KR101056662B1 - Boiler for incinerator using reduction effect of nitrogen oxide - Google Patents

Abstract

PURPOSE: A steam generator using waste heat of the combustion chamber of an incinerator having a nitrogen oxide reducing effect is provided to cut off heat emitted to the outside by connecting a metal membrane between multiple water wall tubes. CONSTITUTION: A steam generator using waste heat of the combustion chamber of an incinerator having a nitrogen oxide reducing effect comprises an incinerator(A), a first combustion chamber(B), and a second combustion chamber(C). The incinerator incinerates waste. The first combustion chamber is formed in one side of the incinerator and first burns heat or flames generated from the incinerated waste. The second combustion chamber is formed on the top of the first combustion chamber and second burns the first burned waste heat.

Description

Steam generator using waste heat of incinerator combustion chamber with reduction effect of nitrogen oxides {boiler for incinerator using reduction effect of nitrogen oxide}

The present invention relates to a steam generator using waste heat of an incinerator combustion chamber having a nitrogen oxide reduction effect, and more particularly, to a nitrogen oxide in a combustion chamber generated by incineration by forming a nitrogen oxide (NOx) reduction device in a combustion chamber of an incinerator ( NOx) is removed and the outer wall of the secondary combustion chamber is composed of a water wall tube in the incinerator to absorb the heat source generated in the combustion chamber to reduce the nitrogen oxides that can maximize the production of steam. It relates to a generating device.

In the present invention, nitrogen oxides (NOx) are mostly called nitrogen monoxide (NO) and contains a small amount of nitrogen dioxide (NO ₂ ), but it is generally called NOx, but recently, N ₂ O is known as a substance that destroys the ozone layer. Included.

Sources of nitrogen oxide (NOx) are divided into thermal NOx, prompt NOx, fuel NOx.

Thermal NOx is produced by the reaction of nitrogen and oxygen in the air in a high temperature atmosphere and can be a major cause of NOx generation when there is no nitrogen in the fuel.

Prompt NOx is produced only in hydrocarbon fuels and is estimated to be generated due to the presence of excess free radicals, including hydrocarbon radicals, near the flame zone, which is negligible compared to thermal NOx and fuel NOx.

Fuel NOx is NOx produced by the reaction of oxygen with nitrogen in the fuel. It takes up a lot of NOx.

According to the current emission standard of NOx, incinerators of 2 tons / hour or less are 100ppm, and incinerators of 2 tons / hour or more are 70ppm, and the Ministry of Environment has installed measuring equipment (TMS) in the final outlet (chimney). It is sending out.

In addition, in case of exceeding the emission limit (if the 30-minute average exceeds two times in a row), administrative disposition will be received.

As such, by controlling the emission limit of nitrogen oxides (NOx) during combustion of incinerators, air pollution is prevented.

In general, the incinerator which incinerates various wastes such as sludge is designed and constructed to be within 80 ℃ to meet the standard that does not impair the atmosphere by constructing the outer wall of the combustion chamber with brick of refractory material. There is a problem that the external temperature rises due to durability degradation, there is a problem that the waste heat in the combustion chamber is not absorbed and released to the outside as it is.

Of course, in the conventional incinerator, the waste heat boiler is installed and configured at the end of the combustion chamber, but there is a technique of using the waste heat of the combustion chamber, but the heat source generated in the combustion chamber may not be properly absorbed and used efficiently.

Accordingly, the present invention has been invented to solve the above conventional problems, the object of the present invention is to form a nitrogen oxide (NOx) reduction device in the secondary combustion chamber of the incinerator to generate nitrogen oxide in the combustion chamber during incineration By removing (NOx), the temperature range is reduced to within the allowable emission limit to prevent air pollution and to reduce NOx to water vapor in the incinerator without constructing the outer wall of the secondary combustion chamber as refractory (850 ℃ ~ 1,000 ℃). By using a water wall tube in order to use the heat source generated during the construction of), it blocks the external emission of the heat source generated in the combustion chamber and absorbs the heat source generated in the combustion chamber to maximize the production of nitrogen oxide. The present invention provides a steam generator using waste heat of an incinerator combustion chamber having a reducing effect.

As a means for achieving the object of the present invention, an incinerator for incineration of various wastes, a primary combustion chamber configured to burn first the heat or flame incinerated waste in the incinerator, and the primary combustion chamber A secondary combustion chamber configured at an upper side of the secondary combustion chamber to completely burn the waste heat firstly burned in the primary combustion chamber to the secondary again, and a boiler configured at the side of the secondary combustion chamber,

In the secondary combustion chamber, an injection nozzle for injecting urea water reducing agent is installed as a nitrogen oxide (NOx) reducing device, and the injection nozzle is connected to a mixing supply pipe supplied with a mixture of urea water reducing agent and process water, and the mixed supply pipe is process water. It is connected to the process water supply pipe and reducing agent supply pipe for supplying the process water supply pipe is connected to the process water storage tank is supplied with the process water, the process water supply pipe is connected to the pressure gauge and the process water injection pump and also the process water supply pipe and the process Between the water storage tank is connected to the process water backflow pipe to flow back when the process water is exceeded, the reducing agent supply pipe is connected to the reducing agent storage tank to which the urea water reducing agent is supplied, and the pressure gauge and reducing agent injection pump is connected to the reducing agent supply pipe Urea water reducing agent between the mixed feed pipe and the reducing agent storage tank When the excess flow is connected to the reducing agent backflow pipe, the pressure gauge is connected between the injection nozzle and the mixed supply pipe,

The secondary combustion chamber is provided with a steam drum on the upper side, a water drum on both sides of the lower combustion chamber, and a plurality of water pipes as an outer wall between the steam drum and the water drum. It is connected by a water wall tube, and the two drums (water drum) is connected by a plurality of connecting pipes, and a plurality of water pipes (water wall tube) forming the outer wall is connected by a metal membrane (mambrane) The heat insulating layer is formed on the outside of the water wall tube, wherein the heat insulating layer is composed of primary and secondary heat insulating layers as a double heat insulating layer, and the primary heat insulating layer is the water wall tube. Blocks the heat released to the outside from the membrane (mambrane) to stay and the second thermal insulation layer to keep the heat released once more to block the heat released once more to allow the heat released to the outside to flow back to the inside, Thermal insulation layer Configuration nestling wool and the second insulating layer is composed of rock wool, the outer surface of said second insulating layer to the installation configuration hayeoseo external finishing plate.

The present invention as described above,

First, by constructing a NOx reduction device in the second combustion chamber of the incinerator, the NOx generated during combustion in the secondary combustion chamber can be more efficiently removed, and the incinerators having an emission limit value (for example, 2 ton / hr or less) are Incinerator 100ppm, 2ton / hr or more can be reduced to within 70ppm) to prevent air pollution.

Second, by constructing the outer wall of the secondary combustion chamber with a plurality of water wall tubes rather than as a refractory, it is possible to produce steam by suppressing the heat emitted to the outside and increasing the recovery of the generated heat source. Can be.

In addition, instead of constructing the outer wall of the secondary combustion chamber as a refractory, it is possible to reduce the construction cost of the installation by configuring a water drum, a water wall tube and a steam drum.

Third, a metal membrane (mambrane) is connected between a plurality of water wall tubes to block heat emitted to the outside, and at one side where a lot of heat sources are generated, the membrane (mambrane) has a predetermined bending angle. The thermal expansion and contraction caused by heat are smoothed to stabilize the thermal deformation such as warping.

Fourth, it is a double thermal insulation layer which is a thermal insulation layer outside a plurality of water wall tubes to block and retain the heat emitted from the water wall tube and the membrane (mambrane) by the primary thermal insulation layer. It is possible to increase the efficiency of thermal energy utilization by maximizing the recovery of waste heat in the secondary combustion chamber by blocking the heat released once more by the heat insulating layer and blocking the heat released once more to the inside.

1 is an overall configuration diagram of a "steam generator using waste heat of an incinerator combustion chamber having a nitrogen oxide reduction effect" according to the present invention.
Figure 2 is an enlarged plan view of a part of the "steam generator using waste heat of the incinerator combustion chamber having a nitrogen oxide reduction effect" according to the present invention.
Figure 3 is an excerpt of the "Q" portion of Figure 1 which is a secondary combustion chamber in the "steam generator using waste heat of the incinerator combustion chamber having a nitrogen oxide reduction effect according to the present invention.
4 is an enlarged side view of FIG. 3 according to the present invention.
5 is an enlarged cross-sectional view taken along line BB of FIG. 3 in accordance with the present invention.
6 is an enlarged cross-sectional view taken along line AA of FIG. 3 according to the present invention.
Figure 7 is an excerpt of the main portion "P" of Figure 6 in accordance with the present invention.
FIG. 8 is an enlarged excerpt view showing a combined state of a water wall tube and a mambrane in the “steam generator using waste heat of an incinerator combustion chamber having a nitrogen oxide reduction effect” according to the present invention.
FIG. 9 is a view showing a state in which a "NOx reduction device" is configured in a secondary combustion chamber in the "steam generator using waste heat of an incinerator combustion chamber having a nitrogen oxide reduction effect" according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, FIGS. 1 to 9.

The terms defined in describing the present invention have been defined in consideration of the functions of the present invention and should not be construed to limit the technical elements of the present invention.

The terminology used herein is for the purpose of describing particular embodiments (suns, aspects, and embodiments) (or embodiments) only and is not intended to be limiting of the invention.

Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art, and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. .

First, as shown in FIG. 1, an incinerator A for incineration of various wastes, and a primary combustion chamber B configured at one side of the incinerator A and primarily burning heat or flame incinerated waste in the incinerator A. ), A secondary combustion chamber (C) configured at an upper side of the primary combustion chamber (B) and completely burning secondly the waste heat firstly burned in the primary combustion chamber (B), and the secondary combustion chamber (C). It consists of a boiler (D) configured on the side of the).

In the secondary combustion chamber (C), as shown in FIGS. 3, 6 and 9, an injection nozzle 100 for injecting urea water reducing agent with a nitrogen oxide (NOx) reduction device N is installed and configured. The urea water reducing agent and the process water is connected to the mixing supply pipe 101 is supplied.

The mixed supply pipe 101 is connected to a process water supply pipe 102 for supplying process water and a reducing agent supply pipe 103 for supplying urea water reducing agent.

The process water supply pipe 102 is connected to the process water storage tank 104 to which the process water is supplied, and the process water supply pipe 102 connects the pressure gauge 105 and the process water injection pump 106 to the process water supply pipe. Between the supply pipe 102 and the process water storage tank 104 is connected to the process water backflow pipe 107 to flow back when the process water is exceeded.

The reducing agent supply pipe 103 is connected to the reducing agent storage tank 108 to which the urea water reducing agent is supplied, and connects the pressure gauge 109 and the reducing agent injection pump 110 to the reducing agent supply pipe 103 and the mixed supply pipe 101 ) And the reducing agent storage tank 108 is connected to the reducing agent backflow pipe 111 to reflux when the urea water reducing agent (mixed with the process water, but is called urea water reducing agent for convenience) is exceeded.

And the pressure gauge 112 is coupled between the injection nozzle 100 and the mixing supply pipe 101.

As described above, the configuration of the nitrogen oxide (NOx) reduction device (N) has been described.

The secondary combustion chamber (C) is provided with a steam drum (1) on the upper side and a water drum (2) (2a) on both sides as shown in Figure 3 to 8, The steam drum 1 and the water drum 2, 2a are connected by a plurality of water wall tubes 3 as outer walls.

The two water drums (2) (2a) are connected by a plurality of connecting pipes (4), the outermost of the connecting pipes 4 of the connecting pipes (4) and the steam drum (steam drum) (1) is configured by connecting a plurality of water wall (water wall tube) (3) (see Figure 4).

 Between a plurality of water wall tubes (3) forming the outer wall is formed by connecting a membrane (mambrane) 5 made of metal.

The heat insulating layer 6 is formed on the outside of the water wall tube 3, and the heat insulating layer 6 is composed of a primary heat insulating layer 7 and a secondary heat insulating layer 8 as a double heat insulating layer. The primary thermal insulation layer 7 blocks and retains heat emitted from the water wall tube 3 and the membrane 5 to the outside, and the secondary thermal insulation layer 8 once. By keeping warm, the heat released is blocked once more to allow the heat released to the outside to flow back.

The primary thermal insulation layer 7 is the material of Cerakwool [Cerakwool; Ultra high temperature fireproof insulating material (Spun Ceramic Fiber) of KC Co., Ltd.] is preferably configured, and the secondary thermal insulation layer 8 is preferably composed of a rock wool material.

And the outer surface of the secondary heat insulating layer (8) is made by installing the external finish plate (9).

In the present invention configured as described above, the heat or flame incinerated various wastes in the incinerator A is primarily burned in the primary combustion chamber B, and the waste heat that is burned again is burned secondly in the secondary combustion chamber C. Is done.

When combustion occurs in the secondary combustion chamber (C), nitrogen oxides (NOx) are generated from various wastes, which are removed by a nitrogen oxide (NOx) abatement device (N) to obtain a reduction effect, using steam generated using a heat source. Production can be increased and the detailed description is as follows.

The method for reducing NOx by the nitrogen oxide (NOx) reducing device (N) is to reduce NOx generated in the combustion gas as a reducing agent [ammonia (NH ₃ ) or urea water (Urea); Hereinafter, collectively referred to as 'urea water'] is injected into the secondary combustion chamber (C) to reduce and remove with harmless nitrogen (N ₂ ) and water vapor (H ₂ O).

The basic reaction is as follows. In other words

(NH ₂ ) ₂ CO + 2NO + 1 / 2O ₂ → 2N ₂ + 2CO ₂ + 2H ₂ O

The critical factor in the reaction between the reducing agent and NOx is the reaction temperature.

Removal efficiency of nitrogen oxides is relatively high in the temperature range of 850 ~ 1,000 ℃.

When the temperature of the secondary combustion chamber is higher than 1,100 ° C, the reducing agent is oxidized to NO, so that the NOx reduction efficiency and the reducing agent utilization rate decrease.

Therefore, it is important to maintain the temperature of the secondary combustion chamber C in the temperature range of 850-1,000 degreeC.

The reaction time is ideally mixed even if the temperature is appropriate even in a short time of 0.2 ~ 0.4 seconds can obtain a high efficiency.

In order to reduce NOx, a reducing agent such as ammonia (NH₃) or urea (Urea) is injected into the combustion chamber at the proper temperature (850 ℃ ~ 1000 ℃) in the secondary combustion chamber where NOx is present. NOx is reduced to nitrogen (N ₂ ) and water vapor (H₂O).

That is, in order to remove nitrogen oxides, urea water is used as a reducing agent to decompose nitrogen oxides in gas into N 2, N 2 O, CO 2, and the like to remove NOx.

If the proper temperature (850 ° C ~ 1000 ° C) range in the secondary combustion chamber (C) is too low or too high, the reduction reaction is not performed smoothly, the nitrogen oxide (NOx) removal efficiency is reduced.

Therefore, since the combustion chamber temperature is higher than 1,100 ℃ due to the heat storage (radiation heat) by the refractory installed in the secondary combustion chamber (C), to prevent this and to maintain the proper temperature (850 ℃ ~ 1000 ℃) secondary range Increase the NOx removal efficiency and maintain the temperature range of 850 ℃ ~ 1,000 ℃ by installing a plurality of water wall tubes and adjusting the input amount of waste without constructing the combustion chamber C as refractory. The heat source flowing into the combustion chamber (C) can be produced by steam.

In order to inject the urea water (Urea) reducing agent to reduce the nitrogen oxides (NOx) in the secondary combustion chamber (C) is used as mixing the urea water as a reducing agent with the process water as shown in Figure 9 The concentration of is connected to the reducing agent supply pipe 103 by the reducing agent injection pump 110 is mixed with the process water supplied by the process water injection pump 106 and mixed supply pipe 101 before being injected into the injection nozzle 100 It determines the NSR ratio (NORMALIZED STOICHIOMETRIC RATIO) according to the NOx removal efficiency and sprays it. (The NSR ratio is the theoretical mole number of reducing agent required to reduce the total amount of NOx generated in the system. Divided by).

At this time, when the process water supply pressure by the process water injection pump 106 is lower than the supply pressure by the reducing agent injection pump 110 for supplying the urea water reducing agent, the NSR ratio is increased to increase the denitrification efficiency of nitrogen oxide, but When the water concentration is increased and, on the contrary, when the process water supply pressure by the process water injection pump 106 is higher than the urea water reducing agent supply pressure by the reducing agent injection pump 110, the process water is reduced through the reducing agent backflow pipe 111. At 108, backflow occurs and the NSR ratio is lowered, resulting in lower removal efficiency.

Therefore, the pressure difference between the pressure of the reducing agent injection pump 110 and the process water injection pump 106 should not be out of 0.5 ~ 0.7kg / ㎠.

In order to remove NOx more efficiently, the NOx value of the measuring equipment (TMS) installed in the final discharge port (chimney) of the incinerator is electrically connected with the reducing agent injection pump 110, so that the NOx value becomes high or low. It is possible to control nitrogen oxide (NOx) efficiently by controlling input amount of reducing agent.

As described above, nitrogen oxides (NOx) generated during combustion in the secondary combustion chamber (C) are more efficiently removed, thereby reducing the emission limit value (for example, incinerators of 2 ton / hr or less 100ppm and incinerators of 2 ton / hr or more 70ppm). To prevent air pollution.

And the waste heat rising from the primary combustion chamber (B) to the secondary combustion chamber (C) is the water drum (2) (2a) and the connecting pipe (4) and the outer wall of the secondary combustion chamber (C) of both Waste water is absorbed by a plurality of water wall tubes 3 to form water in the water drums 2 and 2a, the connecting pipes 4 and the water wall tubes 3, respectively. Steam is generated by heating, and the generated steam is transferred to and stored in a steam drum 1 on the upper side, and the stored steam is used for heating or the like.

As described above, the outer wall of the secondary combustion chamber (C) is constructed with a plurality of water wall tubes (3) instead of being made of refractory to form an outer wall, thereby suppressing heat emitted to the outside. It is possible to produce steam by increasing the recovery of the heat source.

In addition, the plurality of water pipes (water wall tube) 3 as shown in Figures 7 and 8 by connecting a membrane (mambrane) made of metal to block the heat emitted to the outside and generates a lot of heat sources A membrane (5) formed on the left side wall of the secondary combustion chamber (C) is formed at the center of the secondary combustion chamber (C) to form a bend angle toward the inner side of the secondary combustion chamber (C) to facilitate thermal expansion and contraction by heat. This makes it stable from thermal deformation, such as distortion.

Water wall tube (3) by the primary thermal insulation layer (7) of cerakool (Cerakwool) as a double thermal insulation layer (6) to the outside of the plurality of water wall tube (3) Blocking the heat released to the outside from the membrane (mambrane) (5) to stay and also to keep the heat released by the second thermal insulation layer (8) made of rock wool once again to block the heat released By allowing the heat to flow back inside, it is possible to maximize the recovery of waste heat in the secondary combustion chamber to increase the efficiency of thermal energy use.

In addition, instead of constructing the outer wall of the secondary combustion chamber (C) as a refractory, a water drum (2) (2a), a water wall tube (3) and a steam drum as in the present invention are used. The construction cost of the equipment can be reduced by constructing (1) and the like.

Waste heat that is not recovered in the secondary combustion chamber (C) is transferred to the boiler (D) through the duct 10 to recover all the waste heat from the boiler (D).

A: incinerator B: primary combustion chamber
C: secondary combustion chamber D: boiler
N: nitrogen oxide (NOx) reduction device
1: steam drum 2,2a: drum
3: water pipe 4: connector
5: membrane 6: heat insulation layer
7: 1st thermal insulation layer 8: 2nd thermal insulation layer
9: exterior finish plate 10: duct
100: injection nozzle 101: mixing supply pipe
102: process water supply pipe 103: reducing agent supply pipe
104: process water storage tank 105: pressure gauge
106: process water injection pump 107: process water backflow pipe
108: reducing agent storage tank 109: pressure gauge
110: reducing agent injection pump 111: reducing agent backflow pipe

Claims (8)

An incinerator (A) for burning wastes;
A primary combustion chamber (B) configured at one side of the incinerator (A) and burning the heat or flame of the waste incinerator (A) first;
In the upper combustion chamber (B) configured in the upper portion of the secondary combustion chamber (C) for completely burning the waste heat firstly burned in the primary combustion chamber (B) again in the second,
In the secondary combustion chamber (C), the injection nozzle 100 for injecting the urea water reducing agent with a nitrogen oxide (NOx) reduction device (N) is installed and configured,
The injection nozzle 100 is connected to the mixing supply pipe 101 is supplied by mixing the urea water reducing agent and the process water,
The mixed supply pipe 101 is connected to a process water supply pipe 102 for supplying process water and a reducing agent supply pipe 103 for supplying urea water reducing agent,
The process water supply pipe 102 is connected to the process water storage tank 104 is supplied with the process water and the process water supply pipe 102 is connected to the process water injection pump 106 and the process water supply pipe 106 Between the water storage tank 104 is connected to the process water backflow pipe 107 to flow back when the process water is exceeded,
The reducing agent supply pipe 103 is connected to the reducing agent storage tank 108 to which the urea water reducing agent is supplied, and the reducing agent supply pipe 103 connects a reducing agent injection pump 110 to the mixed supply pipe 101 and the reducing agent storage tank ( 108) between the reducing agent backflow pipe 111 to flow back when the urea water reducing agent is exceeded,
The secondary combustion chamber (C) is provided with a steam drum (1) on the upper side and the water drum (2) (2a) on both sides,
Between the steam drum (1) and the water drum (2) (2a) is composed of a plurality of water wall tube (3) as an outer wall,
Steam generator using the waste heat of the incinerator combustion chamber having a nitrogen oxide reduction effect, characterized in that the connection between the two drums (water drum) (2) (2a) by a plurality of connecting pipes (4). The steam generator according to claim 1, wherein a pressure gauge (112) is connected and coupled between the injection nozzle (100) and the mixing supply pipe (101). The method of claim 1, wherein the pressure gauge 105, 109 is connected to the process water supply pipe 102 and the reducing agent supply pipe 103, respectively. Generating device. The waste heat of the incinerator combustion chamber having the effect of reducing nitrogen oxides is characterized in that the temperature in the secondary combustion chamber (C) is maintained at 850 ° C to 1000 ° C and the urea water reducing agent is injected by the injection nozzle (100). Steam generator using. According to claim 1, wherein the pressure difference between the pressure of the reducing agent injection pump 110 and the process water injection pump 106 is 0.5 ~ 0.7kg / ㎠ steam using waste heat of the incinerator combustion chamber having a reduction effect of nitrogen oxides Generating device. 2. A metal membrane (5) is connected between the water wall tube (3) and the outer side of the water wall tube (3) and the membrane (5). The heat insulating layer 6 is composed of, but the heat insulating layer 6 is composed of a primary heat insulating layer 7 and a secondary heat insulating layer 8 as a double heat insulating layer, the outer surface of the secondary heat insulating layer (8) Steam generator using the waste heat of the incinerator combustion chamber having the effect of reducing the nitrogen oxides, characterized in that the external finish plate (9) is installed and configured. The method according to claim 6, wherein a bending angle is formed in a V-shape toward the inner side of the secondary combustion chamber starting from the center of the membrane 5 formed on the left side wall of the secondary combustion chamber among the membranes 5. A steam generator using waste heat from an incinerator combustion chamber having a nitrogen oxide reduction effect. 7. The waste heat of the incinerator combustion chamber according to claim 6, wherein the primary thermal insulation layer 7 is made of Cerakwool, and the secondary thermal insulation layer 8 is formed of rock wool. Steam generator using.

Images