KR102483231B1 - A Regenerative thermal oxidizer that treats odor gas with improved incineration characteristics according to double heat storage and flame size - Google Patents

Abstract

The present invention relates to a regenerative combustion oxidization apparatus for treating a malodorous gas with improved incineration characteristics according to dual heat storage and a flame size. According to the present invention, a post-combustion heat storage technology and a heat storage technology in direct contact with a flame are applied. Therefore, the malodorous gas can be effectively removed in response to flame characteristics according to a combustion conditions. The regenerative combustion apparatus for treating the malodorous gas of the present invention comprises: a combustion burner (200); an odor nozzle (300); and a first falling housing (400).

Description

A regenerative thermal oxidizer that treats odor gas with improved incineration characteristics according to double heat storage and flame size}

The present invention relates to a regenerative combustion oxidizing device that treats odorous gas with improved incineration characteristics according to double heat storage and flame size. The present invention relates to a regenerative combustion oxidizer for treating odor gases with improved incineration characteristics according to dual heat storage and flame size capable of effectively removing odor gases in response to characteristics.

In order to improve the residential environment and prevent environmental pollution, in places where harmful gases and odors are generated, the emission concentration of harmful gases and odors is mandated by law so that harmful gases and odors are not discharged to the outside and do not harm the environment or the residential environment. To this end, in industrial sites that emit large amounts of harmful gases and odors, expensive harmful gas and odor removal facilities must be equipped, but harmful gas and odor removal facilities require considerable costs, making it difficult for small businesses to operate easily. There is a problem, and in particular, there is a problem of not effectively removing a large amount of harmful gases and odors generated in industrial sites.

Substances that make up volatile organic compounds are irritating even at low concentrations and cause unpleasant odors. On the other hand, when absorbed into the human body through the respiratory system, they cause disorders such as the nervous system, and some of them have carcinogenic properties. Strict emission regulations are in place. For example, in the case of urban facilities, the legally permitted emission standard is less than 40ppm, but the concentration of exhaust from workplaces such as shipbuilding and furniture manufacturing is about 2,500 to 4,000ppm, requiring very strict treatment.

Direct combustion and catalytic combustion devices have been used as high-temperature combustion and oxidation treatment devices to treat harmful gases containing volatile organic compounds generated at industrial sites as described above. A combustion oxidation device (R.T.O) is typically used.

In the conventional heat storage type combustion oxidizer, a heat storage material is installed at the bottom of the combustion chamber so that harmful gases are introduced through a plurality of heat storage chambers, and in this process, the harmful gases for processing are preheated using the heat stored in the combustion chamber so that the harmful gases for processing reach the combustion chamber. When doing so, the temperature is raised (700℃) to a temperature close to the combustion temperature, and heat is recovered (heat storage) in the process of exhausting the high-temperature (800℃) clean gas processed after combustion through the heat storage chamber again, and finally The temperature of the exhausted clean gas is maintained at 30 to 40°C higher than the temperature of the low-temperature supply air. As described above, in the conventional regenerative combustion oxidizer, the inflow of harmful gas for treatment and the exhaust of clean gas after treatment are alternately performed by distribution means.

Korean Patent Registration No. 10-2061003 discloses a first suction unit through which gas to be treated containing fine dust, harmful gases and odors is sucked, and water is sprayed on the gas to be treated sucked through the first suction unit to remove fine dust and dust. a first removal means including a first injection nozzle that aggregates and removes harmful gases and odors; A second suction unit into which the target gas moved through the first removal unit is sucked, and a second suction unit configured to agglomerate and remove fine dust, harmful gas, and odor by injecting water into the target gas sucked into the second suction unit. a second removal means including an injection nozzle; a third spray nozzle for condensing and removing fine dust, harmful gas, and odor by spraying water on the target gas moved through the second removing means; a third removal means for removing fine dust and water vapor included in the target gas moved through the third injection nozzle; and a water supply unit for supplying water to the first to third spray nozzles; however, a wet treatment device is configured to effectively remove operational problems and odorous gas. It has no structural limitations.

Korean Patent Laid-Open Publication No. 2003-0011036 includes a disk positioned between an upper and lower fixed plates of a fixed rotating plate and rotated, and having an inlet penetrating portion and a driving means for rotating and driving the disk. The horizontal rotating chain disk, upper fixing plate, upper fixing plate, and lower fixing plate of the prior art are all made of metal, and are large structures with a diameter of about 3m (in the case of large-capacity industrial use). Leakage occurs frequently due to abrasion of the friction surface between the disk and the upper and lower fixing plates. Even if leakage occurs during operation and only 1 to 2% of the toxic gas for treatment and the clean gas after treatment are mixed, a serious problem that does not meet the emission standards emerges, so maintenance and repairs are required from time to time, but this is not costly. Of course, it can cause a very big problem that directly causes a significant hindrance to the operation of production facilities.

Therefore, odor gas treatment effect through heat storage, odor gas treatment with improved incineration characteristics according to capacity-responsive double heat storage according to combustion conditions and flame size while effectively removing odor gas through complete combustion while direct contact with the flame. No technology has been disclosed for a regenerative combustion oxidizer.

Korean Registered Patent Publication No. 10-2061003 Korean Patent Publication No. 2003-0011036

The main object of the present invention to solve the above conventional problems is to apply heat storage technology that directly contacts the flame after combustion and heat storage technology to respond to the flame characteristics according to the combustion situation to effectively remove odor gases. And an object of the present invention is to provide a regenerative combustion oxidizing device for treating malodorous gas with improved incineration characteristics according to flame size.

Another object of the present invention is to provide a bad odor gas with improved incineration characteristics according to double heat storage and flame size, which can increase the treatment efficiency of volatile organic compounds while preventing leakage of volatile organic compounds while realizing the functions of a regenerative odor gas combustion device. It is to provide a regenerative combustion oxidizer for processing.

Other objects, particular advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments taken in conjunction with the accompanying drawings.

In order to solve the above technical problem, the present invention is a thermal regenerative combustion device for incinerating a gas containing a large amount of odorous components by using an inclined cylindrical body 100, at one end of the central axis of the main body. formed combustion burner 200; an odor nozzle 300 formed at one end of the main body in which the combustion burner is formed; and a first falling housing 400 filled with a plurality of first falling rings 410 formed at the other end of the main body where the combustion burner is formed; and a second polling housing 320 filled with a plurality of second pollings 310 is formed at an end of the odor nozzle.

In addition, a plurality of odor nozzles may be arranged in an annular shape around the combustion burner.

In addition, the second falling housing of the odor nozzle may include a nozzle slit 330 for moving relative to the direction of the central axis of the main body in order to contact the flame formed by the combustion burner or to be positioned in the flame. .

In addition, a plurality of wing parts 411 bent inwardly of the first polling may be formed by cutting a part of the outer surface into a rectangle in a cylindrical shape with an empty inside.

In addition, when cutting a rectangle of the first poling to form the wing, one side may not be cut.

In addition, the second polling may be a porous heat-resistant combustion catalyst.

In addition, a rear end housing 500 having a length of 2 to 6 times the length of the main body may be connected to the rear end of the main body.

In addition, in the main body, the first pulling housing and the rear end housing may be thermally insulated.

The present invention is a method of using an auxiliary means such as a burner disposed in a combustion chamber while minimizing damage that may be caused to humans by leaking outside without losing harmfulness, and easily burning odorous gases containing harmful volatile organic compounds. It has the effect of transforming it into a harmless state.

1 is a cross-sectional view of a body of an embodiment of a regenerative combustion device for treating malodorous gas according to the present invention.
2 is a cross-sectional view of a first polling as an embodiment of the regenerative combustion device for treating malodorous gas according to the present invention.
FIG. 3 shows a photograph of an actual production of a first polling as an embodiment of the regenerative combustion device for treating malodorous gas according to the present invention.
4 is a cross-sectional view of a first falling housing as an embodiment of the regenerative combustion device for treating malodorous gas according to the present invention.
5 shows a photograph of an actual manufacturing of a first falling housing as an embodiment of the regenerative combustion device for treating malodorous gas according to the present invention.
6 shows an implementation view of the regenerative combustion device for treating malodorous gas according to the present invention.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. However, the accompanying drawings are only examples for easily explaining the content and scope of the technical idea of the present invention, and thereby the technical scope of the present invention is not limited or changed. In addition, it will be obvious to those skilled in the art that various modifications and changes are possible within the scope of the technical idea of the present invention based on these examples.

In addition, terms or words used in this specification and claims should not be construed as being limited to ordinary or dictionary meanings, and the inventor appropriately defines the concept of terms in order to explain his/her invention in the best way. It should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle that it can be done. Therefore, since the embodiments described in this specification are only the most preferred embodiments of the present invention and do not represent all of the technical spirit of the present invention, there are various equivalents and modifications that can replace them at the time of this application. You need to understand that you can.

1 is a cross-sectional view of a body of an embodiment of a regenerative combustion device for treating malodorous gas according to the present invention.

A thermal storage type combustion device for incinerating a gas containing a large amount of odorous components by using a cylindrical main body 100 provided inclinedly, comprising: a combustion burner 200 formed at one end of a central axis of the main body; an odor nozzle 300 formed at one end of the main body in which the combustion burner is formed; and a first falling housing 400 filled with a plurality of first falling rings 410 formed at the other end of the main body where the combustion burner is formed; It may be a thermal regenerative combustion device for processing malodorous gas, characterized in that a second polling housing 320 filled with a plurality of second pollings 310 is formed at an end of the odor nozzle.

The first polling housing may be composed of a first polling case 420 accommodating the first polling and a first polling cover 430 for accommodating and fixing the first polling within the first polling case.

The first falling case may be insulated on the outside. Preferably, it may be a castable construction.

The first falling cover may be radially formed with perforated holes 431 of a honeycomb structure based on a central axis. It is obvious that the shape or configuration of the perforated hole is not limited as long as the first polling accommodated in the first polling case can be smoothly discharged after combustion without being discharged to the outside.

5 shows a first falling case and a first falling cover actually manufactured. (A) shows a first falling cover in which perforated holes of a honeycomb structure are formed radially with respect to the central axis,

It can be seen that a plurality of fixing pins are formed inside the first falling case for fixing the castable when constructing the castable for insulation.

(B) shows a first falling case that can be combined with the first falling cover of the upper and lower narrow form. (C) shows the shape of the first falling housing in which the first falling case and the first falling cover are coupled with a castable construction for insulation inside the first falling case.

A high temperature of 600 ° C to 1,200 ° C can be maintained by combustion heat and a heat source of the combustion burner, and the first falling housing at the rear end can be maintained at 600 ° C to 800 ° C.

If the temperature conditions are out of range, it becomes difficult to efficiently treat the odorous gas.

2 is a cross-sectional view of a first polling as an embodiment of the regenerative combustion device for treating malodorous gas according to the present invention.

FIG. 3 shows a photograph of an actual production of a first polling as an embodiment of the regenerative combustion device for treating malodorous gas according to the present invention.

A plurality of the odor nozzles may be arranged in an annular shape around the combustion burner.

The odor nozzle is formed in an annular shape around the combustion burner, and the number of odor nozzles is not limited as long as the odor gas injected through the odor nozzle can be smoothly contacted and incinerated with a flame.

The second falling housing of the odor nozzle may include a nozzle slit 330 for moving relative to the central axis of the main body in order to contact the flame formed by the combustion burner or to be positioned in the flame.

A driving motor may be configured to move the odor nozzle closer to or farther from the central combustion burner through the nozzle slit.

The second falling housing formed at the end of the odor nozzle may contain a combustion catalyst therein so that the odor gas injected into the main body can be sufficiently heated and supplied.

The combustion catalyst may be at least one of a heat-resistant ceramic, gamma-alumina (γ -Al ₂ O ₃ ), and cordierite (2MgO.2Al ₂ O ₅ .5SiO ₂ ). It is obvious that the shape of the combustion catalyst is not limited to the shape as long as it can smoothly inject odorous gas into the main body while continuously containing heat. Preferably, it may have a porous spherical shape.

The nozzle slit is configured to secure a movement path through which the odor nozzle can be moved so that the odor nozzle can contact the flame or be located in the flame according to the size of the flame formed through the combustion burner.

The first polling always has a cylindrical shape with an empty inside, and a plurality of wing parts 411 bent inwardly of the first polling can be formed by cutting a part of the outer surface into a square.

The wing portion may be formed in plurality on the outer surface of the first polling. It is possible to obtain a complete incineration effect of malodorous gas through a heat storage effect by effectively maintaining heat through the wings.

When cutting a rectangle of the first poling to form the wing, one side may not be cut.

The second polling may be a porous heat-resistant combustion catalyst.

The odor nozzle may be formed to be slightly inclined or curved in a wavy shape with respect to the discharge direction of the exhaust gas, but since the discharge load may increase, the direction of formation of the odor nozzle is preferably formed to be in the same direction as the discharge direction of the odor gas.

In addition, the inner diameter of the odor nozzle may vary depending on conditions such as the size of the internal volume of the main body, the size of the combustion burner, and the amount of combustion. ~ 100 mm, and the thickness of the combustion catalyst can be formed before and after 50 mm.

The shape of the odor nozzle may be formed in various ways, such as an oval, a triangle, a square, a rectangle, a rhombus, a trapezoid, a pentagon, a polygon, and a modified form thereof or a honeycomb structure, based on a circular shape. It may be formed narrower little by little.

The shape and structure of the odor nozzle exemplified above is only an example, and of course, it is free to have any shape, form, and structure within the range that does not significantly interfere with the discharge of odor gas, and the odor nozzle and odor nozzle The distance between the combustion catalyst and the tip of the odor nozzle should be maintained.

The odorous gas passing through the odor nozzle can be completely burned and removed by the conduction heat or radiant heat of the combustion catalyst heated to a temperature of 600℃ ~ 1,200℃.

If the temperature conditions are out of range, it becomes difficult to efficiently treat the odorous gas.

That is, the odorous gas injected into the main body is directly exposed to a temperature of 600°C to 1,200°C while stagnating for 2 to 5 seconds due to the bottleneck structure of the odor nozzle and the emission resistance of the combustion catalyst, so that dioxins and nitrogen oxides (NO, NO2 , NOx), sulfur oxides (SOx), carbon monoxide (CO), and unburnt gases such as unreacted hydrocarbons (HC), soot, odor, and dust are discharged after complete combustion, and the incineration efficiency is close to complete combustion. will show

If the temperature conditions are out of range, it becomes difficult to efficiently treat the odorous gas.

The combustion catalyst 16 has high thermal conductivity and excellent heat storage efficiency, so that the temperature is maintained at 600 ° C to 1,200 ° C by combustion heat and the combustion heat of the burner, and the temperature of the entire atmosphere of the main body is also stable and continuously at 600 ° C to 1,200 ° C. maintain.

If the temperature conditions are out of range, it becomes difficult to efficiently treat the odorous gas.

5 shows a photograph of an actual manufacturing of a first falling housing as an embodiment of the regenerative combustion device for treating malodorous gas according to the present invention.

6 shows an implementation view of the regenerative combustion device for treating malodorous gas according to the present invention.

A rear end housing 500 having a length of 2 to 6 times the length of the main body may be connected to the rear end of the main body.

By forming the rear end housing relatively longer than the main body, it is possible to secure a space in which odor components that may remain after incineration of the odor gas can be sufficiently removed.

A support 510 capable of supporting the rear end housing and the main body may be configured at one or more locations of the rear end housing.

Additionally, an inclination adjusting unit 530 capable of adjusting inclination of the main body and the rear end housing may be additionally formed.

A gas sampling probe 520 may be formed at an end of the rear housing to check the composition of the exhaust gas after treatment inside the rear housing.

In the main body, the first pulling housing and the rear end housing may be thermally insulated.

The heat insulation treatment may be a castable treatment.

Although the present invention has been described in detail through representative examples above, those skilled in the art to which the present invention pertains can make various modifications to the above-described embodiments without departing from the scope of the present invention. will understand

Therefore, the scope of the present invention should not be limited to the described embodiments and should not be defined, and should be defined by not only the claims to be described later, but also those equivalent to these claims.

100: body
200: combustion burner
300: odor nozzle
310: second polling
320: second falling housing
300: nozzle slit
400: first falling housing
410: first polling
411: wing part
420: first falling case
430: first polling cover
431: perforated hole
500: rear end housing
510: support
520: gas sampling probe
530: slope adjustment unit

Claims (8)

In the thermal regenerative combustion device for incinerating a gas containing a large amount of odorous components by using a cylindrical body 100 provided with an inclination,
a combustion burner 200 formed at one end of the central axis of the main body;
an odor nozzle 300 formed at one end of the main body in which the combustion burner is formed; and
a first falling housing 400 filled with a plurality of first falling rings 410 formed at the other end of the main body where the combustion burner is formed; Including,
A second polling housing 320 filled with a plurality of second pollings 310 is formed at the end of the odor nozzle,
A plurality of odor nozzles are arranged in an annular shape around the combustion burner,
The second falling housing of the odor nozzle includes a nozzle slit 330 for moving relative to the central axis of the main body in order to contact the flame formed by the combustion burner or to be located in the flame. A regenerative combustion device that treats odorous gas.
delete delete According to claim 1,
The first polling has a hollow cylindrical shape, and a portion of the outer surface is cut into squares to form a plurality of wing parts 411 bent inward of the first polling. .
According to claim 4,
Thermal regenerative combustion device for processing malodorous gas, characterized in that one side is not cut when the square is cut of the first polling to form the wing.
According to claim 1,
The second polling is a heat-storage combustion device for treating malodorous gas, characterized in that the porous heat-resistant combustion catalyst.
According to claim 1,
A thermal regenerative combustion device for treating odorous gases, characterized in that a rear end housing 500 having a length of 2 to 6 times the length of the main body is connected to the rear end of the main body.
According to claim 7,
The first falling housing and the rear end housing of the main body are thermally regenerative combustion devices for treating malodorous gases, characterized in that insulated.

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