KR101278150B1 - Collecting Apparatus which have a Multi Hole Pipe for Particulate in Air - Google Patents

Abstract

The present invention relates to a fine dust collecting device for collecting fine dust suspended in the air, and more particularly, to collect a plurality of collecting air to operate the plurality of collecting units using a single particle size granulation device and a pump The present invention relates to a fine dust collecting device having a porous tube including a porous tube for dispensing at a.
The fine dust collecting device of the present invention having the above-described configuration operates a plurality of collecting parts by using a single particle size granulation device and a pump, so that the collection device can be continuously operated for a long time, and is efficient and installs a space. It has the effect of reducing.

Description

Fine dust collecting device having a porous tube {Collecting Apparatus which have a Multi Hole Pipe for Particulate in Air}

The present invention relates to a fine dust collecting device for collecting fine dust suspended in the air, and more particularly, to collect a plurality of collecting air to operate the plurality of collecting units using a single particle size granulation device and a pump The present invention relates to a fine dust collecting device having a porous tube including a porous tube for dispensing at a.

Particulates suspended in the air may be defined as liquid particles or solid particles, and the particles may be subdivided into dust, mist, and fume according to physical conditions. Since these particles are harmful to the human body and cause pollution in various industrial sites, analysis of the collection of particles suspended in the air, mass concentration and chemical composition of the collected particles for accurate evaluation of the risk of the particles. Is being studied in a very important area. Particle collection includes membrane filter, cyclone (size-selective sampling device), horizontal elutriator and cascade impactor, impinger Collectors of various structures are used.

1 shows a conventional fine dust collecting device 10 using a membrane filter paper. The collecting device 10 is a particle size granulation device 11 for filtering dust having a large particle size in the air and the air is introduced into one end, and is installed on the particle size granulation device 11, pollutants in the gas in the air A first denuder 12 and a second denuder 13 for removal, a collecting part 14 installed at the other end of the particle size separating device 11, and installed on the collecting part 14. It is composed of a pump 16 for sucking air through the particle size separation device 11 is connected to the collecting filter 15 and the other end of the collecting unit 14 for collecting fine dust.

The fine dust collecting device 10 having the above-described configuration has a limited capacity for collecting fine dust, and thus, when the fine dust needs to be collected continuously for a long time or simultaneously for analyzing various chemical compositions, the collecting device 10 as described above. You will need a large number. In this case, since each particle size separation device 11 and the pump 16 are mounted to each of the plurality of collecting parts 14, there is a problem that the installation operating space increases.

The present invention has been made to solve the above problems, an object of the present invention, by using a porous tube which is the core configuration of the present invention to install a plurality of collecting units in a single particle size granulation device and a pump to operate fine dust To provide a collecting device.

In addition, to provide a fine dust collecting device having a porous tube to minimize the elements that hinder the flow of air in order to minimize the loss of fine dust introduced into the porous tube.

The fine dust collecting device of the present invention, the particle size granulation device 110 for filtering the large particles in the air is introduced into one end, the collecting unit 140 is installed on the other end of the particle size granulation device 110, and It is installed on the collecting unit 140 includes a collecting filter 150 for collecting fine dust and connected to the other end of the collecting unit 140 and a pump 160 for sucking air through the particle size granulation device 110. In the fine dust collecting device 100, the collecting device 100 is provided with a plurality of collecting portions 140, the other end of the particle size granulation device 110 is connected to one end, a plurality of the other end A porous tube 200 connected to each collection unit 140; And a flow valve 300 connecting the pump and the other end of each of the collecting parts 140 to selectively connect any one of the pump 160 and the collecting part 140. Characterized in that it comprises a.

At this time, the porous pipe 200, the flow space (S) is formed so that the air flows therein; An inlet 210 formed to communicate the other end of the particle size separating apparatus 110 with the flow space S; And outlets 220 formed to communicate one end of each of the plurality of collecting parts 140 and the flow space S; It includes, but the outlet 220 is formed in the other end surface 230 which is the other end surface of the porous pipe 200, the flow space (S) side of the other end surface 230 of the cross section orthogonal to the air flow direction It is formed to be inclined in one direction toward the center (O), in particular characterized in that configured to expose a portion of the outlet 220 on the other end direction extension line of the inlet (210).

In addition, the outlet 220 is characterized in that it is formed radially with respect to the center (O) of the other end surface 230.

The fine dust collecting device of the present invention having the above-described configuration operates a plurality of collecting parts by using a single particle size granulation device and a pump, so that the collection device can be continuously operated for a long time, and is efficient and installs a space. It has the effect of reducing.

1 is a schematic view of a conventional fine dust collecting device
2 is a schematic view of a fine dust collecting device of the present invention
Figure 3 is a partial cross-sectional perspective view of the porous tube of the present invention
4 is a bottom perspective view of FIG.
5 is an exploded view of FIG.
Figure 6 is a longitudinal cross-sectional view of the porous tube of the present invention
Figure 7a is a plan view of the porous tube of the present invention
Figure 7b is a bottom view of the porous tube of the present invention

Referring to FIG. 2, the fine dust collecting device 100 having the porous pipe of the present invention includes a particle size granulation device 110 for filtering dust having a large particle size in the air and having air introduced therein, and the particle size granulation device Is installed on the 110, the first denuder (120) and the second denude 130 for removing contaminants on the gas in the air, and a plurality of installed on the other end of the particle size separation device 110 Collecting unit 140, the collecting filter 150 is installed on the collecting unit 140 to collect fine dust, the porous pipe connecting the other end and the plurality of collecting unit 140 of the particle size granulation unit 110 ( 200, a pump 160 for sucking air through the particle size separating device 110, and a flow valve 300 for selectively connecting the other end of each collecting unit 140 and the pump 160. do.

The particle size separating apparatus 110 serves to filter particles having a large particle diameter in the air. The particle size dividing apparatus 110 serves to supply air to the other end by introducing air by the pump 160 to one end.

The particle dividing apparatus 110 may be provided with a first denuder 120 and a second denude 130 for removing gaseous contaminants in the atmosphere. The first and second denuders 120 and 130 may be applied to a conventional configuration for removing gaseous pollutants in the air, and thus detailed configurations thereof will be omitted.

The other end of the particle size separating device 110 is connected to one end of the porous tube 200. The porous tube 200 is a core configuration of the present invention for connecting the particle size separation device 110 and the collection unit 140 composed of a plurality of details will be described in detail through the following embodiments.

One end of the collecting part 140 is connected to the porous tube 200, and the other end thereof is connected to the flow valve 300. The collecting filter 150 is provided inside the collecting unit 140. Therefore, the fine dust in the air flowing into the collecting unit 140 is collected using the collecting filter 150.

Each of the other ends of the plurality of collecting parts 140 is connected to the flow valve 300 and the flow valve 300 is connected to the pump 160. The plurality of collecting parts 140 and the pump 160 are selectively connected through the flow valve 300. For example, by connecting the one of the collecting unit 140 and the pump 160 by the flow valve 300, after a predetermined time has elapsed by connecting the other collecting unit 140 and the pump to be continuously performed for a long time To help. Since the flow valve 300 can be generally applied to the configuration of the solenoid valve will be described in detail below.

The pump 160 may be a configuration of a conventional air pump for sucking air.

Hereinafter, an embodiment of the porous tube 200 of the present invention as described above will be described in detail with reference to the drawings.

3 to 6, the porous tube 200 of the present invention may be made by the combination of the first tube (200a) located at one end and the second tube (200b) located at the other end. Through the combination of the first pipe 200a and the second pipe 200b, the porous pipe 200 has a flow space S formed therein. The first pipe 200a and the second pipe 200b may each have a female thread or male thread, and may be screwed together.

Side slope portion 240 may be formed so that the diameter of the first pipe (200a) toward one end is smaller. One end of the first pipe (200a) is formed with an inlet 210 for receiving air from the other end of the particle size granulation device (110). The other end of the first tube (200a) is open, the other end of the outer peripheral surface may be formed with a male thread for coupling with the second tube (200b).

The second pipe 200b has a cylindrical shape, the other end of which is sealed by the other end surface 230. One end of the second tube 200b may be formed with a female thread around an inner circumferential surface thereof so as to be coupled to the first tube 200a. The other end surface 230 may be provided with a plurality of outlets 220 for communicating with one end of each of the collecting parts 140.

At this time, the porous tube 200 of the present invention flows out only to the collecting unit 140 where the air flowing from the inlet 210 when the suction force occurs in any one of the collecting unit 140, the suction force is generated. It has the following characteristic configuration.

As shown in FIG. 6, the other end surface 230 may be inclined toward one end of the porous tube 200 toward the center. Therefore, the center of the other end surface 230 is formed closest to one end of the porous tube 200, and is spaced apart from one end of the porous tube 200 toward the outside. In addition, the outlet 250 may be formed radially with respect to the center of the other end surface 230 so as to be located at a predetermined distance from the center of the other end surface 230, respectively. Through the above configuration, the air flowing into the inlet 210 flows to the outlet 220 to which the collecting unit 140 for generating the suction force is connected, and the air flow is also smoothly flowed.

In addition, the porous tube 200 of the present invention has the following characteristic configuration in order to minimize the flow rate by minimizing the air friction in the flow space (S).

As shown in FIG. 7A, a portion of each of the outlets 220 may be exposed on the other end extending line of the inlet 210. Similarly, one end of each outlet 220 may be exposed as shown in FIG. 7B. A portion of the inlet 210 is exposed on the direction extension line. Accordingly, in the air flowing into the inlet 210 toward the outlet 220, friction is minimized. Therefore, the presence of a plurality of outlets in a single inlet has the effect of preventing the flow rate reduction that may be a concern.

The technical spirit should not be interpreted as being limited to the above embodiments of the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, such modifications and changes are within the scope of protection of the present invention as long as it is obvious to those skilled in the art.

100: fine dust collecting device
110: particle size separating apparatus 120: first dinuder
130: second dinude 140: collecting part
150: collection filter 160: pump
200: porous tube 200a: first tube
200b: second tube 210: inlet
220: outlet 230: other end surface
240: side slope portion
300: flow valve

Claims (4)

It is installed on the collecting unit 140 and the collecting unit 140, which is installed at the other end of the particle diameter separating apparatus 110, and the particle size granulation apparatus 110 for filtering large particles in the air into one end The fine dust collecting device 100 is connected to the other end of the collecting filter 150 for collecting fine dust and the pump 160 for sucking the air through the particle size granulation unit 110 to the fine dust collecting device 100 In
The collecting device 100,
The collecting unit 140 is provided in plurality,
The other end of the particle size separating apparatus 110 is connected to one end thereof, and a porous tube 200 connected to each of the plurality of collecting parts 140 at the other end thereof; And
A flow valve 300 connecting the pump and the other end of each of the collecting parts 140 to selectively connect any one of the pump 160 and the collecting part 140;
Containing, fine dust collecting device having a porous tube.
The method of claim 1,
The porous tube 200,
A flow space S formed to flow air therein;
An inlet 210 formed to communicate the other end of the particle size separating apparatus 110 with the flow space S; And
Outlets 220 formed to communicate with one end of each of the plurality of collecting parts 140 and the flow space S;
≪ / RTI >
The outlet 220 is formed on the other end surface 230, which is the other end surface of the porous pipe 200, the flow space (S) side of the other end surface 230 is the center of the cross section orthogonal to the air flow direction (O) Fine dust collecting device having a porous tube is formed to be inclined in one direction toward the ().
The method of claim 2,
The outlet 220 is
Fine dust collecting device having a porous tube, characterized in that formed on the center (O) of the other end surface radially on the basis.
The method of claim 2,
The porous tube 200,
The dust collection device having a porous pipe, characterized in that configured to expose a portion of the outlet 220 on the extension line in the other end direction of the inlet 210.

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