KR101209187B1 - A environment pollution prevention apparatus of cremation furnace - Google Patents

Abstract

PURPOSE: A plant for preventing environmental pollution of a cremation furnace is provided to reduce installation costs and maintenance costs and to completely remove harmful components by simultaneously using a non-catalytic reduction device and a catalytic reduction device without using a nozzle unit. CONSTITUTION: A plant for preventing environmental pollution of a cremation furnace(100) comprises a cremation furnace(A), an exhaust gas combustion unit(B), and a stack(C). The cremation furnace comprises a main furnace burner(1a) and a recombustion furnace burner(2a). The main furnace burner jets flames to a main chamber(1). The recombustion furnace burner jets the flames to a recombustion chamber. The exhaust gas combustion unit comprises multiple exhaust gas supply lines(L) and a filtering dust collector(40). The exhaust gas combustion unit is connected to the cremation furnace through the exhaust gas supply lines. The filtering dust collector has a bag filter(41). Harmful components and dust generated during the operation of the cremation furnace are removed by the exhaust gas supply lines and the filtering dust collector. The stack discharges purified exhaust gas through the exhaust gas combustion unit.

Description

A pollution pollution apparatus of cremation furnace

The present invention relates to a facility for preventing environmental pollution of a toilet for removing dust and harmful components contained in exhaust gas generated in the toilet, and more particularly, a bag of the bag filter upon initial operation through a bypass line. It can prevent the deterioration of the filter to prevent backfire, and by using the non-catalyst reduction device and the catalytic reduction device without the nozzle part at the same time, it can reduce the installation cost and maintenance cost as well as complete removal of harmful components. A white smoke reduction device including a demister and a burner is installed between the filter dust collector and the flue of the exhaust gas combustion unit to remove the water vapor contained in the exhaust gas, thereby eliminating the visual discomfort caused by the white smoke generation. By transferring the hot air with heat exchange to the high temperature chamber of the flue which has a double structure, The present invention relates to an apparatus for preventing environmental pollution of a toilet that can further prevent white smoke by supplying a heat source to the process gas discharged to the outside through the process gas moving path of the same.

The cremation incinerator is a fluid, that is, a furnace for supplying ashes by completely burning the deceased body at a high temperature, and as the funeral culture through cremation is generally spreading and increasing, the use of the cremation incinerator is rapidly increasing. There is a situation. Such cremation incinerators are mainly used in the Orient, which has a balance method and a cabinet method, depending on the installation method.

On the other hand, the general configuration of the crematorium as described above consists of a rear end facility comprising a cremation work and a flue for treating dust and harmful components contained in the exhaust gas generated when the body is incinerated in the crematorium.

1 relates to a registered Patent No. 10-0981454 (2010. 09. 03) for a conventional cosmetic furnace system.

Looking at the configuration of the conventional cosmetic furnace system 300,

A first combustion chamber 111 including a first combustion chamber burner for incineration of the body and a second combustion chamber burner for incineration of unburned gas contained in exhaust gases incinerated in the first combustion chamber 111; The makeup furnace 113 comprised of the 2nd combustion chamber 112 which exists is comprised.

In addition, the rear end facility 200 for treating dust and harmful components generated during incineration of the body in the crematory 113 is configured.

The rear end equipment 200 is connected to the cremation chamber 113 is configured to heat exchanger 210 so as to exchange heat while cooling the high-temperature exhaust gas, is connected to the heat exchanger 210 is included in the exhaust gas Cyclone dust collector 220 is configured to filter the dust through a cyclone method, the bag is configured in the form of a bag (bag) inside to filter the fine dust not filtered through the cyclone dust collector 220 The dust collecting filter 230 including the filter is connected to the year 260 is configured.

Here, the activated carbon injector 240 is configured between the cyclone dust collector 220 and the dust collector 230 to remove harmful components contained in the exhaust gas.

Therefore, the exhaust gas generated when the body is incinerated in the cremation 113 is operated to be discharged to the flue 160 in the state where heat exchange, dust removal, and harmful components are removed through the rear end facility 200. .

In particular, the bag filter included in the dust collecting filter 230 is provided with a compressor 250 to one side so that it can be reused, and periodically sprays compressed air into the bag filter, such as dust filtered by the bag filter. It works to shake off.

Republic of Korea Patent No. 10-0981454 (2010.09.03)

However, in the case of the cremation system 300, when the incineration of the body is completely completed, each component of the rear end equipment 200, that is, the heat exchanger 210, cyclone dust collector 220, dust collector 230 and Moisture remains in the connecting lines connecting the components.

When the burner formed in the first cremation 113 incinerates the body, in the process of applying high temperature heat, since the rear end equipments 200 are heated, water is not generated, but incineration of all the bodies is performed. At the time of completion, when the burner of the crematory 113 is turned off, water is generated while descending to a temperature below the dew point while the temperature of each component of the rear end equipment 200 is lowered.

When the cremation system 300 is operated again the next day in a state in which water remains, the bag filter included in the dust collecting filter 230 may get wet.

That is, the bag filter is configured to remove fine dust of about 20 μm or less and is very sensitive to moisture, and thus exhaust gas containing moisture at the time of operating the cremation furnace 113 of the crematory system 300 as described above. When the gas is delivered directly to the dust collecting filter 230, the bag filter is clogged and thus loses its function again. Therefore, the dust is not removed, and the exhaust gas is not circulated smoothly.

Therefore, the backfire phenomenon in which the exhaust gas moves in the direction in which the exhaust gas moves in the direction reverse to the movement of the exhaust gas in the dust collecting filter 230 occurs, which not only lowers the dust collecting efficiency and the harmful component removing efficiency but also the rear end equipment. This results in the loss of 200.

Of course, when the dust collecting filter 230 using an electrostatic precipitator capable of collecting harmful gases including moisture and dust does not occur as described above, the cost of the equipment is very high, resulting in an increase in the initial cost. There is room.

In addition, the incinerator system 300, but the temperature of the exhaust gas generated in the first cremation chamber 113 is approximately 850 ~ 1,000 ℃, heat exchanger 210, cyclone dust collector 220 of the rear end equipment 200, In the process of sequentially moving the dust collector 230, the temperature of the exhaust gas is lowered a lot.

Therefore, when the exhaust gas including some water vapor is moved along the flue 160 and discharged to the outside, it is often discharged in the form of white smoke (white smoke).

The white smoke caused by white smoke is often perceived as not being properly made up of the body from the viewpoint of the bereaved family, so that the friction with the incinerator is not only frequent, but also visually poor. There was this.

Environmental pollution prevention facility apparatus of the crematorium of the present invention for solving the above problems is the main combustion chamber and the cremation furnace composed of a burner and a reburner to inject the flame into the reburn chamber and the main combustion chamber to inject the flame, And connected through an exhaust gas supply line, and includes a plurality of exhaust gas supply line and bag filter formed to remove dust and dust components of the exhaust gas consisting of harmful components and dust generated during operation of the toilet. An exhaust gas combustion unit and a flue for discharging the purified exhaust gas that has passed through the exhaust gas combustion unit, and is generated by the moisture remaining in the exhaust gas combustion unit during driving for initial preheating of the toilet. Supply exhaust gas before and after the bag filter to prevent backfire due to the deterioration of the bag filter formed in the bag filter. It connects to the formation of by-pass line that is within the year without passing through the fabric filter and further characterized in that configured by a heat source of the burner reenactment Thoreau formed in a make-up to remove the exhaust gas combustion section water.

In the present invention, the bypass line further includes a bypass dust collector for removing dust in a cyclone manner.

In the present invention, a temperature sensor is further formed in the exhaust gas supply line for supplying the exhaust gas to the bag filter in the exhaust gas combustion unit, and a valve is formed in the bypass line so that the temperature of the exhaust gas supply line is raised to a predetermined temperature. , The bypass line is blocked by the valve, characterized in that configured to operate the burner to the main combustion of the toilet.

In the present invention, the exhaust gas combustion unit is a cyclone dust collector for removing the dust contained in the exhaust gas moving through the exhaust gas supply line in the crematory through a cyclone method, and the exhaust of the dust collected in the cyclone dust collector The gas cooler includes a cooling conduit disposed inside the cooling chamber in which gas is supplied through the exhaust gas supply line and configured to move the cooling air supplied by the cooling blower to lower the exhaust gas temperature in the cooling chamber. It is characterized in that the configuration is connected to the bag filter connected via a line.

In the present invention, the flue is composed of a high temperature air chamber in the form of a double pipe to the outside of the process gas flow path and the process gas flow path to move the process gas to remove dust and harmful components, the cooling blower of the cooling pipe of the gas cooler The hot air supply line is connected to the other side connected to the hot air chamber of the year, and the hot air obtained through heat exchange with the exhaust gas from the gas cooler is supplied to the hot air chamber to the process gas discharged into the flue gas treatment furnace of the year. It is characterized by being configured to provide a heat source to prevent white smoke phenomenon.

In the present invention, between the gas cooler and the bag filter, a dry reaction tower having a venturi tube formed therein and a slaked lime storage tank and activated carbon storage tank for supplying hydrated lime and activated carbon to the venturi tube of the dry reaction tower are further configured. It is characterized by.

In the present invention, the exhaust gas combustion unit is configured with a catalytic reduction device and a catalytic reduction device, wherein the non-catalyst reduction device forms a nozzle unit consisting of a nozzle and a nozzle chamber in an exhaust gas supply line connecting the cremator and the exhaust gas combustion unit. And an urea storage tank connected to the nozzle of the nozzle unit, configured to inject urea water into the exhaust gas moving through the exhaust gas supply line, and the catalytic reduction device is disposed at the rear of the bag filter and the catalyst By forming a catalyst inside the reducing apparatus tank, it is configured to react with urea water injected into the exhaust gas passing through the exhaust gas supply line in the non-catalyst reduction apparatus to remove harmful components.

In the present invention, the exhaust gas combustion unit further comprises a white smoke reduction device connected to the flue, the white smoke reduction device is characterized in that it comprises a demister and burner inside the white smoke reduction chamber.

The present invention, when the first operation to remove the water by heating the exhaust gas softening unit through the burner to the reburn of the cremation, the bag filter through the bypass line formed so that the moisture does not move to the bag filter including a moisture sensitive bag filter Degradation can be prevented beforehand.

In addition, it is possible to completely remove the harmful components through a non-catalytic reduction device that serves to remove harmful components at high temperatures and a catalytic reduction device that removes harmful components at low temperatures.

In particular, by injecting a greater amount of urea water than the amount reacting with the doubling gas in the non-catalytic reduction device, the residual urea water is moved to the catalytic reduction device together with the removal of harmful components, thereby installing the nozzle portion of the catalytic reduction device. The cost reduction and the first non-catalyst reduction device removes harmful components contained in the moved exhaust gas from which the harmful components have been removed, thereby reducing the maintenance cost by lengthening the catalyst exchange cycle of the catalytic reduction apparatus.

In addition, a white smoke reduction device including a demister and a burner may be installed between the filter dust collector and the flue of the exhaust gas combustion unit to remove the water vapor contained in the exhaust gas, thereby eliminating the visual discomfort caused by the white smoke generation.

In addition, by moving the hot air heat-exchanged in the gas cooler to the high temperature chamber of the flue structure consisting of a double structure, by supplying a heat source to the process gas discharged to the outside through the flue gas treatment path can further prevent white smoke phenomenon. It is a useful invention.

1 is a process diagram showing a conventional cosmetic furnace system.
Figure 2 is a process diagram showing a device for preventing environmental pollution of the toilet in accordance with the present invention.
3 is a plan view showing a portion H of FIG.

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

As shown in FIG. 2, the present invention includes a crematorium A for incinerating the body and an exhaust gas combustion unit B for removing dust and harmful components contained in the exhaust gas generated in the crematorium A. FIG. And flue (C) for discharging the processing gas processed by the exhaust gas combustion unit (B) to the outside.

First, look at the configuration of the crematory (A).

Burner (1a) is formed in the main combustion chamber (1), which is a space in which the body can be placed, and the main combustion chamber for burning the body placed in the main combustion chamber (1), and the main combustion chamber (1). In the upper part of the reburn chamber (2) including a burner (2a) as a reburn so as to burn the exhaust gas, the material to be discharged and some dust in the state that the combustion of the body in the main combustion chamber (1) is not burned This configuration, and the configuration is generally used because a detailed description thereof will be omitted.

Second, look at the configuration of the exhaust gas combustion unit (B) and the flue (C).

Exhaust gas combustion unit (B) in the present invention includes a bag filter 41 connected through a plurality of exhaust gas supply line (L) to remove dust contained in the exhaust gas generated in the toilet (A). The filter dust collector 40 which is carried out is comprised.

The filter dust collector 40 is connected to receive the exhaust gas generated in the toilet (A) through the exhaust gas supply line (L), in particular, is configured to filter the fine dust.

That is, the bag filter 41 formed in the bag filter 41 is a device used to remove particles having a size of 20 μm or more, and is made of fiber (mostly using glass fiber) in the form of a bag.

Therefore, the exhaust gas containing the dust generated in the incinerator apparatus A passes through the bag filter 41 and is configured to collect the fine particles composed of large particles and fine particles through the bag filter 41. do.

The bag filter 41 has a structure in which the bag filter 41 is disposed in the bag filter chamber 42, and a compressor 43 for generating and spraying compressed air is configured on one side thereof, and the bag filter 41 is disposed in the bag filter 41. Dropped dust is dropped into the filter bag chamber 42 is configured to be reused.

On the other hand, in the present invention, the bypass line to the exhaust gas supply line (L) for supplying the exhaust gas to the filter dust collector 40 and the exhaust gas supply line (L) for moving the exhaust gas filtered by the filter dust collector (40) 50 is configured.

That is, the bypass line 50 is disposed so that the exhaust gas does not pass through the bag filter 40 in the exhaust gas combustion unit B.

In the bypass line 50, a bypass dust collector 51 may be further configured to remove dust included in the exhaust gas.

At this time, the bypass dust device 51 is preferably made of a configuration that can remove the dust in a cyclone method.

In addition, a temperature sensor TS is further formed in the exhaust gas supply line L for supplying the exhaust gas to the filter dust collector 40, and a valve (a valve) is provided in a section where the bypass line 50 starts and ends. 52) may be further formed.

Therefore, when the temperature of the exhaust gas supply line L for supplying the exhaust gas to the bag filter 40 is measured by the temperature sensor TS and reaches a temperature of 180 to 220 ° C., the bypass line 50 ) May be configured to transmit a signal to the valve 52 so as to shut off, and at the same time, to transmit a signal so that the burner 1a can be operated by the main combustion chamber formed in the toilet A. FIG.

Next, in the present invention, the cyclone dust collector SD and the gas cooler 20 may be formed in the exhaust gas combustion unit B.

The cyclone dust collector SD is connected by a cremator A and an exhaust gas supply line L to receive exhaust gas, and rotates the exhaust gas at high speed so that the weight of dust contained in the exhaust gas is high. This large amount of dust is a general matter that operates to separate from the exhaust gas, detailed description thereof will be omitted.

In addition, the gas cooler 20 has a cooling chamber 21 connected by a cyclone dust collector SD and an exhaust gas supply line L, and is configured to circulate inside the cooling chamber 21. The cooling conduit 23 is comprised.

Here, a cooling blower 22 is configured at one side of the cooling conduit 23 to supply cooling air into the cooling conduit 23 to lower the temperature of the exhaust gas moved to the cooling chamber 21. have.

In particular, in the present invention, the cooling air circulated from the gas cooler 20 to the cooling conduit 23 is heat-exchanged with the exhaust gas, thereby forming hot air.

Therefore, the flue (C) in the present invention is a treatment gas moving path 81 for discharging the treatment gas in the state in which dust and harmful components contained in the exhaust gas is removed to the outside as shown in Figures 2 to 3 and the treatment The high temperature air chamber 82 which exists in the concentric circle outside the gas movement path 81 is comprised, The other side connected to the cooling blower 22 of the cooling conduits 23 of the said gas cooler 20, and the high temperature air chamber ( A high temperature air supply line 24 connecting 82 may be further formed to supply a heat source to the process gas discharged to the outside through the process gas movement path 81 of the flue (C).

At this time, the upper side of the flue (C) as shown in Figure 3 is formed in the upper side of the high-temperature air chamber 82 to form a hole exhaust port 82 is configured to discharge the air to the outside.

Here, although the exhaust port 82 is illustrated in the form of a hole in FIG. 3, the exhaust port 82 is not limited thereto. That is, the upper side of the hot air chamber 82 may be formed in an open state.

On the other hand, in the present invention, the cyclone formed in the supply line (L) connecting the crematorium (A) and the exhaust gas combustion unit (B), more specifically, the crematorium (A) and the exhaust gas combustion unit (B). Urea water is supplied to the nozzle unit 11 and the nozzle unit 11 including the nozzle 11a and the nozzle chamber 11b for injecting urea water into the exhaust gas supply line L connecting the dust collector SD. The non-catalytic reduction apparatus 10 consisting of the urea water storage tank 12 may be further formed.

The non-catalytic reduction apparatus 10 is generally referred to as SNCR (Selective Non Catalytic Reduction), which injects urea water or ammonia water into the exhaust gas so that nitrogen oxides (NOx) can be discharged by making nitrogen gas and water vapor harmless to the human body. Device.

In particular, since the reactivity with the nitrogen oxides of the exhaust gas is activated at a high temperature (900 to 1,000 ° C.), the non-catalyst reduction device (10) has a cremator (A) having a temperature of approximately 900 to 1,000 ° C. It is arranged in the exhaust gas supply line (L) between the cyclone dust collector (SD).

In particular, the amount of urea injected through the nozzle 11a formed in the nozzle portion 11 of the non-catalyst reduction apparatus 10 is injected more than the amount reacting with the exhaust gas so that some of the urea water and nitrogen oxide It is preferable to configure the reaction to decompose the nitrogen oxides and to move the residual amount of urea into the state contained in the exhaust gas.

Next, in the present invention, a catalytic reduction device 60 may be further formed in the exhaust gas supply line L connecting the filter dust collector 40 formed in the exhaust gas combustion unit B and the flue C. have.

The catalytic reduction device 60 is formed to remove sulfur and nitrogen oxide contained in the exhaust gas through a catalytic reaction, unlike the catalyst-free reduction device 20 described above.

That is, the catalytic reduction device 60 is formed by forming a catalyst 62 in the catalytic reduction device tank 61, and in particular, the exhaust gas and the catalyst containing urea water injected from the non-catalytic reduction device 20 ( Through the reaction of 62), it is configured to remove the harmful components contained in the exhaust gas.

At this time, the catalyst 62 used in the catalytic reduction device 60 is composed of a solid form layer composed of TiO ₂ -V ₂ O ₅ , and reacts with ammonia or urea water to form nitrogen oxides with nitrogen gas which is harmless to the human body. It works to make it into water vapor.

In addition, in the present invention, a dry reaction tower (31) having a venturi tube (31a) is formed on an exhaust gas supply line (L) connecting the gas cooler (20) and the filter dust (40), and the dry reaction It may be further provided with a slaked lime storage tank 32a and activated carbon storage tank 32b which are connected to the venturi tube 31a of the tower 31 to supply the slaked lime solution and activated carbon to the venturi tube 31a.

The dry reaction tower 31 is configured to remove the acid component (HCL) and sulfur (SOx) by injecting the hydrated lime solution and activated carbon into the exhaust gas.

In particular, the venturi tube 31a formed in the dry reaction tower 31 is exhausted into the dry reaction tower 31 by using a speed and pressure difference generated when the fluid moves from a wide cross section to a narrow place. It is configured to evenly mix and spray the slaked lime liquid and activated carbon in the gas.

Here, the calcined lime solution is dissolved in water of about 20% liquid lime to be used in a slurry state of about 3 to 7% concentration, activated carbon is preferably about 350mesh particle size.

In addition, in the present invention, the white smoke reduction device 70 may be further formed in the exhaust gas supply line L between the catalyst reduction device 60 and the flue C of the exhaust gas combustion unit B.

The white smoke reduction device 70 includes a demister 72 and a burner 73 formed in the white smoke reduction chamber 71 so as to remove water vapor in the exhaust gas moving to the flue C. .

Here, the demister 72 is configured to overlap the mesh network of the fibrous material to remove moisture in the exhaust gas.

Looking at the effect of the environmental pollution prevention facility device 100 of the present invention made of a configuration as described above are as follows.

First, the environmental pollution prevention apparatus 100 of the cremation furnace of the present invention contains moisture in each of the components of the exhaust gas combustion unit B and the exhaust gas supply line L when the next day of use is completed. Will remain intact.

This is because water vapor generated when a chemical reaction occurs in the process of removing harmful components in the exhaust gas passing through the exhaust gas combustion unit B, or water vapor remaining while the temperature decreases from high temperature to low temperature is formed at a temperature below the dew point. When the burner is turned off after the work is completed in the cosmetic furnace A, water vapor remaining in the moving exhaust gas is changed to water.

In addition, the bag filter 41 included in the bag filter 41 of the exhaust gas combustion unit B in the present invention can remove dust of 20 μm or more as mentioned in the problem to be solved in the specification of the present invention. It's very sensitive to moisture.

Accordingly, when the environmental pollution prevention facility 100 of the crematorium of the present invention is initially driven, the valve 52 of the bypass line 50 is switched to the open state, and the burner 2a is reburned in the crematorium A. ) Will only work.

Then, the moisture remaining in the exhaust gas combustion unit B is evaporated by the heat source of the burner 2a by the reburning of the crematorium A, while the nozzle chamber 11b-the cyclone dust collector of the non-catalyst reduction apparatus 10 ( SD)-gas cooler 20-dry reaction tower 31-bypass line 50-catalytic reduction device 60-white smoke reduction device 70-flue (C) in order.

That is, the bypass line 50 acts so that the heat source generated in the burner 2a does not pass through the reburning of the crematorium A during the initial operation of the present invention, so that the bypass line 50 is left in the moisture remaining in the exhaust gas combustion unit B. This prevents the bag filter 41 from being wetted and prevents the performance deterioration from occurring, thereby preventing backfire from moving in the opposite direction in which the exhaust gas moves, thereby removing dust and harmful components of the exhaust gas and exhausting the exhaust gas. It is to act to improve the durability of the gas burner (B).

In particular, a bypass dust collector 52 is formed in the bypass line 50 so as to process a part of fine dust remaining in the exhaust gas combustion unit B together with moisture.

At this time, when the temperature sensor TS formed on the exhaust gas supply line L formed between the dry reaction tower 31 and the bag filter 40 recognizes a range of 180 to 220 ° C., the valve ( 52 is closed and the bypass line 50 is blocked and at the same time a signal is transmitted to the cremator A so that the burner 1a can be operated as the main combustion chamber for incineration of the body placed in the main combustion chamber 1. Works.

On the other hand, in the present invention, by using the non-catalyst reduction device 10 and the catalytic reduction device 60 at the same time, it is possible to further improve the removal efficiency of harmful components contained in the exhaust gas.

Of course, if both types of reducing devices are used as described above, the efficiency is naturally improved. However, in the present invention, the urea water injected into the exhaust gas in the non-catalyst reduction device 10 can be reacted with the exhaust gas. Control to spray more quantity.

Accordingly, some of the urea water injected into the exhaust gas reacts with the harmful substances contained in the exhaust gas to remove harmful components, and some of the urea water is catalytic reduction device 60 through the supply line L. And react with the catalyst 61 to remove harmful components.

Here, the catalytic reduction device 60 has a problem that the removal of harmful components is very good but expensive, but in the present invention because the catalyst reduction device 60 is configured even if the nozzle is not configured at all when the catalyst reduction device 60 is configured. Not only can the facility cost be lowered, but also the exhaust gas in which the first harmful component has been removed from the non-catalyst reduction apparatus 10 is treated with harmful components, so that the replacement cycle of the catalyst 61 becomes longer, thereby maintaining the maintenance cost. It is possible to obtain the effect to reduce the.

On the other hand, in the present invention to form a hydrated lime storage tank (32a), activated carbon storage tank (32b) for supplying the hydrated lime and activated carbon to the dry reaction tower 31 to remove harmful components such as nitrogen oxides, sulfur content contained in the exhaust gas It works.

In particular, the dry reaction tower 31 is adapted to directly inject the hydrated lime and activated carbon to the venturi tube (31a) so that the mixing and injection of the exhaust gas can be performed smoothly.

In addition, the white smoke reduction device 70 in the present invention by removing the water vapor contained in the exhaust gas to prevent the white smoke phenomenon of the processing gas discharged through the process gas flow path 81 of the flue (C), visually It works so as not to cause discomfort.

Each component of the exhaust gas combustion unit B in the present invention maintains a very high temperature state.

That is, between the furnace (A) and the cyclone dust collector (SD) is about 900 ~ 1,000 ℃, about 850 ℃ in the cyclone dust collector (SD) and the gas cooler 20, the gas cooler 20 and the dry reaction tower (31) ) Between 300 ° C, the dry reaction tower 31 and the bag filter 40 is to maintain about 250 ° C.

However, in the catalytic reduction device 60, the temperature is lowered more than 250 ° C.

That is, as described above, the catalytic reduction device 60 decreases the temperature with the generation of nitrogen gas and water vapor through the reaction of nitrogen oxide, urea water, and catalyst 61, and the water vapor is contained in the exhaust gas. Pass through year (C).

Therefore, the problem that the white smoke phenomenon of the processing gas occurs by the steam.

Accordingly, in the present invention, the demister 72 formed in the white smoke reduction device 70 by steam generated from the catalytic reduction device 60 is manufactured by stacking a plurality of fibrous materials in which fine mesh is formed so that the exhaust gas can pass therethrough. When water is absorbed, it acts to remove water.

Further, the water vapor remaining in the exhaust gas after passing through the demister 72 removes all the water vapor from the process gas discharged to the process gas movement path 81 of the flue C by finally evaporating the burner 73. By doing so, white smoke can be prevented.

Meanwhile, in the present invention, the heat source of the gas cooler 20 is supplied to the high temperature air chamber 82 of the flue C having a dual structure to provide a heat source to the process gas moving to the process gas flow path 81. The phenomenon can be prevented.

In particular, the high temperature air chamber 82 is made of a structure that can exert the heat insulating effect of the process gas flow path 81, such as a thermostat, thereby increasing the temperature of the process gas flow path 81 above the dew point to increase the white smoke phenomenon. Additional prevention.

That is, when the structure of the flue (C) is composed only of the process gas flow path 81 of a single structure, the inside of the process gas flow path 81 maintains a high temperature, but the outer wall of the process gas flow path 81 is the atmosphere Although it is configured in an exposed state, the temperature difference between the outer wall and the inner wall can be lowered to a temperature below the dew point, and water vapor can be generated. However, in the present invention, by further configuring the high temperature air chamber 82, the process gas moving path ( It acts to maintain the temperature of 81) will be able to prevent white smoke phenomenon.

Although the above-described embodiments have been described with respect to the most preferred embodiment of the present invention, the present invention is not limited to this and can be modified in various forms within the scope not departing from the technical spirit of the present invention. It is obvious to those skilled in the art.

L: Exhaust gas supply line TS: Temperature sensor
A: makeup
1: main combustion chamber 1a: burner to main combustion 2: reburn chamber 2a: burner to reburn
B: exhaust gas combustion unit
SD: Cyclone Dust Collector
10: non-catalytic reduction device
11 nozzle part 11a nozzle 11b nozzle chamber
12: element storage tank
20: gas cooler
21 cooling chamber 22 cooling blower 23 cooling conduit
24: high temperature air supply line
31: dry reaction tower 31a: venturi tube
32a: slaked lime storage tank 32b: activated carbon storage tank
40: bag filter
41 bag filter 42 filter bag chamber 43 compressor
50: bypass line
51: dust collector for bypass 52: valve
60: catalytic reduction device
61 catalyst reduction tank 62 catalyst
70: white smoke reduction device
71: white smoke reduction chamber 72: demister 73: burner
C: year
81: process gas flow path 82: hot air chamber 82: exhaust port
100: environmental pollution prevention device of toilet

Claims (8)

A revolving furnace (A) composed of a burner (1a) as a main combustion engine for injecting flame into the main combustion chamber (1) and a burner (2a) as a reburning engine for injecting flame into the reburn chamber (2),
Is connected through the toilet (A) and the exhaust gas supply line (L), a plurality of exhaust to remove dust dust and harmful components of the exhaust gas consisting of harmful components and dust generated during the operation of the toilet (A) An exhaust gas combustion unit B including a filter dust collector 40 having a gas supply line L and a bag filter 41;
Composed of the flue (C) for discharging the purified exhaust gas passing through the exhaust gas combustion unit (B),
Preventing backfire due to deterioration of the performance of the bag filter 41 formed in the filter dust collector 40 generated by the moisture remaining in the exhaust gas combustion unit B during the initial preheating of the toilet A. Bypass line 50 which can be connected to the exhaust gas supply line (L) before and after the bag filter 40 to move to the flue (C) without passing through the bag filter 40,
A temperature sensor TS is further formed on the exhaust gas supply line L for supplying the exhaust gas to the bag filter 40 of the exhaust gas combustion unit B, and a valve 52 is further provided on the bypass line 50. When the temperature of the exhaust gas supply line L is elevated to a predetermined temperature, the bypass line 50 is blocked by the valve 52 and the burner 1a is operated by the main combustion of the crematorium A. Is configured to
The exhaust gas combustion unit (B) is further configured to include a smoke reduction device 70 connected to the flue (C), the smoke reduction device 70 is the demister 72 into the smoke reduction chamber 71 And environmental pollution prevention apparatus of the toilet characterized in that comprising a burner (73). The apparatus of claim 1, wherein the bypass line (50) further includes a dust collector (51) for removing dust in a cyclone manner.
delete The cyclone dust collector of claim 1, wherein the exhaust gas combustion unit B removes dust contained in exhaust gas moving through the exhaust gas supply line L in the crematorium A through a cyclone method. (SD),
The cyclone dust collector SD is disposed inside the cooling chamber 21 in which some of the dust collected in the exhaust gas is supplied through the exhaust gas supply line L, and cooling air supplied from the cooling blower 22 is moved. Gas cooler 20 including a cooling conduit 23 configured to lower the exhaust gas temperature in the cooling chamber 21 is connected to the bag filter 40 connected through the flue C and the exhaust gas supply line L. Environmental pollution prevention device of the toilet characterized in that the configuration.
The method of claim 4, wherein the flue (C) is a high temperature air in the form of a double pipe to the outside of the process gas flow path 81 and the process gas flow path 82 to move the process gas is removed dust and harmful components removed Consisting of a chamber 82,
In the cooling conduit 23 of the gas cooler 20, a hot air supply line 24 is formed to connect the other side to which the cooling blower 22 is connected and the high temperature air chamber 82 of the flue C. 20) by supplying the hot air obtained through heat exchange with the exhaust gas to the high temperature air chamber 82 to provide a heat source to the process gas discharged to the process gas flow path 81 of the flue (C) to prevent white smoke phenomenon Environmental pollution prevention device of the toilet characterized in that the configuration.
The dry reaction tower 31 and the venturi tube 31a of the dry reaction tower 31, wherein a venturi tube 31a is formed between the gas cooler 20 and the bag filter 50. The apparatus for preventing environmental pollution of a crematorium characterized by further comprising a slaked lime storage tank (32a) and activated carbon storage tank (2b) for supplying the hydrated lime solution and activated carbon.
According to claim 1, wherein the exhaust gas combustion unit (B) is composed of a catalyst-free reduction device 10 and a catalytic reduction device 20,
The non-catalyst reduction apparatus 10 includes a nozzle part 11 including a nozzle 11a and a nozzle chamber 11b in an exhaust gas supply line L connecting the crematory A and the exhaust gas combustion part B. And urea storage tank 12 connected to the nozzle 11a of the nozzle unit 11, configured to inject urea water into the exhaust gas moving through the exhaust gas supply line L,
The catalytic reduction device 60 is disposed at the rear end of the bag filter 40 of the exhaust gas combustion unit B, and forms the catalyst 62 inside the catalytic reduction device tank 61, so that the catalytic reduction device 10 The apparatus for preventing environmental pollution of a cosmetic furnace, characterized in that configured to remove harmful components by reacting with urea water injected into the exhaust gas passing through the exhaust gas supply line (L).
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