KR20190084537A - Dust measuring apparatus - Google Patents

Abstract

The present invention relates to a dust measuring device which receives light scattered by dust contained in air while irradiating light to air and can accurately measure dust contained in the air in real time. An embodiment of the present invention comprises: an air chamber (100) which has air introduced to one side thereof to flow through an internal space and discharged to the other side thereof; an air supplying unit (200) which supplies air to the internal space of the air chamber (100); an air flow path forming unit (300) which forms an air flow path so that the introduced air is converged and flows; an air curtain forming unit (400) which forms air curtains covering the air flow path formed by the air flow path forming unit (300); a light source unit (500) which irradiates light to form a scattering path in the air flow path; a multi scattering path forming unit (600) which uses light irradiated from the light source unit (500) to form a multi scattering path in the air flow path; and a dust measuring unit (700) which receives light scattered in the scattering path formed by the multi scattering path forming unit (600), and measures dust based on a light amount of received scattered light.

Description

[0001] DUST MEASURING APPARATUS [0002]

The present invention relates to a dust measuring device capable of accurately measuring dust contained in air in real time by receiving light scattered by dust contained in air in a state of irradiating light to air.

In general, the major air pollutants in Korea are the major air pollutants such as PM ₁₀ , NO x, and O ₃ owing to the rapid increase in the number of automobiles and industrial growth since the 1990s. Respectively. Research and management of ultra fine dust (PM _2.5 ), which is attracting attention as a high risk to human health, has not been improved.

Dust less than 2.5 μm (PM _2.5 ) is known to cause lung and cardiovascular disease or increase the likelihood of death of related patients by reaching the lungs without being filtered by the bronchial tube due to its very small size. In addition, recently, the World Health Organization (WHO) has designated diesel particulates as a first-class carcinogen as well as the public health risks of air pollution.

Recently, there is an increasing need to take measures to improve the air environment so as to eliminate public concern due to the generation of high concentration fine dust and to lead a pleasant life. In particular, there is a growing need to establish and promote management measures for ultra fine dust (PM _2.5 ), which is finer in particle size and more health hazardous.

Therefore, it is necessary to develop a measurement device capable of monitoring minute dust (PM ₁₀ ) and dust (PM _2.5 ) while measuring in real time.

Patent Registration No. 10-1424202

SUMMARY OF THE INVENTION It is an object of the present invention to provide a dust measuring device capable of accurately measuring dust contained in air in real time by receiving light scattered by dust contained in air in a state of irradiating light to air .

The dust measuring apparatus according to an embodiment of the present invention includes an air chamber 100 in which air introduced into one side flows through an inner space and is discharged to the other side, An air flow path forming portion 300 for forming an air flow path so as to flow the inflowing air and an air flow forming portion 300 for forming an air flow path surrounding the air flow path formed by the air flow path forming portion 300, A light source unit 500 that irradiates light to form a scattering path in an air flow path, a multi scattering path forming unit that forms a multiple scattering path in an air flow path by using light emitted from the light source unit 500, And a dust measuring unit 700 that receives light scattered in a scattering path formed by the multiple scattering path forming unit 600 and measures dust on the basis of the amount of scattered light received .

Preferably, the air supply part 200 is constituted by a fan for forcibly feeding air to the air flow path forming part 300, and the air path forming part 300 is constituted by a tube whose inner diameter is gradually narrowed.

The air curtain forming unit 400 includes an air separating pipe 410 which surrounds the outside of the air flow path forming unit 300 and separates the air outside the air path forming unit 300, An air guide pipe 420 which surrounds the pipe 410 and guides the separated air to the outside of the air separation pipe 410 and an air guide pipe 420 which is disposed between the air separation pipe 410 and the air guide pipe 420 And a filter unit 430 for filtering dust in the air.

Preferably, the multiple scattering path forming unit 600 includes a plurality of reflectors disposed on both sides of the air flow path, and reflects light emitted from the light source unit 500 to an air flow path to form a multiple scattering path .

Preferably, the reflectors are arranged such that multiple scattering paths pass through the same point (a) in the air flow path.

Preferably, the dust measuring unit 700 includes a scattered light recognizing unit 710 for recognizing scattered light scattered by dust particles in a multiple scattering path, a signal converting unit 720 for converting recognized scattered light into a measured signal, A reference count setting unit 740 for counting the number of times a signal is converted into a reference count, a reference count setting unit 740 for setting a reference count, and a counter counting unit 740 for comparing the counted count with a reference count. If the counted count exceeds the reference count, And a dust concentration display unit 750 for indicating that the number of counting does not exceed the reference number of times.

Preferably, the dust measuring unit 700 includes a signal size checking unit 760 for checking the magnitude of the measurement signal converted by the signal converting unit 710, and a controller 760 for setting a first reference signal corresponding to the fine dust, A reference signal size setting unit 770 for setting a second reference signal for setting a second reference signal to be compared with a reference signal and displaying the number of measurement signals corresponding to the first reference signal, And a dust distribution display unit 780 for displaying the number of signals.

The present invention can accurately measure the dust contained in the air in real time by receiving light scattered by the dust contained in the air while irradiating the air with light.

Also, since light emitted from one light source is reflected by a plurality of reflection plates, a plurality of scattering paths can be formed in the air flow path. That is, since a plurality of scattering paths are formed by a plurality of reflection plates, there is an advantage that a plurality of light sources are not required.

In addition, since a large number of reflection plates are three-dimensionally arranged around the air flow path formed by the air flow path forming portion, precise measurement can be performed through three-dimensional scattering of dust.

In addition, an air curtain is formed on the outside of the air flow path to prevent contamination of optical components such as an optical device (light source) and a reflection plate from dust contained in air passing through the air flow path, So that dust measurement can be accurately performed.

In addition, since the light received through a plurality of scattering paths is measured, the measurement precision for measuring dust can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a dust measuring apparatus according to an embodiment of the present invention; FIG.
2 is a view showing a state where air is supplied by the air supply unit of the present invention.
3 is a bottom view showing a state in which light irradiated from the light source unit of the present invention is formed with a plurality of scattering paths by a multiple scattering path forming unit.
4 is a view showing another embodiment of a multiple scattering path forming part applied to the present invention.
5 is a view showing another embodiment of a multiple scattering path forming unit applied to the present invention.
6 is a block diagram showing a dust measuring part according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 1 to 6, the present invention includes an air chamber 100 in which air introduced into one side flows through the internal space and is discharged to the other side, air (air) supplied to the internal space of the air chamber 100, An air flow path forming part 300 for forming an air flow path so that the inflow air flows and an air flow path surrounding the air flow path formed by the air flow path forming part 300 are formed A light source unit 500 that irradiates light to form a scattering path in an air flow path, a multiple scattering path that forms a multiple scattering path in an air flow path by using light emitted from the light source unit 500, And a dust measuring unit 700 that receives light scattered in a scattering path formed by the multiple scattering path forming unit 600 and measures dust on the basis of the amount of scattered light received .

The air chamber 100 is formed with a space therein, and the inner space is opened at both ends, so that the air introduced into one end of the air chamber 100 can flow through the inner space and be discharged to the other end. An air induction part 120 is formed at the other end of the air chamber 100 through which the air is discharged, and the air induction part 120 is formed so that the inner diameter of the air induction part 120 gradually increases toward the outside so that the air flow path formed by the air flow path forming part 300 can be easily discharged to the outside .

The air supply unit 200 includes a fan that is rotated by electric energy to force air to the air flow path forming unit 300 and may be installed at the inlet side of the air chamber 100. However, And it is preferably provided on the discharge port side. It is preferable that a taper is formed so that the inflow of air into the air chamber 100 side is facilitated. Accordingly, as the air supply unit 200 is operated, external air can be introduced into the internal space of the air chamber 100, and turbulence and vibration that may be generated due to the inflow of air can be minimized.

The air flow path forming part 300 is composed of a tubular body such as a funnel whose inner diameter is gradually narrowed, and is provided at the inlet side of the air chamber 100. Therefore, the air introduced into the air chamber 100 is injected in a form such that it is concentrated at the center by the air passage forming part 300, thereby forming a cylindrical air passage. That is, the introduced air is moved along the inner space of the air chamber 100 while forming the air flow path by the air flow path forming part 300, and is guided through the air induction part 120 formed on the other side of the air chamber 100 .

The air curtain forming unit 400 includes an air separating pipe 410 which surrounds the outside of the air flow path forming unit 300 and separates air from the air path forming unit 300, The air guide pipe 420 is disposed between the air separation pipe 410 and the air guide pipe 420 to guide the separated air to the outside of the air separation pipe 410, And a filter unit 430 that filters dust from the incoming air to prevent the inflow of dust.

The air separation pipe 410 is formed to have a smaller diameter than the diameter of the air guide pipe 420 and is positioned inside the air guide pipe 420 while being integrally fixed to the outer peripheral surface of the airflow passage forming part 300.

The air guide pipe 420 is fixed to the other end of the shaft having one end fixed to the air separation pipe 410. That is, the air curtain can be formed by passing air between the air guide pipe 420 and the air separation pipe 410 which are concentric to each other by the radially connected shaft. Since the end of the air guide pipe 420 is fixed so as to communicate with the inlet port side of the air chamber 100, the introduced air is supplied to the air flow path forming part 300 and is guided by the air guide pipe 420 .

The filter unit 430 may be composed of a micro filter for purifying the incoming air, so that dust can be filtered from the incoming air. Therefore, the clean air filtered by the filter unit 430 flows into the space between the air separation pipe 410 and the air guide pipe 420, so that an air curtain free from dust can be formed.

As described above, it is possible to prevent the dust-containing air from being separated from the air channel, thereby preventing the dust-containing air from contacting the reflection plate, which is the laser and multi-scattering path forming unit 600, which is the light source unit 500 The clean air forming the air curtain is not contaminated by the dust even if it contacts the light source unit 500 and the multiple scattering path forming unit 600. [ Even in a state where the light source unit 500 and the multiple scattering path forming unit 600 are contaminated with dust, the clean state can be continuously maintained while being cleaned by clean air by the air curtain, The amount of light is not reduced and the reflection efficiency of the multiple scattering path forming unit 600 is not reduced.

Here, if the filter unit 430 is not applied, a structure for introducing clean air not containing dust separately between the air separation pipe 410 and the air guide pipe 420 may be applied.

Accordingly, when the air introduced by the air supply unit 200 is separated to the inside of the air separation pipe 410, the air is supplied to the air flow formation unit 300. When the air is separated to the outside of the air separation pipe 410, 410 and is guided by the air guide tube 420. That is, the inflow air is separated to form an air flow path, and at the same time, an air curtain can be formed.

Furthermore, in the air curtain, since the light can be passed without being distorted, even if an air curtain is formed to prevent the inflow of other air, a scatter path that is not distorted in the air flow path can be formed.

The light source unit 500 includes a laser that emits light, and irradiates light toward the air channel while being provided in an inner space of the air chamber 100. Accordingly, the light emitted from the light source unit 500 is scattered by the dust while passing through the air flow path, so that a scattering path can be formed. The light source unit 500 may be provided near the air flow path. The laser beam emitted from the light source unit 500 can be stopped by the stopper 510. [

The multiple scattering path forming unit 600 includes a plurality of mirrors or reflectors dispersed on both sides of the air flow path, and reflects light emitted from the light source unit 500 to an air flow path to form a multiple scattering path. At this time, the reflection surface of the mirror or reflector may be concave to reflect the light, in order to increase the efficiency of light collection. The multiple scattering path forming unit 600 may be provided near the air flow path.

Accordingly, the first reflecting plate provided on one side of the air flow path reflects the first scattering path that is emitted from the light source unit 500 and passes through the air flow path, and the second reflecting plate spaced apart from the first reflecting plate reflects from the first reflecting plate And a third scattering path formed on the other side of the air flow path reflects a second scattering path passing through the air flow path to the outside of the air flow path, The fourth reflector spaced from the reflector reflects a second scatter path reflected from the third reflector back to the air flow path and is provided to the stopper 510 to form a third scatter path that stops.

Also, as in Fig. 4, the reflectors can be disposed at appropriate positions so that the multiple scattering paths pass through the same point (a) in the air flow path. That is, when the positions of the reflectors are adjusted, multiple scattering paths reflected from the reflectors pass through the same point (a) in the air flow path. At this time, when the scattering light is measured at one point (a) where the scattering path passes through the dust measuring unit 700, quantitative analysis of the dust to be measured becomes possible.

The multiple scattering path forming unit 600 includes a plurality of mirrors or reflectors arranged in a zigzag manner on both sides of the air flow path to reflect light emitted from the light source unit 500 to the air flow path to form a multiple scattering path .

Accordingly, the first reflecting plate provided on one side of the air flow path is formed by reflecting the first scattering path passing through the airflow path through the airflow path by emitting light from the light source unit 500 to form a second scattering path, The second reflector reflects a second scatter path reflected from the first reflector to the air flow path to form a third scatter path and the third reflector reflects a third scatter path reflected from the second reflector to the air flow path The fourth scattering path is formed and the fourth reflector reflects the fourth scattering path reflected from the third reflector to the air flow path so as to be provided to the stopper 510 to form the fifth scattering path to be stopped.

Here, the light emitted from one light source unit 500 is provided to the air flow channel a plurality of times by reflection plates disposed staggered about the air flow channel, so that a large number of scattering paths can be formed. This measurement accuracy for measuring dust by a plurality of scattering paths can be improved.

The dust measuring unit 700 includes a photosensor, which is configured as one or a plurality of units and is provided outside the air flow path and receives scattered light scattered by dust in a multiple scattering path. Therefore, since the light of the light source unit 500 is scattered by the dust particles in the scattering path, the dust measuring unit 700 can measure dust by measuring the amount of scattered light received by the photosensor. Accordingly, even if dust is not uniformly distributed in the air flow path, the scattering path is formed by the reflection plates even if the scattering path is concentrated on one side, so that the amount of dust particles can be accurately measured.

The dust measuring unit 700 includes a scattered light recognizing unit 710 for recognizing scattered light scattered by dust particles in a multiple scattering path, a signal converting unit 720 for converting the recognized scattered light into a measured signal, A reference count setting unit 740 for counting the number of times the reference count is converted, a reference count setting unit 740 for setting a reference count, and a counter counting unit 740 for comparing the counted count with the reference count. If the counted count exceeds the reference count, And a dust concentration display unit 750 for indicating that the counted number of times does not exceed the reference number.

The scattered light recognizing unit 710 is connected to a photosensor that receives scattered light scattered by dust particles in the multiple scattering path. Accordingly, the scattered light recognizing unit 710 recognizes the scattered light received through the photosensor.

The number of counting is the number of dust particles. In other words, if the number of counting is large, there is a lot of dust.

The dust concentration display unit 750 determines that the number of counting exceeds the reference number and displays the display as red through a lamp or a monitor, so that the user can visually check the dust concentration display unit 750. In addition, safety indications can be displayed in green through the lamp or monitor. Of course, alarms can also be used to indicate pollution or safety.

The dust measuring unit 700 includes a signal size checking unit 760 for checking the magnitude of the measurement signal converted by the signal converting unit 710, and a signal measuring unit 760 for setting a first reference signal corresponding to the fine dust, A reference signal size setting unit 770 for setting a second reference signal, and a comparator 760 for comparing the measurement signal with a reference signal to display the number of measurement signals corresponding to the first reference signal, And a dust distribution display portion 780 for displaying the number of dust particles.

The first reference signal corresponds to the fine dust (PM ₁₀ ), and the second reference signal corresponds to the dust (PM _2.5 ). Therefore, if the number of measurement signals coinciding with the first reference signal is large, fine dust is large, and if the number of measurement signals coinciding with the second reference signal is large, there is a lot of dust.

The dust measuring unit 700 may include a button for operating or stopping the air supply unit 200 and the light source unit 500. Accordingly, when the test is started, the air supply unit 200 and the light source unit 500 are operated, and when the test is completed, the air supply unit 200 and the light source unit 500 are stopped.

As described above, according to the present invention, dust contained in air can be measured in the course of the air being introduced into the air chamber and being discharged. Accordingly, the present invention can be applied to an apparatus for measuring dust, which is a very useful invention that can be widely used.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is to be understood, therefore, that the embodiments described above are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, All changes or modifications that come within the scope of the equivalent concept are to be construed as being included within the scope of the present invention.

100: air chamber
200: air supply part
300: air passage forming part
400: air curtain forming part
410: air separation pipe
420: air guide tube
430:
500: light source part
510: Stopper
600: multiple scattering path forming unit
700: dust measuring unit
710: Scattered light recognition unit
720:
730:
740: Reference number setting section
750: dust density indicator
760: Signal size check unit
770: Reference signal size setting unit
780: Dust type indicator

Claims (7)

An air chamber 100 through which air introduced into one side flows through the inner space and is discharged to the other side,
An air supply unit 200 for supplying air to the internal space of the air chamber 100,
An air flow path forming part 300 for forming an air flow path so that the inflow air flows,
An air curtain forming part 400 for forming an air curtain surrounding the air flow path formed by the air flow path forming part 300,
A light source unit 500 for irradiating light to form a scattering path in an air flow path,
A multiple scattering path forming unit 600 for forming a multiple scattering path in an air flow path by using light emitted from the light source unit 500,
And a dust measuring unit (700) for receiving light scattered in a scattering path formed by the multiple scattering path forming unit (600) and measuring dust on the basis of the amount of scattered light received, .
The air supply part 200 is constituted by a fan for forcibly transferring the air to the air flow path forming part 300 and the air path forming part 300 is constituted by a tube whose inside diameter is gradually narrowed A dust measuring device.
The air curtain forming part (400) according to claim 1, wherein the air curtain forming part
An air separation pipe 410 which surrounds the outside of the air flow path forming part 300 and separates the air outside the air path forming part 300,
An air guide pipe 420 which surrounds the air separation pipe 410 and guides the separated air to the outside of the air separation pipe 410,
And a filter unit (430) disposed between the air separation pipe (410) and the air guide pipe (420) to filter dust from the air to be introduced.
The multiple scattering path forming unit 600 includes a plurality of reflectors disposed on both sides of the air flow path and reflects light emitted from the light source unit 500 to an air flow path to form a multiple scattering path Wherein the dust measuring device is a dust collecting device.
5. The dust measurement device according to claim 4, wherein the reflection plates are disposed such that the multiple scattering paths pass through the same point (a) in the air flow path.
The dust collecting apparatus according to claim 1, wherein the dust measuring unit (700)
A scattered light recognition unit 710 for recognizing scattered light scattered by the dust particles in the multiple scattering path,
A signal converter 720 for converting the recognized scattered light into a measurement signal,
A counting unit 730 for counting the number of times the signal is converted into a measurement signal,
A reference number setting unit 740 for setting a reference number of times,
And a dust concentration display unit (750) for comparing the number of counting times with the reference number, indicating that the number of counting exceeds the reference number of times of contamination, and displaying the number of counting times of safety Device.
[7] The dust collecting apparatus according to claim 6,
A signal size checking unit 760 for checking the size of the measurement signal converted by the signal converting unit 710,
A reference signal size setting unit 770 for setting a first reference signal corresponding to fine dust and setting a second reference signal corresponding to dust,
And a dust distribution display unit 780 for comparing the measurement signal with the reference signal to display the number of measurement signals corresponding to the first reference signal and displaying the number of measurement signals corresponding to the second reference signal A dust measuring device.

Images