KR101932483B1 - fine dust measurement method - Google Patents

Abstract

The present invention relates to a fine dust measurement method, which measures fine dust by using a light scattering measurement method as an auxiliary measurement method in a beta ray measurement method, and since the light scattering measurement method is used as a supplementary means in the beta ray measurement method, there is a remarkable effect of accurately and easily measuring fine dust.

Description

[0002] Fine dust measurement method [

The present invention relates to a fine dust measuring method, and more particularly, to a fine dust measuring method for reliably measuring fine dust by using a light scattering measuring method as an auxiliary measuring method in a beta ray measuring method.

In general, as a conventional fine dust measurement method, a housing having a first flow path and a second flow path formed therein is disclosed in Korean Patent Registration No. 10-1278289. A filter unit fitted in the housing to be exposed on the first flow path and the second flow path, respectively; A beta ray irradiation unit provided in one direction of the filter unit on the first flow path and the second flow path to irradiate the filter unit with beta rays; A beta ray detection unit provided on the other side of the filter unit on the first flow path and the second flow path to detect the beta rays transmitted through the filter unit; A first dust collecting part having one end exposed to the atmosphere and the other end communicating with an inlet end of the first flow path to supply air containing fine dust to the inlet end of the first flow path; And a second dust collecting part having one end exposed to the atmosphere and the other end communicating with an inlet end of the second flow path for supplying air containing fine dust to the inlet end of the second flow path, And the second dust collecting part collects fine dusts of different sizes. The dual fine dust measuring device using the Betrayer is disclosed.

In addition, JP-A-10-1606561 discloses a method comprising: (a) periodically changing a flow rate of a fluid containing dust particles; (b) irradiating the fluid with light; (c) detecting light scattered by the dust particles and converting the scattered light into an electrical detection signal; (d) collecting the detection signal; And (e) calculating at least one of a size, a number, and a concentration of the dust particles contained in the fluid from the collected detection signals, wherein the step (e) Wherein the time interval for the moving average is calculated by sequentially moving the data for a period of time in accordance with time order to calculate at least one of the size, Is a time interval that coincides with a period in which the flow velocity of the dust particles changes.

However, the above-mentioned conventional Beta line measurement method is unstable in measurement, and it is not easy to grasp a fault immediately and recognize a fault or take measures.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above problems, and it is an object of the present invention to provide a fine dust measurement method which is accurate and easy to measure fine dust by using a light scattering measurement method as a supplementary method.

The present invention relates to a fine dust measurement method, and is characterized in that fine dust is measured using a light scattering measurement method as an auxiliary measurement method in a beta ray measurement method.

Therefore, the present invention has a remarkable effect that accurate and easy fine dust measurement can be achieved by using the light scattering measurement method as a supplementary means in the beta ray measurement method.

1 is a side sectional view showing a conventional particle sensor
2 is a perspective view showing a chamber of a subway fine particle monitoring apparatus according to a first embodiment of the present invention;
3 is a cross-sectional view showing a chamber of a subway fine particle monitoring apparatus according to a first embodiment of the present invention
4 is a cross-sectional view showing a chamber of a subway fine particle monitoring apparatus according to the first embodiment of the present invention
5 is a front view showing a submersible fine particle monitoring apparatus according to the first embodiment of the present invention.
6 is a cross-sectional view showing a state before the side condenser lens coupled to the chamber of the present invention is moved
7 is a cross-sectional view showing a state where the side condenser lens coupled to the chamber of the present invention is transferred

The present invention relates to a fine dust measurement method, and is characterized in that fine dust is measured using a light scattering measurement method as an auxiliary measurement method in a beta ray measurement method.

In addition, the betaine measuring method is characterized by measuring in an hour unit.

In addition, when the beta ray measurement method is wrong, the method is characterized in that it is determined through a light scattering measurement method.

In addition, when the beta ray measurement method is wrong, the light scattering measurement method alone is measured.

The present invention is described in detail as follows.

The present invention uses a light scattering measurement method as an auxiliary measurement method in a beta ray measurement method for a fine dust measurement. Since the beta ray measurement method and the light scattering measurement method use a widely known method as described in the background art of the present invention, detailed description thereof will be omitted.

The beta ray measurement method is an hourly measurement, and if it is out of the set value or the predicted value, it is confirmed through the light scattering measurement method, and if the beta ray measurement method is wrong, it is corrected and if the correction is not performed within a short time, .

The light scattering measurement method can be used simultaneously in the beta ray measurement method.

As an embodiment, the light scattering measurement apparatus of the present invention will be described as follows.

In the drawing, the conveying direction of the fine dust is indicated by a solid line arrow, and the light is indicated by a dotted line.

2 to 4, the subway particulate monitoring apparatus of the first embodiment includes a chamber 100 in which a dust passage 102 is formed so that fine dust 101 passes back and forth.

The chamber 100 is formed in a substantially block shape. On the left and right sides and upper and lower sides of the chamber 100, there are provided structures for measuring fine dust 101 passing through the dust passage 102 by a light scattering method.

The subway dust monitoring apparatus of the first embodiment of the present invention includes a light emitting device 120, a converging optical system 130, a dust channel 102, a beam stopper 140, a front condensing lens 150, a front optical detector 160, A side condenser lens 170, and a side optical detector 180. [

The light emitting device 120 is configured to emit ultraviolet rays using an LED (light emitting diode) 122. LEDs that emit ultraviolet light are more efficient than mercury lamps, have a long life and are environmentally friendly.

The light emitting device 120 emits ultraviolet light in a direction crossing the dust flow path 102 from one side of the chamber 100.

A cylindrical first bracket 104 is vertically connected to one side of the chamber 100 so that the light emitting device 120 is supported at one end and the other end is connected to the dust flow path 102.

A cylindrical second bracket 106 having one end connected to the dust flow path 102 and the other end connected to the front optical detector 160 is provided on the opposite side of the chamber 100 on which the first bracket 104 is located. Is vertically connected.

One end of the chamber 100 is connected to the dust flow path 102 and the other end of the side light detector 160 is connected to the first bracket 104 and the second bracket 106, And a cylindrical third bracket 108 to be installed is vertically connected.

The converging optical system 130 is supported inside the other end (opposite to the light emitting device) of the first bracket 104 to converge the ultraviolet light emitted from the LED 122.

The dust channel 102 is formed to pass the fine dust 101 so as to cross the ultraviolet ray passing through the converging optical system 130.

The beam stopper 140 is installed on the front surface in the traveling direction of the light passing through the converging optical system 130 and blocks the direct light passing through the dust channel 102.

The beam stopper 140 and the converging optical system 130 are installed with the dust flow path 102 therebetween.

The front condensing lens 150 is supported at one end of the chamber 100 or the second bracket 106 and is installed behind the beam stopper 140 to collect light scattered by the fine dust 101.

The front optical detector 160 is disposed behind the front optical condensing lens 150 and detects the condensed light.

Each of the side condenser lens 170 and the side photodetector 180 is provided in pairs.

The pair of side condensing lenses 170 are installed to face each other with the dust flow path 102 therebetween.

The side condenser lens 170 is supported by the chamber 100 or the third bracket 108 and collects light scattered laterally in the traveling direction of the light.

The side photodetector 180 is located behind the side condenser lens 170 and detects light scattered by the fine dust 101. That is, at the end of the third bracket 108, to detect the amount of light collected by the side condenser lens 170.

Since the pair of side condenser lens 170 and the side photodetector 180 are provided in pairs, the light scattered by the fine dust 101 can be detected from three surfaces (three directions), so that the fine dust concentration can be measured more accurately It is possible to do.

Referring to FIG. 5, the inlet 110, the impactor 112, and the pump 114 are connected to the chamber 100 to introduce the fine dust 101 into the dust passage 102.

The impactor 112 is connected to one end of the dust passage 102 to filter out dust particles having a predetermined size or larger. The impactor 112 filters dust particles of 10 mu m or more of the dust particles.

The impactor 112 may be installed to filter dust particles of 2.5 m or more.

The inlet 110 is connected to the impactor 112 so as to allow the ambient dust to flow therein.

The pump 114 is connected to the other end of the dust channel 102 through which the fine dust 101 is discharged and sucks dust through the inlet 110.

The chamber 100 is provided with a first connection port 111 for coupling a pipeline (not shown) connecting one end of the dust flow path 102 to the impactor 112. The chamber 100 is provided with a second connection port 113 to which a pipe (not shown) for connecting the other end of the dust flow path 102 to the pump 114 is connected.

The side condenser lens according to the present invention is movable. The chamber has a curved section on the left and right sides, a hole is formed in the left and right corner parts of the side, and a side condenser lens is selectively installed. Do not open the hole with a stopper.

Large fine dust larger than 10 μm is mainly measured with a front condenser lens and a front photodetector. Small fine dust smaller than 10 μm is measured with a side condenser lens and a side photodetector. In the case of small fine dust measurement of less than 10 mu m, when the left and right side photodetectors have a large deviation, since either one of the left and right side photodetectors is faulty or the distribution of fine dusts is uncertain, all the side photodetectors are moved to arbitrary corners do. At this time, a value close to any one of the first measured values of the left and right side photodetectors is selected.

The third bracket of the lateral photodetector is detachable because the surface area of the chamber is narrow. The third bracket is then coupled with a roller magnet to move the side condenser lens coupled to the chamber.

The roller magnet 500 coupled to the third bracket is composed of a magnet case 510 and a cylindrical magnet 520 inserted into the magnet case and formed in a circular cylindrical shape having a circular section and moving inside the magnet case do.

The roller magnet can be changed to the opposite S and N poles by rotating the cylindrical magnet inside the magnet case, regardless of which poles of the N and S poles of the counterpart object attached to the third bracket have, No repulsive force is generated between the objects, and only the attractive force is generated, and the objects are easily attached to the object.

On the front face of the third bracket, a roller magnet is embedded at the time of bonding or molding. When the material of the third bracket is a metal, grooves are cut on the front surface and the roller magnet is bonded with an adhesive. When the material of the third bracket is plastic, the roller magnet is formed at the time of molding in the mold by a common insert injection method. Alternatively, as in the case of metals, grooves are formed in the front surface, and the roller magnet is bonded with an adhesive.

The chamber may be formed of metal so that the magnet can be attached thereto, or, in the case of a plastic material, a metal plate is attached to the left and right side surfaces with an adhesive. Therefore, the lateral photodetector can be moved to left or right or both corners according to the movement of the side condenser lens.

Therefore, the present invention has a remarkable effect that accurate and easy fine dust measurement can be achieved by using the light scattering measurement method as a supplementary means in the beta ray measurement method.

500: Roller magnet 510: Magnetic case
520: Cylindrical magnet
100: chamber 101: fine dust
102: dust channel 104: first bracket
106: second bracket 108: third bracket
110: inlet 112: impactor
114: Pump 120: Light emitting device
122: LED 130: converging optical system
140: Beam stopper 150: Front condensing lens
160: front optical detector 170: side condensing lens
180: Side light detector

Claims (3)

The fine dust is measured using the light scattering measurement method as an auxiliary measurement method in the beta ray measurement method and the fine dust is measured using the light scattering measurement method alone when the beta ray measurement method is wrong,
The submerged fine particle monitoring apparatus used for measuring the fine dust has a chamber 100 in which a dust passage 102 is formed so that the fine dust 101 passes back and forth, And the fine dust 101 passing through the dust passage 102 is measured by light scattering method on the left and right sides and upper and lower sides of the chamber 100. The submicroscope monitoring device includes a light emitting device 120, A converging optical system 130, a dust channel 102, a beam stopper 140, a front condensing lens 150, a front optical detector 160, a side condensing lens 170, and a side optical detector 180,
The light emitting device 120 is configured to emit ultraviolet rays using an LED 122 to emit ultraviolet rays in a direction intersecting the dust flow path 102 from one side of the chamber 100, Light,
A cylindrical first bracket 104 is vertically connected to one side of the chamber 100 so that the light emitting device 120 is supported at one end and the other end is connected to the dust flow path 102, A second bracket 106 of a cylindrical shape having one end connected to the dust flow path 102 and the other end connected to the front photodetector 160 is vertically disposed on the side opposite to the first bracket 104, Connection is established,
One end of the chamber 100 is connected to the dust flow path 102 and the other side of the chamber 100 is connected to the side photodetector 160 on both side surfaces perpendicular to the first bracket 104 and the second bracket 106 The third bracket 108 is vertically connected,
The converging optical system 130 is supported in the other end of the first bracket 104 to converge ultraviolet light emitted from the LED 122,
The dust channel 102 is formed so as to pass the fine dust 101 so as to cross the ultraviolet ray passing through the converging optical system 130,
The beam stopper 140 blocks the direct light that has passed through the converging optical system 130 and is disposed on the front surface in the traveling direction of the light and has passed through the dust channel 102,
The beam stopper 140 and the converging optical system 130 are installed with the dust path 102 therebetween,
The front condenser lens 150 is supported at one end of the chamber 100 or the second bracket 106 and installed behind the beam stopper 140 to collect light scattered by the fine dust 101,
The front optical detector 160 is disposed behind the front optical condensing lens 150 and detects the condensed light,
Each of the side condenser lens 170 and the side photodetector 180 is provided in a pair and the pair of side condenser lenses 170 are installed to face each other with the dust channel 102 therebetween.
The side condenser lens 170 is supported by the chamber 100 or the third bracket 108 and collects light scattered laterally in the traveling direction of the light,
The side photodetector 180 is disposed behind the side focusing lens 170 and detects light scattered by the fine dust 101. The side photodetector 180 detects the light scattered by the fine dust 101 and is disposed at the end of the third bracket 108, And the amount of light collected by the light-
Since each of the side condenser lenses 170 and the side photodetectors 180 is provided in pairs, the light scattered by the fine dust 101 can be detected from three surfaces, so that it is possible to more accurately measure the fine dust density ,
The chamber 100 is connected to the inlet 110, the impactor 112, and the pump 114 to introduce the fine dust 101 into the dust passage 102,
The impactor 112 is connected to one end of the dust passage 102 to filter out dust particles having a predetermined size or more. The inlet 110 is connected to the impactor 112 to introduce dust therein, However,
The pump 114 is connected to the other end of the dust passage 102 through which the fine dust 101 is discharged and sucks dust through the inlet 110,
The chamber 100 is provided with a first connection port 111 for coupling a piping connecting one end of the dust flow path 102 to the impactor 112. The chamber 100 is provided with a dust- And a second connection port 113 to which a pipe connecting the other end and the pump 114 is connected,
The side condenser lens 170 is movable. The chamber 100 has a curved section at its left and right sides, and a hole is formed at the left and right corners of the side, so that the side condenser lens 170 is selectively installed And the unused holes are closed with a plug,
The large fine dust larger than a predetermined size is measured by the front condenser lens 150 and the front photodetector 160 and the minute fine dust smaller than a predetermined size is measured by the side condenser lens 170 and the side photodetector 180 , When the deviation of the left and right side photodetectors 180 is large in the case of measuring minute dust smaller than a predetermined size, either one of the left and right side photodetectors 180 is faulty or the distribution of fine dusts is uncertain. 180 are moved to the corners so as to select a value close to any one of the first measured values of the left and right side photodetectors 180,
The third bracket 108 of the side photodetector 180 is detachable because the surface area of the chamber 100 is narrow and the magnet is coupled to the third bracket 108, And the lens (170) can be moved.
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