KR100893833B1 - Separating element for pollutant and separating device having the same - Google Patents

Abstract

A pollutant separating element and a pollutant separating device including the same are provided to separate pollutants in the air without consuming energy efficiently. A pollutant separating element(100) includes a first curved surface part(10), a first symmetrical curved surface part(20), a second curved surface part(30), a second symmetrical curved surface part(40), and a connection part(50). A first curved surface(11) and a second curved surface(12) are formed on the first curved surface part. A first symmetry curved part(21) and a second symmetry curved part(22) are formed on the first symmetrical curved surface part. A third curved surface(31) and a fourth curved surface(32) are formed on the second curved part. A third symmetry curved(41) and a fourth symmetry curved(42) are formed on the second symmetrical curved surface part.

Description

Separating element for pollutant and separating device having the same}

The present invention relates to a contaminant separating element and a contaminant separating apparatus including the separating element, and more particularly, to a contaminant separating element and a separating element for separating contaminants such as particles or liquids contained in air. It relates to a contaminant separating apparatus containing.

Devices for sucking contaminants such as gas, steam, mist and dust are widely used in various fields. For example, in the work space where work such as painting, soldering, smelting, etc. is performed, a discharge system is installed for sucking various pollutants generated during the work and discharging them out of the work space. In addition, ventilation and exhaust systems are provided in the tunnels and buildings for ventilating and evacuating the interior of the tunnel or the interior of the building. In the kitchen and smoking rooms, hoods are used to remove food smells and tobacco smoke.

In such an exhaust system, a ventilation and an exhaust system or a hood, a fan for sucking contaminants and a power supply for driving the fan are essentially provided.

However, in the conventional exhaust system, ventilation and exhaust system or hood, energy is inevitably consumed, and there is a limit that is difficult to use in the future where energy resources are insufficient. In addition, if energy is not excessively consumed, contaminants are not inhaled, and in particular, there is a limit in increasing the intake efficiency of contaminants.

In addition, in the conventional exhaust system and the like, in addition to a fan or a power supply, a number of additional devices must be provided, so that the implementation of the system is difficult and costly to implement.

Therefore, there is a need for a device which can be configured to be simple structure but does not consume energy and can separate pollutants in the air.

The present invention has been made to solve the above problems, an object of the present invention is to provide a structure to separate the contaminants in the air passing through without consuming energy as long as the air containing the contaminant passes through It is to provide an improved contaminant separation element and a contaminant separation device including the separation element.

In order to achieve the above object, the contaminant separating apparatus according to the present invention is elongated in one direction, the first curved surface is formed to be curved in a direction crossing with respect to the one direction and the first curved surface facing in the opposite direction to the A first curved portion including a second curved surface having the same radius of curvature as the first curved surface, the first curved portion being formed such that any cross sections perpendicular to the one direction are the same; It is symmetric about an imaginary plane formed between the first curved portion, is formed long in the same direction as the one direction, is formed curved in a direction crossing the one direction and the same curvature as the first curved surface A first radius of symmetry with respect to the first curved surface and a direction opposite to a direction in which the first symmetry curved surface faces, and a radius of curvature equal to that of the first symmetry curved surface, A first symmetric curved surface portion including a second symmetric curved surface symmetrical with the second curved surface with respect to a plane, and having arbitrary cross sections perpendicular to the one direction; The first curved surface is formed in the same direction as the one direction, the first curved surface is formed to be curved in the same direction as the curved direction and the third curved surface having a radius of curvature larger than the radius of curvature of the first curved surface and the third curved surface facing A second curved portion facing a direction opposite to a direction and including a fourth curved surface having the same radius of curvature as the third curved surface, wherein any of the cross sections perpendicular to the one direction are the same; It is symmetric about the imaginary plane, is formed long in the same direction as the one direction, is formed to be curved in a direction crossing the one direction, has the same radius of curvature as the third curved surface and has a center of the imaginary plane The third symmetric curved surface symmetrical to the third curved surface and the third symmetric curved surface facing in the opposite direction to the direction and has the same curvature radius as the third symmetric curved surface and the fourth curved surface around the imaginary plane A second symmetric curved surface portion including a symmetrical fourth symmetric curved surface and formed such that any cross sections perpendicular to the one direction are identical to each other; And a first connection surface formed to extend in the same direction as the one direction and connecting the first curved surface and the third curved surface, the first connecting surface having a curved or planar shape, and connecting the first symmetric curved surface and the third symmetric curved surface, and the curved surface or the flat surface. The second connection surface is formed in a shape and has the same radius of curvature as the first connection and is formed in a direction opposite to the direction in which the first connection is directed, and connects the second curved surface and the second symmetric curved surface to form a curved shape. And a third connecting surface formed thereon, and a fourth connecting surface connecting the fourth curved surface and the fourth symmetric curved surface and having a fourth connecting surface formed in a curved shape, and having any cross section perpendicular to the one direction being the same as each other. The first curved portion, the second curved portion, the first symmetrical curved portion, the second symmetrical curved portion and the connecting portion is characterized in that composed of a body.

According to the present invention, it is possible to separate the contaminants only by passing the air containing the contaminants. In particular, pollutants in the air can be separated without consuming energy.

1 is a schematic perspective view of a pollutant separating element according to an embodiment of the present invention, and FIG. 2 is a schematic plan view of the pollutant separating element shown in FIG. 1.

1 and 2, the contaminant separating element 100 according to an embodiment of the present invention may include a first curved portion 10, a first symmetric curved portion 20, and a second curved portion 30. ), A second symmetric curved surface portion 40, and a connecting portion 50.

The first curved portion 10 is formed long in one direction (L). A first curved surface 11 and a second curved surface 12 are formed in the first curved portion 10. The first curved surface 11 is a curved surface formed to be curved in the direction (T) intersecting with respect to the one direction (L). The second curved surface 12 is a curved surface formed to have the same radius of curvature as the first curved surface, and thus, the distance between the first curved surface 11 and the second curved surface 12, that is, the thickness of the second curved surface 12 is reduced. It is always constant along the forming direction. The second curved surface 12 faces the direction opposite to the direction in which the first curved surface 11 faces. In addition, any cross section perpendicular to the longitudinal direction of the first curved portion 10, that is, any cross section perpendicular to one direction, is the same.

The first symmetric curved portion 20 is formed to be symmetrical with the first curved portion 10 about an imaginary plane P formed between the first curved portion 10. The first symmetric curved surface portion 20 is formed long in the same direction as the longitudinal direction (L) of the first curved portion. The first symmetric curved surface 21 and the second symmetric curved surface 22 are formed in the first symmetric curved surface portion 20. The first symmetric curved surface 21 and the second symmetric curved surface 22 are face symmetrical with the first curved surface 11 and the second curved surface 21 about the virtual plane P, respectively. The first symmetric curved surface 21 is formed to be curved in a direction crossing with one direction, and has the same radius of curvature as the first curved surface 11. The second symmetric curved surface 22 is formed to have the same radius of curvature as the first symmetric curved surface 21, so that the distance between the first symmetric curved surface 21 and the second symmetric curved surface 22, that is, the thickness thereof is It is always constant along the formation direction of the bisymmetric curved surface 22. The second symmetric curved surface 22 faces the direction opposite to the direction that the first symmetric curved surface 21 faces. Further, any cross section perpendicular to the longitudinal direction L of the first symmetric curved surface portion 20, that is, any cross section perpendicular to one direction, is the same.

The second curved portion 30 is formed long in the same direction as the longitudinal direction L of the first curved portion. A third curved surface 31 and a fourth curved surface 32 are formed in the second curved portion 30. The third curved surface 31 is a curved surface in which the first curved surface 11 is curved in the same direction T as the curved direction. The radius of curvature of the third curved surface 31 is greater than the radius of curvature of the first curved surface. The fourth curved surface 32 is a curved surface formed to have the same curvature radius as that of the third curved surface 31. Accordingly, the distance between the third curved surface 31 and the fourth curved surface 32, that is, the thickness is the fourth curved surface ( It is always constant along the formation direction of 32). The fourth curved surface 32 faces the direction opposite to the direction in which the third curved surface 31 faces. In addition, any cross section perpendicular to the longitudinal direction L of the second curved portion 30, that is, any cross section perpendicular to one direction, is the same.

The second symmetric curved portion 40 is formed to be symmetrical with the second curved portion 30 about the imaginary plane P. As shown in FIG. The second symmetric curved surface portion 40 is formed long in the same direction (L) as the longitudinal direction of the second curved portion 30. The third symmetric curved surface 41 and the fourth symmetric curved surface 42 are formed in the second symmetric curved surface portion 40. The third symmetric curved surface 41 and the fourth symmetric curved surface 42 are face symmetrical with the third curved surface 31 and the fourth curved surface 32 with respect to the virtual plane P, respectively. The third symmetric curved surface 41 is formed to be curved in a direction crossing the one direction, and has the same radius of curvature as the third curved surface 31. The fourth symmetric curved surface 42 is formed to have the same radius of curvature as the third symmetric curved surface 41, so that the distance between the third symmetric curved surface 41 and the fourth symmetric curved surface 42, that is, the thickness thereof is equal to It is always constant along the formation direction of the four-symmetry curved surface 42. The fourth symmetric curved surface 42 faces the direction opposite to the direction in which the third symmetric curved surface 41 faces. Further, any cross section perpendicular to the longitudinal direction of the second symmetric curved surface portion 40, that is, any cross section perpendicular to the one direction, is the same.

The connecting portion 50 is formed long in the same direction L as the longitudinal direction of the first curved portion. The connecting portion 50 is for connecting the first curved portion 10, the second curved portion 30, the first symmetric curved portion 20, and the second symmetric curved portion 40 to each other. The connecting portion 50 is formed with a first connecting surface 51, a second connecting surface 52, a third connecting surface 53, and a fourth connecting surface 54.

The first connection surface 51 is for smoothly connecting the first curved surface 11 and the third curved surface 31, and has a curved or planar shape. In particular, in the present embodiment, the first connection surface 51 has a curved shape.

The second connection surface 52 is for smoothly connecting the first symmetric curved surface 21 and the third symmetric curved surface 41, and has a curved or planar shape. In particular, in the present embodiment, the second connection surface 52 has a curved shape. The second connection surface 52 is plane symmetrical about the virtual plane (P). Accordingly, the radius of curvature of the second connection surface 52 is the same as the radius of curvature of the first connection surface 51, and the direction in which the second connection surface 52 faces is opposite to the direction in which the first connection surface 51 faces. to be.

The third connection surface 53 is for smoothly connecting the second curved surface 12 and the second symmetric curved surface 22, and has a curved shape. In particular, in the present embodiment, the third connecting surface 53 is formed in a substantially semicircular shape. Since the curved direction of the second curved surface 12 and the curved direction of the second symmetric curved surface 22 are different from each other, it is preferable that the third connecting surface 53 has a curved shape.

The fourth connection surface 54 is for smoothly connecting the fourth curved surface 32 and the fourth symmetric curved surface 42 and has a curved shape. In particular, in the present embodiment, the fourth connecting surface 54 has a substantially semi-circular shape. Since the curved direction of the fourth curved surface 32 and the curved direction of the fourth symmetric curved surface 42 are different from each other, it is preferable that the fourth connecting surface 54 has a curved shape.

In addition, any cross section perpendicular to the longitudinal direction of the connecting portion 50, that is, any cross section perpendicular to one direction, is the same as each other.

Meanwhile, the first curved surface 11, the first connecting surface 51, the third curved surface 31, the first symmetric curved surface 21, the second connecting surface 52, and the third symmetric curved surface 41 are each provided in plural. Grooves 60 and 61 are formed. The plurality of grooves 60 and 61 are elongated in one direction and are parallel to each other. Each of the grooves 60 and 61 may be formed in various shapes, but in the present embodiment, it is formed in a sawtooth shape. Here, the sawtooth refers to the shape of the groove portion on any cross section perpendicular to the longitudinal direction of the groove portions 60 and 61.

The first curved portion 10, the second curved portion 30, the first symmetrically curved portion 20 and the second symmetrically curved portion 40 are not connected to the connecting portion 50 at each end portion. Circular ends 13, 23, 33 and 43 are formed, respectively. Here, the circular ends 13, 23, 33, 43 have a substantially circular cross section perpendicular to one direction. The circular ends 13, 23, 33, and 43 have diameters of the first curved portion 10, the second curved portion 30, the first symmetric curved surface portion 20, and the second symmetric curved surface portion 40, respectively. Is greater than the thickness of.

Further, the distance between the end of the first curved portion 10 and the imaginary plane P is smaller than the distance between the end of the second curved portion 20 and the imaginary plane P.

In addition, the first curved portion 10, the second curved portion 30, the first symmetric curved portion 20, the second symmetric curved portion 40 and the connecting portion 50 are composed of one body. The pollutant suction element 100 is preferably manufactured by machining a metallic material such as aluminum.

On the other hand, the contaminant separating apparatus according to the present embodiment has a plurality of contaminant separating elements 100 as shown in FIG.

The plurality of contaminant separating elements 100 are divided into a plurality of contaminant separating elements forming a first row and a plurality of contaminant separating elements forming a second row, and the first row and the second row are arranged in parallel with each other. .

The plurality of contaminant separating elements 100 forming the first row may be disposed to be spaced apart from each other at equal intervals in the arrangement direction. The contaminant separating element 100 arranged in the first row has a first symmetric curved portion 20 and a second symmetry of another separating element adjacent to the first curved portion 10 and the second curved portion 30 of the separating element. It is disposed to face the curved portion 40, respectively.

The plurality of contaminant separating elements 100 forming the second row may also be arranged to be spaced apart from each other at equal intervals in the arrangement direction. The contaminant separating element 100 arranged in the second row has a first symmetric curved portion 20 and a second symmetry of another separating element adjacent to the first curved portion 10 and the second curved portion 30 of the separating element. It is disposed to face the curved portion 40, respectively.

In addition, the pollutant separating element 100 disposed in the second row is configured such that only a part of the pollutant separating element 100 is disposed between the pollutant separating elements 100 arranged in the first row. That is, each of the first curved portion 10, the first symmetric curved portion 20, and the connecting portion 50 of each of the pollutant separating elements 100 arranged in the second row has a pair of separating elements 100 arranged in the first row. And the first curved portion 10 and the first symmetric curved portion 20 of the separating element in the first row are in particular arranged between the second curved portion 20 and the second symmetric curved surface of the separating element in the second row. It is arranged to face each other between the parts (40).

Hereinafter, an example of a process of separating contaminants using the contaminant separating apparatus configured as described above will be described.

After the contaminant separating apparatus is configured as shown in FIG. 3, air containing contaminants is introduced in a direction perpendicular to the longitudinal direction L of the contaminant separating element 100 constituting the contaminant separating apparatus. Let's do it. When the air flows in this way, the air flows between the second curved portion 30 and the second symmetric curved surface portion 40 of the pollutant separating element 100 disposed in the first row, and then the pollutant disposed in the second row. It flows out between the second curved portion 30 and the second symmetric curved portion 40 of the separating element 100. Then, the air rotates through the rapid flow change as shown by the arrow in FIG. 3 while passing through the pollutant separating element 100 of the first row and the second row, and contaminates the air in the process. As the mass aggregates, the weight falls downward along the longitudinal direction of the pollutant separating element. Thus, contaminants are filtered out.

On the other hand, the condensation process of the pollutant is made through a three-step process as follows.

First, in the first step, the air supplied between the second curved portion 30 and the second symmetric curved surface portion 40 of the pollutant suction element 100 arranged in the first row, as shown in FIG. After hitting the third connecting surface 53 of the pollutant suction element 100 disposed in the second row, the direction is changed so that the second curved surface 12 and the second symmetry of the pollutant suction element 100 arranged in the second row Each of which is guided by the curved surface 22 and flows toward the third curved surface 31 and the third symmetric curved surface 41 of the pollutant suction element 100 disposed in the first row, respectively, to form turbulence. Thereafter, the air flowing toward the third curved surface rotates rapidly while contacting the third curved surface 31 and the circular end portion 33 of the pollutant suction element 100 disposed in the first row, and then disposed in the first row. The contaminant suction element flows toward the first curved surface, and the flow toward the first curved surface is guided by the first curved surface 11, the first connecting surface 51, and the third curved surface 31. At this time, the rapid rotation of the air is made with the help of the flow of air supplied to the pollutant suction element 100 disposed in the first row. On the other hand, the air flowing toward the third symmetric curved surface is also rapidly rotated in contact with the third symmetric curved surface 41 and the circular end 43 of the contaminant suction element disposed in the first row similar to the air flowing toward the third curved surface Afterwards, the contaminant suction element disposed in the first row flows toward the first symmetric curved surface, and the flow toward the first symmetric curved surface is performed by the first large symmetric curved surface 21, the second connecting surface 52, and the third symmetrical surface. Guided by curved surface 41. Even at this time, the rapid rotation of the air is made with the help of the flow of air supplied to the pollutant suction element 100 arranged in the first row. As described above, in the first step, the supplied air undergoes turbulent flow and rotational flow. In the process, contaminants in the air are agglomerated with each other. Fall down along the longitudinal direction (L) of the suction element. Therefore, the filtration operation by aggregation is performed in the first step.

Next, in the second step, as shown in FIG. 3, the air flowing toward the first curved surface is contaminated in the second row after being confronted with the first curved surface 11 and the circular end 13 and disposed in the second row. The first flow of the contaminant suction element disposed in the first row after the rapid rotation to the first curved surface of the intake element 100 and hitting the first curved surface 11 and the circular end 13 again in the flow process It flows toward three curved surfaces. At this time, the rotation of the air is made with the help of air flowing toward the first curved surface of the pollutant suction element 100 in the first row. On the other hand, the air flowing toward the first symmetrical curved surface is suddenly turned toward the first symmetrical curved surface of the pollutant suction element 100 arranged in the second row after the first symmetrical curved surface 21 and the circular end 23 hit the direction In the flow process, the first symmetric curved surface 21 and the circular end 23 is rotated rapidly and then rotates toward the third symmetric curved surface of the pollutant suction element 100 arranged in the first row. . Even at this time, the rotation of the air is made with the help of air flowing toward the first symmetric curved surface of the pollutant intake element 1000 of the first row. Thus, in the second step, the air accelerated in the first step has a higher speed. As it is further accelerated and rotates again rapidly, the micro-contaminants, especially liquid contaminants, which have not been agglomerated in the first step can be tensioned to make coagulation more effectively coercive with each other. In the second step, it is possible to aggregate and filter the foreign matter that has not been agglomerated in the first step.

Finally, in the third step, the air flowing toward the third curved surface impinges on the third curved surface 31 and the circular end 33 and is redirected so that the third connecting surface of the pollutant suction element disposed in the first row ( 53, and after hitting and rotating the third connecting surface 53 is guided by the second curved surface 12 is discharged to the outside. On the other hand, the air flowing toward the third symmetric curved surface hits the third symmetric curved surface 41 and the circular end portion 43 and is redirected to flow to the third connecting surface 53 of the pollutant suction element disposed in the first row. After being rotated by hitting the third connection surface 53, the second guide surface is guided by the second symmetric curved surface 22 and discharged to the outside. As described above, in the third step, as in the first step, condensation occurs between the contaminants by the rapid rotational flow of air, but the turbulent flow of the air is faster than in the first step. Coagulation is more effective than in.

As described above, in this embodiment, simply supplying the air containing the pollutants to the pollutant suction device, the air rotates to form a turbulence in the process of passing the air through the pollutant suction device, and the pollutants in the process Aggregates and falls by gravity. In particular, since it is configured to apply tension to the pollutants, it is possible to more effectively aggregate and filter the oil or liquid harmful substances. Here, tension is generated when the liquid contaminants rotate. That is, centrifugal force is generated when the pollutants in the liquid phase rotate, and the pollutants in the liquid phase are increased by the centrifugal force so that the tension acts on the pollutants in the liquid phase. In this way, when tension is generated and contaminants in the liquid phase increase, the interval between the contaminants in the liquid phase becomes narrower, so that condensation between the contaminants in the liquid phase can be made more effectively. Therefore, unlike the conventional art, it is possible to filter contaminants using a simple structure without using energy. In addition, it is possible to obtain better filtration performance without energy consumption compared with the prior art.

In addition, the grooves are formed in the first curved surface 11, the first connecting surface 51, the third curved surface 31, the first symmetric curved surface 21, the second connecting surface 52, and the third symmetric curved surface 41. By forming 60, 61, it is possible to increase the flow rate of the air, thereby making it easier to form a turbulent flow in the air to aggregate the contaminants with higher efficiency.

Meanwhile, as illustrated in FIG. 4, the pollutant suction element may be configured.

Referring to FIG. 4, the pollutant suction element 100a according to the present exemplary embodiment corresponds to half of the pollutant suction element described with reference to FIGS. 1 and 2. That is, the pollutant suction element 100a includes the first curved portion 10, the second curved portion 30, and the connecting portion 50a as a body. Here, the connecting portion 50a includes a connecting surface 51 connecting the first curved surface 11 and the third curved surface 31, and also includes a pair of semicircular connecting surfaces 55 and 56 which are formed in a semicircular shape as a whole. do. Therefore, when the pair of contaminant suction elements 100a of the present embodiment are bonded to or disposed in contact with each other, the contaminant suction element 100 shown in FIGS. 1 and 2 may be configured.

As mentioned above, the present invention has been described in detail with reference to preferred embodiments, but the present invention is not limited to the above embodiments, and various modifications may be made by those skilled in the art within the technical idea of the present invention. It is obvious.

1 is a schematic perspective view of a contaminant separating element according to an embodiment of the present invention.

FIG. 2 is a schematic plan view of the contaminant separating element shown in FIG. 1.

3 is a schematic plan view of a contaminant separating apparatus according to an embodiment of the present invention.

4 is a schematic plan view of a contaminant separating element according to another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10 ... first surface part 11 ... first surface

12 ... 2nd curved surface 13,23,33,43 ... round end

20 ... first symmetric surface 21 ... first symmetric surface

22 ... 2nd Symmetrical Surface 30 ... 2nd Curved Surface

31 ... 3rd surface 32 ... 4th surface

40.2nd symmetrical surface 41 ... 3rd symmetrical surface

42 4th symmetrical surface 50,50a ...

51 ... first connection plane 52 ... second connection plane

53 ... 3rd connection surface 54 ... 4th connection surface

55,56 Semi-circular interface 100,100a ... Contaminant separation element

Claims (6)

In order to separate the contaminants of the liquid from the air by condensing the liquid contaminants contained in the air to fall in the direction of gravity, It is formed in one direction elongated, and includes a first curved surface formed to be curved in a direction crossing with respect to the one direction and a second curved surface facing the direction opposite to the direction toward which the first curved surface and having the same radius of curvature as the first curved surface, A first curved portion formed such that arbitrary cross sections perpendicular to the one direction are the same; It is symmetric about an imaginary plane formed between the first curved portion, is formed long in the same direction as the one direction, is formed curved in a direction crossing the one direction and the same curvature as the first curved surface A first radius of symmetry with respect to the first curved surface and a direction opposite to a direction in which the first symmetry curved surface faces, and a radius of curvature equal to that of the first symmetry curved surface, A first symmetric curved surface portion including a second symmetric curved surface symmetrical with the second curved surface with respect to a plane, and having arbitrary cross sections perpendicular to the one direction; The first curved surface is formed in the same direction as the one direction, the first curved surface is formed to be curved in the same direction as the curved direction and the third curved surface having a radius of curvature larger than the radius of curvature of the first curved surface and the third curved surface facing A second curved portion facing a direction opposite to a direction and including a fourth curved surface having the same radius of curvature as the third curved surface, wherein any of the cross sections perpendicular to the one direction are the same; It is symmetric about the imaginary plane, is formed long in the same direction as the one direction, is formed to be curved in a direction crossing the one direction, has the same radius of curvature as the third curved surface and has a center of the imaginary plane The third symmetric curved surface symmetrical to the third curved surface and the third symmetric curved surface facing in the opposite direction to the direction and has the same curvature radius as the third symmetric curved surface and the fourth curved surface around the imaginary plane A second symmetric curved surface portion including a symmetrical fourth symmetric curved surface and formed such that any cross sections perpendicular to the one direction are identical to each other; And Is formed long in the same direction as the one direction, connecting the first curved surface and the third curved surface and the first connection surface made of a curved surface or planar shape, and the first symmetric curved surface and the third symmetric curved surface and the curved surface or planar shape And a second connection surface formed to face the direction opposite to the direction in which the first connection surface is directed, and having the same radius of curvature as the first connection surface, and connecting the second curved surface and the second symmetric curved surface to have a curved shape. And a third connection surface consisting of a third connection surface and a fourth connection surface connecting the fourth curved surface and the fourth symmetric curved surface, and having a fourth connection surface formed in a curved shape, and having any cross section perpendicular to the one direction being the same as each other. , The first curved surface portion, the second curved surface portion, the first symmetric curved surface portion, the second symmetric curved surface portion and the connecting portion is characterized in that it consists of a body. The method of claim 1, The first curved surface, the first connecting surface, the third curved surface, the first symmetrical curved surface, the second connecting surface and the third symmetrical curved surface are each formed long in the one direction and a plurality of grooves parallel to each other is provided Pollutant separation element. The method of claim 1, A distance between the virtual plane and an end of the first curved portion that is not connected to the connecting portion is smaller than a distance between the virtual plane and an end of the second curved portion that is not connected to the connecting portion. Pollutant separation element. The method of claim 1, Ends of the first curved portion, the second curved portion, the first symmetric curved portion, and the second symmetric curved portion that are not connected to the connecting portion have a circular cross section perpendicular to the one direction, respectively. And a circular end formed to have a diameter larger than a thickness of each of the first curved portion, the second curved portion, the first symmetric curved portion, and the second symmetric curved portion. In order to separate the contaminants of the liquid from the air by condensing the liquid contaminants contained in the air to fall in the direction of gravity, It is formed in one direction elongated, and includes a first curved surface formed to be curved in a direction crossing with respect to the one direction and a second curved surface facing the direction opposite to the direction toward which the first curved surface and having the same radius of curvature as the first curved surface, A first curved portion formed such that arbitrary cross sections perpendicular to the one direction are the same; The first curved surface is formed in the same direction as the one direction, the first curved surface is formed to be curved in the same direction as the curved direction and the third curved surface having a radius of curvature larger than the radius of curvature of the first curved surface and the third curved surface facing A second curved portion facing a direction opposite to a direction and including a fourth curved surface having the same radius of curvature as the third curved surface, wherein any of the cross sections perpendicular to the one direction are the same; Connecting to the first curved portion and the second curved portion, is formed long in the same direction as the one direction, connecting the first curved surface and the third curved surface and the curved surface or planar shape and in one direction And a connecting portion formed such that any cross sections perpendicular to each other are the same. The first curved portion, the second curved portion and the connecting portion is composed of a body, The first curved surface, the connecting surface and the third curved surface is formed in each of the elongated in one direction and a plurality of grooves parallel to each other is provided with a pollutant separation element, characterized in that. A plurality of contaminant separating element according to any one of claims 1 to 4, The plurality of separating elements are divided into a plurality of separating elements forming a first row and a plurality of separating elements forming a second row. Any pair of adjacent separating elements of the plurality of separating elements forming the first row may include a first symmetrically curved portion and a first curved portion and a second curved portion of the other separating element. It is arranged to face each other with the two symmetric curved surface, Any one pair of adjacent separating elements of the plurality of separating elements forming the second row may include a first symmetric curved portion and a first curved portion and a second curved portion of the other separating element. It is arranged to face each other with the two symmetric curved surface, The first curved portion, the first symmetric curved surface portion, and the connecting portion of each of the separation elements forming the second row are disposed between a pair of separation elements adjacent to each other among the separation elements forming the first row, and the separation elements on the first row. A first curved portion and a first symmetric curved portion of the second columnar arrangement is disposed between the second curved portion and the second symmetric curved surface portion, A plurality of separation elements and a second row forming the first row of air containing contaminants in a liquid phase from any one of the plurality of separation elements forming the first row and the plurality of separation elements forming the second row When supplied to the other one of the plurality of separation elements forming the separation element, the contaminants of the liquid phase in the process of passing through the separation element of the first row and the separation element of the second row are mutually coagulated and fall in the direction of gravity Air discharged from the separation element is a pollutant separation device, characterized in that discharged in a state in which the contaminant of the liquid phase is removed.

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