KR102203139B1 - Apparatus for purifying exhaust gas using rotational force - Google Patents

Abstract

The present invention relates to an exhaust gas purifying device using rotational force. The exhaust gas purifying device comprises: an external cylinder through which exhaust gas is introduced from a lower portion thereof; a first compressed air supply unit connected to an upper portion of the external cylinder and configured to supply compressed air into the external cylinder; a central pipe longitudinally extending from the center of the external cylinder, and having a lower portion that is closed and an upper portion communicating with the outside; an internal cylinder installed inside the external cylinder, and having an upper portion that is opened, wherein the lower portion of the central pipe is inserted into the internal cylinder; and a first discharge passage connected to a lower portion of the internal cylinder and configured to discharge purified exhaust gas. According to this configuration, it is possible to provide an exhaust gas purifying device with low installation and operation costs since pollutants are removed using a temperature difference while the exhaust gas in the cylinder is rotated by rotational force.

Description

{Apparatus for purifying exhaust gas using rotational force}

The present invention relates to an exhaust gas purification apparatus using rotational force.

In general, when waste is incinerated in an incinerator, exhaust gas is generated due to combustion, and such exhaust gas contains CO, SO _X , NO _X, etc. and acts as a pollutant polluting the atmosphere. In particular, among these pollutants, nitrogen oxides cause disgusting odors and smog.

As devices for purifying exhaust gas, multi-cron bag filters and electric precipitators are known, but odor particles and nitrogen oxides with very small particle sizes are difficult to remove, so some pollutants are removed by these exhaust gas purification devices. The exhaust gas was secondarily purified through chemical treatment.

Chemical purifiers require a lot of facility cost and operation cost, and nonetheless, there is a problem that the treatment capacity is limited, so that they cannot be used except for some sites.

Accordingly, there is a need for an exhaust gas purification device capable of effectively removing pollutants contained in exhaust gas while having low installation cost and operation cost.

Korean Patent Registration No. 10-1122748

Accordingly, the present invention was invented in view of the above circumstances, and by removing pollutants using a temperature difference while rotating the exhaust gas in the cylinder by the rotational force, it is intended to provide an exhaust gas purification apparatus with low installation cost and operation cost. There is a purpose.

An exhaust gas purification apparatus according to the present invention for realizing the object as described above includes: an external cylinder through which exhaust gas is introduced from a lower portion; A first compressed air supply unit connected to an upper portion of the outer cylinder to supply compressed air into the outer cylinder; A central pipe extending longitudinally from the center of the outer cylinder, the lower part being closed, and the upper part communicating with the outside; An inner cylinder installed inside the outer cylinder and into which an upper portion is opened and a lower portion of the central pipe is inserted; A first discharge passage connected to a lower portion of the inner cylinder to discharge the purified exhaust gas; Includes.

In addition, the exhaust gas purification apparatus includes an air inlet pipe extending into the central pipe and through which outside air is introduced; It includes more.

In addition, the exhaust gas purification device includes a second compressed air supply unit for supplying compressed air into the air inlet pipe; It includes more.

In addition, the exhaust gas purification device includes a fallout recovery cylinder through which the exhaust gas is introduced by the first discharge passage connected to the upper portion; A third compressed air supply unit connected to an upper portion of the fallout recovery cylinder to supply compressed air into the fallout recovery cylinder; A second discharge passage connected to the upper center of the fallout recovery cylinder and extending downward, and for discharging exhaust gas in the fallout recovery cylinder; It includes more.

According to the present invention, by removing pollutants using a temperature difference while rotating exhaust gas in a cylinder by a rotational force, it is possible to provide an exhaust gas purification apparatus having low installation cost and operation cost.

1 is a diagram showing the configuration of an exhaust gas purifying apparatus according to an embodiment of the present invention.
2 is a diagram showing the configuration of a compressed air supply unit in FIG. 1.
FIG. 3 is a diagram showing a state in which a plurality of exhaust gas purification devices of FIG. 1 are installed in series.
4 is a diagram showing a configuration of a central pipe according to another embodiment of the present invention.

Hereinafter, the configuration and operation of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. Here, in adding reference numerals to elements of each drawing, it should be noted that only the same elements are marked with the same numerals as possible, even if they are indicated on different drawings.

1 is a diagram showing the configuration of an exhaust gas purifying apparatus according to an embodiment of the present invention. 2 is a diagram showing the configuration of a compressed air supply unit in FIG. 1. FIG. 3 is a diagram showing a state in which a plurality of exhaust gas purification devices of FIG. 1 are installed in series.

1 to 3, the exhaust gas purification device of the present invention includes an external cylinder 110, a first compressed air supply unit 111, a central pipe 120, an air inlet pipe 130, and a second compressed air supply unit. (131), an inner cylinder 140, a first discharge passage 150, a fallout recovery cylinder 160, a third compressed air supply unit 161, and a second discharge passage 170.

The outer cylinder 110 is formed in a cylindrical shape, and the lower part is connected to the exhaust gas inlet, and exhaust gas is introduced from the lower part. The outer cylinder 110 may have a shape in which the cross-sectional area of the lower portion is reduced in a funnel shape. The temperature of the exhaust gas can be 80~150℃.

The first compressed air supply unit 111 is connected to the upper portion of the outer cylinder 110 to supply compressed air at room temperature into the outer cylinder 110. The compressed air supplied into the outer cylinder 110 is rotated along the inner wall of the outer cylinder 110 by the rotational force.

The central pipe 120 is inserted into the outer cylinder 110. The central pipe 120 extends longitudinally from the center of the outer cylinder 110, the lower portion is closed, and the upper portion protrudes through the upper portion of the outer cylinder 110 to communicate with the outside. The central pipe 120 may have a shape in which the cross-sectional area decreases toward the bottom.

The air inlet pipe 130 is inserted into the central pipe 120 from the outside of the outer cylinder 110 and extends into the central pipe 120. Room temperature outside air is introduced through the air inlet pipe 130.

The second compressed air supply unit 131 may be connected to the air inlet pipe 130 to supply compressed air into the air inlet pipe 130.

The inner cylinder 140 is installed inside the outer cylinder 110 and the upper portion is opened so that the lower portion of the central pipe 120 is inserted into the inner cylinder 140. The inner cylinder 140 may have a shape in which a cross-sectional area of the lower portion is reduced in a funnel shape. The portion where the cross-sectional area of the inner cylinder 140 is reduced is formed in a portion corresponding to the outer cylinder 110, so that the flow path formed between the inner cylinder 140 and the outer cylinder 110 is smaller than the exhaust gas inlet. .

The first discharge passage 150 is connected to the lower portion of the inner cylinder 140. The first discharge passage 150 is for discharging the purified exhaust gas in the inner cylinder 140. The first discharge passage 150 may extend through the outer cylinder 110.

Referring to FIG. 2, the first compressed air supply unit 111 injects compressed air inclined at a predetermined angle with a tangent line of the inner wall of the outer cylinder 110. The compressed air injected into the outer cylinder 110 obtains a rotational force and flows along the inner wall due to the Coanda effect.

Compressed air introduced into the outer cylinder 110 increases in volume due to adiabatic expansion and decreases the ambient temperature.

The exhaust gas flowing from the exhaust gas inlet to the outer cylinder 110 through the flow path between the outer cylinder 110 and the inner cylinder 140 decreases in temperature and the water vapor contained in the exhaust gas is condensed to become moisture. Harmful substances (pollutants) contained in exhaust gas adhere to moisture and become dust. This dust falls into the inner cylinder 140 along the outer wall of the central pipe 120.

The central pipe 120 is formed so that the cross-sectional area decreases toward the bottom, so that moisture and harmful substances in the exhaust gas move better toward the central pipe 120 to form dust well, and the inner cylinder ( 140) Allows you to fall inside.

The outside air supplied into the central pipe 120 through the air inlet pipe 130 lowers the temperature of the central pipe 120 so that water vapor in the exhaust gas can be more easily condensed, thereby helping the formation of dust. A fan is installed in the central pipe 120 to allow air in the central pipe 120 to be well discharged to the outside.

When compressed air is supplied into the air inlet pipe 130 by the first compressed air supply unit 111, the compressed air is discharged through the air inlet pipe 130 and then adiabatically expanded to lower the temperature and take away heat from the surrounding area. It may be discharged to the outside through the central pipe 120. The central pipe 120 having a lowered temperature lowers the temperature in the outer cylinder 110 so that dust can be better formed.

In contrast, a water supply pipe is installed instead of the air inlet pipe 130, and water is supplied into the central pipe 120 through the water supply pipe to lower the temperature of the central pipe 120, and the water in the central pipe 120 It can be discharged to the outside by a pump.

Exhaust gas in the outer cylinder 110 may be introduced into the inner cylinder 140 together with dust, and purified through the first discharge passage 150 to be discharged.

The exhaust gas purification apparatus of the present invention may be connected in series to the exhaust gas inlet.

The first discharge passage 150 may be connected to the fallout recovery cylinder 160. The first discharge passage 150 is connected to the upper portion of the fallout recovery cylinder 160 so that exhaust gas flows into the fallout recovery cylinder 160.

The third compressed air supply unit 161 is connected to the upper portion of the fallout recovery cylinder 160 to supply compressed air into the fallout recovery cylinder 160.

The second discharge passage 170 is connected to the upper center of the fallout recovery cylinder 160 and extends downward, and discharges the exhaust gas in the fallout recovery cylinder 160.

The third compressed air supply unit 161 injects compressed air at a predetermined angle with the tangent line of the inner wall of the fallout recovery cylinder 160, and the compressed air introduced into the fallout recovery cylinder 160 increases in volume due to adiabatic expansion. It lowers the ambient temperature.

The water vapor contained in the exhaust gas flowing into the fallout recovery cylinder 160 is condensed to become moisture, and harmful substances contained in the exhaust gas adhere to this moisture to become dust and fall along the outer wall of the second discharge passage 170. It is accumulated under the fallout recovery cylinder 160.

The lower part of the fallout recovery cylinder 160 is formed to have a reduced cross-sectional area in a funnel shape, so that the fallout may be collected under the fallout recovery cylinder 160. This fallout may be processed after being stored in the fallout recovery unit 162. A door is formed between the fallout recovery cylinder 160 and the fallout recovery unit 162, and when a certain amount of fallout is accumulated, the door may be opened automatically by a load.

The exhaust gas from which dust has been additionally removed may be discharged to the outside along the second discharge passage 170. A fan is installed in the second discharge passage 170 to provide a negative pressure.

Referring to FIG. 3, a plurality of exhaust gas purification apparatuses of the present invention are connected in series to improve exhaust gas purification efficiency. In this case, a plurality of first discharge passages 150 may be connected to be connected to the fallout recovery cylinder 160, or one first discharge passage 150 may be connected to one fallout recovery cylinder 160.

4 is a diagram showing a configuration of a central pipe according to another embodiment of the present invention.

The central pipe 120 of the present embodiment includes a protrusion 121 protruding upwardly in the center of the bottom portion. An opening 121a having a fine diameter is formed in the center of the protrusion 121.

The protrusion 121 is distributed in the direction of the arrow while the compressed air supplied into the central pipe 120 from the second compressed air supply unit 131 through the air inlet pipe 130 hits the protrusion 121 and is distributed in the direction of the arrow. Allows it to spread quickly within. Compressed air quickly spread in the central pipe 120 can quickly cool the central pipe 120.

Part of the compressed air is discharged through the opening 121a to lead the dust falling into the inner cylinder 140 and to be rapidly discharged along the first discharge passage 150. The diameter of the opening 121a may be selected so that an appropriate amount of compressed air can be discharged through the opening 121a.

As described above, in the exhaust gas purification apparatus of the present invention, compressed air injected into the outer cylinder 110 by the first compressed air supply unit 111 is adiabaticly expanded and the temperature in the outer cylinder 110 is decreased. As the water vapor contained in the exhaust gas is condensed by the temperature drop in the outer cylinder 110, harmful substances may adhere to the moisture and be collected as dust.

In addition, outside air or compressed air supplied into the central pipe 120 through the air inlet pipe 130 further lowers the temperature of the central pipe 120 so that harmful substances can be better collected as dust.

It is obvious to those of ordinary skill in the art that the present invention is not limited to the above embodiments and can be implemented with various modifications or modifications within the scope not departing from the technical gist of the present invention. will be.

10: exhaust gas inlet
100: exhaust gas purification device
110: outer cylinder
111: first compressed air supply unit
120: central piping
121: protrusion
121a: opening
130: air inlet pipe
131: second compressed air supply unit
140: inner cylinder
150: first discharge passage
160: fallout recovery cylinder
161: third compressed air supply unit
162: Fallout recovery unit
163: door
170: second discharge passage

Claims (4)

In the exhaust gas purification device,
An external cylinder through which exhaust gas is introduced from a lower portion;
A first compressed air supply unit connected to an upper portion of the outer cylinder to supply compressed air into the outer cylinder;
A central pipe extending longitudinally from the center of the outer cylinder, the lower part being closed, and the upper part communicating with the outside;
An inner cylinder installed inside the outer cylinder and into which an upper portion is opened and a lower portion of the central pipe is inserted;
A first discharge passage connected to a lower portion of the inner cylinder to discharge the purified exhaust gas;
Exhaust gas purification device comprising a. The method of claim 1,
An air inlet pipe extending into the central pipe and through which outside air is introduced;
Exhaust gas purification device further comprising a. The method of claim 2,
A second compressed air supply unit for supplying compressed air into the air inlet pipe;
Exhaust gas purification apparatus further comprising a. The method of claim 2,
A fallout recovery cylinder through which exhaust gas is introduced by connecting the first discharge passage to an upper portion;
A third compressed air supply unit connected to an upper portion of the fallout recovery cylinder to supply compressed air into the fallout recovery cylinder;
A second discharge passage connected to the upper center of the fallout recovery cylinder and extending downward, and for discharging exhaust gas in the fallout recovery cylinder;
Exhaust gas purification apparatus further comprising a.

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