KR101196017B1 - Apparatus for treating air pollutants - Google Patents

Abstract

The present invention relates to an apparatus for treating air pollutants, the apparatus for treating air pollutants by introducing air containing contaminants into a transport pipe, comprising: an ultraviolet irradiation part for irradiating ultraviolet rays to treat air pollutants; And an ultraviolet reflecting unit provided on the opposite surface of the ultraviolet irradiating unit and reflecting the irradiated ultraviolet rays, and a steam generating unit provided downstream of the ultraviolet irradiating unit to process ozone generated in the ultraviolet irradiating unit. Therefore, the present invention improves the irradiation efficiency of ultraviolet rays by installing an ultraviolet reflector on the opposite side of the ultraviolet irradiation unit, and installs a water vapor generator downstream of the ultraviolet irradiation unit to treat residual ozone generated in the ultraviolet irradiation unit to prevent secondary pollution and to prevent air pollution. Provides the effect of improving the processing efficiency of the material.

Description

Apparatus for treating air pollutants

The present invention relates to an air pollutant treating apparatus, and more particularly, to an air pollutant treating apparatus for treating air pollutants by introducing an air containing contaminants into a transport pipe.

Power plants, steel mills, incinerators and other industrial boilers, and internal combustion engines in vehicles are well known today as the main source of serious air pollutants, and their emissions and components vary depending on the combustion engine and combustion conditions.

Air pollution in metropolitan areas is mainly caused by mobile pollution sources such as automobiles, and is mainly exposed to serious air pollution because of the large number of automobile movements in areas with large population.

The characteristics of mobile pollutants are air pollution caused by unspecified mobile pollutants, which are relatively low compared to high concentrations of air pollutants emitted from general outlets, and therefore, it is difficult to treat air pollutants.

As such, various techniques such as adsorption method, combustion catalyst method, low temperature plasma method, high temperature plasma method, and photocatalyst method are used as an air pollutant treatment device for treating air pollutants.

The adsorption method is mainly used in the form of a large plant, and the internal adsorbent is periodically replaced. Since it is manufactured in the form of a large plant, it requires a lot of installation cost and requires a large space for processing capacity. In addition, maintenance costs are high because the adsorbents must be replaced periodically. Initially, it is effective for removing pollutants, but after a certain time, its performance drops rapidly, making it difficult to achieve air quality standards.

The combustion catalyst method also requires a large installation space for its capacity, and it requires a lot of installation and maintenance costs due to the need for periodic replacement of the combustion catalyst, but the replacement cycle is longer than that of the adsorption method. However, in order to activate the combustion catalyst, it must be maintained above a certain temperature to supply energy up to the temperature of the catalytic activity.

The low temperature plasma method has been recognized as a good way to treat high concentrations of pollutants, but the energy efficiency is not good, it is difficult to configure a large-capacity device. In addition, since a large amount of ozone is generated, there is a risk of secondary pollution caused by ozone.

The high temperature plasma method is suitable for the treatment of high concentrations of pollutants and can be easily configured as a device capable of processing a large capacity. However, energy efficiency is low and maintenance costs are high.

The photocatalytic device is a very economical method for the treatment of pollutants due to the low installation and maintenance costs, and a method of removing pollutants using the strong oxidation power of the photocatalyst has emerged. The photocatalyst has a strong oxidative power to decompose pollutants by irradiating light of a certain wavelength.

However, due to the characteristics of the photocatalyst, it is difficult to treat high concentrations of pollutants due to the slow reaction rate, and a large space is required for the processing capacity. In addition, the photocatalytic oxidation method is inconvenient to secure a residence time of a gas for obtaining a certain efficiency, such as a property that is activated only when light above a certain energy is irradiated to the catalyst and a substance to be decomposed to the surface of the catalyst as a surface reaction. There is a problem in that the need for the treatment of additional pollutants by generating secondary pollutants.

The present invention has been made to solve the conventional problems as described above, to improve the irradiation efficiency of ultraviolet rays and to treat the residual ozone generated in the ultraviolet light to prevent secondary pollution and improve the treatment efficiency of air pollutants, Increasing the contact between air and ozone, including pollutants, increases the throughput of air pollutants, maintains the maximum amount of ozone generated by ultraviolet rays, and detects the amount of ozone generated by the ultraviolet irradiation unit to detect ozone generated by the ultraviolet irradiation unit. It is an object of the present invention to provide an air pollutant treatment apparatus capable of controlling.

The present invention for achieving the above object is an air pollutant treatment apparatus for treating the air pollutants by introducing the air containing the contaminants into the transport pipe, ultraviolet irradiation unit for irradiating ultraviolet rays to treat the air pollutants; An ultraviolet reflector installed on an opposite surface of the ultraviolet irradiator to reflect the irradiated ultraviolet rays; And a steam generating unit installed downstream of the ultraviolet irradiation unit to process ozone generated in the ultraviolet irradiation unit.

In addition, the present invention is characterized in that it further comprises a turbulence generating unit provided on at least one of upstream and downstream of the ultraviolet irradiation unit. The turbulence generation portion of the present invention is composed of a plurality of turbulence generation blocks installed on the inner wall of the transfer pipe.

The ultraviolet irradiation unit of the present invention irradiates ultraviolet rays of 180 ~ 190nm wavelength. An ozone sensing unit is provided between the ultraviolet irradiating unit and the steam generating unit of the present invention to measure the concentration of ozone and to adjust the ultraviolet irradiation amount of the ultraviolet irradiating unit.

As described above, the present invention improves the irradiation efficiency of ultraviolet rays by installing an ultraviolet reflector on the opposite surface of the ultraviolet irradiation unit, and installs a water vapor generator downstream of the ultraviolet irradiation unit to treat residual ozone generated in the ultraviolet irradiation unit, thereby causing secondary pollution. It also prevents the damage and improves the treatment efficiency of air pollutants.

In addition, by installing a turbulence generating unit consisting of a turbulence generating block upstream or downstream of the ultraviolet irradiation unit it is possible to increase the contact between the air containing the pollutant and ozone to increase the throughput of air pollutants.

By limiting the wavelength of the ultraviolet rays irradiated from the ultraviolet irradiation unit to a predetermined range it is possible to maintain the maximum amount of ozone generated by the ultraviolet rays.

An ozone detecting unit is installed downstream of the ultraviolet irradiation unit to detect the amount of residual ozone generated in the ultraviolet irradiation unit to control the amount of ozone generated in the ultraviolet irradiation unit.

1 is a block diagram showing an air pollutant treatment apparatus according to an embodiment of the present invention.

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

1 is a block diagram showing an air pollutant treatment apparatus according to an embodiment of the present invention.

As shown in FIG. 1, the air pollutant treating apparatus of this embodiment includes an ultraviolet irradiating unit 10, an ultraviolet reflecting unit 20, and a water vapor generating unit 50, and the air pollutant in a closed space such as a tunnel on a road. It is an air pollutant treatment apparatus for processing the air pollutants by introducing the air contained in the transfer pipe 100.

The ultraviolet irradiator 10 is a plurality of ultraviolet light sources 11 that irradiate ultraviolet rays to treat air pollutants contained in the atmosphere, and generates ozone (O ₃ ) for treating the atmospheric pollutants by the irradiated ultraviolet rays. .

It is preferable that such an ultraviolet irradiation part 10 irradiates the ultraviolet-ray of 180-190 nm wavelength. This is because the amount of ozone generated decreases when the wavelength of ultraviolet rays is smaller than 180 nm or larger than 190 nm.

In particular, since the amount of ozone is kept to a maximum when the wavelength of ultraviolet rays is 184.9 nm, it is most preferable to control the ultraviolet irradiation unit 10 to irradiate ultraviolet rays of 184.9 nm wavelength.

The ultraviolet reflecting unit 20 is formed on the opposite surface 21 of the ultraviolet irradiating unit 10 is made of a reflecting plate 22 reflecting the ultraviolet rays irradiated from the ultraviolet irradiating unit 10, thereby improving the irradiation efficiency of ultraviolet rays. Therefore, as the irradiation efficiency of ultraviolet rays is improved, the amount of ozone is increased, thereby improving the treatment efficiency of air pollutants.

The steam generator 50 is composed of a plurality of steam generators 52 installed inside the passage 51 provided downstream of the ultraviolet irradiation part 10, and reacts with the residual ozone which is water-soluble generated in the ultraviolet irradiation part 10 to remain. It will remove ozone.

That is, when the ozone generated by the ultraviolet irradiation unit 10 treats the air pollutant and the remaining ozone is discharged as it is, the air is polluted again. Thus, water-soluble residual ozone is generated by the steam generating unit 50. It is removed by and then discharged.

In addition, between the ultraviolet irradiator 10 and the steam generator 50, the concentration of ozone generated by the ultraviolet rays irradiated by the ultraviolet irradiator 10 is measured, and the amount of ultraviolet irradiated by the ultraviolet irradiator 10 is transmitted to the controller 60. The ozone detecting unit 70 is provided to adjust by the.

As the ozone detecting unit 70, it is preferable to use an ozone amount measuring sensor for measuring the amount of ozone contained in the atmosphere.

Therefore, by adjusting the intensity of ultraviolet light through the ozone concentration through an ozone monitoring system such as the ozone detecting unit 70 installed downstream of the ultraviolet irradiation unit 10, the ultraviolet light source is optimized by minimizing the generation of ozone, a secondary pollutant. The efficiency of

In addition, the air pollutant treating apparatus of the present embodiment preferably further includes turbulence generating units 30 and 40 provided at least one of upstream and downstream of the ultraviolet irradiation unit 10.

The turbulence generation units 30 and 40 are composed of a first turbulence generation unit 30 provided downstream of the ultraviolet irradiation unit 10 and a second turbulence generation unit 40 provided upstream of the ultraviolet irradiation unit 10.

The first and second turbulence generating units 30 and 40 are composed of a plurality of turbulence generating blocks 32 and 42 provided on the inner walls 31 and 41 of the conveying pipe 100. 42) is formed at different heights, but formed in different shapes to form a turbulent flow of air containing contaminants moving in the conveying pipe 100, thereby extending the residence time of air pollutants, the contact reaction is Will increase.

As such, when turbulence is formed in the atmosphere including the air pollutants, the contact between ozone generated by the ultraviolet light irradiated by the ultraviolet irradiation unit 10 and the air pollutants is frequently generated, and the residence time is prolonged. Processing efficiency is improved.

The turbulence generating units 30 and 40 are provided upstream or downstream of the ultraviolet irradiation unit 10, or both, thereby maximizing the contact of air atoms and molecules in the air transport pipe, thereby promoting photochemical reactions.

As described above, according to the present invention, by installing an ultraviolet reflector on the opposite surface of the ultraviolet irradiating unit to improve the irradiation efficiency of the ultraviolet ray, and installing a water vapor generating unit downstream of the ultraviolet irradiating unit to treat residual ozone generated in the ultraviolet irradiating unit, thereby causing secondary pollution. It also prevents the damage and improves the treatment efficiency of air pollutants.

In addition, by installing a turbulence generating unit consisting of a turbulence generating block upstream or downstream of the ultraviolet irradiation unit can increase the contact between the atmosphere and ozone including pollutants to increase the throughput of air pollutants, and By limiting the wavelength to a predetermined range, it is possible to maintain the maximum amount of ozone generated by ultraviolet rays, and to install an ozone detector downstream of the ultraviolet irradiation unit to detect the residual ozone generated by the ultraviolet irradiation unit to control the amount of ozone generated by the ultraviolet irradiation unit. It can be effective.

The present invention described above can be embodied in many other forms without departing from the spirit or main features thereof. Therefore, the above embodiments are merely examples in all respects and should not be interpreted limitedly.

10: ultraviolet irradiation unit 20: ultraviolet reflector
30: first turbulence generator 40: second turbulence generator
50: steam generator 60: control unit
70: ozone detection unit

Claims (5)

An air pollutant treatment device for treating air pollutants by introducing the air containing contaminants into the transfer pipe,
An ultraviolet irradiation unit for irradiating ultraviolet rays to treat air pollutants;
An ultraviolet reflector installed on an opposite surface of the ultraviolet irradiator to reflect the irradiated ultraviolet rays;
A water vapor generating unit installed downstream of the ultraviolet irradiation unit to process ozone generated in the ultraviolet irradiation unit; And
And a turbulence generation unit disposed at least one of upstream and downstream of the ultraviolet irradiation unit.
The turbulence generating unit, air pollutant processing apparatus, characterized in that formed on the inner wall of the conveying pipe with a different height, but consisting of a plurality of turbulence generating blocks installed in different shapes. delete delete The method of claim 1,
The ultraviolet irradiation unit is an air pollutant treatment device, characterized in that for irradiating ultraviolet rays of 180 ~ 190nm wavelength. The method of claim 1,
An ozone detecting unit is provided between the ultraviolet irradiation unit and the water vapor generating unit to measure the concentration of ozone and to adjust the ultraviolet irradiation amount of the ultraviolet irradiation unit.

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