KR101999243B1 - Purifying apparatus for chimney - Google Patents

Abstract

The present invention relates to a purifying apparatus for a chimney and, more specifically, to a purifying apparatus for a chimney, which comprises: a roof unit installed on an upper end of the chimney; a purification unit connected to the roof unit through a first pipe and configured to purify exhaust gas introduced from the roof unit; and an air blowing unit connected to the purification unit through a second pipe and configured to guide a flow of the exhaust gas. The purification unit comprises: a housing; a plurality of first filters vertically installed in the housing and configured to filter out contaminants included in the exhaust gas; and a plurality of first and second air pipes, each of which is separately installed in a vertical direction at a rear side of each first filter and configured to inject air to a rear surface of each first filter to detach the contaminants from the first filter, wherein both ends of each of the first and second air pipes are coupled, using a bearing, to both side walls of the housing and accordingly, are rotated at a predetermined angle by a first rotation means, thereby increasing an air-injected area for each filter, and thus, it is possible to more effectively remove the contaminants attached to the filters.

Description

[0001] Purifying apparatus for chimney [

[0001] The present invention relates to a chimney purifier, and more particularly, to a chimney purifier that can rotate the first air pipe and the second air pipe at a predetermined angle by rotating means, And more particularly, to a chimney purifier capable of more effectively removing contaminants attached to a filter.

Generally, a factory, a manufacturing facility, a ship, etc. have a chimney for discharging exhaust gas, and the exhaust gas generated by the operation of various mechanical devices is discharged to the atmosphere through the chimney.

The exhaust gas discharged to the atmosphere through the chimney contains various pollutants that pollute the atmosphere, and the environmental pollution problem that is caused by such pollutants is becoming an international issue as well as Korea.

As a solution to this problem, various solutions have been suggested. One of the solutions is known as a technique of purifying contaminants contained in exhaust gas and exhausting the exhaust gas to the atmosphere.

In this connection, Korean Patent Application No. 20-1972-0003223 discloses a technique relating to a chimney purifier, and such a conventional purifier for purifying chimney has a structure in which a chimney 1 The separation tower 9 is connected to the upper end and the exhaust pipe 3 is connected to the outer periphery thereof in four directions so as to be piped to the lower purification tank 2. In the lower end side of the collection pipe 3, 5 ', 5 "and 5"' in the washing chamber 2 'into which the water 2' 'is inserted and the water tubes 4' and 4 ' The air pipe 6 'on the opposite side of the puddle is vertically installed on the lower end side of the exhaust pipe 6 installed to communicate with the cleaning chamber 2' of the one side purification tank 2, (10) to blow air.

However, in such a conventional chimney purifier, when the soot discharged from the chimney is purified for a long time, the exhaust of the soot filtered by the filter net is excessively adhered to the filter net, thereby deteriorating the overall purifying efficiency of the apparatus.

In addition, in the conventional chimney purifier, when a certain amount or more of the solder is attached to the filter net, the filter net needs to be replaced occasionally, resulting in an excessive cost.

Korean Patent Application No. 20-1972-0003223

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide an air- It is an object of the present invention to provide a chimney purifier capable of more effectively removing contaminants attached to a filter.

According to an aspect of the present invention, there is provided a chimney purifier including: a roof part installed at an upper end of a chimney; A purifier connected to the roof part through a first pipe to purify the exhaust gas introduced from the roof part; And a blowing unit connected to the purifying unit and the second pipe to guide the flow of the exhaust gas, the purifying unit including: a housing; A plurality of first filters installed vertically inside the housing to filter contaminants contained in the exhaust gas; A plurality of first and second air pipes spaced apart from each other on the rear side of the first filter and jetting air to the back surface of each of the first filters to remove the pollutants from the first filter; Wherein both ends of the first and second air pipes are coupled to both side walls of the housing by bearings and are rotated at a predetermined angle by the first rotating means.

The first rotating unit may include: a first air cylinder fixedly installed on an outer surface of a side wall of the housing; A first link that linearly reciprocates in a horizontal direction by the first air cylinder; The first air pipe is hinged to an upper portion of the first link through a first long hole formed on one side and the other side is integrally fixed to the first air pipe to rotate each first air pipe in accordance with a linear reciprocating motion of the first link. A plurality of second links for providing a plurality of second links; And the other end is hinged to the lower portion of the first link through a second slot formed on one side and the other end is integrally fixed to the second air pipe so as to rotate each of the second air pipes in accordance with the linear reciprocating motion of the first link And a plurality of third links which are connected to each other.

The first link may be formed with a guide hole extending in the horizontal direction, a protruding guide pin may be formed on the outer surface of the side wall of the housing, the guide pin may be inserted into the guide hole, So as to be reciprocated linearly by a predetermined distance.

The first air pipe may include a plurality of first air injection holes formed in a single row, and the second air pipe may include a plurality of second air injection holes formed in a single row, the first air injection holes formed in one row, And the second air injection holes are arranged to be shifted from each other.

In addition, the housing is provided with a partition plate for partitioning the internal space into an upper purification chamber and a lower exhaust chamber, and the partition plate is provided in front of each of the first filters, And a door is provided in each of the inlet ports, the doors being opened and closed by the opening and closing means, respectively.

Further, the opening / closing means includes: a plurality of fourth links integrally fixed to one side of the rotary shaft of each door; A fifth link hinged across the other side of each of the fourth links; And a second air cylinder rotatably installed on an outer surface of the side wall of the housing and having a rod hinged to any one of the fourth links.

Further, the door is characterized in that a rubber plate is padded to protrude outward in the horizontal direction from the front side upper edge and the rear side edge from the center with respect to the rotation axis at the center.

Further, a water supply pipe is installed along the inner peripheral surface of the discharge chamber.

Further, a discharge port is formed at one side of the inner bottom surface of the discharge chamber, and the bottom surface is formed to be inclined to be lower toward the discharge port.

In addition, an exhaust part communicating with the purifying chamber is formed on the upper surface of the housing, a second filter for filtering contaminants contained in the exhaust gas is installed in the exhaust part in the horizontal direction, Third and fourth air pipes are spaced apart from each other to blow air onto the upper surface of the second filter so as to detach the pollutants from the second filter, and the third and fourth air pipes serve as bearings on both side walls of the exhaust part And both ends are coupled and rotated at a predetermined angle by the second rotating means.

The second rotating means may include a third air cylinder fixedly installed on the outer surface of the side wall of the housing; A sixth link reciprocating in a vertical direction by the third air cylinder; And the other end is fixed integrally with the third air pipe to rotate the third air pipe in accordance with a linear reciprocating motion of the sixth link. The third air pipe is hinged to the front portion of the sixth link through a third hole formed on one side, A seventh link; The fourth air pipe being hinged to a rear portion of the sixth link through a fourth slot formed on one side and the other side being integrally fixed to the fourth air pipe to rotate the fourth air pipe in accordance with a linear reciprocating motion of the sixth link And an eighth link.

In addition, the partition plate is further provided with a charging port at a portion opposed to the second filter, and the charging port is further provided with the door, and is opened / closed by the opening / closing means.

The chimney purifier according to the present invention has the following advantages.

The chimney purifier according to the present invention has an advantage that the overall purifying efficiency of the apparatus can be improved by jetting air onto the back surface of the filter to remove contaminants adhering to the filter.

The chimney purifier according to the present invention has an advantage that it can increase the air injection area for the filter and can more effectively remove contaminants attached to the filter.

Since the chimney purifier according to the present invention can remove pollutants adhered to the filter, it is possible to reduce the replacement period of the filter and reduce the cost.

The chimney purifier according to the present invention can isolate contaminants that have been removed from the filter from the purifying chamber, thereby preventing the discharged contaminants from being scattered in the purifying chamber.

The chimney purifier according to the present invention can rotate a plurality of first and second air pipes using one first air cylinder, thereby reducing the overall manufacturing cost of the apparatus.

1 is a side view showing a part of a conventional chimney purifier.
2 is a perspective view showing a state of installation of a chimney purifier according to a preferred embodiment of the present invention;
3 is a perspective view showing the inside of a purifier of a chimney purifier according to a preferred embodiment of the present invention.
4 is an enlarged perspective view of an enlarged view of a portion A in Fig.
Fig. 5 is a perspective view showing the opposite side of Fig. 3; Fig.
6 is a use state diagram schematically showing the operation of the first rotating means of the chimney purifier according to the preferred embodiment of the present invention.
FIG. 7 is a schematic view showing a state in which a first air pipe and a second air pipe of a chimney purifier according to a preferred embodiment of the present invention are rotated. FIG.
8 is a cross-sectional view schematically showing the arrangement of the first air injection hole and the second air injection hole in the chimney purifier according to the preferred embodiment of the present invention.
9 to 11 are explanatory views schematically showing a state in which a door is opened and closed as the opening and closing means of the chimney purifier according to the preferred embodiment of the present invention operates.

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

For reference, the same components as those of the prior art of the present invention will be described with reference to the above-mentioned prior arts, and a detailed description thereof will be omitted.

The front, rear, left and right directions described in the following description are the front side of the intake port side of Fig. 3, the rear side of the intake port, the left side of the first rotation means, and the right side of the opposite side of the first rotation means.

FIG. 2 is a perspective view of a chimney purifier according to a preferred embodiment of the present invention, and FIG. 3 is a perspective view of the chimney purifier according to a preferred embodiment of the present invention, FIG. 4 is an enlarged perspective view enlargedly showing a portion A in FIG. 3, FIG. 5 is a perspective view showing the opposite side of FIG. 3, and FIG. 6 is a perspective view of a chimney purifier according to a preferred embodiment of the present invention 7 is a schematic view showing a state in which the first air pipe and the second air pipe of the chimney purifier according to the preferred embodiment of the present invention are rotated, 8 is a cross-sectional view schematically showing an arrangement state of the first air injection hole and the second air injection hole in the chimney purifier according to the preferred embodiment of the present invention, and Figs. 9 to 11 are cross- It is used a simplified view of the state in which the door is opened and closed state diagram as the opening and closing means of the flue purification apparatus for operation in accordance with the probable embodiment.

2 to 11, a chimney purifier according to a preferred embodiment of the present invention includes a roof part 100 installed at an upper end of a chimney C; A purifier (200) connected to the roof part (100) and the first pipe (P1) to purify the exhaust gas flowing from the roof part (100); And a blowing unit 300 connected to the purifying unit 200 and the second pipe P2 to guide the flow of the exhaust gas. The purifying unit 200 includes a housing 210; A plurality of first filters (F1) installed vertically inside the housing (210) to filter contaminants contained in the exhaust gas; A plurality of first and second filters F1 and F2 disposed vertically on the rear side of the respective first filters F1 and discharging contaminants from the first filter F1 by spraying air on the back surfaces of the respective first filters F1, The first and second air pipes 221 and 223 are connected to both side walls of the housing 210 by bearings B so that the first and second air pipes 221 and 223 are connected to the first rotating means 230 ) At a certain angle.

2, the chimney purifier according to the preferred embodiment of the present invention includes a roof part 100, a purifier 200, and a blower 300.

The roof part 100 is formed in a conical shape and installed at the upper end of the chimney C.

The roof part 100 is installed so as to cover the upper end of the chimney C and accommodates the exhaust gas discharged from the chimney C therein. Through holes (not shown) are formed so that the gas can be sent to the purifying unit 200 to be described later.

The roof part 100 is fixed to the upper part of the chimney C by a supporting frame 11 which is installed vertically in the vertical direction along the height of the chimney C and the supporting frame 11 is fixed to the lower part of the roof part 100 (Not shown) and may be fixed to the outer peripheral surface of the chimney by a separate fixing mechanism (not shown).

It is preferable that the roof part 100 is installed such that there is a clearance between the roof part 100 and the chimney C for smooth flow of the exhaust gas introduced by the blowing part 300 to be described later.

On the other hand, the purifier 200 is connected to the roof part 100.

The purifying unit 200 is configured to purify the exhaust gas flowing from the roof part 100 and includes a roof part 100 so that the exhaust gas inside the roof part 100 can be sucked into the purifying part 200, And the first pipe P1.

More specifically, one end of the first pipe P1 is fitted and fixed in a through hole (not shown) of the roof part 100 and the other end of the first pipe P1 is connected to the intake port 210a formed in the purifying part 200. [ The roof part 100 and the purifying part 200 are communicated with each other by the first pipe P1 so that the exhaust gas can flow from the roof part 100 to the purifying part 200 through the first pipe P1.

The purifying unit 200 may be installed on one side and the other side of the mounting surface 12 so as to be adjacent to the chimney C but the number of the purifying units 200 may vary depending on the amount of exhaust gas to be purified .

On the other hand, the purifier unit 200 is connected to a blower unit 300.

The blowing section 300 is provided for forcibly guiding the flow of exhaust gas discharged from the chimney C to the exhaust hole of the blowing section 300 through the operation of a fan (not shown) and a motor (not shown) The purifier 200 and the second pipe P2 are connected to the exhaust pipe 300 so that the exhaust gas discharged from the chimney C can be discharged from the roof part 100 to the outside of the blowing part 300 through the purifying part 200 .

More specifically, one end of the second pipe P2 is fitted and fixed to the exhaust port 271 of the purifier 200 and the other end of the second pipe P2 is connected to an intake hole (not shown) The purifier unit 200 and the airflow guide unit 300 are communicated with each other by the second pipe P2 through which the exhaust gas flows from the roof part 100 to the purifier unit 200 through the purifier unit 200, So that the exhaust gas can be exhausted to the exhaust hole of the engine.

The blowing unit 300 may be installed on one side and the other side of the installation surface 12 so as to be adjacent to the chimney C in the same manner as the purifying unit 200. The number of the blowing units 300 may be different from that of the purifying unit 200, As shown in FIG.

3 to 5, the purifying unit 200 includes a housing 210, a first filter F1, first and second air pipes 221 and 223, and a first rotating unit 230 .

The housing 210 is configured to form an appearance of the purifier 200, and a space is provided therein.

The housing 210 is formed in the shape of a rectangular parallelepiped as a whole, and is disposed on the mounting surface 12 by a support L formed at four corners of the lower end.

An intake port 210a for sucking exhaust gas from the roof part 100 to the inner space of the housing 210 is formed on the front surface of the housing 210. One end of the intake port 210a is connected to the roof part 100 And the other end of the first pipe P1 is connected.

A control valve (not shown) for opening and closing the flow of exhaust gas may be installed in the intake port 210a or the first pipe P1.

A partition plate 211 is provided in a horizontal direction near the inner center of the housing 210. The partition plate 211 guides the inner space of the housing 210 to the upper purifying chamber 213 and the lower exhaust chamber 215, .

The purifying chamber 213 is a part for purifying the exhaust gas discharged from the chimney C and provided with a first filter F1 and first and second air pipes 221 and 223 to be described later, Is a portion for isolating the pollutants separated from the first filter (F1) to be described later and discharging them to the outside.

The partition plate 211 is provided with a plurality of inlet ports 211a.

The inlet 211a is a rectangular hole penetrating the partition plate 211 up and down, and is a hole through which contaminants separated from the first filter F1 to be described later are injected.

A plurality of inlet ports 211a are formed to be spaced apart from each other in the front and rear directions and disposed one by one in front of each of the first filters F1 to be described later so that contaminants separated from each of the first filters F1 are introduced into the discharge chamber 215 .

Each of the input ports 211a is provided with a door 240 which is opened and closed by the opening / closing means 250, as will be described later.

On the other hand, a discharge port 215b is formed at one side of the bottom surface 215a of the discharge chamber 215 so as to communicate with the discharge chamber 215 and the outside.

The discharge port 215b is an opening for discharging pollutants and water for washing pollutants to the outside, and the discharge port 215b may be connected to a separate discharge pipe (not shown).

A control valve (not shown) is installed in the discharge port 215b or the discharge pipe (not shown) to close the discharge port 215b when the exhaust gas is purified. As a result, the door 240, It is possible to prevent air from being sucked through the discharge port 215b and to prevent the suction force of the discharge portion 300 from being deteriorated.

A control valve (not shown) provided in the exhaust port 215b or the exhaust pipe (not shown) is closed during the purification process of the exhaust gas, while the intake port 210a or the control valve It is preferable that the catalyst is opened during the purification process of the exhaust gas.

The control valve (not shown) provided in the discharge port 215b or the discharge pipe (not shown) is opened during the cleaning process of the first filter F1 and the second filter F2 which will be described later with air, It is preferable that the control valve (not shown) provided on the first pipe 210a or the first pipe P1 is closed during the cleaning process of the first filter F1 and the second filter F2 which will be described later with air.

The bottom surface 215a of the discharge chamber 215 is formed to be inclined so as to be lowered toward the discharge port 215b.

That is, the bottom surface 215a of the discharge chamber 215 is inclined in such a manner that its circumference decreases from the upper side to the lower side, and the discharge port 215b is formed at the lower end thereof, The water to be washed is naturally discharged to the discharge port 215b.

In the discharge chamber 215, the water supply pipe 260 is installed in a 'K' shape when viewed in a plan view over the inner circumferential surface of the discharge chamber 215.

The water supply pipe 260 is a circular pipe, and water spray holes 261 are formed at regular intervals along the inner circumferential surface.

The water supply pipe 260 is connected to a water supply means (not shown) for spraying water into the discharge chamber 215.

When water is supplied by water supply means (not shown), water is sprayed through a plurality of water spray holes 261 to wash out contaminants introduced into the discharge chamber 215 and to discharge water through the discharge port 215b To be discharged to the outside.

On the upper surface of the rear side of the housing 210, an exhaust part 270 is formed.

The exhaust part 270 is formed in the shape of a rectangular parallelepiped, has an exhaust port 271 formed at an upper end thereof, and is installed to communicate with the purifying chamber 213.

The exhaust unit 270 is formed to exhaust the exhaust gas purified in the purification chamber 213 through the exhaust port 271 to the outside of the purification unit 200. The exhaust gas discharged through the exhaust port 271 is introduced into the second pipe P2 and flows toward the airflow 300 side.

On the other hand, a first filter (F1) is installed inside the housing (210).

The first filter F1 is configured to filter pollutants of the exhaust gas sucked into the inner space of the housing 210 through the intake port 210a. The first filter F1 is disposed inside the housing 210, more specifically, Direction.

The first filter F1 is preferably provided at the same longitudinal cross-sectional area as the longitudinal direction of the purifying chamber 213 and is provided on the upper surface of the partition plate 211, the inner surface of the upper wall of the housing 210, The inner wall of the left side wall, and the inner side wall of the right side wall of the housing 210.

In the present invention, three first filters (F1) are installed at regular intervals in the path along which the exhaust gas flows, and the exhaust gas sucked through the intake port (210a) sequentially passes through the three first filters (F1) The contaminants contained in the exhaust gas are adhered to the front of each first filter F1 and filtered.

At this time, each of the first filters F1 may be composed of different kinds or may be composed of the same kind as necessary. In the present invention, the first front filter F1 of the three first filters F1 is a demister filter The first filter F1 at the center is a medium filter, and the rearmost first filter F1 is a medium filter.

On the other hand, a plurality of first air pipes 221 and a plurality of second air pipes 223 are provided on the rear side of each first filter F1.

The first air pipe 221 and the second air pipe 223 are configured to air pollute the pollutants accumulated in the first filter F1 after the purification process of the exhaust gas is finished.

That is, the first air pipe 221 and the second air pipe 223 are filtered by the first filter F1 through the injection of air, and the pollutant attached to the front surface of the first filter F1 is filtered by the first filter F1, And is disposed in the purifying chamber 213 so as to be vertically spaced on the rear side of each first filter F1.

That is, one first air pipe 221 and one second air pipe 223 disposed directly below the first air pipe 221 are vertically spaced apart from each other, and a pair of first air pipes 221, And the second air pipe 223 are provided so as to be arranged one behind each of the three first filters F1.

The first air pipe 221 and the second air pipe 223 are preferably spaced a predetermined distance from the back surface of the first filter F1.

The first air pipe 221 is a long circular tube, and a plurality of first air injection holes 221a are formed in a single row at regular intervals along the longitudinal direction.

The left end of the first air pipe 221 is connected to the air supply means (not shown) and the right end thereof is closed. The left end and the right end of the first air pipe 221 are connected to the left And is rotatably mounted in a clockwise or counterclockwise direction.

The first air pipe 221 is provided on the rear side of the first filter F1 so as to be disposed at a height between the upper end and the center of the first filter F1. When air is supplied from the air supply means (not shown) Air is sprayed to the back surface (rear surface) of the first filter F1 through the air injection hole 221a.

The second air pipe 223 is a circular tube elongated in the left and right direction, and a plurality of second air injection holes 223a are formed in one row at regular intervals along the length direction.

8, the second air injection holes 223a formed in one row are arranged to be offset from the first air injection holes 221a formed in a single row. More specifically, the second air injection holes 223a, And the first air injection holes 221a are formed opposite to the portions between the two second air injection holes 223a closest to each other. .

The reason why the first air injection hole 221a and the second air injection hole 223a have such an arrangement is that the air is uniformly sprayed over the entire area of the rear surface of the first filter F1.

In the present embodiment, the first air injection hole 221a and the second air injection hole 223a are formed to have the same diameter from the front side to the rear side. However, if necessary, the diameter is gradually decreased from the front side to the rear side And the diameter of the air is gradually increased from the front side to the rear side to increase the injection pressure of the air. This increases the injection pressure of the air, (Not shown) of the fourth air pipe 283 and a fourth air injection hole (not shown) of the fourth air pipe 283.

Similarly to the first air pipe 221, the second air pipe 223 is opened at its left end and connected to air supply means (not shown), and its right end is closed. The left end and the right end are connected to a bearing B To be coupled to the left and right walls of the housing 210 to be rotatable in a clockwise or counterclockwise direction.

The second air pipe 223 is provided on the rear side of the first filter F1 so as to be disposed at a height between the lower end and the center of the first filter F1 and is supplied with air from the air supply means Air is sprayed to the rear surface (rear surface) of the first filter F1 through the air injection hole 223a.

On the other hand, the first air pipe 221 and the second air pipe 223 are rotated by the first rotating means 230.

The first rotating means 230 may include a first air pipe 221 and a second air pipe 223 for increasing the air injection range of the first air pipe 221 and the second air pipe 223 during air injection to the first filter F1, And the second air pipe 223 is rotated at a predetermined angle.

The first rotating means 230 includes a first air cylinder 231, a first link 233, a second link 235 and a third link 237.

The first air cylinder 231 is a movable part for moving the first rotating means 230, and is fixed long before and behind the outer surface of the left side wall of the housing 210.

The first air cylinder 231 is provided with a rod which can reciprocate linearly in the horizontal direction, that is, forward and backward.

The first link 233 is coupled to the rod of the first air cylinder 231.

The first link 233 is fixed to the front end of the rod of the first air cylinder 231 and linearly reciprocates forward and backward in the horizontal direction in accordance with the movement of the rod of the first air cylinder 231.

The front portion and the rear portion of the first link 233 penetrate right and left, and one guide hole 233a formed long before and after is formed.

Two guide pins 217 protruding from the outer surface of the left side wall of the housing 210 are inserted into the respective guide holes 233a and each of the guide holes 233a is guided by corresponding guide pins 217 So that the linear reciprocating motion of the first link 233 can be accurately performed by a predetermined stroke distance (length before and after the guide hole).

At this time, a separate washer (not shown) may be fixed to the left end of the guide pin 217 to prevent the first link 233 from coming off.

On the upper portion of the first link 233, three upward protruding portions protruding upward are formed at regular intervals, and a first hinge shaft 233b is fixedly mounted on each of the upper protruding portions. The number of the hinge shafts 233b may vary corresponding to the number of the first air pipes 221.

In addition, three lower protruding portions protruding downward are formed at a lower portion of the first link 233, and a second hinge shaft 233c is fixedly mounted on each of the upper protruding portions. The number of the second hinge shafts 233c may be varied corresponding to the number of the second air pipes 223. [

Each of the upper protrusions and each of the lower protrusions are symmetrical with respect to each other, and each of the first hinge axis 233b and each second hinge axis 233c is formed to be symmetrical with respect to each other .

A plurality of second links 235 and a plurality of third links 237 are hinged to the first link 233.

The second link 235 is a member connecting the first link 233 and the first air pipe 221, and a plurality of the second links 235 are provided corresponding to the respective upper protrusions. In this embodiment, three are provided.

Each of the second links 235 has a first long hole 235a formed along the longitudinal direction on the lower end side thereof and is hinged to the respective first hinge shafts 233b and an upper end side thereof is connected to each of the first air pipes 221 As shown in Fig.

The first long hole 235a is formed to convert the linear movement of the first link 233 into the rotational movement of the second link 235. [

The second link 235 rotates in the clockwise direction when the first link 233 linearly moves forward and is fixed to the second link 235 integrally with the second link 235 as the second link 235 rotates clockwise The first air pipe 221 also rotates clockwise.

The second link 235 rotates counterclockwise when the first link 233 moves linearly toward the rear side and the second link 235 rotates counterclockwise as the second link 235 rotates counterclockwise. The first air pipe 221 fixed integrally with the first air pipe 221 also rotates counterclockwise.

The third link 237 is a member connecting the first link 233 and the second air pipe 223, and a plurality of the third links 237 are provided corresponding to the respective lower protrusions. In this embodiment, three are provided.

Each of the third links 237 is formed with a first long hole 235a along the longitudinal direction on the upper end side and is hinged to the respective second hinge shafts 233c and the lower end side is connected to the respective second air pipes 223 As shown in Fig.

The second long hole 237a is formed to convert the linear motion of the first link 233 into the rotational motion of the third link 237. [

The third link 237 rotates counterclockwise when the first link 233 linearly moves toward the front side and the third link 237 rotates counterclockwise when the first link 233 linearly moves forward, And the second air pipe 223 fixed to the second air pipe 223 also rotates counterclockwise.

The third link 237 rotates in the clockwise direction when the first link 233 linearly moves to the rear side and the third link 237 rotates clockwise as the third link 237 rotates clockwise, The second air pipe 223 fixed to the second air pipe 223 also rotates clockwise.

The rotation of the second link 235 and the third link 237 proceeds simultaneously in opposite directions in accordance with the linear reciprocating motion of the first link 233.

6 (a) and 7 (a), the rod of the first air cylinder 231 moves the first link 233 forward The first air blowing hole 221a of the first air pipe 221 and the second air blowing hole 223a of the second air pipe 223 are formed in a state of pushing the first air pipe 221 as far as possible (the guide pin is positioned at the rear end of the guide hole) Are positioned opposite to the back surface of the first filter (F1) by about 45 degrees from the upper side and the lower side, respectively.

In this state, when the first air cylinder 231 pulls the first link 233 to the rear side by half the length of the guide hole 233a (the guide pin is positioned at the center of the guide hole) the first hinge shaft 233b is linearly moved from the lower end to the upper end in the first long hole 235a so that the second link 235 rotates counterclockwise about 45 degrees, At the same time, the second hinge shaft 233c linearly moves from the upper end to the lower end in the second long hole 237a, and the third link 237 rotates clockwise by about 45 degrees. Accordingly, the first air pipe 221 And the second air injection holes 223a of the second air pipe 223 are positioned facing the front side of the first filter F1 so as to face the rear face of the first filter F1 .

In this state, when the first air cylinder 231 further pulls the first link 233 to the rear side by half of the length of the guide hole 233a (the guide pin is positioned at the front end of the guide hole) The first hinge shaft 233b is linearly moved from the upper end to the lower end in the first long hole 235a so that the second link 235 rotates counterclockwise about 45 degrees as shown in FIG. 7 (c) At the same time, the second hinge shaft 233c linearly moves from the lower end to the upper end in the second long hole 237a, thereby rotating the third link 237 clockwise by about 45 degrees, The first air injection hole 221a of the second air pipe 221 and the second air injection hole 223a of the second air pipe 223 are rotated by about 45 degrees from the bottom of the first filter F1 .

In this state, when the first air cylinder 231 pushes the first link 233 forward (the guide pin is located at the center of the guide hole) by half the length of the guide hole 233a, the first hinge shaft 233b is linearly moved from the lower end to the upper end in the first long hole 235a so that the second link 235 rotates clockwise by about 45 degrees, At the same time, the second hinge shaft 233c linearly moves from the upper end to the lower end in the second long hole 237a, and the third link 237 rotates counterclockwise about 45 degrees, And the second air injection holes 223a of the second air pipe 223 are positioned facing the front side of the first filter F1 so as to face the rear face of the first filter F1 .

In this state, when the first air cylinder 231 further pushes the first link 233 forward (the guide pin is positioned at the rear end of the guide hole) by half the length of the guide hole 233a, 7 (a), the first hinge shaft 233b linearly moves from the upper end to the lower end in the first long hole 235a, and the second link 235 rotates clockwise by about 45 degrees, At the same time, the second hinge shaft 233c is linearly moved from the lower end to the upper end in the second long hole 237a, and the third link 237 is rotated counterclockwise about 45 degrees, The first air injection hole 221a of the second air pipe 221 and the second air injection hole 223a of the second air pipe 223 rotate about 45 degrees to the upper side and the lower side respectively opposite to the back surface of the first filter F1 .

The first air pipe 221 and the second air pipe 223 are configured to be rotatable at a certain angle due to the above-described operations, so that the air jet range to the back surface of the first filter F1 can be increased, It is possible to effectively remove contaminants attached to the front surface of the first filter F1 from the first filter F1.

On the other hand, doors 240 are respectively installed in the plurality of input ports 211a formed in the partition plate 211. [

The door 240 is configured to open or close the inlet 211a by the opening and closing means 250 to be described later and to communicate or isolate the purifying chamber 213 from the discharge chamber 215, Respectively.

The reason why the door 240 is installed so as to be inserted into the charging port 211a is that the door 240 is installed such that the inner circumferential surface of the charging port 211a and the outer circumferential surface of the door 240 are opposed to each other.

The door 240 has a shape corresponding to the opening face of the inlet 211a and is formed to have the same thickness as the partition plate 211. [

The left and right ends of the rotary shaft 241 are connected to the bearings B and the left and right ends of the rotary shaft 241 are integrally formed with the plate member constituting the door 240, To the left side wall and the right side wall of the housing 210 by means of the opening 210a.

The door 240 is padded with a rubber plate 243.

The rubber plate 243 protrudes outward in the horizontal direction so as to be stepped on the upper side of the front side and the lower side of the rear side with reference to the rotation axis 241 of the door 240 and is coupled to the door 240 by bolting or the like.

The rubber plate 243 is padded on the door 240 to seal the gap between the door 240 and the inner circumferential surface of the insertion port 211a when the door 240 closes the insertion port 211a.

The lower surface of the rubber plate 243 padded on the upper surface of the rim of the door 240 is in close contact with the upper surface of the adjacent partition plate 211 and the lower surface of the door 240 is pushed The upper surface of the rubber plate 243 is in close contact with the lower surface of the adjacent partition plate 211.

On the other hand, the door 240 is opened and closed by the opening / closing means 250.

The opening and closing means 250 closes the door 240 during the exhaust gas purifying process and closes the inlet 211a so that the suction force of the discharge portion 300 due to the discharge port 215b is lowered and the amount of contaminants contained in the discharge chamber 215 The first filter F1 and the second filter F2 are opened by opening the door 240 when the first filter F1 and the second filter F2 to be described later are opened to prevent scattering and to open the inlet 211a, 2 filter F2 falls into the discharge chamber 215 and is accommodated in the discharge chamber 215. In addition, the door 240 can be opened and closed as required.

The opening and closing means 250 is provided on the right side wall of the housing 210 so as to open or close the inlet 211a by rotating the door 240. The fourth link 251, the fifth link 253, And a second air cylinder 255.

The fourth link 251 is a rectangular plate having a long vertical length, and a plurality of the fourth links 251 are provided.

The fourth link 251 is provided for each rotary shaft 241 of each door 240 and the upper end thereof is integrally fixed to the rotary shaft 241 of the door 240.

The fifth link 253 is coupled to the lower end of each fourth link 251.

The fifth link 253 is hinged to the fourth link 251 and the third hinge axis 253a while traversing the lower end of each fourth link 251 in a rectangular plate shape elongated in the forward and rearward directions.

The fifth link 253 serves to allow each fourth link 251 to rotate simultaneously in the same direction.

The second air cylinder 255 is coupled to any one of the fourth links 251.

The second air cylinder 255 is a movable part for moving the opening and closing means 250. The second air cylinder 255 is rotatably installed through a second hinge pin 255b on the front side of the outer surface of the right side wall of the housing 210. [

The second air cylinder 255 is provided with a rod which can linearly reciprocate forward and backward.

The rod of the second air cylinder 255 is hinged to any one of the fourth links 251 by the first hinge pin 255a and is hinged to one of the four fourth links 251 in this embodiment, The lower end of the fourth link 251 located second from the second air cylinder 255 is hinged to the rod of the second air cylinder 255 through the first hinge pin 255a.

The fourth link 251 located second from the front side is pulled or pushed by the rod of the second air cylinder 255 to rotate forward or rearward while the fifth link 253 is rotated from the front side to the second side And each of the fourth links 251 other than the fourth link 251 located at the second position from the front side rotates in the same direction while maintaining the horizontal position according to the rotational motion of the fourth link 251 located at the fifth position, And the respective rotation shafts 241 rotate in the same direction in accordance with the rotational motion of each fourth link 251 fixed integrally to the right end.

The opening and closing operation of the door 240 according to the operation of the opening and closing means 250 will be described in detail. As shown in FIG. 9, the rod of the second air cylinder 255 is connected to any one of the fourth links 251, That is, when the second forward fourth link 251 is fully pushed rearward, the door 240 is completely closed with the inlet 211a. At this time, each of the fourth links 251 And is inclined by about 45 degrees from the rotation axis 241 to the rear lower side.

In this state, when the forward second link 251 is pulled forward and rotated to a substantially vertical position by the rod of the second air cylinder 255, as shown in Fig. 10, the second air cylinder And the fifth link 253 rotates in the same direction and at the same angle as the rotation of the second fourth link 251 in the forward direction, And each of the fourth links 251 other than the fourth link 251 located at the second position on the front side rotates in the same direction and at the same angle as the rotation of the fifth link 253, The rotation shaft 241 rotates in the same direction and at the same angle as the rotation of each fourth link 251 integrally fixed to the right end so that the door 240 partially opens the inlet 211a.

In this state, when the second forward fourth link 251 is further pulled forward by the rod of the second air cylinder 255 and rotated about 45 degrees forward from the substantially vertical position, as shown in FIG. 11 Likewise, the second air cylinder 255 rotates to be in a horizontal state about the second hinge pin 255b, and the fifth link 253 rotates in the same direction as the rotation of the fourth forward link 251 And each of the fourth links 251 other than the fourth link 251 positioned at the second position on the front side is rotated in the same direction and at the same angle as the rotation of the fifth link 253 And each rotary shaft 241 is rotated in the same direction and at the same angle as the rotation of each fourth link 251 integrally fixed to the right end so that the door 240 is vertically disposed, Is fully opened.

Since the operation for closing the door 240 in this state is the reverse of the above-described process, the description is omitted.

On the other hand, a second filter (F2) is installed in the exhaust part (270).

The second filter F2 is configured to filter the exhaust gas filtered once through the plurality of first filters F1, and is provided in the inner space of the exhaust part 270 in the horizontal direction.

The second filter F2 is desirably installed in the transverse sectional area equal to the transverse sectional area of the exhaust part 270 and is preferably installed so as to be in close contact with the inner peripheral surface of the exhaust part 270. [

The exhaust gas flowing into the exhaust part 270 from the purifying chamber 213 through the housing 210 passes through the second filter F2 so that contaminants contained in the exhaust gas adhere to the lower surface of the second filter F2 It is filtered.

At this time, the second filter F2 may be configured as a HEPA filter.

On the other hand, a third air pipe 281 and a fourth air pipe 283 are installed on the upper side of the second filter F2.

The third air pipe 281 and the fourth air pipe 283 are configured to air pollute the pollutants accumulated in the second filter F2 after the purification process of the exhaust gas is finished.

The third air pipe 281 and the fourth air pipe 283 are filtered by the second filter F2 through the injection of the air and the contaminants attached to the lower surface of the second filter F2 are passed through the second filter F2 , And is disposed in the exhaust part 270 so as to be spaced back and forth on the upper side of each second filter F2.

The third air pipe 281 and the fourth air pipe 283 are preferably spaced a predetermined distance from the upper surface of the second filter F2.

The third air pipe 281 is a circular tube formed long in the left and right direction and has a plurality of third air injection holes (not shown) formed in one row at regular intervals along the longitudinal direction.

The left end of the third air pipe 281 is connected to the air supply means (not shown) and the right end thereof is closed. The left end and the right end of the third air pipe 281 are connected to the left wall of the exhaust portion 270 And is rotatably mounted in a clockwise or counterclockwise direction.

The third air pipe 281 is provided on the upper side of the second filter F2 so as to be disposed between the front end and the center of the second filter F2. When air is supplied from the air supply means (not shown) Air is sprayed to the upper surface of the second filter F2 through the pores (not shown).

The fourth air pipe 283 is a circular pipe elongated in the left and right direction, and a plurality of fourth air jet holes (not shown) are formed in one row at regular intervals along the longitudinal direction.

At this time, the fourth air injection hole (not shown) formed in one line is arranged to be offset from the third air injection hole (not shown) formed in one line. More specifically, the fourth air injection hole (Not shown), and a third air jet hole (not shown) is formed opposite to a portion between two fourth air jet holes (not shown) closest to each other , Which is the same as the arrangement of the first air injection hole 221a and the second air injection hole 223a described above.

The reason why the third air injection hole (not shown) and the fourth air injection hole (not shown) have such an arrangement is that the air is uniformly sprayed over the entire area of the upper surface of the second filter F2.

Similarly to the third air pipe 281, the fourth air pipe 283 is opened at its left end and connected to air supply means (not shown), and its right end is closed. The left end and the right end are respectively connected to bearings And is installed to be rotatable in a clockwise or counterclockwise direction by being coupled to the left and right walls of the exhaust unit 270.

The fourth air pipe 283 is provided on the rear side of the second filter F2 so as to be disposed between the rear end and the center of the second filter F2. When air is supplied from the air supply means (not shown) Air is sprayed to the upper surface of the second filter F2 through the pores (not shown).

On the other hand, the third air pipe 281 and the fourth air pipe 283 are rotated by the second rotating means 290.

The second rotating means 290 is provided with a third air pipe 281 and a second air pipe 282 in order to increase the air injection range of the third air pipe 281 and the fourth air pipe 283 during air injection to the second filter F2. And the fourth air pipe 283 is rotated at a predetermined angle.

The second rotating means 290 includes a third air cylinder 291, a sixth link 293, a seventh link 295 and an eighth link 297.

The third air cylinder 291 is a movable part for moving the second rotating means 290. The third air cylinder 291 is vertically fixed to the rear of the outer surface of the left side wall of the housing 210, .

The third air cylinder 291 is provided with a rod which can reciprocate linearly in the vertical direction, that is, up and down.

The sixth link 293 is coupled to the rod of the third air cylinder 291.

The sixth link 293 is fixed to the upper end of the rod of the third air cylinder 291 and linearly reciprocates vertically up and down in accordance with the movement of the rod of the third air cylinder 291 .

A guide hole 293a is formed at the upper center of the sixth link 293 so as to pass through the guide hole 293a.

A pin protruding from the left side wall of the exhaust part 270 is inserted into the guide hole 293a and the guide hole 293a is guided by the pin so that the sixth link 293 ) In a straight line.

At this time, a separate washer (not shown) may be fixed to the left end of the pin to prevent the sixth link 293 from coming off.

One forward protruding portion protruding forward is formed on the upper front portion of the sixth link 293, and a fourth hinge axis 293b is fixed on the front protruding portion.

In addition, a rear protruding portion protruding rearward is formed on the upper rear portion of the sixth link 293, and a fifth hinge axis 293c is fixed on the rear protruding portion.

The upper protruding portion and the lower protruding portion are formed symmetrically with respect to each other, and the fourth hinge axis 293b and each fifth hinge axis 293c are formed to be symmetrical to each other.

The seventh link 295 and the eighth link 297 are hinged to the sixth link 293.

The seventh link 295 is a member connecting the sixth link 293 and the third air pipe 281. A third long hole 295a is formed on the rear side along the longitudinal direction so that the fourth hinge shaft 293b And the front side is integrally fixed to the left end of the third air pipe 281. [

The third slot 295a is formed to convert the linear movement of the sixth link 293 into the rotational movement of the seventh link 295. [

The seventh link 295 rotates in a counterclockwise direction when the sixth link 293 linearly moves upward and the seventh link 295 rotates counterclockwise when the seventh link 295 rotates counterclockwise, So that the third air pipe 281 is also rotated counterclockwise.

The seventh link 295 rotates in the clockwise direction when the sixth link 293 linearly moves downward and the seventh link 295 rotates clockwise as the seventh link 295 rotates clockwise, The third air pipe 281 is also rotated clockwise.

The eighth link 297 is a member connecting the sixth link 293 and the fourth air pipe 283 and has a fourth long hole 297a formed on the front side thereof along the longitudinal direction to form a fifth hinge shaft 293c And the rear side is integrally fixed to the left end of the fourth air pipe 283. [

The fourth slot 297a is formed to convert the linear movement of the sixth link 293 into the rotational movement of the fourth link 251. [

The eighth link 297 rotates in the clockwise direction when the sixth link 293 linearly moves upward and is fixed integrally with the eighth link 297 as the eighth link 297 rotates clockwise And the fourth air pipe 283 is also rotated clockwise.

The eighth link 297 rotates counterclockwise when the sixth link 293 linearly moves downward and the eighth link 297 rotates counterclockwise as the eighth link 297 rotates counterclockwise, And the fourth air pipe 283 fixed integrally with the first air pipe 282 also rotates counterclockwise.

The rotation of the seventh link 295 and the eighth link 297 proceeds simultaneously in opposite directions in accordance with the linear reciprocating motion of the sixth link 293.

Since the operation of the second rotating means 290 is substantially the same as the operation and direction of the first rotating means 230 described above, the description thereof will be omitted.

The third air pipe 281 and the fourth air pipe 283 are configured to be rotatable at a certain angle due to the above-described operations, so that the air jet range to the upper surface of the second filter F2 can be increased, The second filter F2 can effectively remove contaminants attached to the lower surface of the second filter F2.

On the other hand, the partition plate 211 is further provided with a charging port 211a at a portion opposed to the second filter F2.

The portion of the partition plate 211 opposed to the second filter F2 means a portion of the partition plate 211 located directly below the second filter F2.

The inlet 211a of the portion facing the second filter F2 is substantially the same as the inlet formed at the front lower portion of the first filter F1 and the third air pipe 281 and the fourth air pipe 283 When air is sprayed on the upper surface of the second filter F2 to remove the contaminants attached to the lower surface of the second filter F2, the contaminants fall down and are injected.

The door 240 is further provided at the inlet 211a of the portion facing the second filter F2 and the door 240 installed at the inlet 211a of the portion facing the second filter F2 is opened / Is opened and closed simultaneously with the other inlet ports (211a) by means (250).

The first air cylinder 231 of the first rotating means 230, the second air cylinder 255 of the opening and closing means 250 and the third air cylinder 291 of the second rotating means 290 are connected to a separate control unit (Not shown).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

11: Support frame 12: Mounting surface
100: roof part 200: purifying part
210: housing 210a:
211: partition plate 211a: inlet port
213: purifying chamber 215: discharging chamber
215a: bottom surface 215b: outlet
217: guide pin 221: first air pipe
211a: first air blow hole 223: second air pipe
223a: second air blow hole 230: first rotating means
231: first air cylinder 233: first link
233a: Guide ball 233b: First hinge shaft
233c: second hinge shaft 235: second link
235a: first slot 237: third link
237a: 2nd slot 240: door
241: rotating shaft 243: rubber plate
250: opening / closing means 251: fourth link
253: fifth link 253a: third hinge shaft
255: second air cylinder 255a: first hinge pin
255b: second hinge pin 260: water pipe
261: Water spray hole 270:
271: exhaust port 281: third air pipe
283: fourth air pipe 290: second rotating means
291: third air cylinder 293: sixth link
293a: Guide hole 293b: Fourth hinge shaft
293c: fifth hinge shaft 295: seventh link
295a: 3rd slot 297: 8th link
297a: fourth long hole 300:
B: Bearing C: Chimney
F1: first filter F2: second filter
L: support P1: first pipe
P2: second pipe

Claims (12)

delete A roof part provided at an upper end of the chimney;
A purifier connected to the roof and the first pipe to purify the exhaust gas flowing from the roof;
And a blowing unit connected to the purifying unit and the second pipe to guide the flow of the exhaust gas,
The purifier may further include:
housing;
A plurality of first filters installed vertically inside the housing to filter contaminants contained in the exhaust gas;
A plurality of first and second air pipes spaced apart from each other on the rear side of the first filter and jetting air to the back surface of each of the first filters to remove the pollutants from the first filter; Including,
Wherein each of the first and second air pipes has both ends thereof coupled to both side walls of the housing by a bearing and is rotated at a predetermined angle by the first rotating means,
Wherein the first rotating means comprises:
A first air cylinder fixedly installed on an outer surface of a side wall of the housing;
A first link reciprocating in a horizontal direction by the first air cylinder;
The first air pipe is hinged to an upper portion of the first link through a first long hole formed on one side and the other side is integrally fixed to the first air pipe to rotate each first air pipe in accordance with a linear reciprocating motion of the first link. A plurality of second links;
And the other end is hinged to the lower portion of the first link through a second slot formed on one side and the other end is integrally fixed to the second air pipe so as to rotate each of the second air pipes in accordance with the linear reciprocating motion of the first link And a plurality of third links for supplying the purge air to the chimney.
The method of claim 2,
A guide hole is formed in the first link to be long in the horizontal direction,
A protruded guide pin is formed on the outer surface of the side wall of the housing,
Wherein the guide pin is inserted into the guide hole to guide the first link to linearly reciprocate by a predetermined stroke distance.
The method of claim 3,
Wherein the first air pipe is formed with a plurality of first air injection holes in one row,
Wherein the second air pipe is formed with a plurality of second air injection holes in one row,
Wherein the first air injection hole formed in one row and the second air injection hole formed in one row are arranged to be shifted from each other.
The method according to any one of claims 2 to 4,
The housing is provided with a partition plate for partitioning the inner space into an upper purification chamber and a lower exhaust chamber,
Wherein the partition plate is provided with a plurality of inlet ports which are disposed in front of each of the first filters and into which contaminants dropped from the first filter are injected,
Wherein a door is provided at each of the inlet ports, the door being opened and closed by the opening and closing means.
The method of claim 5,
The opening /
A plurality of fourth links integrally fixed to one side of the rotary shaft of each door;
A fifth link hinged across the other side of each fourth link;
And a second air cylinder rotatably installed on an outer surface of a side wall of the housing and having a rod hinged to any one of the fourth links.
The method of claim 6,
Wherein a rubber plate is attached to each of the door so as to protrude outward in a horizontal direction from a front edge upper surface and a rear edge bottom surface with respect to the rotation axis at the center.
The method of claim 7,
Wherein a water supply pipe is installed along an inner peripheral surface of the discharge chamber.
The method of claim 8,
A discharge port is formed at one side of the inner bottom surface of the discharge chamber,
Wherein the bottom surface is inclined so as to be lowered toward the discharge port.
The method of claim 9,
An exhaust portion communicating with the purifying chamber is formed on an upper surface of the housing,
A second filter for filtering contaminants contained in the exhaust gas is installed in the exhaust part in a horizontal direction,
And third and fourth air pipes are provided on the upper side of the second filter so as to be spaced back and forth so that air is sprayed on the upper surface of the second filter to remove the pollutant from the second filter,
Wherein the third and fourth air pipes are coupled to both side walls of the exhaust unit by bearings, and are rotated at a predetermined angle by the second rotating unit.
The method of claim 10,
Wherein the second rotating means comprises:
A third air cylinder fixedly installed on an outer surface of the side wall of the housing;
A sixth link reciprocating in a vertical direction by the third air cylinder;
And the other end is fixed integrally with the third air pipe to rotate the third air pipe in accordance with a linear reciprocating motion of the sixth link. The third air pipe is hinged to the front portion of the sixth link through a third hole formed on one side, A seventh link;
The fourth air pipe being hinged to a rear portion of the sixth link through a fourth slot formed on one side and the other side being integrally fixed to the fourth air pipe to rotate the fourth air pipe in accordance with a linear reciprocating motion of the sixth link Wherein the chimney includes a first link and an eighth link.
The method of claim 11,
The partition plate is further provided with a charging port at a portion facing the second filter,
Wherein the door is further provided with the door and is opened / closed by the opening / closing means.

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