KR102292834B1 - Disk rotation type scrubber for removing NOx and SOx simultaneously - Google Patents

Abstract

The present invention can control the absorption liquid contact time by adjusting the residence time through the disk even if the flow rate of the inflow exhaust gas is low, and by applying a high voltage to the body part and spraying fine droplets of the absorption liquid generated at this time, it is contained in the exhaust gas. It relates to a disk rotating scrubber for simultaneous reduction of SOx-NOx capable of simultaneously removing particulate and gaseous pollutants.

Description

Disk rotation type scrubber for removing NOx and SOx simultaneously}

The present invention relates to a disk rotating scrubber for simultaneous reduction of SOx-NOx, and more particularly, even if the flow rate of the inflow exhaust gas is low, it is possible to control the absorption liquid contact time by adjusting the residence time through the disk, and It relates to a disk rotating scrubber for simultaneous reduction of SOx and NOx, which can simultaneously remove particulate and gaseous pollutants contained in exhaust gas by applying a high voltage and spraying fine droplets of the absorbed liquid generated at this time.

Gas emitted from thermal power plants or waste incineration contains various air pollutants such as dust, nitrogen oxides, and sulfur oxides. Among them, fine dust with a small particle size enters the human body and not only causes respiratory diseases, but also causes plant growth. have a detrimental effect on the environment, such as

In order to manage fine dust (PM2.5) with a diameter smaller than 2.5 μm, which is known to be particularly harmful among these air pollutants, the U.S. Environmental Protection Agency (EPA) and the European Union (EU) have was revised to strengthen environmental regulations on these substances.

On the other hand, gravity dust collection, inertial force dust collection, filter dust collection, cleaning dust collection, and electric dust collection techniques are generally known dust collection techniques. Gravity dust collection technology uses the gravity of particles to naturally precipitate particles as air moves. , it is effective for the removal of relatively large particles, but hardly removes fine particles.

On the other hand, the filtration technology of removing particles by passing gas through a filter having fine pores and the electrostatic precipitation technology of removing particles by supplying electricity to the dust are known to have relatively high dust collection efficiency. However, in the case of filtration technology, the amount of exhaust gas is rapidly reduced because the particles block fine pores, and frequent replacement of the filter is directly related to an increase in the cost of exhaust gas treatment.

In addition, among the electrostatic precipitation technologies, the dry method proceeds in the order of particle charging, particle attachment to the dust collecting pole, desorption of particles attached to the dust collecting pole, and removing particles accumulated on the dust collecting pole. There is a problem that dust collection efficiency is lowered due to the occurrence of re-scattering and back corona depending on the particle resistivity. Water use, non-uniform water film formation on the dust collecting pole, and corrosion are pointed out as major problems.

In addition, since the cyclone type particle removal device requires a minimum linearity of the exhaust gas to be introduced that can form an internal swirling flow, there is a constraint when applying the process. Therefore, in order to effectively remove the above-mentioned air pollutants, in particular, substances with small particles, and furthermore, to achieve enhanced air environment standards by removing various gaseous pollutants together, it is urgently necessary to develop a new dust collecting device that is economical and has high removal efficiency. situation.

Republic of Korea Patent Publication No. 1918549 Republic of Korea Patent Publication No. 1892256 Republic of Korea Patent Publication No. 1951185 Republic of Korea Patent Publication No. 1971917 Republic of Korea Patent Publication No. 1953743 Republic of Korea Patent Publication No.1995742 Republic of Korea Patent Publication No.1995733 Republic of Korea Patent Publication No. 1965189

The present invention has been devised to solve the above problems, and it is an object of the present invention to provide a disk rotating scrubber for simultaneously reducing SOx-NOx, which can effectively remove particulate matter and various gaseous pollutants contained in exhaust gas and the like at the same time. do.

Another object of the present invention is to provide a disk-rotating scrubber for simultaneous reduction of SOx-NOx, which is easy to operate and has a simple structure, and can also reduce the amount of secondary pollutants generated.

The disk rotary scrubber for simultaneous SOx-NOx reduction of the present invention for solving the above problems has an exhaust gas inlet 110 for inducing exhaust gas containing one or more pollutants among particulate and gaseous pollutants in the upper central part. The upper body portion 100 is provided on the outer surface of the side surface of the derived circular tube 120, the high-pressure injection nozzle 130 for spraying the first absorption liquid to react with the gaseous pollutants is formed in the upper center of the circular tube; The central body 200 in the form of a circular tube communicating with the upper body portion; And the lower body portion 300 of the lower correlative slit in communication with the central body portion; including, the exhaust gas formed below the center of the lower body portion an exhaust gas outlet 310 that has an induction port and is rounded to discharge exhaust gas to the side of the lower body part; and a liquid outlet 320 in the lower portion of the lower body, and at least one second absorption liquid injection pipe 140 provided on a side surface of the central body 200 to spray the second absorption liquid; a '+' lead wire connected to the scrubber; and a '-' lead wire connected to the second absorption liquid injection pipe 140 .

In addition, the distribution plate 210 having a disk shape coupled to the side surface of the central body portion, and having one or more arcs formed to have a radius of the disk shape smaller than the radius of the central body portion; may include.

In addition, the motor 220 formed on the upper portion of the distribution plate; a rotating shaft 221 extending from the driving shaft of the motor; It may include; a disk 222 formed at the other end of the rotation shaft.

In addition, a plurality of guide vanes 223 for swirl formation formed on the upper surface of the disk may be included.

In addition, the lower body part 300 communicating with the middle body part 200 may form a shape of a correlative constriction while forming a predetermined lower angle α in the central axis direction from the vertical direction of the outer surface of the middle body part. have.

In addition, the main wire 240 for connecting the second absorption liquid injection pipe 140; may include.

In addition, the linear velocity of the exhaust gas introduced through the exhaust gas inlet may be a linear velocity at which a swirling flow cannot be formed.

In addition, the injection pipe may be formed while maintaining a predetermined distance from the central body portion and the lower body portion to generate electrostatic spraying.

In addition, the disk may be formed to have a predetermined interval with the injection pipe.

In addition, the first absorption liquid and the second absorption liquid may be distributed in a predetermined ratio to absorb sulfur oxides and nitrogen oxides contained in the exhaust gas.

In addition, the diameter of the circular tube may be greater than the diameter of the exhaust gas outlet.

In addition, the diameter of the liquid outlet may be greater than the diameter of the exhaust gas outlet.

In addition, the diameter of the circular tube may be greater than the diameter of the liquid outlet.

In addition, the liquid outlet is connected to the water treatment tank, the water treatment tank includes a first drain for separating the absorption liquid; and a surge pump for removing particulate residues.

In addition, a gas analyzer at the rear end of the exhaust gas outlet; connected, and the flow rate of the exhaust gas and supply amounts of the first absorbent and the second absorbent may be adjusted according to the gas composition of the exhaust gas.

In addition, the injection angle β with respect to the central axis of the high-pressure injection nozzle may be greater than 0 degrees and less than 180 degrees.

In addition, the inner end of the circular tube of the high-pressure injection nozzle may be located at the lower end of the exhaust gas inlet.

In addition, the circular tube, the exhaust gas outlet inlet 311 and the liquid outlet may all be formed on the same axis.

According to the disk rotary scrubber for simultaneous SOx-NOx reduction of the present invention, fine droplets are generated by applying a high voltage and the fine droplets are brought into contact with the exhaust gas. There is an advantage that the removal efficiency can be improved.

In addition, since the disk rotary scrubber for simultaneous SOx-NOx reduction of the present invention can generate fine droplets, it is possible to minimize the amount of waste liquid generated, thereby reducing secondary treatment costs.

1 is a schematic diagram of a disk rotary scrubber for simultaneous SOx-NOx reduction according to a first embodiment of the present invention.
2 is a view from the top of the disk rotating scrubber for simultaneous SOx-NOx reduction according to the first embodiment of the present invention.
3 is a vertical cross-sectional view of a disk rotating scrubber for simultaneous SOx-NOx reduction according to the first embodiment of the present invention.
4 is a horizontal cross-sectional view including a disk of the central body of the disk rotary scrubber for simultaneous SOx-NOx reduction according to the first embodiment of the present invention.
5 is a horizontal cross-sectional view without a disk of the central body of the disk rotary scrubber for simultaneous SOx-NOx reduction according to the first embodiment of the present invention.
6 is a horizontal cross-sectional view including the main wire of the lower body of the disk rotary scrubber for simultaneous SOx-NOx reduction according to the first embodiment of the present invention.

Hereinafter, a disk rotary scrubber for simultaneous SOx-NOx reduction according to the present invention will be described with reference to the accompanying drawings. In the specification of the present invention, particulate pollutants refer to substances that exist in the form of particles having a size of several μm or more, and gaseous pollutants are gaseous substances that can adversely affect the human body or ecosystem, such as odor-causing substances, nitrogen oxides, and sulfur oxides. contaminants present.

In the present application, terms such as include, have or have are intended to designate that a feature, number, step, component, part, or combination thereof described in the specification exists, and includes one or more other features, number, step, It should be understood that the existence or addition of operations, components, parts or combinations thereof is not precluded in advance.

In addition, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

1 is a schematic diagram of a disk rotary scrubber for simultaneous SOx-NOx reduction according to a first embodiment of the present invention.

2 is a view from the top of the disk rotating scrubber for simultaneous SOx-NOx reduction according to the first embodiment of the present invention.

3 is a vertical cross-sectional view of a disk rotating scrubber for simultaneous SOx-NOx reduction according to the first embodiment of the present invention.

1 to 3, the disk rotary scrubber for simultaneous SOx-NOx reduction according to the first embodiment of the present invention includes an upper body portion 100, a central body portion 200, and a lower body portion. 300, a '+' lead wire connected to the scrubber body and a '-' lead wire connected to the first injection pipe 140 are included.

More specifically, the lower body part has a conical shape of a sang-gwang-ha-kwan structure that gradually decreases in cross-sectional area as it goes down, and the central body part is vertically erected in a long cylindrical shape having a predetermined height and inner diameter. In addition, the upper body part serves as the upper casing of the scrubber of the present invention, and injects the exhaust gas inlet into which the exhaust gas flows and the first absorption liquid at high pressure to mix with the exhaust gas and absorb nitrogen oxides and sulfur oxides in the exhaust gas. It may include a spray nozzle.

An exhaust gas inlet 110 for inducing exhaust gas containing any one or more pollutants of particulate pollutants and gaseous pollutants is provided at a predetermined position of the upper body part, and at the bottom of the lower body part, the exhaust gas is removed from the introduced exhaust gas. A liquid outlet for discharging various contaminants and the sprayed liquid is provided. Although not shown in the drawings, it is obvious that a valve for opening and closing may be provided at the liquid outlet.

On the ceiling of the upper body part, a circular pipe having an exhaust gas inlet for introducing an exhaust gas containing pollutants is formed on the central axis, and the exhaust gas inlet has a smaller diameter than the circular pipe.

Here, the scrubber body is made of a conductive material so that a positive (+) charge can be applied, and the accompanying drawings show that the horizontal cut surface is circular, but polygons other than triangles such as squares, pentagons, and hexagons are also acceptable.

The high-pressure injection nozzle, which first comes into contact with the exhaust gas introduced through the exhaust gas inlet, consists of a nozzle pipe and a nozzle tip. Specifically, the nozzle pipe is formed on the central axis of the circular pipe to inject the absorbent liquid from the outside into the circular pipe at high pressure.

The insertion position of the nozzle pipe is not limited to the insertion position as long as the contact efficiency between the exhaust gas and the absorbent liquid injected at high pressure increases. Preferably, an insertion position may be formed at the lower end of the exhaust gas inlet. It is obvious that the nozzle tip may have various shapes as long as the first absorbent liquid can be sprayed over the entire area of the circular tube. Preferably, the injection pressure may be 1 bar or more, and more preferably 5 bar or more. The high-pressure injection nozzle may be formed in plurality or may be formed in a bundle form.

An exhaust gas inlet 110 for inducing an exhaust gas containing one or more pollutants among particulate and gaseous pollutants is provided on the outer surface of the side of the circular tube 120 derived from the upper central part, and reacting with the gaseous pollutants an upper body portion 100 having a high-pressure injection nozzle 130 for spraying a first absorption liquid for the upper central portion of the circular tube; The central body 200 in the form of a circular tube communicating with the upper body portion; And the lower body portion 300 of the lower correlative slit in communication with the central body portion; including, the exhaust gas formed below the center of the lower body portion an exhaust gas outlet 310 that has an induction port and is rounded to discharge exhaust gas to the side of the lower body part; and a liquid outlet 320 in the lower portion of the lower body, and at least one second absorption liquid injection pipe 140 provided on a side surface of the central body 200 to spray the second absorption liquid; a '+' lead wire connected to the scrubber; and a '-' lead wire connected to the second absorption liquid injection pipe 140 .

It is obvious that the '+' lead wire and the '-' lead wire connected to the scrubber and the second absorption liquid injection pipe may be connected in reverse.

The exhaust gas inlet may be coupled to the circular tube in an orthogonal form, and may be coupled in a tangential direction.

The liquid outlet is connected to the lower body in the form of a cone, and the inclination angle of the cone is constant 0° to 90° for smooth discharge of the salt slurry generated through the reaction between the exhaust gas and the absorbent. can have

4 is a horizontal cross-sectional view including a disk of the central body of the disk rotary scrubber for simultaneous SOx-NOx reduction according to the first embodiment of the present invention.

5 is a horizontal cross-sectional view without a disk of the central body of the disk rotary scrubber for simultaneous SOx-NOx reduction according to the first embodiment of the present invention.

6 is a horizontal cross-sectional view including the main wire of the lower body of the disk rotary scrubber for simultaneous SOx-NOx reduction according to the first embodiment of the present invention.

A distribution plate 210 having a disk shape coupled to a side surface of the central body portion, and having one or more arcs formed in a radius of the disk shape smaller than the radius of the central body portion; may include.

The distribution plate may serve to induce a flow of the exhaust gas including the first absorption liquid injected through the upper body portion to the outermost side of the central body portion and the lower body portion.

The shape of the distribution plate is not limited as long as it uniformly guides the exhaust gas to the outer shells of the central body and the lower body.

The distribution plate may have distribution grooves formed radially based on a central point so that the first absorption liquid contained in the exhaust gas may uniformly flow to the side surface of the central body portion.

The distribution groove may be formed in a spiral shape to induce a swirling flow of the exhaust gas.

It is obvious that the spacing and spiral direction of the distribution grooves can be variously changed in design according to the conditions of the exhaust gas including the input first absorption liquid.

The distribution plate may be formed in a cone shape around a central point.

A cone-shaped distribution cone 230 may be additionally formed above the central point of the distribution plate to uniformly distribute the exhaust gas input from the upper body to the distribution plate.

The distribution cone also has the effect of preventing corrosion of the motor from the exhaust gas.

A distribution band formed in a circular band shape to be connected to the upper surface of the distribution plate and the lower portion of the upper body portion may be additionally formed.

The distribution band may have a porous material or a mesh shape.

The distribution plate may be formed below the pipe for injection is bent downward from the horizontal.

a motor 220 formed on the upper portion of the distribution plate; a rotating shaft 221 extending from the driving shaft of the motor; It may include; a disk 222 formed at the other end of the rotation shaft. The motor may be made of an acid-resistant material that can withstand the exhaust gas.

The rotation shaft may be made of an acid-resistant material that can withstand the exhaust gas.

The disk may be made of an acid-resistant material that can withstand the exhaust gas.

At least one material of the motor, the rotating shaft, and the disk may be an acid-resistant stainless alloy or a metal material coated with an inorganic material on the surface.

The disk may be formed to be spaced apart from the distribution plate by a predetermined distance.

The separation distance is determined by the length of the rotating shaft connected to the central axis of the motor formed on the upper surface of the distribution plate.

The diameter of the disk may be greater than or equal to the diameter of the distribution plate.

When the central axis of the circular tube of the upper body part coincides with the central axis of the disk, it is formed to be spaced apart by a predetermined distance.

The separation distance is also determined by the length of the rotation shaft. Therefore, the length of the rotation shaft cannot exceed the lower end of the upper body part from the motor installed on the distribution plate.

In addition, a predetermined distance may be formed from the lower end of the upper body part in consideration of the height of the guide vanes formed on the upper part of the disk.

The predetermined interval is not limited as long as the exhaust gas containing the first absorption liquid introduced through the circular tube of the upper body can form a swirling flow through the rotating disk in which the guide vanes are formed.

It may include a plurality of guide vanes 223 for swirl formation formed on the upper surface of the disk.

The guide vanes may be radially formed around a central axis of the disk.

The interval between each guide vane may be formed uniformly, and preferably, 1 or more and up to 360 may be formed in an integer number at a constant angular interval based on 360 degrees. More preferably, there may be 6 or more and 36 or less.

The guide vane may be formed uniformly radially from a leading edge 224 and bent at a predetermined angle at a predetermined distance from a trailing edge 225 .

An upper surface may be formed vertically from a lower surface of the guide vane in contact with the upper surface of the disk.

The cross-section of the leading edge may be formed vertically, and the cross-section toward the trailing edge may be bent at a predetermined angle γ from the vertical.

The disk may be formed to be spaced apart from the distribution plate by a predetermined distance.

The separation distance is determined by the length of the rotating shaft connected to the central axis of the motor formed on the upper surface of the distribution plate.

The diameter of the disk may be greater than or equal to the diameter of the distribution plate.

When the central axis of the circular tube of the upper body part coincides with the central axis of the disk, it is formed to be spaced apart by a predetermined distance.

The separation distance is also determined by the length of the rotation shaft. Therefore, the length of the rotation shaft cannot exceed the lower end of the upper body part from the motor installed on the distribution plate.

In addition, a predetermined distance may be formed from the lower end of the upper body part in consideration of the height of the guide vanes formed on the upper part of the disk.

The predetermined interval is not limited as long as the exhaust gas containing the first absorption liquid introduced through the circular tube of the upper body can form a swirling flow through the rotating disk in which the guide vanes are formed.

at least one second absorption liquid injection pipe 140 provided on the outer periphery of the upper body portion 100 to spray the second absorption liquid; a '+' lead wire connected to the scrubber; and a '-' lead wire connected to the second absorption liquid injection pipe 140 .

When a high voltage is applied while supplying an absorbent liquid having the same configuration as the injection pipe, minute droplets are generated between the inner wall surface of the scrubber and the injection pipe.

To explain the principle of the electrospray method using such a high voltage, when a high voltage of positive (+) and negative (-) is applied while passing a conductive liquid through the nozzle, the ions in the nozzle and the liquid become liquid by repulsive force and attractive force. moves to the surface. At this time, when the Coulomb repulsion force becomes a force greater than the surface tension, it is sprayed into fine droplets, and when the voltage applied to the electrode is small, the electric force and the repulsive force of the positive ions acting on the curved surface of the liquid are smaller than the surface tension of the liquid, so the droplets are not sprayed, but the voltage is not applied. When it is increased, the electric force acting on the curved surface of the liquid and the repulsive force of positive ions become larger than the surface tension of the liquid, and the droplet is sprayed from the capillary tip.

An insulating insulator 150 for preventing the upper body 100 and the second absorbent liquid injection pipe 140 from being electrically energized may be further provided on the outer surface of the second absorbent liquid injection pipe.

The insulator is not limited to the material as long as it is a non-conductive material. Preferably, it may be Teflon.

The pipe for injecting the second absorption liquid has a long cylindrical shape with one side open to supply the second absorption liquid and the other side closed, and the one or more electrostatic spray tubes 141 may be formed on the circumferential surface.

An electrostatic spray nozzle 142 for spraying the second absorption liquid to the inner side surface of the lower body 300 may be further provided in the electrostatic spray tube 141 .

The electrostatic spray tubes may be formed in a line with equal intervals or predetermined intervals on the second absorption liquid injection pipe.

The diameter of the electrostatic spray nozzle coupled to the electrostatic spray tube is not limited to the size of the injection amount of the second absorption liquid and the size of the electrostatic spray nozzle as long as a charge can occur in a state in which a short circuit does not occur.

A plurality of electrostatic spray tubes may be formed on the same axis of the second absorption liquid injection pipe.

A plurality of the electrostatic spray tubes coaxially formed on the second absorption liquid injection pipe may be formed at an angle of 90 degrees or more and 180 degrees or less to an adjacent electrostatic spray tube.

Preferably, the angle may be 120 degrees or more and 160 degrees or less, and more preferably 140 degrees. If it is out of the above angle range, electrostatic spray generation and spraying effect may be reduced.

The injection pipe may be formed horizontally from the side of the central body to the inside by a predetermined distance and then bent at a predetermined angle.

The bent angle is not limited to the angle as long as it can generate an electrostatic spraying effect, but is preferably formed to be the same as the angle of the lower body portion.

If the angles of the injection pipe and the lower body part do not match, the injection pipe and the lower body part may be too far apart from each other in a predetermined portion, and thus electric charge may not occur, and if they approach too close, a short circuit may occur.

In the scrubber device using the conventional liquid spray method, it is difficult to collect particles having a small particle diameter because the sprayed droplets are large, and there is a problem in that the secondary treatment cost is increased due to the use of an excessive amount of liquid.

However, since the scrubber in the present invention generates droplets using the electrostatic spraying method as described above, the diameter of the droplets is very small. Since the aggregation phenomenon of the liver does not appear, the initial diameter can be maintained for a long time, and it is possible to collect various contaminants including fine particles having a particle diameter of 0.1 μm or less.

On the other hand, the high voltage is not particularly limited as long as electrostatic spraying is possible and the voltage at which the heat of the insulating material is destroyed. Preferably, it may be 2-10 kV/cm, and the distance between the tip of the nozzle and the wall surface of the lower body is 5~ It is preferably 20 cm.

The lower body part 300 communicating with the middle body part 200 may form a shape of a correlative lower narrowing while forming a predetermined lower angle α in the central axis direction from the vertical direction of the outer surface of the middle body part.

The lower angle α is not limited to the angle as long as calcium sulfate generated by the reaction of the absorption liquid and the exhaust gas and/or particulate matter aggregated through electrostatic spraying smoothly moves in the direction of the liquid outlet.

Preferably, the lower angle may be greater than 0 degrees and less than 90 degrees, more preferably 5 degrees or more and 45 degrees or less, and very preferably 20 degrees.

If the angle is out of the lower angle, the removal of the particulate matter may not be smooth.

and a main wire 240 connecting the second absorption liquid injection pipe 140 .

The main wire 240 may connect the inner ends of the plurality of second absorption liquid injection pipes inside the lower body portion.

The main wire functions to firmly position the pipe for injecting the second absorbent liquid inside the scrubber.

The main wire may have a circular, oval, or polygonal shape by connecting a plurality of pipes for injecting the second absorbent liquid.

Three or more auxiliary wires made of a circular or polygonal shape may be further provided inside the main wire.

The auxiliary wire, three or more auxiliary wires may be arranged in a radial form around one circular auxiliary wire.

The main wire may be further provided with one or more electrode guide rods facing the liquid outlet.

Additionally, an electrode guide rod is attached to the main wire so that discharge efficiency can be maximized, and the electrode guide rod has a pin shape of a predetermined length, and a plurality of the electrode guide rods are arranged spaced apart from each other at a predetermined interval so as to face the liquid outlet.

The main wire has a function of applying a voltage, and deviates from the form of applying a voltage to each water pipe exposed to the outside, and applies a voltage to only one water pipe among the water pipes exposed to the outside, Voltage application of the remaining water pipe may be formed in such a way that a voltage is applied by the main wire formed therein.

The main wire may be made of an electrically conductive material.

The linear velocity of the exhaust gas introduced through the exhaust gas inlet may be a linear velocity at which a swirling flow cannot be formed.

In order for the scrubber to be coupled to the exhaust gas removal process, the exhaust gas forms a swirling flow inside the scrubber to remove particulate pollutants, sulfur oxides, and nitrogen oxides contained in the exhaust gas. Secure a minimum residence time shall.

In general, a cyclone type pollutant treatment mechanism requires a minimum linear velocity at the inlet of the exhaust gas to form a swirling flow. In general, when exhaust gas flows into the cyclone at a linear velocity of 10 m/sec or more, the residence time through the swirling flow can be secured.

However, depending on the flow rate of the exhaust gas, there are many limiting conditions in securing a residence time for removing cyclone-type particles, sulfur oxides, and nitrogen oxides.

Therefore, it is possible to control the residence time of the exhaust gas through the forced rotation through the disk inside, like the scrubber of the present invention.

For this purpose, the linear velocity of the exhaust gas may be 2 m/sec.

The injection pipe may be formed while maintaining a predetermined distance from the central body portion and the lower body portion to generate electrostatic spraying.

The disk may be formed to have a predetermined interval with the injection pipe.

The first absorption liquid and the second absorption liquid may be distributed in a predetermined ratio to absorb sulfur oxides and nitrogen oxides contained in the exhaust gas.

The diameter of the circular tube may be greater than the diameter of the exhaust gas outlet.

A diameter of the liquid outlet may be greater than a diameter of the exhaust gas outlet.

The diameter of the circular tube may be greater than the diameter of the liquid outlet.

The liquid outlet is connected to the water treatment tank and

The water treatment tank may include a first drain for separating the absorption liquid; and a surge pump for removing particulate residues.

a gas analyzer at the rear end of the exhaust gas outlet; connected, and the flow rate of the exhaust gas and supply amounts of the first absorbent and the second absorbent may be adjusted according to the gas composition of the exhaust gas. The absorption liquid may be Ca(OH) ₂ , Fe ²⁺ EDTA.

The injection angle β with respect to the central axis of the high-pressure injection nozzle may be greater than 0 degrees and less than 180 degrees.

The injection angle may be greater than 0 degrees and less than 180 degrees. Preferably, it may be 90 degrees or more and 140 degrees or less, and more preferably 100 degrees or more and 120 degrees or less. Very preferably, it may be 112 degrees.

If the injection angle is out of the range, the contact efficiency between the exhaust gas and the first absorption liquid may be lowered.

The inner end of the circular tube of the high-pressure injection nozzle may be located at a lower end of the exhaust gas inlet.

The circular tube, the exhaust gas outlet inlet 311 and the liquid outlet may all be formed on the same axis.

As described above in detail a specific part of the content of the present invention, to those of ordinary skill in the art, these specific descriptions are only preferred embodiments, and the scope of the present invention is not limited thereby, It is obvious to those skilled in the art that various changes and modifications can be made within the scope and spirit of the present invention, and it is natural that such variations and modifications fall within the scope of the appended claims.

100: upper body part
110: exhaust gas inlet
120: round tube
130: high pressure injection nozzle
140: injection pipe
141: electrostatic spray tube
142: electrostatic spray nozzle
150: insulator
200: central body portion
210: distribution plate
220: motor
221: rotation shaft
222: disk
223: guide vane
224: leading edge
225: trailing edge
240: main wire
300: lower body portion
310: exhaust gas outlet
311: exhaust gas outlet inlet
320: liquid outlet

Claims (18)

A circular tube 120 having an exhaust gas inlet 110 for inducing an exhaust gas containing one or more pollutants among particulate and gaseous pollutants protruding from the upper central part.
The upper body portion 100 is provided on the outer surface of the side, the high-pressure injection nozzle 130 for spraying the first absorption liquid for reacting with the gaseous pollutant is formed in the upper center of the circular tube;
The central body part 200 in the form of a circular tube communicating with the upper body part; And
Including;
an exhaust gas outlet 310 having an exhaust gas guide hole formed downwardly in the center of the lower body part and being rounded to discharge exhaust gas to the outside through a side surface of the lower body part; and a liquid outlet 320 at the lower part of the lower body part;
at least one second absorption liquid injection pipe 140 provided on a side surface of the central body 200 to spray the second absorption liquid;
'+' lead wire connected to scrubber; and
and a '-' lead wire connected to the second absorption liquid injection pipe 140,
It has a disk shape coupled to a side surface of the central body,
and a distribution plate 210 having one or more arcs in which the radius of the disk shape is smaller than the radius of the central body portion.
and a main wire 240 connecting the second absorption liquid injection pipe 140 .
A disk rotating scrubber for simultaneous SOx-NOx reduction having one or more electrode guide rods facing the liquid outlet in the main wire.
delete According to claim 1,
a motor 220 formed on the upper portion of the distribution plate;
a rotating shaft 221 extending from the driving shaft of the motor;
A disk rotatable scrubber for simultaneous SOx-NOx reduction comprising a; a disk 222 formed at the other end of the rotation shaft.
4. The method of claim 3,
A disk rotation type scrubber for simultaneous reduction of SOx-NOx including a guide vane 223 for swirl formation formed in a plurality on the upper surface of the disk.
4. The method of claim 3,
The lower body part 300 in communication with the central body part 200 forms a predetermined lower angle α in the central axis direction from the vertical direction of the outer surface of the central body part SOx-NOx constituting the shape of the lower correlation. Disc rotating scrubber for simultaneous abatement.
delete According to claim 1,
A disk rotation type scrubber for simultaneous reduction of SOx-NOx, which is a linear velocity at which a linear velocity of exhaust gas flowing in through the exhaust gas inlet cannot form a vortex flow.
5. The method of claim 4,
The second absorption liquid injection pipe is formed while maintaining a predetermined distance from the central body and the lower body so as to generate electrostatic spraying.
9. The method of claim 8,
The disk is a disk rotation type scrubber for simultaneous SOx-NOx reduction which is formed to have a predetermined interval with the second absorption liquid injection pipe.
5. The method of claim 4,
The disk rotation type scrubber for simultaneous reduction of SOx-NOx in which the first absorption liquid and the second absorption liquid are distributed and input in a predetermined ratio to absorb sulfur oxides and nitrogen oxides contained in the exhaust gas.
◈Claim 11 was abandoned when paying the registration fee.◈ According to claim 1,
The diameter of the circular tube is larger than the diameter of the exhaust gas outlet, the disk rotation type scrubber for simultaneous reduction of SOx-NOx.
◈Claim 12 was abandoned when paying the registration fee.◈ According to claim 1,
The diameter of the liquid outlet is larger than the diameter of the exhaust gas outlet. A disk rotating scrubber for simultaneous reduction of SOx-NOx.
◈Claim 13 was abandoned when paying the registration fee.◈ According to claim 1,
The diameter of the circular tube is larger than the diameter of the liquid outlet SOx-NOx disk rotation type scrubber for simultaneous reduction.
According to claim 1,
The liquid outlet is connected to the water treatment tank and
The water treatment tank may include a first drain for separating the first absorption liquid; and a surge pump for removing particulate residues; a disk rotary scrubber for simultaneous reduction of SOx-NOx including.
5. The method of claim 4
a gas analyzer at the rear end of the exhaust gas outlet; connected,
A disk rotating type scrubber for simultaneously reducing SOx and NOx, which adjusts the flow rate of the exhaust gas and the supply amounts of the first absorption liquid and the second absorption liquid according to the gas composition of the exhaust gas.
◈Claim 16 was abandoned at the time of payment of the registration fee.◈ The method of claim 1
A disk rotation type scrubber for simultaneous reduction of SOx-NOx in which the injection angle (β) is greater than 0 degrees and less than 180 degrees with respect to the central axis of the high-pressure injection nozzle.
◈Claim 17 was abandoned when paying the registration fee.◈ The method of claim 1
The inner end of the circular tube of the high-pressure injection nozzle is located at the lower end of the exhaust gas inlet, a disk rotation type scrubber for simultaneous SOx-NOx reduction.
◈Claim 18 was abandoned when paying the registration fee.◈ The method of claim 1
The circular tube and the exhaust gas outlet inlet 311 are formed on the same axis as a disk rotating scrubber for simultaneous reduction of SOx-NOx.

Images