KR200465003Y1 - Detecting apparatus for air pollution using differential optical abosrption spectroscopy - Google Patents

Abstract

The present invention relates to an apparatus for measuring air pollutants using differential absorption spectroscopy, and includes a pollutant measuring device for irradiating light to a detection target measurement area, receiving and analyzing light reflected by a reflector to measure pollutants in the measurement area. It is provided with a main body, and a rotating unit for rotating the main body based on the center line extending in the vertical direction and the vertical direction.
Air pollutant measuring apparatus using the differential absorption spectroscopy according to the present invention can be rotated in the vertical and east-west direction by measuring the pollutants in the air through the differential absorption spectroscopy, so even if the measurement area is changed easily pollutants There is an advantage that can be detected.

Description

Air pollutant measuring apparatus using differential absorption spectroscopy {detecting apparatus for air pollution using differential optical abosrption spectroscopy}

The present invention relates to an apparatus for measuring air pollutants using differential absorption spectroscopy (DOAS), and more specifically, to measure the pollutants in the air using differential absorption spectroscopy to easily rotate up and down and east-west directions. The present invention relates to an air pollutant measuring apparatus using differential absorption spectroscopy.

In general, spectroscopy is the study of the interaction between electromagnetic radiation and a sample (including one or more of gas, solids and liquids). The way the radiation reacts with the sample depends on the nature of the sample.

As the radiation passes through the sample, a particular radiation wavelength is absorbed by the molecules in the sample. The specific wavelength of radiation absorbed is specific to each molecule in a particular sample. By identifying which wavelength of radiation is absorbed, it is possible to identify specific molecules present in the sample.

Differential Optical Absorption Spectrometry (DOAS) is a widely used technique for the detection of various trace gaseous substances in the atmosphere, and basically uses the principle that absorption occurs depending on the wavelength when light passes through a medium. .

The system using the differential absorption spectroscopy has been applied to the atmospheric environment field and presented various functions to the atmospheric measurement field. In particular, the introduction of the differential absorption spectroscopy has provided an opportunity to promote the reorganization of the observation system that enables the calculation of spatial representative concentrations of contaminants existing within the distance of light transmission beyond the conventional concept of the center of observation. .

The system using the differential absorption spectroscopy emits parallel light into the atmosphere using a white light source and detects the light returned by the reflector to quantitatively measure the pollutants such as pollutants having absorption bands in the ultraviolet region and the visible region using the differential absorption spectroscopy. Phosphorus concentration will be determined.

Recently, systems using differential absorption spectroscopy have received great attention as a device that can simultaneously detect various pollutants in the air at a long distance.

The air pollutant measuring device using the differential absorption spectroscopy can be classified into an active system using an artificial light source and a passive system using natural light (eg, solar scattered light, moonlight) according to the light source.

Among these, the active system includes a light source for generating light, a transmission optical system for irradiating light from the light source into the atmosphere, a reception optical system for receiving light reflected by a reflector, a spectrometer for measuring light through the reception optical system, It consists of a computer that automatically analyzes the transmitted data and analyzes the pollutants.

Conventional air pollutant measuring device as described above is fixed in the initial installation position, when there is no rotation means is provided, when changing the measurement area, the measuring device has to be separated, and reinstalled according to the measurement area has a disadvantage.

An object of the present invention is to provide an air pollutant measuring apparatus using a differential absorption spectroscopy that can rotate the pollutant detector in the vertical and east-west directions according to the measurement area.

The air pollutant measuring apparatus using the differential absorption spectroscopy according to the present invention for achieving the above object is irradiated with light to the detection target measurement area, receiving and analyzing the light reflected by the reflector to analyze the contaminants in the measurement area It includes a main body provided with a pollutant measuring device for measuring, and a rotating unit for rotating the main body based on the center line extending in the vertical direction and the vertical direction.

The rotation unit is installed on the main frame, the main frame, the subframe rotatably with respect to the center line, the main body is rotatably installed in the vertical direction, and the sub to rotate the main body in the vertical direction It is preferable to have a first rotating member for rotating the frame in the vertical direction, and a second rotating member for rotating the subframe to rotate the main body about the center line.

The first rotation member includes a first engagement member fastened to a rotation shaft of the main body, a second engagement member engaged with the first engagement member, and the second engagement member to rotate the subframe vertically. It is provided with a first drive member for rotating.

The second rotating member may include a rotating shaft member protruding upward or downward on an upper surface or a lower surface of the subframe, a third engagement member fastened to the rotation shaft member, and a fourth engagement member engaged with the third engagement member; And a second driving member for rotating the fourth engagement member to rotate the subframe with respect to the center line.

On the other hand, the second rotating member according to another embodiment of the present invention is fixed to the main frame, and predetermined based on the center line with respect to the main frame to guide the sub-frame rotating about the main frame A main rail formed along an arc-shaped trajectory having a radius, a fifth engagement member fixed along an outer circumferential surface of the main rail, a sixth engagement member meshed with the fifth engagement member and rotatably installed in the subframe; And a third driving member installed in the subframe and rotating the sixth engagement member to rotate the subframe in the east-west direction with respect to the mainframe along the main rail.

Air pollutant measuring apparatus using the differential absorption spectroscopy according to the present invention can be rotated in the vertical and east-west direction by measuring the pollutants in the air through the differential absorption spectroscopy, so even if the measurement area is changed easily pollutants There is an advantage that can be detected.

1 is a perspective view of an air pollutant measuring apparatus using a differential absorption spectroscopy according to an embodiment of the present invention,
2 is a side view of an air pollutant measuring apparatus using differential absorption spectroscopy according to an embodiment of the present invention,
3 is a perspective view of an air pollutant measuring apparatus using differential absorption spectroscopy according to another embodiment of the present invention,
4 is a side view of the air pollutant measuring apparatus using the differential absorption spectroscopy of FIG.

Hereinafter, an air pollutant measuring apparatus using differential absorption spectroscopy according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 2 will be described in more detail the air pollutant measuring device 10 using the differential absorption spectroscopy according to the present invention.

Referring to the drawings, the air pollutant measuring apparatus 10 using the differential absorption spectroscopy method is the main body 20 is provided with a pollutant measuring instrument 21 for analyzing the gas of the detection target measurement area, and the main body 20 in the vertical direction and It is provided with a rotating unit 30 for rotating based on the center line extending in the vertical direction.

The main body 20 is formed in a plate shape having a predetermined thickness, and the scattered light detector 21 is provided on an upper surface thereof. The lower surface of the main body 20 is provided with a rotating shaft 23 which is rotatably installed at both ends in the subframe 50 to be described later.

The pivot shaft 23 is formed in an annular bar shape having a predetermined radius and extends in parallel to the longitudinal direction of the main body 20. The pivot shaft 23 is provided at the center portion with respect to the width of the main body 20. At this time, the rotating shaft 23 is rotated by the first rotating member to be described later, the outer peripheral surface by a plurality of fixing brackets 22 so that the main body 20 can be rotated by the rotational force supplied by the first rotating member It is fixed to the lower surface of the main body 20.

On the other hand, although not shown in the drawing, unlike the present embodiment, the rotation shaft 23 is not fixed to the lower surface of the main body 20 by a plurality of fixing brackets 22, but the rotation shaft ( The outer circumferential surface of 23 may be fixed by welding.

The pollutant measuring unit 21 measures a pollutant in a measuring area by differential optical absorption spectroscopy (DOAS). The pollutant measuring device 21 irradiates light to the measuring area and returns the light returned through the reflector to the differential absorption spectroscopy. By measuring the absorption spectrum of the material of each wavelength band by using the type and composition of the pollutants in the atmosphere.

Although not shown in the drawing, the pollutant measuring unit 21 reflects an artificial light source, a transmission optical system that irradiates the light of the artificial light source to the measurement zone, a reflector that reflects light passing through the measurement zone, and is reflected back from the reflector. It includes a receiving optical system for receiving light, a spectrometer for measuring the light received through the receiving optical system using an optical sensor, and an analysis unit for calculating contaminants by calculating the data transmitted from the spectrometer.

The rotating unit 30 is rotatably installed based on the main frame 40 and the center line extending in the vertical direction on the main frame 40, and the main frame 20 is installed to be rotatable in the vertical direction. 50, a first pivot member 60 for rotating the subframe in the vertical direction to rotate the main body 20 in the up and down direction, and the main body 20 for the rotation of the main body 20 with respect to the center line. A second rotating member 70 for rotating the subframe 50 is provided.

The main frame 40 is formed in a plate shape having a predetermined thickness and extends in a direction parallel to the longitudinal direction of the main body 20. The main frame 40 is fixedly installed adjacent to the position where the harmful gas to be measured is generated.

On the other hand, although not shown in the figure, the bearing is provided in the center of the upper surface of the main frame 40 so that the lower end of the rotating shaft member 71 of the second pivot member 70 to be described later can be installed rotatably.

The subframe 50 is formed in a plate shape having a predetermined thickness and extends in the longitudinal direction corresponding to the main frame 40. Two supports 51 are provided on the upper surface of the subframe 50 so as to rotatably support both ends of the rotation shaft 23 of the main body 20.

A second pivot member 70 is installed between the subframe 50 and the main frame 40, and the subframe 50 is rotated by the main frame 40.

The support 51 is extended upwardly on the upper surface of the main body 20, and at intervals corresponding to the length of the rotation shaft 23 so as to rotatably support both ends of the rotation shaft 23 of the main body 20. Installed apart from each other. The upper surface of the support 51 is provided with a rotating bracket 52 so that both ends of the rotation shaft 23 can be easily supported.

Although not shown in the drawings, the bearing is installed on the rotating bracket 52 at the position where the rotating shaft 23 is supported so that the rotating shaft 23 supported by the rotating bracket 52 can be easily rotated.

On the other hand, the first rotation member 60 according to the present invention will be described in detail as follows.

The first rotation member 60 is a first engagement member 61 fastened to the rotation shaft 23 of the main body 20, a second engagement member 62 engaged with the first engagement member 61, and A first driving member 63 for rotating the second engagement member 62 to rotate the main body 20 in the vertical direction is provided.

The first engagement member 61 is a worm gear in which a plurality of gears are formed along the circumferential direction on the outer circumferential surface, and the outer circumferential surface is concave so that the second engagement member 62 to be described later can be easily engaged. The first engagement member 61 is preferably fastened to one end of the rotation shaft 23 to prevent interference with the main body 20 during the rotation.

The second engagement member 62 is formed in a cylindrical shape, and is formed of a worm provided with a spiral in an outer circumferential surface thereof so as to be engaged with the first engagement member 61. The rotary shaft of the first driving member 63 is fastened to the end of the second engagement member 62.

The first driving member 63 is installed on the upper surface of the subframe 50, it is preferable that the electric motor for generating a rotational force by electric power. The second engagement member 62 is fastened to the rotation shaft of the first driving member 63 to rotate the main body 20 through the second engagement member 62.

On the other hand, the second rotating member 70 according to the present invention will be described in detail as follows.

The second pivot member 70 includes a rotation shaft member 71 protruding downward from the lower surface of the subframe 50, a third engagement member 72 fastened to the rotation shaft member 71, and a third engagement member 72. ) And a second driving member (74) for rotating the fourth engagement member (73) to rotate the subframe (50) with respect to the center line extending in the vertical direction. do.

The rotary shaft member 71 is formed in a round bar shape having a predetermined radius. The rotary shaft member 71 has an upper end surface fixed to the center portion of the subframe 50, and a lower end surface is rotatably installed on the upper surface of the main frame 40.

The third engagement member 72 has a plurality of gears formed along the circumferential direction on the outer circumferential surface thereof, and preferably, the third engagement member 72 is a worm gear having a concave outer circumferential surface so that the fourth engagement member 73 to be described later can be easily engaged.

The fourth engagement member 73 is formed in a cylindrical shape, and is a worm formed in a spiral shape on an outer circumferential surface thereof so as to be engaged with the third engagement member 72. The rotary shaft of the second driving member 74 is fastened to the end of the fourth engagement member 73.

The second driving member 74 is preferably installed on the lower surface of the subframe 50 and is an electric motor that generates rotational force by electric power. The fourth engagement member 73 is fastened to the rotation shaft of the second driving member 74 to rotate the subframe 50 through the fourth engagement member 73.

Meanwhile, FIGS. 3 to 4 show a second pivot member 80 according to another embodiment of the present invention.

Referring to the drawing, the second rotating member rotates the subframe 50 in the east-west direction with respect to the main frame 40. The second rotating member includes a main rail 81, fifth and sixth engagement members 82 and 83, a third driving member 84, and a rail wheel 85.

The main rail 81 is installed on the upper surface of the main frame 40 and has a predetermined radius with respect to the center of the main frame 40 to form an arc-shaped trajectory having a predetermined radius about the center line. It is formed in a ring shape.

The fifth engagement member 82 is fixed to the outer circumferential surface of the main rail 81 in a closed circuit along the circumferential direction. It is preferable that the first engagement member is a chain so as to easily weld fix the outer peripheral surface of the main rail 81.

It is preferable that the sixth engagement member 83 is a sprocket to be engaged with the fifth engagement member. The sixth engagement member 83 is fastened to the rotation shaft of the third driving member 84.

The third driving member 84 is installed on the lower surface of the subframe 50 to rotate the sixth engagement member 83. Preferably, the third drive member is an electric motor that generates rotational force by electricity.

The rail wheel 85 is installed on the bottom surface of the subframe 50 at a position opposite to the main rail 81 so that the subframe 50 can be easily rotated along the main rail 81. Guide the rotation. The rail wheel 85 has a fixing member 86 and a main roller 87.

Fixing member 86 is installed on the lower surface of the subframe 50, the bottom is branched apart from each other at intervals corresponding to the width of the main rail 81 so that a portion can be inserted into the top of the main rail 81 have.

The main roller 87 is rotatably installed on the fixing member 86 and rotates along the upper surface of the main rail 81 in contact with the main rail 81.

Referring to the operation of the second rotating member 80 configured as mentioned above is as follows.

When electric power is supplied to the third driving member 84, the third driving member 84 rotates the sixth engagement member 83. Since the sixth engagement member 83 rotating by the supplied rotational force is engaged with the fifth engagement member 82, the subframe 50 rotates along the main rail 81.

The air pollutant measuring apparatus 10 using the differential absorption spectroscopy method according to the present invention configured as described above is the scattering light detector 21 for measuring the scattered light of the gas to be detected by the first rotating member and the second rotating member. And because it can be rotated in the east-west direction, there is an advantage that can easily measure the pollutants even if the measurement area is changed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

10: Air pollutant measuring device using differential absorption spectroscopy
20: main body
30: rotating unit
40: mainframe
50: subframe
60: first rotating member
61: first engagement member
62: second engagement member
63: first driving member
70: second rotating member
71: rotating shaft member
72: third engagement member
73: fourth engagement member
74: second driving member

Claims (5)

A main body provided with a pollutant measuring device for irradiating light to a detection target measurement area, receiving and analyzing light reflected by a reflector to measure pollutants in the measurement area;
And a rotating unit rotating the main body based on the center line extending in the vertical direction and the vertical direction.
The rotating unit
The mainframe,
A subframe installed on the main frame rotatably with respect to the center line, and the main body rotatably installed in a vertical direction;
A first rotating member rotating the subframe in the vertical direction to rotate the main body in the vertical direction;
And a second pivot member for rotating the subframe to rotate the main body about the center line.
The second rotating member is
A main rail fixed to the main frame and formed along a trajectory of an arc shape having a predetermined radius about the center line with respect to the main frame to guide the subframe rotating with respect to the main frame;
A fifth engagement member fixed along an outer circumferential surface of the main rail;
A sixth engagement member meshed with the fifth engagement member and rotatably installed in the subframe;
And a third driving member installed in the subframe and rotating the sixth engagement member to rotate the subframe in the east-west direction with respect to the mainframe along the main rail. Air pollutant measuring device using spectroscopy.







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