KR20190131524A - Exhaust Gas Treatment System and Exhaust Gas Treatment Method - Google Patents

Abstract

An exhaust gas treating apparatus of the present invention includes an exhaust gas flow passage provided so that exhaust gas containing NOx flows, and a first spray nozzle, wherein the first spray nozzle sprays cooling water into the exhaust gas flow path to form a first mist. And at least one spraying hole provided so as to supply ozone gas to the local cooling zone of 150 ° C. or less of the first mist, wherein the at least one spraying hole has an ozone gas flow path for supplying ozone gas to the ozone blowing hole. Or it is arranged to surround the ozone outlet.

Description

Exhaust Gas Treatment System and Exhaust Gas Treatment Method

The present invention relates to an exhaust gas treating apparatus and an exhaust gas treating method.

Glass products such as glass bottles are manufactured by melting a raw material such as silica sand, soda ash, lime, and empty bottles and the like and melting the melted glass in a melting furnace with a burner or the like (about 1500 ° C.), and molding the melted glass. From the melting furnace which melts glass, the combustion exhaust gas containing the combustion exhaust gas from a burner and the component which generate | occur | produces from melted glass is discharged. The combustion exhaust gas discharged from the furnace contains NOx or SOx, which are air pollutants, and these pollutants need to be removed from the combustion exhaust gas before the combustion exhaust gas is released into the atmosphere. Moreover, since this combustion exhaust gas contains catalyst poisoning components, such as SOx derived from a glass raw material, an adhesion component, etc., it is difficult to use the "selective catalyst reduction reaction method" which is a conventional NOx treatment technique.

An exhaust gas treatment method is known in which NO is oxidized to NO ₂ by ozone using a local cooling zone of a mist formed by spraying cooling water on the exhaust gas, and then NO ₂ is removed by a reducing agent (for example, , Patent Document 1). In this exhaust gas treatment method, a method of supplying cooling water and ozone gas into the exhaust gas from another nozzle, a method of mixing the cooling water and ozone gas with a two-fluid nozzle and spraying the exhaust gas into the exhaust gas, etc. have been proposed.

Japanese Laid-Open Patent Publication No. 2015-16434

In the method of supplying cooling water and ozone gas from the other nozzle into the exhaust gas, the nozzle for supplying the ozone gas is heated by the exhaust gas, and the ozone gas may be thermally decomposed before the ozone gas is ejected. Moreover, in the method of mixing with cooling water and ozone gas by the two-fluid nozzle and spraying in the exhaust gas, ozone gas is decomposed into oxygen gas by compressing the ozone gas. Therefore, in these methods, it is difficult to efficiently use ozone gas for NO gas oxidation reaction.

This invention is made | formed in view of such a situation, and provides the waste gas processing apparatus which can utilize ozone gas efficiently for NO gas oxidation reaction, and can improve the denitrification efficiency of waste gas processing.

The present invention includes an exhaust gas flow path provided so that exhaust gas containing NOx flows, and a first spray nozzle, wherein the first spray nozzle is provided with at least one sprayed coolant in the exhaust gas flow path to form a first mist. And a spray hole and an ozone outlet provided to supply ozone gas to a local cooling zone of 150 ° C. or lower of the first mist, wherein at least one spray hole is provided with an ozone gas flow path or ozone outlet for supplying ozone gas to the ozone outlet. An exhaust gas treating apparatus is provided so as to be surrounded.

The exhaust gas treating apparatus of the present invention includes an exhaust gas flow path provided so that exhaust gas containing NOx flows, and a first spray nozzle, and the first spray nozzle sprays cooling water into the exhaust gas flow path to form a first mist. At least one spray hole installed to form. For this reason, the first mist can be formed in the exhaust gas, and a local cooling region in which the temperature of the exhaust gas is locally lowered by the heat of vaporization of water droplets contained in the first mist can be formed in the first mist.

The first spray nozzle has an ozone ejection port provided to supply ozone gas to a local cooling zone of 150 ° C. or less of the first mist. For this reason, ozone gas can be supplied to the local cooling area | region where the temperature of exhaust gas fell locally to 150 degrees C or less, and it can suppress that the ozone gas supplied in exhaust gas thermally decomposes. Further, in a local cooling zone of 150 ° C. or less, NO gas which is hard to be dissolved in water by ozone gas can be oxidized to NO ₂ gas which is easy to react with water or a reducing agent. For this reason, the denitrification efficiency of waste gas processing can be improved.

Since the first spray nozzle includes at least one spray hole and an ozone outlet, the first spray nozzle can be cooled by the cooling water supplied to the at least one spray hole, and the ozone gas is pyrolyzed in the first spray nozzle. It can be suppressed.

At least one spray hole is arranged so as to surround an ozone gas flow path or an ozone outlet for supplying ozone gas to the ozone outlet. For this reason, ozone gas can be supplied to the center part of the 1st mist formed by spraying cooling water from at least 1 spray hole, and it can suppress that ozone gas is supplied to the exterior of a 1st mist. For this reason, ozone gas can be suppressed from thermal decomposition, and ozone gas can be utilized efficiently for NO gas oxidation reaction. Moreover, the direction which sprays cooling water and the direction which blows out ozone gas can be made substantially the same, and ozone gas can be supplied to the wide range of a 1st mist.

Moreover, the ozone gas flow path which supplies ozone gas to an ozone jet port can be arrange | positioned inside the cooling water flow path which supplies cooling water to at least 1 spray hole, and it can suppress that an ozone gas flow path raises a temperature. For this reason, it can suppress that ozone gas thermally decomposes in a 1st spray nozzle, and ozone gas can be utilized efficiently for NO gas oxidation reaction.

1 is a schematic configuration diagram of an exhaust gas treating apparatus of one embodiment of the present invention.
FIG. 2A is a schematic cross-sectional view of the spray nozzle included in the exhaust gas treating apparatus of one embodiment of the present invention, and FIG. 2B is a schematic front view of the spray nozzle.
3 is a schematic configuration diagram of an exhaust gas treating apparatus of one embodiment of the present invention.
Fig.4 (a)-(g) is a schematic front view of the spray nozzle contained in the waste gas processing apparatus of 1 Embodiment of this invention, respectively.

An exhaust gas treating apparatus of the present invention includes an exhaust gas flow path provided so that exhaust gas containing NOx flows, and a first spray nozzle, wherein the first spray nozzle sprays cooling water in the exhaust gas flow path to form a first mist. And at least one spraying hole provided so as to supply ozone gas to the local cooling zone of 150 ° C. or less of the first mist, wherein the at least one spraying hole has an ozone gas flow path for supplying ozone gas to the ozone blowing hole. Or it is arranged to surround the ozone outlet.

At least one spray hole included in the first spray nozzle is preferably a curved or circular slit. By this structure, the spray hole can be arrange | positioned so that a spray hole may surround the ozone gas flow path or ozone outlet which supplies ozone gas to an ozone outlet, and can supply ozone gas to the center part of a 1st mist.

At least one spray hole included in the first spray nozzle preferably includes a plurality of spray holes arranged in a circular shape. By this structure, the spray hole can be arrange | positioned so that a spray hole may surround the ozone gas flow path or ozone outlet which supplies ozone gas to an ozone outlet, and can supply ozone gas to the center part of a 1st mist.

At least one spray hole of the first spray nozzle included in the exhaust gas treating apparatus of the present invention is preferably installed to spray cooling water and air in a two-fluid manner. By this, the first mist containing fine water droplets can be formed, and the gas-liquid contact area can be enlarged. Moreover, exhaust gas can be cooled efficiently by a 1st mist.

The first spray nozzle included in the exhaust gas treatment apparatus of the present invention preferably has at least one spray hole or an air discharge hole installed to surround a cooling water flow path for supplying cooling water to the at least one spray hole. By releasing air into the exhaust gas from the air releasing holes, the tip of the first spray nozzle is heated by the exhaust gas and the rise of the exhaust gas temperature near the tip of the first spray nozzle can be suppressed. The gas can be suppressed from thermal decomposition.

Preferably, the exhaust gas treating apparatus of the present invention includes a second spray nozzle, and the exhaust gas flow passage is provided so that the exhaust gas containing NOx and SOx flows, and the second spray nozzle is formed of the exhaust gas flow passage. It is preferable to provide so that a 2nd mist may be formed by spraying the aqueous solution which NaOH melt | dissolved in exhaust gas downstream of 1st mist at least. Since the exhaust gas flowing through the exhaust gas flow path includes SO ₂ and the fine water droplets containing the second mist contain NaOH, Na ₂ SO ₃ , which is a reducing agent, can be generated from SO ₂ and NaOH in the second mist. In addition, since the exhaust gas flowing through the exhaust gas flow path includes NO ₂ produced by NO being oxidized by ozone, NO ₂ can be reduced to N ₂ by Na ₂ SO ₃ in the second mist 7, NOx in the exhaust gas can be removed.

It is preferable that the 2nd spray nozzle contained in the waste gas processing apparatus of this invention is installed so that the 2nd mist may be formed by spraying the aqueous solution which melt | dissolved NaOH and a reducing agent in waste gas. As a result, it is possible to reduce the NO to NO ₂ generated is oxidized by ozone to the N ₂ by the reducing agent, it can remove NOx in the exhaust gas.

The present invention forms a first mist by spraying cooling water from at least one spray hole in exhaust gas containing NOx, and localizes ozone gas at 150 ° C. or less of the first mist from a portion surrounded by the at least one spray hole. An exhaust gas treatment method for supplying a cooling zone is also provided.

Moreover, in the waste gas processing method of this invention, it is preferable to supply air around a 1st mist from the air discharge hole provided so that the cooling water flow path which supplies a cooling water to at least 1 spray hole or at least 1 spray hole may be enclosed.

EMBODIMENT OF THE INVENTION Hereinafter, one Embodiment of this invention is described using drawing. The structure shown in drawing and the following description is an illustration, and the scope of the present invention is not limited to what is shown in drawing or the following description.

1 is a schematic configuration diagram of an exhaust gas treating apparatus of the present embodiment. Fig. 2 (a) is a schematic sectional view of the spray nozzle contained in the waste gas processing apparatus of this embodiment, and Fig. 2 (b) is a schematic front view of the said spray nozzle. 3 is a schematic block diagram of the exhaust gas treating apparatus of the present embodiment. 4A to 4G are schematic front views of the spray nozzles included in the exhaust gas treating apparatus of the present embodiment, respectively.

The exhaust gas processing apparatus 50 of this embodiment is equipped with the exhaust gas flow path 5 provided so that exhaust gas containing NOx may flow, and the spray nozzle 23a, and the spray nozzle 23a is the exhaust gas flow path 5 ) To supply ozone gas to at least one spray hole (11) provided to spray the coolant (41) in the air) to form the first mist (6) and a local cooling zone of 150 ° C or lower of the first mist (6). It is characterized in that it is provided with an ozone outlet 13, the at least one spray hole 11 is arranged to surround the ozone gas flow passage 37 or the ozone outlet 13 for supplying ozone gas to the ozone outlet 13. .

In the exhaust gas treatment method of the present embodiment, the first mist 6 is formed by spraying cooling water from at least one spray hole 11 in the exhaust gas containing NOx, and at least one spray hole 11 is formed. The ozone gas is supplied from the enclosed portion to the local cooling zone of 150 ° C. or less of the first mist 6.

Hereinafter, the waste gas processing apparatus and waste gas processing method of this embodiment are demonstrated.

The exhaust gas to be treated by the exhaust gas treatment device 50 and the exhaust gas treatment method of the present embodiment is not particularly limited as long as it is an exhaust gas containing NOx. For example, the exhaust gas of the glass melting furnace 1, Exhaust gases from boilers and waste incinerators. In addition, the exhaust gas used as the process target of the waste gas processing apparatus 50 and the waste gas processing method of this embodiment may be exhaust gas containing NOx and SOx.

The exhaust gas discharged from the exhaust gas source is processed by the exhaust gas processing apparatus 50 or the exhaust gas processing method of this embodiment while flowing through the exhaust gas flow path 5, and the exhaust gas after processing is discharged | emitted in air | atmosphere. . The exhaust gas flow path 5 is a flow path through which exhaust gas flows from the exhaust gas source to discharge into the atmosphere. The exhaust gas flow path 5 may include a reaction tower 2, a dust collector 3, and the like. Moreover, the exhaust gas flow path 5 can be made into the atmospheric pressure lower than atmospheric pressure.

The spray nozzle 23a is provided with the spray hole 11 provided so that the cooling water 41 may be sprayed in the waste gas flow path 5 through which the waste gas containing NOx flows, and the 1st mist 6 is formed. For this reason, the first mist 6 can be formed in the exhaust gas containing NOx, and the local temperature where the temperature of the exhaust gas was locally lowered by the heat of vaporization of the water droplets 31 included in the first mist 6. A cooling zone can be formed in the first mist 6.

In this embodiment, a spray nozzle is a nozzle provided with the spray hole which ejects the liquid supplied as fine droplets, and ejects it. In the present embodiment, the mist means that a plurality of minute droplets float in the exhaust gas, and a plurality of minute droplets flow with the flow of the exhaust gas. Moreover, 80% or more of the water droplets contained in mist may be 500 micrometers or less in size.

A part of the spray nozzle 23a is arrange | positioned in the opening provided in the flow path member 10 of the exhaust gas flow path 5, and the front end of the spray nozzle 23a is provided in the exhaust gas flow path 5 inside. Can be installed to be deployed. By this, the rise of the temperature of the spray nozzle 23a can be suppressed, and the thermal decomposition of ozone gas in the spray nozzle 23a can be suppressed.

A plurality of spray nozzles 23a may be provided in the flow path member 10 of the exhaust gas flow path 5. In addition, the plurality of spray nozzles 23a can be provided so that each spray nozzle 23a sprays the cooling water 41 and forms the integrated first mist 6. Moreover, the some spray nozzle 23a can be arrange | positioned so that the 1st mist 6 may be enclosed.

The spray hole 11 may be installed to spray the cooling water 41 in a two-fluid manner. The spray nozzle 23a may be installed such that, for example, the cooling water and the air are mixed inside the spray nozzle 23a so that the cooling water ejects fine water droplets from the spray hole 11. The spray nozzle 23a may be formed so that the cooling water and the air are mixed after the cooling water is ejected from the spray hole 11. The spray nozzle 23a mixes the cooling water supplied to the spray nozzle 23a with the pump 22a, for example, and the air supplied to the spray nozzle 23a from the air compressor, and the cooling water from the spray hole 11, for example. It can be installed to eject minute water droplets.

Moreover, the cooling water flow path 38 through which the cooling water sprayed from the spray hole 11 flows can be provided in the spray nozzle 23a. Moreover, the compressed air flow path 40 through which the air blown out from the spray hole 11 flows can be provided in the spray nozzle 23a.

The spray holes 11 may be round holes as shown in Figs. 4A to 4F, or may be slit-like as shown in Figs. 2B and 4G.

The spray nozzle 23a has at least one spray hole 11. In addition, the spray nozzle 23a may have a plurality of spray holes 11. By spraying cooling water from each spray hole 11, the 1st mist 6 which spreads widely in exhaust gas can be formed. In addition, it is possible to arrange the ozone jet port 13 between the plurality of spray holes 11.

The spray nozzle 23a is provided with an ozone jet port 13 provided to supply ozone gas to a local cooling zone of 150 ° C. or less of the first mist 6. For this reason, ozone gas can be supplied to the local cooling area | region where the temperature of exhaust gas fell locally to 150 degrees C or less, and it can suppress that the ozone gas supplied in exhaust gas thermally decomposes. Further, in a local cooling zone of 150 ° C. or less, NO gas which is hard to be dissolved in water by ozone gas can be oxidized to NO ₂ gas which is easy to react with water or a reducing agent. For this reason, the denitrification efficiency of waste gas processing can be improved.

The spray nozzle 23a can be provided so that the ozone containing gas produced | generated by the ozone generator 36 (ozone generator), for example may be ejected from the ozone ejection port 13, for example. Moreover, the ozone gas flow path 37 through which ozone gas blown off from the ozone blowing port 13 flows can be provided in the spray nozzle 23a.

Moreover, the spray nozzle 23a can be provided so that the cooling water 41 and the ozone containing gas may be ejected separately. The spray nozzle 23a includes a cooling water flowing through the cooling water flow path 38 for supplying cooling water to the jet hole 11 and an ozone-containing gas flowing through the ozone gas flow path 37 for supplying ozone-containing gas to the ozone jet port 13. It can be installed so that it may not mix in the spray nozzle 23a.

At least one spray hole 11 is arranged so as to surround the ozone gas flow path 37 or the ozone ejection port 13 for supplying the ozone gas to the ozone ejection port 13. For this reason, it is possible to supply ozone gas to the center of the first mist 6 formed by spraying cooling water from the at least one spray hole 11, and to supply the ozone gas to the outside of the first mist 6. It can be suppressed. For this reason, ozone gas can be suppressed from thermal decomposition, and ozone gas can be utilized efficiently for NO gas oxidation reaction. Moreover, the direction which sprays cooling water and the direction which blows out ozone gas can be made substantially the same, and ozone gas can be supplied to the wide range of the 1st mist 6. For example, like the exhaust gas treatment apparatus 50 shown in FIG. 1, the ozone jet port 13 surrounded by the spray hole 11 is formed in the first mist 6 formed by spraying cooling water from the spray hole 11. The ozone gas 14 can be supplied to the center part of the 1st mist 6 by blowing out the ozone gas 14 from ().

As for the spray nozzle 23a, for example, as shown in Figs. 4A to 4F, two to eight spray holes 11 arranged in a circle form the ozone gas flow passage 37 or the ozone jet opening 13. Can be installed to enclose. In addition, the spray nozzle 23a can be provided so that the slit-shaped spray hole 11 may surround the ozone gas flow path 37 or the ozone ejection opening 13, for example as shown in FIG.2 (b) and FIG.4 (g). have. Moreover, the slit-shaped spray hole 11 may be curved, an annular slit, or a circular slit may be sufficient as it.

The spray nozzle 23a can be provided so that the cooling water flow path 38 which supplies cooling water to the at least 1 spray hole 11 may surround the ozone gas flow path 37. By this, it is possible to suppress that the ozone gas flow path 37 rises in temperature. For this reason, it can suppress that ozone gas thermally decomposes in the spray nozzle 23a, and ozone gas can be utilized efficiently for NO gas oxidation reaction.

The spray nozzle 23a can be provided so that the ozone blowing port 13 may be disposed at the front end side of the at least one spray hole 11. By this, ozone gas can be supplied directly from the ozone jet port 13 to the 1st mist 6, and it can suppress that ozone gas is thermally decomposed.

The spray nozzle 23a may have an air discharge hole 12 installed to surround at least one spray hole 11 or a cooling water flow passage 38 for supplying cooling water to the at least one spray hole 11. By discharging air into the exhaust gas from the air discharge hole 12, the tip of the spray nozzle 23a is heated by the exhaust gas and the rise of the exhaust gas temperature near the tip of the spray nozzle 23a is suppressed. It is possible to suppress the thermal decomposition of ozone gas.

The air discharge hole 12 may be annular, such as the spray nozzle 23a shown in FIG.2 (b) and FIG.4. In addition, the air discharge hole 12 may be a plurality of holes arranged to surround the at least one spray hole 11 or the cooling water flow path 38.

The spray nozzle 23a is configured such that air in the air flows into the exhaust gas flow passage 5 from the air discharge hole 12 due to a difference between the internal air pressure of the exhaust gas flow passage 5 and the external atmospheric pressure of the exhaust gas flow passage 5. Can be installed. In addition, the spray nozzle 23a may be formed so that the air supplied from the air compressor is discharged from the air discharge hole 12.

An air passage 39 through which air discharged from the air discharge hole 12 flows can be installed in the spray nozzle 23a. Moreover, the air flow path 39 can be provided so that the ozone gas flow path 37 and the cooling water flow path 38 may be enclosed. By flowing air into the air flow path 39, the temperature of the ozone gas flow path 37 can be suppressed from rising, and thermal decomposition of the ozone gas in the spray nozzle 23a can be suppressed.

The spray nozzle 23a can be provided so that the ozone ejection opening 13 and the at least one spray hole 11 are arrange | positioned rather than the air discharge hole 12 at the front end side. By this, it is possible to suppress that the temperature of the tip end of the spray nozzle 23a is increased by the air discharged from the air discharge hole 12. In addition, dust adhering to the distal end portion of the spray nozzle 23a can be suppressed by the air discharged from the air discharge hole 12.

The exhaust gas treating apparatus 50 is provided so as to spray the aqueous solution 42 in which NaOH is dissolved in the exhaust gas downstream of the first mist 6 of the exhaust gas flow passage 5 to form the second mist 7. The spray nozzle 23b can be provided. In addition, the exhaust gas flowing through the exhaust gas flow path 5 may include SOx. In the exhaust gas using a spray nozzle (23b) comprises a SOx and NO ₂ on the downstream side than the first mist (6) to form a second mist (7) by spraying a NaOH aqueous solution of 42 .

When NaOH aqueous solution 42 is sprayed in exhaust gas, many micro droplets are formed in waste gas, and the 2nd mist 7 is formed in waste gas. The micro droplets contained in the second mist 7 gradually evaporate and disappear due to the heat of the exhaust gas. Therefore, the exhaust gas of the exhaust gas flow path 5 flows in the second mist 7 in the region until the second mist 7 is formed and disappears.

Since the exhaust gas flowing through the exhaust gas flow passage 5 contains SO ₂ and the micro droplets containing the second mist 7 contain NaOH, the chemical composition of the second mist 7 is represented by the following equation (1). The reaction can proceed. Therefore, the SO ₂ contained in the exhaust gas can be removed (the exhaust gas can be desulfurized), and Na ₂ SO ₃ , which is a reducing agent, can be generated in the microdroplets of the second mist 7.

SO ₂ +2 NaOH → Na ₂ SO ₃ + H ₂ O (1)

In addition, since the exhaust gas flowing through the exhaust gas flow path 5 contains NO ₂ produced by NO being oxidized by ozone, the gas-liquid reaction as shown in the following formula (2) can be advanced.

2NO ₂ + 4Na ₂ SO ₃ → N ₂ + 4Na ₂ SO ₄ (2)

Therefore, it is possible to reduce the NO ₂ from the second mist (7) to N ^2, it is possible to remove NOx in the exhaust gas. Since the chemical reactions of the formulas (1) and (2) are thought to proceed in the microdroplets of the second mist 7 or at the gas-liquid interface between the microdroplets and the exhaust gas, the duration of the microdroplets is determined by It can be made more than the time (we think it is necessary for about 1 second) to advance.

When the reaction of formula (2) proceeds, Na ₂ SO ₄ is produced from the reducing agent is Na ₂ SO _3, and the dust of the Na ₂ SO ₄ occurs in the exhaust gas.

The spray nozzle 23b may be formed to spray the mixed aqueous solution 42 in which NaOH and a reducing agent (for example, Na ₂ SO ₃ ) are dissolved in the exhaust gas. In this case, since NO ₂ in exhaust gas can be reduced to N ₂ by a reducing agent, exhaust gas not containing SOx or exhaust gas having a sufficiently low Sox concentration may flow through the exhaust gas flow path 5. In addition, when only Na ₂ SO ₃ generated from SOx in the exhaust gas cannot sufficiently reduce NO ₂ to N ₂ , a spray nozzle 23b is provided to spray the mixed aqueous solution 42 in which NaOH and the reducing agent are dissolved. Can be.

The spray nozzle 23b can be provided so as to form the second mist 7 by spraying the NaOH aqueous solution 42 in the exhaust gas after the first mist 6 disappears. By this, the first mist 6 and the second mist 7 can be formed separately, and the reaction of the reducing agent in the second mist 7 and the ozone gas in the first mist 6 can be suppressed. Can be.

A plurality of spray nozzles 23b may be provided on the flow path wall of the exhaust gas flow path 5. The plurality of spray nozzles 23b can be provided so that each spray nozzle 23b sprays NaOH aqueous solution to form an integrated second mist 7. Moreover, the some spray nozzle 23b can be arrange | positioned so that the 2nd mist 7 may be enclosed.

The spray nozzle 23b may be installed to spray, for example, the NaOH aqueous solution 42 delivered by the pump 22b into the exhaust gas. The spray nozzle 23b can be, for example, a two-fluid spray exposure in which NaOH aqueous solution 42 and compressed air are mixed and ejected.

Like the exhaust gas treatment device 50 shown in FIG. 3, the spray nozzle 23a is provided to form the first mist 6 inside the reaction tower 2, and the spray nozzle 23b is the reaction tower 2. ), The exhaust gas treatment device 50 sprays the cooling water 34 (sea water 34) into the exhaust gas flowing through the reaction tower 2, when the second mist 7 is formed inside the exhaust gas. It may have a spray nozzle 23c installed to form three mists 8. By installing the spray nozzle 23c, the exhaust gas can be cooled by the first to third mists, and the hot exhaust gas (for example, the temperature at the inlet of the reaction tower 2 is 450 ° C or more). ), The temperature of the exhaust gas flowing into the dust collector 3 can be 350 ° C or less or 230 ° C or less.

Spray nozzle (23c) can be installed to spray by spraying the sealing water 34 collected in the watertight seal (9). In this case, water is newly supplied to the watertight sealing tank 9 by the amount of water poured up. For this reason, the concentration of the sealing water 34 gathered in the watertight sealing tank 9 can be prevented by dissolving relatively large dust produced inside the reaction tower 2. In addition, in order to prevent the solute concentration of the sealing water 34 from increasing, drainage treatment of the sealing water 34 can be omitted.

The exhaust gas treating apparatus 50 may include a dust collector 3 downstream of the first mist 6 and the second mist 7 of the exhaust gas flow passage 5. By providing the dust collector 3, the dust of Na ₂ SO ₄ generated in the exhaust gas flow passage 5 can be removed from the exhaust gas. The dust collector 3 may be an electric dust collector or a bag filter. The heat resistance temperature of the electrostatic precipitator is about 350 ° C, and the heat resistance temperature of the bag filter is about 230 ° C.

The spray amount of the spray nozzle 23a, the spray nozzle 23b, or the spray nozzle 23c is controlled so that the temperature of the exhaust gas flowing into the dust collector 3 is 150 ° C, 180 ° C, 200 ° C, 220 ° C or 250 ° C or more. I can regulate it. By adjusting the spray amount in this way, it is possible to prevent the temperature of the exhaust gas flowing through the dust collector 3 below the acid dew point (for example, sulfuric acid dew point) to prevent the acid solution from adhering to the dust collector 3. It can be suppressed. For this reason, it can suppress that the metal member contained in the dust collector 3 is corroded by the acidic solution. In addition, it is possible to prevent dust from adhering to the inside of the dust collector 3 by using the acidic solution as a binder, and to suppress clogging of the filter included in the dust collector 3.

Moreover, the spray amount of the spray nozzle 23a, the spray nozzle 23b, or the spray nozzle 23c can be adjusted so that the temperature of the exhaust gas which flows into the dust collector 3 may be below the heat-resistant temperature of the dust collector 3.

Exhaust Gas Treatment Experiment

( EXAMPLE )

The exhaust gas discharged from the glass melting furnace was processed by the exhaust gas processing apparatus as shown in FIG. In addition, the spray nozzle as shown in FIG. 2 was used for the spray nozzle 23a. The duct diameter of the reaction tower is 3.5m.

By spraying the cooling water in the exhaust gas flowing through the reaction tower by the slit-shaped spray hole of the spray nozzle 23a, a first mist is formed, and an ozone generator is formed in the first mist from the ozone ejection port of the spray nozzle 23a. The ozone containing gas produced | generated from was supplied. In addition, air from the atmosphere was introduced into the reaction tower from the air discharge hole of the spray nozzle 23a. Further, the spray nozzle 23b was sprayed with an aqueous NaOH solution (which does not contain a reducing agent) in the exhaust gas flowing through the reaction column to form a second mist. In addition, spraying by the spray nozzle 23c is not performed. In addition, an electric dust collector was used for the dust collector.

Table 1 shows the exhaust gas amount and the spray amount. Table 2 shows the measured values of the exhaust gas temperature and the gas concentration measurement results at the reaction tower inlet and the reaction tower outlet. The measured value of the exhaust gas temperature at the height where the spray nozzle 23a of the reaction tower is provided, the measured value of the exhaust gas temperature at the height of 1.5 m higher than the spray nozzle 23a of the reaction tower, and the spray nozzle of the reaction tower. Table 3 shows measured values of the exhaust gas temperature at a height higher than 3.0 m (23a). In addition, the measured value shown in Table 3 is the measured value average value of several points in a reaction column.

Cooling water is sprayed from the spray hole of the spray nozzle 23a under conditions as shown in Table 1, ozone gas is supplied into the first mist from the ozone jet port of the spray nozzle 23a, and the NaOH aqueous solution is sprayed from the spray nozzle 23b. By spraying, 57.3% of desulfuric acid efficiency and 19% of denitrification efficiency were achieved. In addition, the oxidation efficiency (ΔNO / O ₃ ) of NO by ozone gas was 85%.

In addition, the exhaust gas temperature flowing into the electrostatic precipitator could be 244 ° C. This prevented the electrostatic precipitator from corroding.

Moreover, the exhaust gas temperature of height 1.5m higher than the spray nozzle 23a was 94 degreeC. Since the flow velocity of the exhaust gas in the reaction tower is about 0.7 m / sec, the exhaust gas flows through a local cooling zone of 150 ° C. or lower of the first mist formed by spraying cooling water by the spray nozzle 23a over 2.1 seconds or more. The local cooling zone could be formed. Based on this, it is thought that the decomposition of ozone in the local cooling zone can be suppressed and the reaction time for NO gas contained in the exhaust gas is oxidized by the ozone gas can be secured.

( Comparative example )

In Comparative Example it was oxidized to NO 2 by ozone from the second mist mist directly supplied to the ozone gas, and in the NO _2. Moreover, reaction of said Formula (1), (2) was advanced in 2nd mist, and NOx in exhaust gas was removed. Specifically, in the comparative example, the spraying nozzle 23a does not spray the cooling water and eject the ozone. Further, the spray nozzle 23b was sprayed with an aqueous NaOH solution (which does not contain a reducing agent) in the exhaust gas flowing through the reaction column to form a second mist. Moreover, the ozone supply nozzle which has an ozone blowing port which blows out ozone containing gas in a 2nd mist from the center of a reaction tower was provided. Moreover, the spray by the spray nozzle 23c is not performed. The other structure processed exhaust gas using the waste gas processing apparatus of the structure similar to an Example. Table 4 shows the exhaust gas amount, spray amount and the like in the comparative example. Moreover, the exhaust gas temperature of the height which provided the spray nozzle 23b was 75 degreeC, and the local cooling area | region could be formed in 2nd mist.

In the comparative example, the oxidation efficiency (ΔNO / O ₃ ) of NO by ozone gas was 75%. On the other hand, in the Example, the oxidation efficiency (ΔNO / O ₃ ) of NO by ozone gas was 85%. Therefore, as in the embodiment, by using the spray nozzle 23a as shown in FIG. 2, thermal decomposition of ozone gas can be suppressed and the oxidation efficiency (ΔNO / O ₃ ) of NO by ozone gas is improved. I knew it could be done.

1: glass melting furnace
2: reaction tower
3: dust collector
4: chimney
5: exhaust gas flow path
6: first miss
7: second mist
8: third mist
9: watertight seal
10: flow path member
11, 11a, 1lb, 11c, 11d, 11e, 11f, 11g, 11h: sprayer
12: air discharge hole
13: ozone outlet
14: ozone gas
22, 22a, 22b, 22c, 22d: pump
23, 23a, 23b, 23c: spray nozzle
25, 25a, 25b, 25c, 25d: exhaust gas thermometer
26, 26a, 26b, 26c: gas concentration measuring device
28: ORP system
29: pH measuring device
31: Drip
32: dust
34: water seal (cooling water)
36: ozone generator
37: ozone gas flow path
38: coolant flow path
9: air euro
40: compressed air flow path
41: coolant
42: NaOH aqueous solution (mixed aqueous solution of NaOH and Na ₂ SO ₃ )
43: high concentration aqueous NaOH solution (high concentration mixed aqueous solution of NaOH and Na ₂ SO ₃ )
50: exhaust gas treatment device

Claims (9)

An exhaust gas flow path provided so that exhaust gas containing NOx flows, and a first spray nozzle,
The first spray nozzle includes at least one spray hole provided to spray cooling water in the exhaust gas flow path to form a first mist, and an ozone outlet provided to supply ozone gas to a local cooling region of 150 ° C. or lower of the first mist. ,
At least one spray hole is disposed so as to surround the ozone gas flow path for supplying ozone gas to the ozone outlet or the ozone outlet. According to claim 1,
At least one spray hole is a curved or circular slit. According to claim 1,
At least one spray hole comprises a plurality of spray holes arranged in a circular shape. The method according to any one of claims 1 to 3,
At least one spray hole is installed to spray cooling water and air in an airflow manner. The method according to any one of claims 1 to 4,
The first spray nozzle has at least one spray hole or an air discharge hole installed to surround the cooling water flow path for supplying the cooling water to the at least one spray hole. The method according to any one of claims 1 to 5,
Further provided with a second spray nozzle,
The exhaust gas flow path is installed so that the exhaust gas containing NOx and SOx flows,
The second spray nozzle is provided so as to form a second mist by spraying at least an aqueous solution in which NaOH is dissolved in the exhaust gas downstream of the first mist of the exhaust gas flow path. The method of claim 6,
The second spray nozzle is installed so as to spray the aqueous solution of NaOH and reducing agent in the exhaust gas to form a second mist. The first mist is formed by spraying cooling water from at least one spray hole in the exhaust gas containing NOx,
An exhaust gas treatment method for supplying ozone gas to a local cooling zone of 150 ° C. or less of a first mist from a portion surrounded by at least one spray hole. The method of claim 8,
An exhaust gas treatment method for supplying air around a first mist from an air discharge hole provided to surround a cooling water flow path for supplying cooling water to at least one spray hole or at least one spray hole.

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