KR102589114B1 - Hazardous Exhaust Gas Wet Purification device - Google Patents

Abstract

The present invention relates to a wet purification device capable of treating exhaust gas emitted together with pollutants such as fine dust and harmful gases. More specifically, the present invention relates to a harmful gas purification device (100) and a first filter tank (111). ), a second filtration tank 112, a third filtration tank 113, and a fourth filtration tank 114. The first filtration tank 111 to the fourth filtration tank 114 sequentially discharge exhaust gas. Washing water is supplied to the spray nozzle 150 and mist nozzle 151, which are respectively connected to the gas movement line 160 for purification and movement, and are installed in the first to fourth filtration tanks 111 to 114. A washing water supply line is installed to supply the purified gas, and the fourth filtration tank 114 includes a primary demister filter 141 and a secondary demister filter 142 to remove moisture from the purified gas before discharge. As a configuration, the present invention relates to a wet purification device for harmful exhaust gases that can purify exhaust gases generated from waste incinerators, exhaust gases generated from a combined heat and power plant, and exhaust gases generated from a waste sludge dryer in a wet manner. .

Description

Hazardous Exhaust Gas Wet Purification device}

The present invention relates to a wet purification device capable of treating exhaust gases emitted together with pollutants such as fine dust and harmful gases, and more specifically, exhaust gases generated from waste incinerators and exhaust gases generated from combined heat and power plants. , relates to a wet purification device for harmful exhaust gases that can purify exhaust gases generated from steel mills, waste gases generated from waste sludge drying equipment, etc. in a wet manner.

Generally, treatment devices for purifying harmful gases generated at industrial sites consist of dry and wet purification devices.

The dry purification device is a method of removing gas by filling the inside of the purification device with a neutralizing adsorbent with good gas removal performance. While it has excellent gas removal efficiency and is highly adaptable to the incoming gas concentration, it is affected by the thickness of the packing layer. The disadvantage is that the pressure loss is large and the gas removal efficiency is reduced due to drift phenomenon occurring inside the packed layer.

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In addition, in processes where high concentration gases are introduced, the lifespan is short, so the neutralizing adsorbent or filler must be replaced frequently, and it has the disadvantage of being large, which generates a large amount of waste.

In addition, the wet purification device is a technology that removes bad odors and harmful gases by absorbing the gas from the cleaning liquid sprayed by the nozzle into the liquid film formed by the filling or plate and the sprayed liquid droplets. The cleaning liquid used at this time is water or a neutralizing adsorption liquid.

Wet purification devices are classified into spray towers, packed towers, cyclone scrubbers, and venturi scrubbers, depending on the removal principle.

In its simplest form, the spray tower is a method of removing dust with sufficient contact time between the rising polluted gas and the droplets of the cleaning liquid sprayed from the top. It has low pressure loss, but has the disadvantage of low removal efficiency.

Packed towers are widely used for hazardous gas treatment due to their good efficiency, but they have the disadvantage of forming scale on the filler material, increasing pressure loss, enlarging the tower when high concentrations are removed, and generating a large amount of waste.

Looking at the prior art in this field, the scrubber device for exhaust gas purification that can simultaneously treat harmful gases and fine dust in Registered Patent Publication No. 10-0484563 (registration date: April 13, 2005) is shown in Figure 1. As described above, in the scrubber device for purifying exhaust gas using the vortex method equipped with a cylindrical multi-stage reactor,

A gas inflow fan that flows solid particles and exhaust gas in the gas and vapor state into the first reactor in the cylinder in a certain amount and in a desired direction;

In order to remove dust and harmful gases by inducing the combination of the vortex airflow formed by the gas introduced by the gas inlet fan and the cleaning liquid, the cleaning liquid stored in the lower part of the cylinder is evenly sprayed in multiple directions through a nozzle inside each reactor in the cylinder. A cleaning liquid spray pump,

A turbidity sensor installed at the same location as the cleaning solution spray pump to detect the degree of turbidity of the cleaning solution;

An LED (display unit) that compares the electrical signal measured by the turbidity sensor with an already set reference signal (turbidity reference value) and indicates that the cleaning solution needs to be replaced when the turbidity of the cleaning solution is high;

The gas and dust introduced into the first reactor at the bottom of the cylinder by the gas inlet fan and the cleaning liquid sprayed by the cleaning liquid spray pump induce as many collisions as possible by the vortex airflow formed by the gas inlet fan and remove harmful substances by gravity. A first reactor in a cylinder to remove gas and dust,

A first blade equipped with a direction key and installed to reverse the flow of the incoming gas when the incoming gas moves from the first reactor in the cylinder to the second reactor at the top and at the same time control the amount of gas inflow;

The gas that passes through the first blade and flows into the second reactor in the cylinder moves in the opposite direction to the air flow in the first reactor, removing as much of the residual harmful gas and dust in the second reactor and the cleaning liquid sprayed through the nozzle as possible. A second reactor in the cylinder that removes harmful gases and dust by inducing collision,

A second blade equipped with a direction key and installed to reverse the flow of the incoming gas when it moves from the second reactor in the cylinder to the third reactor at the top and at the same time control the amount of gas inflow;

The gas that passes through the second blade and flows into the third reactor in the cylinder moves in the opposite direction to the air flow in the second reactor, causing as many collisions as possible with the gas and dust in the second reactor and the cleaning liquid sprayed through the nozzle. a third reactor in the cylinder that removes harmful gases and dust;

The third reactor is combined with the uppermost exhaust part of the cylinder to induce a collision between the vortex airflow formed in the third reactor and the plate to which the direction key is attached, thereby removing gas and dust once again and at the same time changing the direction and flow of the airflow of the exhaust gas. a gas exhaust unit that induces

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The collision between the vortex airflow formed by the gas inlet fan and the cleaning solution and the falling gas and dust due to gravity are guided to the lower part of the cleaning solution to minimize turbidity of the cleaning solution, and a layer of materials with a greater specific gravity than the cleaning solution and materials with a lower specific gravity than the cleaning solution A funnel-shaped structure that naturally induces a cleaner cleaning solution to be present in the input part of the cleaning solution supply pump,

A scrubber device for purifying exhaust gases equipped with an organic solvent recovery line capable of recovering an organic solvent with a specific gravity lower than that of the cleaning liquid has been disclosed.

The prior art in FIG. 1 is a scrubber for removing harmful exhaust gases using a high-speed vortex airflow to remove and process gas and dust with high efficiency by supplementing the gas removal function and dust removal function of conventional dry and wet scrubbers. The prior art of Figure 1, which provides a device that employs a vortex-type wet scrubber, utilizes an increase in the number of rotating airflow due to an increase in rotational force within the cylinder, rather than absorbing gas and liquid droplets or neutralizing them by chemical reactions between gas and liquid droplets. It is a configuration in which gas or dust is collected in the liquid droplets by forced collision between the accelerated centrifugal force of the air flow and the high-speed injection of the cleaning liquid, and there is a problem in that noise is generated due to the accelerated centrifugal force of the air flow and the high-speed injection of the cleaning liquid.

In particular, there is a problem in that the cleaning liquid that is rotated and sprayed through the cleaning liquid spray nozzle forms large particles and has a small contact area with the incoming gas, resulting in low purification efficiency.

Republic of Korea Patent Publication No. 10-0484563

The present invention is intended to solve the above problems, and the exhaust gas generated from a waste incinerator, the exhaust gas generated from a combined heat and power plant, and the exhaust gas generated from a waste sludge dryer are repeatedly purified by sequentially passing through a plurality of wet filtration tanks. With the purpose of being able to be.

Another purpose is to provide a purification device with improved economic efficiency by simplifying the structure of the filtration tank that purifies exhaust gas and increasing efficiency.

In addition, if necessary, it can be installed in a box such as a container to install a purification device regardless of the installation location. At the same time, the treatment facility has a beautiful appearance and is in harmony with the surrounding environment to provide an environmentally friendly facility to remove harmful exhaust gases. It is about a wet purification device.

The present invention is a means to achieve the above object, and the harmful gas purification device is formed of a first filtration tank, a second filtration tank, a third filtration tank, and a fourth filtration tank. are each connected to a gas movement line so that the exhaust gas is sequentially purified and moved, and a washing water supply line is installed to supply washing water to the spray nozzles installed in the first to fourth filtration tanks, and the fourth filtration tank The tank is characterized by a primary demister filter and a secondary demister filter installed to remove moisture from the purified gas before discharge.

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The first to third filtration tanks constituting the harmful gas purification device include an inflow pipe installed on one side of the tank body to allow exhaust gas generated from the incinerator to flow in;

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spray nozzles and mist nozzles installed at predetermined intervals to purify harmful gases at the upper end of the inlet pipe in the tank body;

a cleaning water supply pipe connected between the spray nozzle and the mist nozzle and the motor pump to spray cleaning water to the spray nozzle and the mist nozzle;

an adsorbed water storage unit in which the cleaning water sprayed from the spray nozzle and the mist nozzle is stored after contact with harmful gases;

An adsorbed water supply device formed on one side of the adsorbed water storage unit to control the level of the adsorbed water;

It is characterized in that it includes an outlet formed at the top of the tank body to discharge the purified gas.

The harmful gas inlet pipe installed in the first to third filtration tanks is characterized in that the end located inside the tank body is bent downward and a funnel-shaped dust collection demister filter is installed inside the bent end.

The harmful gas inlet pipe of the first filtration tank is characterized in that a spray nozzle and a mist nozzle are installed inside the inlet and connected to a cleaning water supply line.

The fourth filtration tank has a spray nozzle for spraying cleaning water inside the upper part of the harmful gas inlet pipe, and a primary demister filter and a secondary demister filter are installed at the top of the spray nozzle to remove moisture from the exhaust gas. It is characterized by

A mist nozzle and a spray nozzle are installed on the upper inner part of the first to third filtration tanks, and a viewing window is installed on one side of the tank body.

As another embodiment of the present invention, the first to fourth filtration tanks constituting the harmful gas purification device are installed in a container box, are easy to move, have an attractive appearance, and are characterized by unitizing the components. Do it as

The present invention constructed as described above allows exhaust gas generated from a waste incinerator, exhaust gas generated from a combined heat and power plant, exhaust gas generated from a steel mill, exhaust gas generated from a waste sludge dryer, etc. to flow into the harmful gas inlet pipe on one side of the first filtration tank. In this way, it relates to a wet purification device for harmful exhaust gases that can repeatedly purify harmful substances in the process of sequentially passing through the first to fourth filtration tanks.

The present invention filters exhaust gas generated from a waste incinerator, exhaust gas generated from a combined heat and power plant, exhaust gas generated from a steel mill, exhaust gas generated from a waste sludge dryer, etc. into a multi-stage filter tank equipped with a spray nozzle and a mist nozzle. By installing it to repeatedly wet purify harmful gases, it has the effect of reducing facility costs and treatment costs while improving purification efficiency.

In addition, as another embodiment of the present invention, the exhaust gas purification facility can be easily expanded by installing a multi-stage filtration tank in a container box, and the installation facility has a beautiful appearance and is in harmony with the surrounding environment, making it environmentally friendly. It has the effect of providing a harmful gas purification device.

Figure 1 is an overall configuration diagram showing a conventional scrubber device for purifying exhaust gas.
Figure 2 is an overall configuration diagram showing the harmful exhaust gas purification device of the present invention.
Figure 3 is a cross-sectional view showing the internal configuration of the first to third filter tanks that constitute the harmful exhaust gas purification device of the present invention.
Figure 4 is a cross-sectional view showing a funnel-shaped dust collection demister filter installed at the end of the inlet pipe inside the first to third filtration tanks of the present invention.
Figure 5 is a cross-sectional view showing the absorption water supply device installed on one side of the absorption water storage tank of the present invention.
Figure 6 is a plan cross-sectional view of the interior of the first to third filtration tanks in the harmful gas purification device of the present invention.

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

Figure 2 is an overall configuration diagram showing the harmful gas purification device of the present invention, which consists of a first filtration tank 111, a second filtration tank 112, a third filtration tank 113, and a fourth filtration tank 114. Constructs a gas purification device (100).

The first filtration tank 111 to the fourth filtration tank 114 has an inlet pipe 116 installed on one side of the tank body 115, and the inlet pipe 116 is used for exhaust gas generated from a waste incinerator or a combined heat and power plant. It is connected to the exhaust gas pipe of either the exhaust gas generated from the exhaust gas or the exhaust gas generated from the waste sludge drying device.

For example, when installing the hazardous gas purification device 100 of the present invention in a waste incinerator, it is connected to the exhaust gas flue of the waste incinerator's incinerator and the inlet pipe 116 of the first filtration tank 111.

After the exhaust gas generated from the incinerator of the incinerator flows into the inlet pipe 116 of the first filtration device 111, a dust collection demister filter 140 is installed inside the end of the inlet pipe 116 of the first filtration device 111. The exhaust gas flowing in is subjected to primary purification treatment.

After the harmful exhaust gas introduced as described above filters the primary fine dust in the dust collection demister filter 140, the exhaust gas moves upward by the air current generated by the operation of the blower fan 161, and then reaches the mist nozzle. Harmful substances mixed in the exhaust gas are adsorbed and purified by the washing water sprayed from the spray nozzle (151) and the spray nozzle (150), and then secondary filtration is performed through the gas transfer line (160) in the form of a flue connected to the upper outlet (117). It flows into the inlet pipe 116 of the tank 112, and its exhaust gas passes through the second filtration tank 112 and the third filtration tank 113 using the same purification method as the first filtration tank 111. Again, the exhaust gas is adsorbed by the washing water sprayed from the spray nozzle of the fourth filtration tank 114, and then released after moisture is removed from the first demister filter 141 and the second demister filter 142. .

The first to fourth filtration tanks 111 to 114 are installed so that a gas transfer line 160 is connected between the filtration tanks so that the exhaust gas passes sequentially and is purified.

In addition, a spray nozzle 150 and a mist nozzle 151 are installed at the inner entrance of the inlet pipe 116 of the first filtration tank 111 to spray and mist the washing water, thereby allowing the water to flow in through the inlet pipe 116. After primary purification and cooling of the exhaust gas, it is sent to the funnel-shaped dust collection demister filter 140 installed inside the end of the inlet pipe 116.

The washing water sprayed from the spray nozzle 150 and mist nozzle 151 installed at the entrance of the inlet pipe 116 is stored in the first filter tank 111 by the heat, pressure, and air current of the exhaust gas discharged after incineration in the incinerator. moves to the side.

Figure 3 is a diagram illustrating the internal configuration of the first to third filtration tanks constituting the harmful gas purification device of the present invention. The first filtration tanks 111 to 3 filtration tanks 113 are located on one side of the tank body 115. An inflow pipe 116 is installed to allow exhaust gas generated from the incinerator to flow into the incinerator.

Spray nozzles 150 and mist nozzles 151 are installed at the upper part of the inlet pipe 116 in the tank body 115 at predetermined intervals to purify harmful gases.

The spray nozzle 150 and the mist nozzle 151 spray or mist the cleaning water supplied from the cleaning water supply line 170 installed on one side.

The spray nozzle 150 and the mist nozzle 151 installed in parallel in the first filtration tank 111 to the third filtration tank 113 are installed vertically, and the spray nozzle 150 sprays fine water droplets and exhausts the air. It is brought into contact with the gas, and the mist nozzle 151 sprays the cleaning water into a mist to prolong the contact time with the exhaust gas and allows it to come into contact with the exhaust gas for purification.

The washing water supplied to the spray nozzle 150 and the misting nozzle 151 can be ordinary tap water or a cleaning liquid. Additionally, washing water made of a cleaning liquid can be sprayed into the spray nozzle 150, and the misting nozzle 151 ), mist spraying can be done using water as the washing water.

In the present invention, the exhaust gas flowing in through the inlet pipe 116 is purified by contacting the washing water sprayed from the spray nozzle 150 and the mist nozzle 151 of the first filter tank 111, and then re-cleaned. After being purified by contact with the washing water sprayed from the spray nozzle 150 and mist nozzle 151 of the second filtration tank 112, the exhaust gas is purified repeatedly with the washing water in the same manner in the third filtration tank 113. The purification efficiency can be increased.

In addition, a motor pump 171 is installed in the cleaning water supply pipe 170 so that cleaning water is supplied to the spray nozzle 150 and the misting nozzle 151, so that the cleaning water is sprayed from the spray nozzle 150 and the misting nozzle 151. .

In addition, while being sprayed from the spray nozzle 150 and the mist nozzle 151 at the inner bottom of the first filtration tank 111 to the fourth filtration tank 114 of the present invention, harmful substances are adsorbed to the washing water during contact with the exhaust gas. An adsorbed water storage unit 120 is provided in which the adsorbed water is stored.

Additionally, an adsorbed water supply device 130 is installed on one side of the tank body 115 of the adsorbed water storage unit 120 to control the level of the adsorbed water.

The adsorption water supply device 130 is designed to manage the level of adsorption water stored in the adsorption water storage unit 120. It supplies water when the water level in the adsorption water storage unit 120 decreases, and when the level of adsorption water increases above a certain standard. Make sure it is discharged automatically.

In addition, an outlet 117 is formed at the top of the tank body 115 of each of the first to fourth filtration tanks 111 to 114 of the present invention to discharge exhaust gas.

Figure 4 is a cross-sectional view showing a funnel-shaped dust collection demister filter installed at the end of the inlet pipe inside the first to third filtration tanks of the present invention, and exhaust gas flowing in from the inlet pipe 116 of each filtration tank. As it passes through the dust collector filter 140, fine dust and harmful substances are adsorbed and only air is allowed to pass through.

The dust collector filter 140 is shaped like a funnel and has a wide upper part and a narrow lower part. A metal filter 143 is installed on the inner peripheral surface of the body of the dust collector filter 140, and the metal filter 143 is a corresponding dust collector. The body of the Mr. Filter 140 is formed with a space 144 so that as the exhaust gas passes through the metal filter 143, fine dust and gas are collected and only air passes through.

In addition, the dust collection demister filter 140 is formed in a funnel shape to collect fine dust on the metal filter 143 by the spray nozzle 150 installed at the entrance of the inlet pipe 116 and the washing water sprayed from the mist nozzle 151. The dust is washed and separated into the lower absorption water storage unit 120 to fall.

The dust collection demister filter 140 of the present invention can collect fine dust and comprehensive harmful substances in exhaust gas with a long lifespan, and is easy to clean, so it can be used semi-permanently.

In addition, the filter medium of the demister filter is made of iron materials such as stainless steel and aluminum, so it is free from corrosion at high and low temperatures and can be used freely.

Figure 5 is a cross-sectional view showing the adsorbed water supply device installed on one side of the adsorbed water storage tank of the present invention, which includes the first filtration tank 111, the second filtration tank 112, the third filtration tank 113, and the fourth filtration tank of the present invention. At the inner bottom of 114, an adsorbed water storage unit 120 is provided to store adsorbed water that falls after harmful substances such as fine dust are adsorbed to the washed water during the process of contact between the sprayed and misted washing water and the exhaust gas.

An adsorbed water supply device 130 is installed on one side of the adsorbed water storage unit 120 to control the adsorbed water level.

The adsorbed water supply device 130 is equipped with a float 131, a supply pipe 132, and a drain pipe 133, and a “ㄷ”-shaped screen 134 is installed on the front of the adsorbed water to move the exhaust gas. It is installed to prevent the float 131 from moving up and down while being fluttered by the air current generated from.

The screen 134 is installed in a “ㄷ” shape in plan and the top and bottom are open.

The adsorbed water supply device 130 is designed to manage the adsorbed water level. When the water level in the adsorbed water storage unit 120 decreases, tap water, etc. can be supplied from the supply pipe 132 where the float 131 is installed, and the adsorbed water level When it rises above a certain standard, it is automatically discharged through the drain pipe (133).

The float 131 is installed in the front of the supply pipe 132 to open and close the supply pipe 132 according to the level of the adsorbed water, so that water can be automatically supplied when the water level decreases.

In addition, a drain pipe 190 is installed on one side of the bottom of the tank body of each of the first filtration tanks 111 to 4th filtration tanks 114 of the present invention to drain the absorbed water stored in the absorbed water storage unit 120 of each filtration tank. Alternatively, it is designed to drain the cleaning material when cleaning the inside of the tank.

Figure 6 is a plan cross-sectional view of the interior of the first to third filtration tanks in the harmful gas purification device of the present invention, including the first filtration tank 111, the second filtration tank 112, and the third filtration tank of the present invention. (113) is shown cut in plane, and a spray nozzle 150 is installed at the top to spray cleaning water, and a misting nozzle 151 is installed at the bottom to spray the cleaning water like a mist. It was made to be so.

The arrangement of the spray nozzle 150 and the mist nozzle 151 shown in Figure 6 of the present invention is shown as a circle, but this is an example and the arrangement form of the spray nozzle 150 and the mist nozzle 151 is "-" It can be installed selectively according to the installation environment, such as square, circular, square, or polygon.

In addition, Figure 6 is a flat cross-sectional view of the filter tank of the present invention showing the position of each component installed in the tank body 115 as an example, and the arrangement of the components can be installed in various forms as needed.

In addition, as another embodiment of the present invention, a harmful gas purification device configured as shown in Figure 1 can be installed in a container box so that it can move freely and be installed to harmonize with the surrounding environment.

In addition, the first filtration tank 111, the second filtration tank 112, the third filtration tank 113, and the fourth filtration tank 114, which constitute the present invention, are designed to allow observation of the spraying and misting devices installed therein. A viewing window 180 was installed on one side of the tank body.

In addition, the present invention installs a concentration sensor in the adsorbed water storage unit 120 provided in each of the first filtration tank 111, the second filtration tank 112, the third filtration tank 113, and the fourth filtration tank 114. A digital indicator is installed on one side of the tank body to be connected to the concentration sensor so that the concentration of the absorbed water stored in the absorbed water storage can be observed.

Unitizing the present invention in a container box has the advantage of allowing it to be freely installed in mountainous areas, islands, ships, buildings, industrial sites, etc. Additionally, if the amount of exhaust gas treatment and purification is to be increased, multiple container boxes installed with the present invention can be stacked. Alternatively, if you connect them in a row, you have the advantage of being able to expand them easily.

This invention allows for the simple and easy purification of exhaust gas generated from a waste incinerator, exhaust gas generated from a combined heat and power plant, and exhaust gas generated from a waste sludge dryer in a wet manner, while also providing an environmentally friendly wet process for harmful exhaust gases. It was designed to provide a purification device.

100: Harmful gas purification device 111: First filtration tank
112: Second filtration tank 113: Third filtration tank
114: Fourth filtration tank 115: Tank body
116: inlet pipe 117: outlet
120: Absorption water storage unit 130: Absorption water supply device
131: sub-portion 132: supply pipe
133: Drain pipe 134: Screen
140: Dust collection demister filter 141: First demister filter
142: Second demister filter 143: Metal filter
144: Space 150: Spray nozzle
151: Fog nozzle 160: Gas transfer line
161: Blowing fan 170: Washing water supply pipe
180: View window 190: Drain pipe

Claims (6)

The harmful gas purification device 100 is formed of a first filtration tank 111, a second filtration tank 112, a third filtration tank 113, and a fourth filtration tank 114, and the first filtration tank 111 ) to fourth filtration tanks 114 are each connected to a gas movement line 160 so that exhaust gas is sequentially purified and moved, and are also installed in the first filtration tanks 111 to 4th filtration tanks 114. A washing water supply line is installed to supply washing water to the spray nozzle 150 and the mist nozzle 151, and the fourth filtration tank 114 is a primary demister installed to remove moisture from the purified gas before discharge. Includes a filter 141 and a secondary demister filter 142,
The first filtration tank 111 to the third filtration tank 113 constituting the harmful gas purification device 100 has an inflow pipe 116 installed on one side of the tank body 115 to allow exhaust gas generated from the incinerator to flow in. class; Spray nozzles 150 and mist nozzles 151 installed at predetermined intervals to purify harmful gases at the upper end of the inlet pipe 116 in the tank body 115;
a cleaning water supply pipe 170 with a motor pump 171 installed on one side to spray cleaning water into the spray nozzle 150 and the mist nozzle 151; An adsorbed water storage unit 120 in which the cleaning water sprayed from the spray nozzle 150 and the mist nozzle 151 is stored after contacting harmful gases; It is formed on one side of the adsorbed water storage unit 120 to control the level of the adsorbed water. An adsorption water supply device (130) installed so as to; It includes an outlet 117 formed at the top of the tank body 115 to discharge the purified gas,
The harmful gas inflow pipe 116 installed in the first filtration tank 111 to the third filtration tank 113 has an end located inside the tank body 115 bent downward, and a funnel-shaped inside of the bent end. A dust collection demister filter (140) is installed,
The harmful gas inflow pipe 116 of the first filtration tank 111 has a spray nozzle 150 and a misting nozzle 151 installed inside the inlet and is connected to the cleaning water supply pipe 170,
The fourth filtration tank 114 is equipped with a spray nozzle 150 through which cleaning water is sprayed inside the upper part of the harmful gas inlet pipe 116, and the upper part of the spray nozzle 150 is capable of removing moisture mixed in the exhaust gas. A wet purification device for harmful exhaust gas, characterized in that a primary demister filter (141) and a secondary demister filter (142) are installed. delete delete delete delete According to claim 1 or 2,
The first filtration tank 111 to the fourth filtration tank 114 constituting the harmful gas purification device 100 are unitized in a container box for easy movement, and the harmful gas purification device 100 ) A wet purification device for harmful exhaust gases, characterized in that it can be installed in a stacked or arranged form when expanding.