Air Pollution Conservation Act.

The sources of VOC are detected in a large number of coating booths, paint processes, petrochemical processes, oil storage and gas stations of automobiles. In particular, in liquefied LNG and petroleum products, gaseous harmful substances generated by volatilization are exploded or released into the atmosphere, which is a serious cause of environmental pollution.

Therefore, it is an important technical task to develop a prevention facility that efficiently handles these volatile harmful substances, and in fact, much research is in progress.

As described above, the VOC not only has various kinds of sources, but also shows a big difference in the generation amount depending on the sources.

Most of VOCs generated from paint process, paint booth, drying process, etc. are mostly local sources, and generally do not have a high concentration, and in some cases, local emissions are generated that cannot be processed by combustion. For this reason, treatment methods such as adsorption towers are mainly used, and in some cases, inefficient methods of adsorbing activated carbon to high concentrations and then desorbing and incineration and treatment are used.

On the other hand, high concentrations of VOCs of nearly 100% are initially emitted from refining processes of petrochemical complexes and reservoirs or gas station tanks storing liquefied petroleum, LNG and LPG. Therefore, there is no need to adsorb it separately, but a combustion method such as catalytic combustion is not suitable, and an active combustion method such as flame combustion is applied.

The method of treating VOC is slightly different depending on the source, and the control technology currently commercialized or developed for treating VOC can be classified into incineration method, adsorption method, and absorption method. Law is the most widely used method. Since VOCs are emitted in various forms, it is not possible to select a treatment device uniformly. However, since the VOC concentration determines the installation and operating costs of the treatment system, the VOC treatment method can be selected by the emission concentration.

In recent years, the combustion cracking method has been used more actively as a more aggressive treatment method, and the method using a catalytic combustion method and a flame combustion method, and a combination of these two methods are used.

Catalytic combustion is a method in which the catalyst lowers the activation energy to treat VOC at a relatively low temperature of 250 to 400 ° C. Catalytic combustion can be burned at low temperatures and is advantageous for processes that emit low concentrations of VOC rather than high concentrations due to the physical properties of the support that supports the catalyst. It is low in maintenance cost. As the catalyst material, precious metals such as platinum and palladium and metal oxides such as chromium oxide, cobalt oxide, copper oxide, and manganese oxide are used.

Catalytic incineration has a disadvantage in that the activity of the catalyst decreases due to the unburned material and the catalyst poison material in the reaction product during the low temperature combustion process, and the activity may be drastically decreased. Common factors include thermal shock or thermal aging caused by catalytic poisons such as lead, arsenic, sulfur, mercury, etc., pollutants such as dust, and high calorific values during high concentrations of VOC treatment. Recently, the heat storage method is additionally introduced, and the heat storage method is a technology that uses waste heat again by using a heat recovery device or a regeneration device such as a heat exchanger to reduce energy costs and improve combustion efficiency. However, catalytic combustion alone is not easy to control actively in response to changes in the concentration of the source, especially in high concentration sources there are fatal disadvantages such as thermal shock of the material and deactivation of the catalytic material activity. In the conventional diffusion combustion method, only VOC combustion supplied in a state of being mixed with air generated in a low oil station was possible, and the flame length was long and the combustor itself had to be enlarged. In addition, it was possible to burn only under uniform supply conditions, so that a device for supplying the pressurized equipment and storing the generated VOCs once in a storage facility was needed. In addition, there was a problem such as incomplete combustion or flame extinguishes in a low concentration lean combustion conditions.

Recently, in order to make up for this drawback, a combination of a flame combustion method and a catalytic combustion method has been started to be developed or used in some cases. The main stage is the catalytic combustion process at the rear stage. This principle has the great advantage that the system can be burned almost completely. However, the flame combustion technology used in the pretreatment process is still used in such a way that the flame length is long and unburned gas is generated, and the fine carbon particles generated in this process are adsorbed by the catalyst in the rear stage to lower the activity. There are disadvantages such as that.

An object of the present invention for solving the above problems is to produce a flame burner (burner) to effectively treat the volatile organic compounds, which are representative pollution, in particular, such as a paint process, a drying process generated as a local source Flame burning equipment with various concentration conditions and capacities ranging from low concentration sources with low concentration to high generation sources with near 100% concentration, such as liquefied petroleum gas production and storage facilities, and flame stability To provide.

Another object of the present invention is to provide a flame combustion apparatus having a combustion structure in which no backfire occurs at all by installing a unique flameback nozzle in a unique form.

Another object of the present invention is to provide a flame combustion apparatus having a selective premixing method of air and VOC so that combustion performance can be effectively generated according to the concentration of VOC supplied from the source.

In addition, another object of the present invention is to provide a flame combustion device is installed on the flame prevention nozzle side for flame stability, and equipped with a swing device for minimizing the flame length through the rapid mixing of air and VOC.

In the flame combustion apparatus for volatile organic compound (VOC) treatment, the present invention which achieves the object as described above and removes the drawbacks of the prior art, the air for treating VOC from one side to the horizontal direction An air supply chamber portion including an air supply chamber in which the supplied air is stored, and an air supply pipe configured to supply air supplied from the air supply chamber to the flame generator by changing a flow path in a vertical direction; a gas station tank or a storage station of liquefied petroleum gas A VOC supplying unit comprising a VOC supplying pipe installed inside the air supplying pipe to supply the VOC generated in the flame generating unit to process the flame combustion; A flame generator installed in a circumferential direction of the vertical end of the VOC supply pipe, and having a flame holder which stabilizes the flame when the flame is generated by diffusion of air and VOC supplied from the air supply pipe and the VOC supply pipe; Flashback prevention unit is characterized in that the first flashback prevention nozzle of the porous structure mounted on the vertical end of the VOC supply pipe.

In another aspect, the present invention and the secondary flashback prevention nozzle installed in the VOC supply pipe and spaced apart at a predetermined interval in the lower side of the primary flashback prevention nozzle;

A primary mixed air supply pipe passing through the VOC supply pipe to supply air supplied from the air supply chamber to the lower portion of the secondary reverse flame prevention nozzle;

The air and the VOC mixing device installed on the upper part of the secondary backlash prevention nozzle may be further configured to mix the air and the VOC supplied from the primary mixed air supply pipe.

In addition, the configuration of the present invention is a flame combustion apparatus for treating volatile organic compounds (VOC),

Air supply consisting of an air supply chamber in which the air supplied in the horizontal direction to the air for processing the VOC is stored, and an air supply pipe formed to supply the air supplied from the air supply chamber to the flame generator by changing the flow path in the vertical direction A chamber portion;

A VOC supply unit comprising a VOC supply pipe installed inside the air supply pipe to supply VOC generated from a gas station tank or a low oil station of the liquefied petroleum gas to a flame generating unit for flame combustion treatment;

The flame generating unit is installed in the circumferential direction of the vertical end of the VOC supply pipe and comprises a turning device that rotates the air to widen the width of the flame when the flame is generated by diffusion of air and VOC supplied from the air supply pipe and the VOC supply pipe. Wow;

The porous backfire prevention nozzle of the porous structure mounted on the vertical end of the VOC supply pipe, the secondary flashback prevention nozzle installed at a predetermined distance apart from the lower side of the primary primary flashback prevention nozzle, and the air and the VOC are mixed well. A flashback prevention part composed of air and a VOC mixing device installed on the secondary flashback prevention nozzle so as to be possible;

And a secondary mixed air supply pipe and a primary VOC mixed supply pipe installed through the VOC supply pipe and the air supply pipe so as to be selectively connected to a lower portion of the secondary backfire prevention nozzle.

In addition, the present invention was configured by adding a turning device to the flame holder lower.

In another aspect, the present invention further comprises a flame holder for stabilizing the flame on the top of the turning device.

In addition, the flame holder of the present invention Made of perforated nickel-chromium steel plate to keep flames well even when the air for combustion passes at a high speed, it is attached to the tip of the primary flashback prevention nozzle to make the mixing role between the air for combustion and VOC well. It was.

In addition, the flame holder of the present invention has a structure in which a plurality of perforations are formed in each divided surface in a structure divided into four, each hole in the divided surface serves as a primary flame holder, and other than four divided surfaces In this part, the air flow is directed to the flame, so that diffusion mixing with the VOC flowing from the primary backfire prevention nozzle occurs smoothly.

In addition, the air and VOC mixing device of the present invention is configured to be inclined 15 degrees to 30 degrees and the flow direction of the fluid depending on the amount of air and VOC supplied.

In addition, the surface of the air and VOC mixing apparatus of the present invention is composed of any one surface selected from the structure that is not perforated or a plurality of perforated structure.

In addition, in the primary flashback prevention nozzle or the secondary flashback prevention nozzle of the present invention, the height of the nozzle should be at least 25mm or more and 100mm or less (variable according to the burner's capacity) according to the mixing amount of VOC and air, and the material can be used even at high temperature. It is manufactured by using nickel-chromium steel to prevent corrosion, and it is designed to maintain flame stability and prevent backfire by designing very small microporous structure of 200-300 cells per inch.

In addition, the present invention is configured such that any one or more of the primary or secondary flashback prevention nozzle and the flame holder is configured in a module type combined in one structure.

In addition, the swivel device of the present invention is installed at the bottom of the primary flashback prevention nozzle and the flame holder, so that the air and VOC can be uniformly mixed at the shortest distance just before the flame is generated, the swivel wing constituting the swivel device The angle is designed to be within 15 to 45 degrees and can be modified in a wide flow range.

In addition, the present invention is composed of a module, the primary backfire prevention nozzle, the flame holder and the swinging device is coupled to the VOC supply pipe.

In addition, the present invention is a flame combustion apparatus for treating volatile organic compounds (VOC),

Three individual air supply chambers and VOC supply units are formed to penetrate the circumferential appearance on both sides, and are configured to supply air and VOC individually, and each of the individual air supply chambers and VOC supply units is provided in one air supply pipe. It is composed of three flame holders and primary flashback prevention nozzles, which combines three combustion devices into one module and combines them again.

Combustion apparatus having a premixed combustion method of the present invention configured as described above ensures the stability of the flame in all supply conditions from VOC of less than 5% of FUEL (process or low oil generation) to 100% of FUEL component (occurring in the carrier) The flame length is reduced from fast mixed combustion, and complete combustion is realized.

In addition, the VOC treatment combustion apparatus (burner) according to the present invention is designed in a structure suitable for continuously installing a plurality of combustion apparatus (burners) from a single combustion device (burner) according to the VOC generating capacity from a low capacity to a petrochemical complex The processing capacity range is large up to the large capacity that can be applied, and the flame retardant prevention technology is applied to the nozzles twice to form a safer combustion system.

Hereinafter, the configuration and the operation of the embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an overall schematic diagram of a combustion apparatus of a basic form according to the present invention, and shows an overall schematic diagram of the combustion apparatus of the basic form of the present invention composed of an air supply chamber portion, a VOC supply portion, a flame combustion portion, and a flashback prevention portion. have. Specifically, the configuration of the present invention is the most common form of diffusion type VOC combustion apparatus of the present invention, the air 15 supplied through the air supply pipe 14 after entering through the air supply chamber 13 of the air supply chamber unit 1 (15). After the VOC 22 is separately supplied to the VOC supply pipe 21 of the VOC supply part 2), the primary backfire prevention nozzle of the flame holder 31 of the flame generating part 3 and the flashback prevention part 4 41) is characterized by the fact that the flame is generated as mixing is in earnest.

However, the apparatus of the present invention configured as described above has superior flame stability due to the installation of the primary reverse flame prevention nozzle 41, but the flame is slightly longer due to the longer mixing section of the air 15 and the VOC 22. .

The height of the nozzle in the primary flashback prevention nozzle 41 or the secondary flashback prevention nozzle 42 is at least 25 mm or more and 100 mm or less (variable according to the burner's capacity) depending on the mixing amount of the VOC 22 and the air 15, The material can be used at high temperature, and it is manufactured using nickel-chromium steel to prevent corrosion, and it is designed to maintain flame stability and prevent backfire by designing very small microporous structure of 200-300 cells per inch.

The flame holder 31 is made of nickel-chromium steel that is optimally perforated and attached to the tip of the nozzle 41 so that the flame is well preserved even when the combustion air 15 passes at a high speed. It is designed to obtain a dual effect that can be well mixed between the 15 and the VOC 22, the detailed structure is shown in detail in FIG.

The combustion device (burner) configured as described above is applied to the shipping site of the gasoline steam generation, and the inlet air generated when the combustion gas is discharged even if only 30-40% of the total required air is supplied to the primary combustion air 15. Residual VOC (22) is a method of combustion, and if the combustible component of the VOC (22) is more than 60% has a disadvantage that the flame may be long or a large amount of unburned gas.

The present invention compensates for the shortcomings of the combustion device (burner) disclosed in FIG. 1 and enables the treatment system to be miniaturized by securing more stable flames and reducing the flame length, and minimizing the generation of unburned gas, thereby reducing air pollution. A combustion apparatus (burner) was also invented, but this configuration of the present invention is disclosed in FIG.

FIG. 2 is an overall schematic diagram of a combustion apparatus according to a modification of the basic combustion apparatus of the present invention shown in FIG. 1, the configuration of which is a mixture of air and VOC in the combustion apparatus of the present invention basic type shown in FIG. , The primary mixed air supply pipe (11), and the secondary backfire prevention nozzle (42) is a combustion device of the type added in the middle.

Specifically, the combustion device (burner) of the present invention creates a mixed space (chamber) having a double nozzle structure composed of the primary flashback prevention nozzle 41 and the secondary flashback prevention nozzle 42, and the primary mixed air supply pipe ( 11) the air 15 supplied from the secondary flashback prevention nozzle 42 passes through the device and immediately mixes with the VOC 22 while passing through the air and VOC mixing device 43, thereby preventing the primary flashback prevention nozzle 41. It can be fed to the tip to form a stable flame and achieve fast combustion.

The structure of the secondary flashback prevention nozzle (42) is the same as that of the primary flashback prevention nozzle (41), and the air and VOC mixing device (43) is installed at a right angle with the secondary flashback prevention nozzle (42). The upper surface is circular, and the surface structure is designed to be mixed with a porous structure consisting of a plurality of holes or a structure without holes at all, and the circular surface and air flow direction are within 15 to 30 degrees. Deformation is possible according to the capacity of the fluid, and its structure is shown in FIG.

Reference numeral 5 denotes a drain, and the combustion apparatus of the present invention has a structure in which the upper end is open (open), and is installed externally due to the operation characteristics of the apparatus, so that it may be exposed to rain or other similar weather conditions. There is a high possibility that water may accumulate inside the device. Therefore, in the present invention, it is possible to remove the water from time to time by installing a drain.

FIG. 3 is an overall schematic diagram of a combustion apparatus according to another modification of the basic combustion apparatus of the present invention shown in FIG. 1, the configuration of which is circumferentially around the primary backfire prevention nozzle 41 in the basic configuration of FIG. 1. Removed the flame holder 31 is installed, the turning device 33 is installed, the secondary flashback prevention nozzle (42) is installed in the middle of the VOC supply pipe (21), and the upper portion of the secondary flashback prevention nozzle (42) The air and VOC mixing device 43 was installed at right angles to the secondary flashback prevention nozzle 42. The upper surface of the air and VOC mixing device 43 is circular, and the surface structure is designed to be a mixture of a porous structure consisting of a plurality of holes or a hole-free structure, and the circular surface and air flow direction is 15 degrees Within 30 degrees, it is possible to modify according to the total volume of fluid supplied, the structure is shown in FIG.

In addition, by configuring the swinging device 33 composed of a swing wing type instead of the flame holder 31 disclosed in Figure 1 or 2 by rotating the air to widen the width of the flame, by configuring as described above the multi-burner combustion Made it possible.

In addition, the primary mixed VOC supply pipe 23 through the VOC supply pipe 23 and the air supply pipe 14 to selectively supply additional VOC or additional air to the vertical pipe connected to the secondary reverse flame prevention nozzle 42. And the secondary mixed air supply pipe 12 communicate with the vertical pipe in a direction symmetrical with each other. In such a configuration, when the amount of VOC 22 generated is small, the VOC 22 can be selectively burned by supplying VOC through the primary mixed VOC supply pipe 23. Similarly, the secondary mixed air supply pipe 12 supplies air in such a case. Done.

FIG. 4 is a general schematic view of a combustion device including a swing device further included in the combustion device according to the modification of FIG. 2, and a flame holder installed around the primary backfire prevention nozzle 41 located at an upper end as shown in FIG. (31) By attaching a swinging device 33 with swinging wings at the lower side, flame stabilization and a wide flame can be obtained, so that it can be applied to a large-capacity multiple combustion device (burner) system. Other configurations are omitted as described above.

FIG. 5 is an overall schematic diagram of a combustion apparatus according to another modification of the basic combustion apparatus of the present invention shown in FIG. 1, and most of the apparatus configuration is the same as that of FIG. 3, but as shown in FIG. The flame holder 31 provided around the nozzle 41 is left without being removed. The combustion device configured as described above is designed to be capable of selective combustion in the combustion device disclosed in FIG. 4 and is suitable for a combustion device having a large VOC 22 generation range. Other configurations are omitted as described above.

Figure 6 is a schematic diagram showing the flame characteristics of each of the combustion apparatus of the present invention. The burner structure of type A having a structure in which premixing does not occur with the turning device 33 has a long flame length, and a flame lift is likely to occur when the SV (space velocity) of the total fluid supplied is large. Has

On the other hand, type B is equipped with a primary mixed air supply pipe 11 and the air and VOC mixing device 43 is reduced in flame length and excellent flame resistance.

Finally, Type C has the shortest flame length and the best flame resistance because the primary mixed air supply pipe 11, the air and VOC mixing device 43, and the turning device 33 are installed.

7 is a schematic view showing the structure of the flashback prevention nozzle and the flame holder of the present invention, the primary flashback prevention nozzle 41 and the flame holder 31 is made integrally and located on the top of the VOC supply pipe 21, the turning device 33 ) Is integrally attached to the bottom of the flame holder 31 as shown in FIG. 7, or alone attached to the top of the VOC supply pipe 21 as shown in FIG. 3. In the present invention, the flame holder 31 has a structure in which a plurality of holes are formed in each divided surface in a structure divided into four, each hole in the divided surface serves as a primary flame holder, and other than four divided surfaces. In the portion of the air to guide the flame toward the role of the diffusion mixing with the VOC (22) flowing from the primary backfire prevention nozzle (41) to smoothly occur.

8 is a schematic view showing the structure of the swing device of the present invention, the swing wing 34 constituting the swing device 33 is 45 degrees in the flow direction of the fluid and 45 degrees depending on the total flow rate of the combustion air (15) supplied Designed within degrees, the angle of the swing blade 34 as described above is limited by the flow rate of the supplied air 15, the magnitude of the swing strength is changed, VOC supplied through the VOC supply pipe 21 ( For smooth mixing with 22), the angle of swing vanes 34 should be varied to provide optimum swing strength for each supply flow rate of air 15. In other words, the optimum turning strength showed the best results at the limited section angle. In addition, in order to allow the mixing of the air 15 and the VOC 22 to be made at the shortest distance through the control of the turning strength, the turning device 33 is designed to be easily detachable and attached to the turning machine suitable for each condition. It was easy to replace.

9 is a schematic view showing the structure of the present invention air / VOC mixing device, the VOC supplied through the air 15 and the VOC supply pipe 21 supplied from the primary mixed air supply pipe 11 as shown in the secondary Mixing while passing through the prevention nozzle (42), at this time, the mixing device 43 of air and VOC was installed in order to advance the mixing. The air and VOC mixing device 43 is configured to be inclined in the direction of fluid flow and a angle (15 degrees to 30 degrees), and the angle is designed differently according to the amount of air 15 and VOC 22 supplied. The reason for limiting the angle a to 15 degrees to 30 degrees is that air and VOC are best mixed at such an angle.

In addition, the surface structure of this air and VOC mixing device 43 is composed of a structure in which no hole is punched out as shown in the figure (I) on the right and a structure in which a plurality of pores are drilled as shown in the figure (II). This made it possible.

10 is a schematic view showing the structure of the present invention when the module type single combustion device (burner) is composed of a multiple combustion device (burner) structure, the present invention is a single combustion device (burner) structure of various forms in Figures 1 to 9 It was designed as. By designing these individual combustor modules in combination with other combustor modules, they can be applied wherever various processing capacities are required.

Usually three burners form one large module and the device can be modified in such a way that the modules are combined according to their capacity.

That is, in the embodiment of FIG. 10, three separate air supply chamber portions 1 and VOC supply portions 2 penetrating the outer circumferential appearance 6 on both sides are formed to individually separate the air 15 and the VOC 22. The air supply chamber unit 1 and the VOC supply unit 2 each have a module composed of three flame holders 31 and a primary backfire prevention nozzle 41 in one air supply pipe 14. It is shown.

That is, in FIG. 10, three air supply pipes 14 constituting three modules, nine flame holders 31, and a primary backfire prevention nozzle 41 are shown. This ease can be seen.

delete

The present invention has a structure (module type) in which one burner forms one single structure as described above. Therefore, such a single burner can be used in combination with multiple burners, that is, if the burner's capacity is increased (Scale-up), only the size of the supply pipe of the air 15 supplied is greatly affected on the burner's combustion characteristics. It is designed not to fall. Therefore, the present invention can have the advantage of easy expansion of capacity according to the modular method.

11 is an embodiment of the present invention. Gas generated from liquefied LNG was used as a fuel source, and diluted about 300 times and supplied to a combustion device (burner). The total hydrocarbon (THC) value of the gas entering the combustor (burner) was measured to be approximately 29,000-31,000 ppm and the value emitted through the combustor was less than approximately 5-10 ppm. The combustion conversion rate for the entire combustion device was very high, 99.99%, and the combustion stability was excellent.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

According to the above-described combustion apparatus of the present invention, the flashback prevention nozzle having the microporous structure is installed in a double structure, which greatly reduces the possibility of backfire, and has the advantage of excellent flame stability by installing a flame holder around the nozzle. Have

In addition, the present invention has the advantage that it is possible to reduce the installation cost of the combustion system by not installing a separate VOC storage device by burning the total amount generated regardless of the VOC supply conditions.

In addition, unlike conventional diffusion flame method, it is designed as a flow path structure that can selectively premix air and VOC, so that VOC does not go through flame holder and flashback prevention nozzle alone, but is mixed in the middle of combustor in advance to improve combustion performance. This has the advantage that the flame length can be minimized.

In addition, since the mixing device of air and VOC and the turning device are installed on the side of the secondary flashback prevention nozzle between the primary flashback prevention nozzle and the secondary flashback prevention nozzle, the air and the VOC are well mixed at the shortest distance.

In addition, since the combustion device (burner) structure is designed as a single type of combustion device (burner), it can be easily changed into a complex structure to be applied to a large processing capacity of the VOC, and thus it is applicable to a wide range of processing capacity. It is a useful invention having an industrial invention that is expected to use greatly.

Claims (14)

In the flame combustion device for treating volatile organic compounds (VOC), The air supply chamber 13 in which the air 15 for processing the VOC 22 is supplied from one side in the horizontal direction is stored, and the air supplied from the air supply chamber 13 changes the flow path in the vertical direction. An air supply chamber part 1 formed of an air supply pipe 14 formed to supply the flame generating part 3; VOC supply unit (2) consisting of a VOC supply pipe (21) installed inside the air supply pipe 14 to supply flame to the flame generator (3) to supply the VOC (22) generated in the gas station tank of the liquefied petroleum gas, such as reservoirs Wow; The flame holder 31 is installed in the circumferential direction of the vertical end of the VOC supply pipe 21 to stabilize the flame when the flame is generated by diffusion and mixing of the air supplied from the air supply pipe 14 and the VOC supply pipe 21 and VOC. A flame generating unit 3 installed; The backfire prevention part 4 is comprised by the 1st backfire prevention nozzle 41 of the porous structure mounted in the vertical direction end part of the VOC supply pipe 21, A secondary flashback prevention nozzle (42) installed in the VOC supply pipe (21) to be spaced apart at a predetermined interval from the lower side of the primary flashback prevention nozzle (41); A primary mixed air supply pipe (11) having a flow path formed therethrough through the VOC supply pipe (21) to supply air supplied from the air supply chamber (1) to the lower backfire prevention nozzle (42); Air and VOC mixing device 43 is further provided on the secondary reverse flame prevention nozzle 42 so that the air 15 supplied from the primary mixed air supply pipe 11 and the VOC 22 can be mixed well. Flame-burning apparatus for treating volatile organic compounds having a large processing capacity range and no flame inversion, designed in a modular type. delete In the flame combustion device for treating volatile organic compounds (VOC), The air supply chamber 13 in which the air 15 for processing the VOC 22 is supplied from one side in the horizontal direction is stored, and the air supplied from the air supply chamber 13 changes the flow path in the vertical direction. An air supply chamber part 1 formed of an air supply pipe 14 formed to supply the flame generating part 3; VOC supply unit (2) consisting of a VOC supply pipe (21) installed inside the air supply pipe 14 to supply flame to the flame generator (3) to supply the VOC (22) generated in the gas station tank of the liquefied petroleum gas, such as reservoirs Wow; It is installed in the circumferential direction of the vertical end of the VOC supply pipe 21, the air supplied from the air supply pipe 14 and the VOC supply pipe 21 and VOC diffused and mixed, when the flame is generated, by rotating the air to widen the width of the flame A flame generator 3 including a swing device 33; Secondary backfire prevention nozzle (34) installed in the vertical end of the VOC supply pipe (21) and the secondary backlash prevention nozzle (34) spaced apart at regular intervals on the lower side of the primary backfire prevention nozzle (41) 42) and a backfire prevention portion 4 composed of air and a VOC mixing device 43 installed on the secondary backfire prevention nozzle 42 so that the air 15 and the VOC 22 can be mixed well; The secondary mixed air supply pipe 12 and the primary VOC mixed supply pipe installed through the VOC supply pipe 21 and the air supply pipe 14 so as to be selectively connected to the lower backfire prevention nozzle 42 to form a premix. (23); Flame-burning apparatus for treating volatile organic compounds having a large processing capacity range and no flame backfire, which is designed in a modular type, comprising a configuration. The method of claim 1, Flame burning apparatus for treating volatile organic compounds having a large processing capacity range and no flame inversion since the swing type device 33 is added to the lower portion of the flame holder. The method of claim 3. Flame-burning apparatus for treating volatile organic compounds having a large processing capacity range and no flame inversion by designing a modular type further comprising a flame holder 31 for stabilizing the flame on top of the turning device 33 . delete The method of claim 1, 4 or 5. The flame holder 31 has a structure in which a plurality of holes are formed in each divided surface in a structure divided into four, and each hole in the divided surface serves as a primary flame holder, and portions other than the four divided surfaces. Is designed in a modular type, characterized in that the flow of air to the flame directed to the diffusion control with the VOC (22) flowing from the primary flashback prevention nozzle 41 is designed in a modular type, the processing capacity range is large and the flame Flame burning apparatus for processing volatile organic compounds. The method according to any one of claims 1, 3, 4 and 5, The air and VOC mixing device 43 is designed in a modular type, characterized in that it is configured to be inclined from 15 degrees to 30 degrees and the flow direction of the fluid according to the amount of air 15 and VOC 22 to be supplied has a processing capacity range Large flameless flame retardant device for treating volatile organic compounds. The method of claim 8, The air and VOC mixing device 43 is designed in a modular type, characterized in that the surface structure is composed of any one surface structure selected from the structure that is not perforated structure or a plurality of perforated structure, the processing capacity range is large and flame Flame-burning apparatus for treating volatile organic compounds without backfire. The method according to any one of claims 1, 3, 4 and 5, The height of the nozzle in the primary flashback prevention nozzle 41 or the secondary flashback prevention nozzle 42 is at least 25 mm or more and 100 mm or less (variable according to the burner's capacity) depending on the mixing amount of the VOC 22 and the air 15, The material can be used at high temperature, and it is manufactured using nickel-chromium steel to prevent corrosion, and it is designed to maintain flame stability and prevent backfire by designing very small microporous structure of 200-300 cells per inch. Flame-burning device designed to treat volatile organic compounds with a large processing capacity and no flame inversion. The method according to claim 1 or 4, It is designed as a module type, characterized in that it consists of a module type in which at least one of the primary or secondary flashback prevention nozzles (41, 42) and the flame holder 31 is combined into one structure, so that the processing capacity range is large and flame backing Flame retardant for volatile organic compound treatment. The method according to any one of claims 3, 4 and 5, The turning device 33 is installed at the lower portion of the primary flashback prevention nozzle 41 and the flame holder 31, and the air 15 and the VOC 22 can be uniformly mixed at the shortest distance just before the flame is generated. It is designed as a module type, characterized in that the angle of the swinging wing 34 constituting the swinging device is designed to be modified within a wide flow rate range from 15 degrees to 45 degrees, the processing capacity range is large and flame backing Flame burning apparatus for processing volatile organic compounds. The method according to claim 3 or 5, The primary flashback prevention nozzle 41, the flame holder 31 and the swinging device 33 is designed as a module type, characterized in that composed of a module coupled to the VOC supply pipe 21, the processing capacity range is large and the flame backfire Flame burning apparatus for processing volatile organic compounds. In the flame combustion device for treating volatile organic compounds (VOC), The air supply chamber part 1 and the VOC supply part 2 according to any one of claims 1 to 5, which penetrate the outer appearance 6 circumferentially on both sides, are formed separately, so that the air 15 and Configure the VOC 22 to be supplied, The individual air supply chamber part 1 and the VOC supply part 2 each consist of a module consisting of three flame holders 31 and a primary backfire prevention nozzle 41 for each one of the air supply pipes 14. It is designed as a module type characterized in that it is configured to process up to flame processing apparatus for treating volatile organic compounds having a large processing capacity range and no flame backfire.

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