WO2020032319A1 - Dust measurement device - Google Patents

Abstract

Provided is a dust measurement device which comprises: a first housing which forms an accommodation space to measure the concentration, in the air, of dust that becomes deposited in an alveolus as a person respires, and which comprises a first hole through which a fluid comprising the dust is introduced and a second hole through which the fluid introduced via the first hole is discharged; a fan for supplying power by which the fluid is introduced via the first hole and discharged via the second hole; a first dust path mounted on the first housing, for connecting the first hole and the second hole; a second dust path which is mounted on the first housing, bifurcates from the first dust path, and is connected to the second hole; and a dust sensing unit for sensing the dust passing through the second dust path, wherein the second dust path bifurcates from the first dust path by forming an obtuse angle to the direction of a dust flow, in order to separate the dust introduced via the first hole, into a certain fraction according to the particle size.

Description

Dust measuring device

The present invention relates to a dust measuring apparatus, and more particularly, to a dust measuring apparatus that classifies dust in the air at a specific fraction according to the size of dust particles and senses the classified dust.

Fine dust is divided into fine dust (PM10) of 2.5μm ~ 10μm in diameter and ultrafine particles of less than 2.5μm (PM2.5) according to the particle size. Given that the diameter of the hair is 50-70 μm, PM2.5 is a very small particle about 1/20 to 1/30 of the thickness of the hair.

The source of fine dust can be classified into two categories. The first is elemental carbon, trace metals and minerals from automobile exhaust, factory fuel combustion, etc. The second is sulfate from combustion or evaporation of fuel, Nitrates, sulfur dioxide, nitrogen oxides and the like. Unlike dust, which is naturally occurring dust, fine dust is generated by combustion such as fuel, plant, and exhaust gas.

Fine dust is a particulate matter, which is more likely to be deposited in the human lungs than gaseous matter. Therefore, there is a possibility of causing a greater adverse effect on human health than other air pollutants.

In particular, when the person breathing fine dust (PM 10) of 10μm or less in diameter can reach the lungs through the respiratory tract to be deposited. Therefore, the fine dust of PM10 is included as an air environment reference item.

In addition, when a person breathes, the fine dust differs in the reachable area and the fraction deposited depending on the particle size.

Thus, a dust measuring device capable of calculating the concentration of dust deposited in the lungs when a person breathes in the dust in the atmosphere may be useful.

Dust measuring devices include filter based gravimetric samplers, tapered element oscillating microbalance (TEOM) meters, β- attenuation meters, and optical meters.

An optical measuring device is a device for sensing dust by receiving light scattered by dust by irradiating light. The optical measuring device is a portable measuring device that can be operated using a battery, and at the same time, various size fraction measurements can be conveniently used.

However, the conventional optical measuring device has a difficulty in classifying particle size to meet the PM10 definition, and has a disadvantage in that accuracy is poor in measurement because dust does not flow uniformly in the light irradiation part.

The present invention aims to solve the above-mentioned problem and other problems through the specification of the present invention as well.

The present invention seeks to provide a particle classification structure capable of classifying dust on the basis of the fraction deposited on the alveoli according to the size of the dust particles in the atmosphere dust.

An object of the present invention is to provide a particle concentrating structure in which an optical dust measuring device forms a path in which dust is focused on a portion to which light is irradiated.

According to an aspect of the present invention to achieve the above or another object, in the dust measuring apparatus, the first hole and the fluid introduced through the first hole to form a receiving space, the fluid containing dust is introduced A first housing including a second hole which flows out, a fan that provides power to flow into the first hole and flows out of the second hole, and is mounted in the first housing, and the first hole and the second hole A first dust passage communicating with the second dust, a second dust passage mounted in the first housing, branched from the first dust passage, communicating with the second hole, and dust sensing the dust passing through the second dust passage; And a sensing unit, wherein the second dust passage forms an obtuse angle based on the dust flow direction with the first dust passage in order to classify the dust introduced through the first hole at a specific fraction according to the particle size. Provided is a dust measuring device, characterized in that.

In addition, according to an aspect of the present invention, the first dust passage provides a dust measuring apparatus, characterized in that the width of the cross section through which the fluid passes before and after the branching point of the second dust passage.

In addition, according to an aspect of the present invention, the first dust passage provides a dust measuring apparatus, characterized in that it comprises a stepped portion at the point where the second dust passage is branched.

In addition, according to an aspect of the present invention, the first dust passage comprises a dust measuring device, characterized in that it comprises at least one bent portion between the point communicating with the first hole and the point where the second dust passage is branched. To provide.

In addition, according to an aspect of the present invention, the at least one bent portion provides a dust measuring device, characterized in that the first dust passage comprises a first bent in vertical communication with the first hole.

In addition, according to an aspect of the present invention, the second dust passage is dust measurement, characterized in that it comprises a section that gradually increases or decreases the width of the cross section through which the fluid passes at the point where the second dust passage is branched Provide the device.

According to an aspect of the present invention, the second dust passage may include at least one bent portion between a point where the second dust passage is branched and a point where the dust sensing unit senses dust. Provide a dust measuring device.

In addition, according to an aspect of the present invention, the at least one bent portion provides a dust measuring device, characterized in that it comprises a second bent portion to vertically introduce the fluid to the point of sensing the dust.

In addition, according to an aspect of the present invention, the second bent portion provides a dust measuring device, characterized in that it comprises a groove recessed in the path direction of the fluid flowing into the second bent portion.

In addition, according to an aspect of the present invention, the second dust passage is formed in the receiving space, and the third hole including the fluid flows through the third hole and the fourth hole through which the fluid introduced through the third hole flows out A second housing, an inflow passage branched from the first dust passage to introduce the fluid into the third hole, and an outlet passage flowing out of the fluid from the fourth hole to the second hole, wherein the second housing includes: 2 is provided with the third hole and the fourth hole facing the symmetry plane so that dust flows along a straight path across the housing.

In addition, according to an aspect of the present invention, the dust sensing unit includes a light source for irradiating light from one surface of the second housing, and a detection unit provided on the other surface of the second housing and receiving scattered light. In addition, the light source provides a dust measuring device, characterized in that for irradiating light toward the straight path through which the dust flows.

In addition, according to an aspect of the present invention, the third hole has a diameter smaller than the width of the area for receiving the light scattered by the detector, and the straight path through which the dust flows receives the scattered light. Provided is a dust measuring device, characterized in that provided on one surface of the second housing so as to pass over the center of the area.

In addition, according to an aspect of the present invention, the third hole provides a dust measuring device, characterized in that having the same diameter or smaller diameter than the fourth hole.

In addition, according to an aspect of the present invention, the flow rate flowing into the second dust passage provides a dust measuring apparatus, characterized in that corresponding to half of the flow rate introduced through the first hole.

In addition, according to an aspect of the present invention, the dust sensing unit provides a dust measuring device, characterized in that for measuring the number of dust in the unit flow rate flowing into the second dust passage.

In addition, according to an aspect of the present invention, the specific fraction provides a dust measuring apparatus, characterized in that corresponding to the fraction of PM (Particular Matter) is absorbed by the human alveoli.

According to an aspect of the present invention, the second dust passage forms an angle of 120 degrees or more and 150 or less with respect to the first dust passage and the dust flow direction, and is branched from the first dust passage. A dust measuring device is provided.

In addition, according to an aspect of the present invention, the dust measuring apparatus further includes a temperature sensor for measuring the temperature of the fluid flowing through the first hole, the fan corresponding to the temperature measured by the temperature sensor Provided is a dust measuring device, characterized in that the flow rate flowing into the first hole is varied.

The effects of the mobile terminal and its control method according to the present invention will be described below.

The present invention can classify the dust particles in a specific fraction according to the size through the particle classification structure, it is possible to measure the concentration of fine dust deposited in the alveoli when a person in the air breathing.

The present invention is an optical dust measuring device, by forming a path in which dust is concentrated in the light irradiating portion through the particle focusing structure can increase the accuracy in dust sensing.

Further scope of the applicability of the present invention will become apparent from the following detailed description. However, various changes and modifications within the spirit and scope of the present invention can be clearly understood by those skilled in the art, and therefore, specific embodiments, such as the detailed description and the preferred embodiments of the present invention, are given by way of example only. Should be.

1 and 2 are diagrams for explaining the fraction in which fine dust is deposited in the alveoli of the human depending on the size of the particles.

3 is a block diagram including the main configuration of the dust measuring apparatus according to an embodiment of the present invention.

4 is a perspective view of a dust measuring device according to an embodiment of the present invention.

5 is a cross-sectional view taken along the line A-A 'of FIG. 4 for explaining a dust measuring apparatus according to an embodiment of the present invention.

6 and 7 are views for explaining the effect of connecting the first dust passage and the second dust passage at an obtuse angle in one embodiment of the particle flow path of the present invention.

FIG. 8 is an enlarged view of region B of FIG. 5.

9 is a cross-sectional view along the line A-A 'of FIG. 4 for explaining the dust measuring apparatus according to another embodiment of the present invention.

FIG. 10 is a view illustrating dust moving paths by particle size in the particle fractionation passage of the present invention. FIG.

FIG. 11 is a diagram illustrating a fraction in which dust is classified according to particle size through a particle sorting flow path according to the present invention compared with a PM10 definition curve. FIG.

FIG. 10 is an enlarged view of area A of FIG. 9.

Hereinafter, embodiments of the present disclosure will be described in detail with reference to the accompanying drawings, and the same or similar components will be given the same reference numerals regardless of the reference numerals, and redundant description thereof will be omitted. The suffixes "module" and "unit" for components used in the following description are given or mixed in consideration of ease of specification, and do not have distinct meanings or roles. In addition, in the following description of the embodiments disclosed herein, when it is determined that the detailed description of the related known technology may obscure the gist of the embodiments disclosed herein, the detailed description thereof will be omitted. In addition, the accompanying drawings are intended to facilitate understanding of the embodiments disclosed herein, but are not limited to the technical spirit disclosed herein by the accompanying drawings, all changes included in the spirit and scope of the present invention. It should be understood to include equivalents and substitutes.

Terms including ordinal numbers such as first and second may be used to describe various components, but the components are not limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

When a component is said to be "connected" or "connected" to another component, it may be directly connected to or connected to that other component, but it may be understood that another component may be present in the middle. Should be. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that there is no other component in between.

Singular expressions include plural expressions unless the context clearly indicates otherwise.

In this application, the terms "comprises" or "having" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or a combination thereof.

1 and 2 are diagrams for explaining the fraction in which fine dust is deposited in the alveoli of the human depending on the size of the particles.

Fine dust is a particulate matter, which is more likely to be deposited in the human lungs than gaseous substances. Therefore, there is a possibility of causing a greater adverse effect on human health than other air pollutants.

The fine dust can be deposited at different depths depending on the particle size. Microparticles less than 10μm in diameter can be deposited in the lungs through the respiratory tract, which can be a standard for distinguishing fine dust.

Figure 1 (a) is a view illustrating a region where fine dust is deposited in the breathing process. The fine dust is deposited in the respiratory process includes a head region corresponding to the oral cavity, a thoracic region corresponding to the trachea, and a respiratory region corresponding to the alveoli.

Fine dust can be deposited on inhalable dust that can be deposited in the head region, thoracic dust, and respiratory region, depending on the particle size. It can be classified as respirable dust, and FIG. 1 (b) shows the fraction deposited in each region according to the particle size.

Specifically, Figure 1 (b) is the horizontal axis of the particle size (

), And the vertical axis represents the fraction deposited in each region. If the fraction to be deposited (Fraction) is 1, it means that all of the contact with the surface in each area is deposited, while 0 means that it is not deposited.

The head region is a region corresponding to the oral cavity in the human body, and may have a small effect on the human body. Therefore, the concentration of dust that can be deposited in the thoracic region can be an important indicator of fine dust concentration.

FIG. 1 (b) shows the PM (Particular Matter) 10 fraction curve and PM (Particular Matter) 2.5 fraction curve in addition to the fraction curves deposited in the respective regions. The PM10 fraction curve is similar to the dust fraction curve that can be deposited below in the Thoracic Region so that the PM10 fraction curve can be an important indicator of fine dust concentration.

The dust fraction curve that can be deposited in the thoracic region is a fraction curve based on the dust passing through the head region. However, the PM10 fraction curve is a fraction curve based on dust in the atmosphere. Therefore, the PM10 fraction curve may be easier to classify the dust that can penetrate below the thoracic region of the human body from the dust in the atmosphere.

The PM 10 fraction curve can be defined as follows.

Specifically, FIG. 2 (a) shows the PM fraction curve as defined in the horizontal axis category different from that of FIG. 1 (b), and FIG. 2 (b) shows the corresponding data.

The PM 10 fraction curve is a standard published in 1997 by the US Environmental Protection Agency. In some cases, the PM 10 fraction curve may be expressed by another equation, but the characteristic of displaying a sigmoid curve based on PM 10 is not different.

Hereinafter, the dust measuring apparatus according to the present invention, which corresponds to the PM10 fraction curve, may classify dust and increase the accuracy of dust measurement.

3 is a block diagram including the main configuration of the dust measuring apparatus according to an embodiment of the present invention.

The dust measuring apparatus may include a sensing unit 110, a flow path forming unit 120, a fan 130, a memory 140, a power supply unit 150, and an interface unit 160.

The components shown in FIG. 3 are not essential to implementing the dust measurement apparatus, so that the dust measurement apparatus described herein may have more or fewer components than those listed above.

More specifically, the sensing unit 110 of the components may include a temperature sensor 111, dust sensor 112.

The temperature sensor 111 measures the temperature of the fluid sucked into the dust measuring device, the dust sensor 112 is a light irradiation unit 112a for irradiating light to the optical dust sensor 112 and a light detector for receiving the scattered light And may include 112b.

The light detector 112b may convert light scattered by the light irradiated by the light emitter 112a into dust and measure the number of light particles through the converted electric signal.

The flow path forming unit 120 may include a particle sorting flow path 121 that classifies the flow path according to the size of the dust particles and a particle concentration flow path 122 that focuses the dust particles for accurate sensing through the optical dust sensor 112. Can be.

The particle sorting flow passage 121 is a flow path structure that classifies the dust sucked by the dust measuring device into a specific fraction according to the particle size and guides the dust sensor 112 to the sensing point. The particle sorting passage 121 may include a structure in which the dust passage is branched at an obtuse angle, a structure including a bent portion in the dust passage, a structure in which a cross-sectional width of the dust passage is varied, and the like. Specifically, the particle sorting passage 121 may use different inertia and resistive forces depending on the size of the dust particles. If the dust is heavy, the characteristic of maintaining the path by the inertial force is strong, and if the dust is large and the flow rate is fast, the resistance may be large. The specific particle flow path 121 will be described in detail with reference to FIGS. 4 through 11.

The particle concentration flow passage 122 corresponds to a point where the dust sensor 112 senses dust, and has a flow path structure that improves accuracy in dust sensing by collecting and passing dust through a point where dust is sensed. Particle concentration channel 122 is a structure that focuses the dust using the vortex phenomenon, in this regard will be described in detail with reference to FIG.

The fan 130 may provide power for the dust measuring device to introduce and discharge dust. The fan 130 provides power to move the fluid inside the dust measurement device. The speed at which the fan 130 moves the fluid may affect the resistance to the dust. That is, the rotation speed of the fan 130 may be controlled by the controller 170 because the fraction in which the particles are classified in the particle flow path 131 may be different.

In addition, the fan 130 may vary the rotation speed according to the temperature of the fluid measured by the temperature sensor 111. The reason for this is to vary the fraction in which particles are classified in the particle classification flow path 131 according to the temperature of the fluid.

The memory 140 may data the rotation speed of the fan 130 in response to the temperature of the fluid measured by the temperature sensor 111, and the controller 170 may control the fan 130 based on the data stored in the memory 140. You can control the speed.

The power supply unit 150 receives power from an external power source and an internal power source under the control of the controller 170 to supply power to each component included in the dust measuring device. The power supply unit 150 includes a battery, which may be a built-in battery or a replaceable battery.

The interface unit 160 is connected to the dust measuring device to serve as a passage with various kinds of external devices. The interface unit 160 may include an external charger port, a wired / wireless data port, a memory card port, a port for connecting a device equipped with an identification module, and audio I / O. It may include at least one of an (Input / Output) port, a video I / O (Input / Output) port, and an earphone port. The dust measurement apparatus may connect an external device to the interface unit 160 to perform appropriate control related to the connected external device.

The controller 170 may be connected to the components constituting the dust measuring apparatus and perform a function of controlling each component. In addition, the calculator 110 may perform a function of an operation unit for generating new data for analyzing data acquired through the sensing unit 110.

4 is a perspective view for explaining a dust measuring apparatus according to an embodiment of the present invention, Figure 5 is a cross-sectional view taken along the line AA 'of FIG.

The dust measuring apparatus according to the present invention may include a first hole 311 through which the fluid 400 containing dust is introduced and a second hole through which the fluid introduced through the first hole 311 flows out. A first housing 310 including a 312, a fan 340 for providing power to the fluid 400 flows into the first hole 311 and outflow into the second hole 312, the first housing jing 310 Mounted in the first dust passage 320 and the first housing 310 to communicate with the first hole 311 and the second hole 312 and branched from the first dust passage 320. The second dust passage 330 communicating with the hole, and the dust sensing unit 340 for sensing the dust passing through the second dust passage 330.

In the dust measuring apparatus according to the present invention, the structure of classifying the dust introduced into the first hole 311 into a specific fraction according to the particle size may correspond to the particle sorting passage 121 described with reference to FIG. 3.

In one embodiment of the particle sorting passage 121, the second dust passage 330 may be branched by forming an obtuse angle with respect to the dust flow direction with the first dust passage 320. This is a feature corresponding to region B in FIGS. 4 and 5. In the region B, the large particles of heavy dust go straight through the first dust passage 320 due to the inertia, but the small particles of light weight have a low inertia force, and the ratio of the particles entering the second dust passage 330 1 The rate of passage through dust paths may be comparable. In this regard, it will be described in detail with reference to Figures 6 and 7.

In addition, in one embodiment of the particle flow path 121, the first dust passage 330 may have a different width of the cross section through which the fluid 400 passes before and after the point where the second dust passage is branched, and the second dust passage It may include a stepped portion at the branch. Since the width of the cross section is related to the flow velocity and thus affects the resistance of the dust, the cross-sectional width of the first passage in region B may affect the fraction of dust that can enter the second dust passage. In addition, the second dust passage 330 may include a section in which the width of the cross section through which the fluid 400 passes gradually increases or decreases at the point where the second dust passage 330 is branched. In this regard, it looks at in detail through FIG.

In addition, in one embodiment of the particle flow path 121, at least one bent portion between the point where the first dust passage 320, the first hole 311 and the second dust passage 330 is branched. It may include. In addition, the second dust passage 330 may include at least one bent portion between a point where the second dust passage 330 is branched and a point C region where the dust sensing unit 340 senses dust. . Heavy dust accumulates on the wall of the passage while maintaining straightness by inertia, and light dust can change the flow path along the curvature of the bent portion. Thus, the bend may serve to filter heavy dust inside the fluid. In this regard, it will be described in detail with reference to FIG.

The dust sensing unit 340 may include a light source 341 for irradiating the light 500 to the C region with an optical dust sensor and a detector 342 for receiving the scattered light. In the region C, the dust introduced into the second dust passage 330 passes from the region B of the dust introduced into the first hole 311, and the detector 342 converts the light received in the region C into an electrical signal. The number of dusts passing through the area can be measured. That is, the dust sensing unit 340 may measure the number of dusts (or concentrations) corresponding to the specific fractions in the air by measuring the number of dusts classified at a specific fraction by the particle fractionation passage.

In the dust measuring apparatus according to the present invention, the dust may be concentrated and flow in the region C. FIG. This is a feature corresponding to the particle concentration channel 122 in FIG. The dust sensing unit 340 according to the present invention senses dust by irradiating light. When the dust flows out of an area irradiating light, the accuracy of the dust sensing unit 340 sensing dust may be reduced. Therefore, in order to increase the accuracy of dust sensing, dust needs to be concentrated and flow to the area irradiated with light. In this regard, it looks at in detail with reference to FIG.

The fan 350 may provide power to suck air or fluid in the atmosphere from the first hole 311 and power to discharge air or fluid sucked into the second hole 312. The speed at which the fan 350 draws fluid is related to the resistance to the dust particles. The resistance may affect the fraction of dust entering the second dust passage 330 according to the particle size in the region B together with the inertia force.

The dust measuring apparatus according to the present invention may be connected to an external device through the interface 360 to transmit or receive data. The interface 360 may correspond to the interface unit 160 described with reference to FIG. 3.

In the dust measuring apparatus according to the present invention, light that is not scattered from the light irradiated by the light source 341 through the prism 370 may be absorbed through the prism 370. When the light emitted from the light source 341 is reflected on the inner wall of the second dust passage 330, the detector 342 may receive the light and may cause an error in dust sensing.

Therefore, the prism 370 according to the present invention can prevent the light irradiated from the light source 341 to be directly introduced, scattered inside and emitted to the outside. In some cases, the prism 270 may include a light absorber on one surface.

The dust measuring apparatus according to the present invention may include a temperature sensor 380 capable of measuring the temperature of the fluid introduced into the first hole 311. 5 illustrates an embodiment in which the temperature sensor 380 is provided in the first dust passage 320. However, the position of the temperature sensor 380 may be provided in the second dust passage 330.

Hereinafter, the particle flow path 131 (see FIG. 3) that classifies the dust introduced into the first hole 311 at a specific fraction according to the particle size will be described in detail.

6 and 7 are diagrams for explaining an effect of connecting the first dust passage 320 and the second dust passage 330 at an obtuse angle in one embodiment of the particle fractionation passage of the present invention.

According to the present invention, the second dust passage 330 is branched with an obtuse angle with respect to the dust flow direction of the first dust passage 320 in order to classify the dust introduced into the dust measuring device according to the particle size. .

Specifically, in the dust measuring apparatus of the present invention, the second dust passage 330 forms an angle of 120 degrees or more and 150 or less based on the first dust passage 320 and the dust flow direction, and the first dust passage 320. Can be branched).

FIG. 6 (a) illustrates an embodiment in which the second dust passage 330 is branched to form the 135 degree with the first dust passage 320 in region B. FIG. An embodiment in which the dust passage 330 is branched perpendicular to the first dust passage 320 is shown.

In the present invention, the specific fraction for classifying the dust introduced into the dust measuring device according to the particle size may be a fraction corresponding to the PM 10 fraction curve described in FIGS. 1 and 2. That is, according to the present invention, the more accurate the classification of dust introduced into the dust measuring apparatus into the PM10 fraction curve according to the particle size is obtained.

The PM10 fraction curve is characterized by having a sigmoid curve shape with respect to PM10 as defined.

FIG. 7 is a graph showing a fraction curve corresponding to FIGS. 6 (a) and 6 (b).

When the second dust passage 330 is branched at 135 degrees from the first dust passage 320, the fraction curve has a sigmoid curve based on a particle size of 10 μm, whereas the second dust passage 330 is When vertically branched from the first dust passage 320, it can be seen that the particle size has a sigmoid curve based on the particle size smaller than 10 μm.

Also, when the second dust passage 330 is branched at 135 degrees from the first dust passage 320, the second dust passage 330 has a steeper slope than that when the second dust passage 330 is vertically branched at the first dust passage 320. You can check. That is, when the second dust passage 330 is branched at 135 degrees from the first dust passage 320, it can be confirmed that the ability to classify based on PM10 is excellent.

Accordingly, in the present invention, the second dust passage 330 is branched by forming an obtuse angle with respect to the dust flow direction with the first dust passage 320, so that the dust measuring apparatus of the present invention is configured to remove dust particles so as to correspond to the PM10 fraction curve. You can sort by size.

Hereinafter, another embodiment of the particle sorting flow path 122 (see FIG. 3) classifying the dust introduced into the dust measuring device according to the particle size to correspond to the PM10 fraction curve will be described.

FIG. 8 is an enlarged view of region B of FIG. 5.

In FIG. 8, the second dust passage 330 forms an obtuse angle with respect to the flow direction of the first dust passage 320 and the dusts 401 and 402. The dusts 401 and 402 may have different fractions depending on the particle size due to inertia and resistance at the point where the second dust passage 330 is branched. The inertial force is related to the weight of the dust 401, 402, and the resistive force may be related to the size and flow rate of the dust 401, 402.

The large dust 401 maintains straightness because the inertia force is greater than the resistivity, and the fraction of the dust 401 flowing into the second dust passage 330 is small. However, the dust 402 having the small particles may have the same inertia force and resistance force, and thus the fraction introduced into the second dust passage 330 may reach half.

That is, when it is assumed that the flow rate flowing into the second dust passage 330 and the flow rate maintaining the first dust passage 320 are the same at the point where the second dust passage 330 is branched, the second dust passage 330 The concentration of the large dust 402 in the fluid introduced into) may be close to zero, and the small dust 403 may be the same as the concentration in the atmosphere.

Therefore, the dust measuring apparatus of the present invention can sense the concentration of fine dust in the atmosphere, in particular, the concentration of dust that may be deposited on the alveoli by sensing the dust of the second dust passage 330.

In order to approximate the fraction of the dust flowing into the second dust passage 330 according to the particle size to the PM10 fraction curve described in FIGS. 1 and 2, the dust measuring apparatus of the present invention uses the dust in the first dust passage 320. The width of the cross section through which the 401 and 402 pass may differ before and after the point where the second dust passage 330 branches.

8 (a) illustrates an embodiment in which the first dust passage cross section width h1 before the point where the second dust passage 330 is branched is smaller than the cross section width h2 after the point where the second dust passage 330 is branched. It is shown.

8 (b) also shows that the first dust passage cross-sectional width h1 before the point where the second dust passage 330 is branched is larger than the cross-sectional width h2 after the point where the second dust passage 330 is branched. An example is shown.

The cross-sectional width of the first dust passage 320 is related to the flow rate, which is related to the resistance to the dust particles. Therefore, the present invention may adjust the fraction of the particle size of the dust flowing into the second dust passage 330 by varying the cross-sectional width of the first dust passage 320 before and after the branching point to the second dust passage 330.

In addition, in the dust measuring apparatus of the present invention, the width of the cross section through which the dusts 401 and 402 pass in the first dust passage 320 is different before and after a point where the second dust passage 330 is branched to form a height difference hd. It may include a stepped portion. The stepped portion may affect the fraction of the particle size of the dust flowing into the second dust passage 330 in a configuration to block or return the path of the dust.

In addition, the dust measuring apparatus of the present invention may include a cumulative increase or decrease in the cross-sectional width of the second dust passage 330 at the point where the second dust passage 330 is branched.

Specifically, FIG. 8 illustrates an embodiment in which the cross-sectional width of the second dust passage 330 increases from h3 to h4 at the point where the second dust passage 330 is branched.

The width of the cross section of the second dust passage 330 is related to the flow rate flowing into the second dust passage 330. Therefore, by adjusting the width of the cross section in the section flowing into the second dust passage 330, the fraction of the particle size of the dust flowing into the second dust passage 330 may be adjusted to be close to the PM10 fraction curve.

Hereinafter, the first dust passage and the second dust passage include a curved portion so that the dust flowing into the second dust passage 330 is classified at a PM10 fraction according to the particle size.

9 is a cross-sectional view along the line A-A 'of FIG. 4 for explaining the dust measuring apparatus according to another embodiment of the present invention.

In the dust measuring apparatus according to the present invention, the dust flowing into the second dust passage 330 is classified into a specific fraction according to the particle size, so that the first dust passage 320 communicates with the first hole 311. At least one curved portion 322a and 322b may be included between the two dust passages 330.

The large dust flowing into the first hole 311 may be attached to one side of the passage by going straight without changing the path in the at least one bent portion (322a, 322b). That is, at least one of the bent portions 322a and 322b may serve to filter large dust from the dust passing through the bent portions 322a and 322b.

In particular, the first dust passage 320 may include a first bent portion 322a through which the first dust passage 320 communicates with the first hole 311.

In the first curved portion 322a, a large amount of dust introduced into the first hole 311 is accumulated on one surface of the first curved portion 322a while maintaining the straightness, and the second curved portion 320 along the first dust passage 320. The dust passage 330 may be prevented from flowing to the branching point.

That is, the dust measuring apparatus of the present invention includes the bent portions 322a and 322b in the first dust passage 320 before the branch where the second dust passage 330 is branched, where the second dust passage 330 is branched. It can prevent large dust from reaching.

In addition, in the second dust passage 330, at least one curved portion 322a, 322b is disposed between a point where the second dust passage 230 is branched and a point where the dust sensing unit 340 senses dust. It may include.

The curved portions 322a and 322b of the second dust passage 330 may serve to remove large dust introduced into the second dust passage 330. That is, despite the structure in which the bent portions 322a and 322b of the first dust passage 330 and the second dust passage 330 are connected at an obtuse angle, the large dust introduced into the second dust passage is the second dust passage 230. Filtering through the bends 322a and 322b.

In particular, the second dust passage may include a second bent portion 322b for vertically introducing the fluid to a point where the dust sensing unit 340 senses dust, and the second bent portion 322b is the second bent portion 322b. Including a groove 333 recessed in the path direction of the fluid flowing into the), it is possible to filter large dust from the fluid flowing to the point where the dust is sensed.

FIG. 10 is a view illustrating dust moving paths by particle size in the particle fractionation passage of the present invention, and FIG. 11 is a diagram illustrating a fraction in which dust is classified according to particle size through the particle fractionation passage of the present invention in comparison with a PM10 definition curve. Drawing.

10 (a) to 10 (e) are diagrams illustrating paths of the dust 400 passing through the first dust passage 320 and the second dust passage 330 by particle size, respectively.

10 (a) is a view showing a path of dust 400 having a size of 100 μm. The dust 400 having a size of 100 μm is introduced into the first hole 311 to maintain straightness by inertia, and does not flow to the point where the second dust passage 200 of the first dust passage 320 is branched. That is, the dust 400 having a size of 100 μm may be filtered by the bent portion of the first dust passage 320.

10 (b) is a view showing a path of the dust 400 having a size of 20μm. The dust 400 having a size of 20 μm is kept straight due to inertia at the point where the second dust passage 330 is branched. That is, the degree of inflow into the second dust passage 330 may be minute. In addition, the dust 400 having a size of 20 μm introduced into the second dust passage 330 may be filtered by the bent portion of the second dust passage 330.

10 (c) is a view showing a path of dust 400 having a size of 15 μm. The dust 400 having a size of 15 μm may be introduced into the second dust passage 330 more than the dust 400 having a size of 20 μm, but the first dust passage may be kept straighter than the ratio of the dust having the size of the dust. There is more dust to keep track of 320.

10 (d) is a view showing a path of the dust 400 having a size of 10 μm. It can be seen that the dust 400 having a size of 10 μm is introduced into the second dust passage 330 more than the dust 400 having a size of 15 μm. However, 10 μm is a particle size that is a reference in the PM10 fraction curve, and more dust is maintained to maintain the straightness than the ratio introduced into the second dust passage 330 to maintain the path of the first dust passage 320.

10 (e) to 10 (h) are diagrams showing paths of dust 400 having sizes of 2.5 μm, 1 μm, 0.5 μm, and 0.3 μm, respectively. It can be seen that the ratio classified as the passage 330 reaches half. That is, half of the size of the dust flowing into the first hole 311 may be introduced into the second dust passage 330. Therefore, if the flow rate flowing into the second dust passage 330 reaches half of the flow rate flowing into the first hole 311, the dust concentration per unit flow rate passing through the second dust passage is equal to the dust concentration of the corresponding size in the atmosphere. can do. That is, FIGS. 10 (e) to 10 (h) are particle sizes having a fraction close to 1 in the fraction curve.

That is, the dust measuring apparatus of the present invention may have a different fraction of dust flowing into the second dust passage depending on the size of the particles, and the fraction may correspond to a PM10 positive curve.

Therefore, the dust measuring apparatus of the present invention may measure the concentration of dust classified to correspond to the PM10 positive curve in the dust in the air by sensing the dust introduced into the second dust passage.

The present invention is an optical dust measuring apparatus, hereinafter, looks at a structure for sensing the number accurately by concentrating particles classified close to the ideal PM10 positive curve.

FIG. 12 is an enlarged view of area A of FIG. 9.

The second dust passage 330 of the present invention forms a receiving space and includes a third hole 335 through which the fluid flows and a fourth hole 336 through which the fluid introduced through the third hole 335 flows out. The second housing 330b, the first dust passage 320 (refer to FIG. 9), the inflow passage 330a for introducing the fluid into the third hole 335, and the second hole (4) in the fourth hole 336. 312 (see FIG. 9) may include an outlet passage 330c for outflowing the fluid.

The dust sensing unit 340 may sense dust passing through the second housing 330b.

The dust sensing unit 340 is provided on a light source 341 for irradiating light from one surface of the second housing 330b, and a detector 342 provided on the other surface of the second housing 330b and receiving scattered light. It may include.

The second housing 330b may include a third hole 335 and a fourth hole 336 facing the symmetry plane so that the dust 400 flows along a straight path crossing the second housing 330b. have. The symmetrical structures of the third hole 335 and the fourth hole 336 may correspond to the particle focus passage 122 described with reference to FIG. 3.

The third hole 335 and the fourth hole 336 are provided to face the symmetry plane of the second housing 330b, so that the third hole 335 and the fourth hole 336 face each other in a central axis. Can be formed. Through this, the dust introduced into the third hole 335 due to the inertia force generated when moving through the narrow hole and the vortex generated in the symmetrical direction may be discharged to the fourth hole 336 while maintaining the straightness.

In this case, the light source 341 of the dust sensing unit 340 may irradiate light toward a straight path through which the dust 400 flows, and measure the number of focused dusts.

The third hole 335 has a diameter smaller than the width of the area receiving the light scattered by the detector 342, and a straight path through which the dust 400 flows passes through the center of the area receiving the light scattered. It may be provided on one surface of the second housing 330b.

That is, the small particles moved to the point where the dust is sensed are focused by the particle converging flow channel at a certain distance in the area for receiving the scattered light in the detector 342, thereby obtaining a result closer to the true value in the signal processing. have.

Although the third hole 335 and the fourth hole 336 may have the same diameter, in some cases, the second housing 330b and the outlet passage 330c communicate with each other without the fourth hole 336, or The diameter of the four holes 336 may be larger than the third hole 335.

In addition, the dust measuring apparatus according to the present invention may include a prism 270 that receives light that is not scattered by the dust from the light irradiated from the light source 341. The prism 270 may absorb the light emitted from the light source 341 to prevent the detector 342 from receiving other light in addition to the light scattered by the dust.

The foregoing detailed description should not be construed as limiting in all aspects, but should be considered as illustrative. The scope of the present invention should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent scope of the present invention are included in the scope of the present invention.

Claims (18)

1. In the dust measuring device,

   A first housing forming a receiving space, the first housing including a first hole through which a fluid containing dust flows in and a second hole through which the fluid introduced through the first hole flows out;

   A fan providing power to the fluid to flow into the first hole and to flow out of the second hole;

   A first dust passage mounted in the first housing and communicating with the first hole and the second hole;

   A second dust passage mounted in the first housing, branched from the first dust passage, and in communication with the second hole; And,

   A dust sensing unit configured to sense dust passing through the second dust passage; Including,

   The second dust passage is

   The dust measuring apparatus, characterized in that the branched to form an obtuse angle with respect to the dust flow direction and the first dust passage in order to classify the dust introduced through the first hole in a specific fraction according to the particle size.
2. The method of claim 1,

   The first dust passage is

   And a width of a cross section through which the fluid passes before and after a point at which the second dust passage is branched.
3. The method of claim 2,

   The first dust passage is

   And a stepped portion at a point at which the second dust passage is branched.
4. The method of claim 1,

   The first dust passage is

   And at least one bent portion between a point communicating with the first hole and a point at which the second dust passage is branched.
5. The method of claim 4, wherein

   The at least one bent portion

   And a first bent portion in which the first dust passage is in communication with the first hole.
6. The method of claim 1,

   The second dust passage is

   And a section in which the width of the cross section through which the fluid passes gradually increases or decreases at the point where the second dust passage is branched.
7. The method of claim 1,

   The second dust passage is

   And at least one bent portion between the point where the second dust passage is branched and the point where the dust sensing unit senses dust.
8. The method of claim 7, wherein

   The at least one bent portion

   And a second curved portion for vertically introducing the fluid to a point where the dust is sensed.
9. The method of claim 8,

   The second bent portion

   And a groove recessed in a direction of a path of the fluid flowing into the second bent portion.
10. The method of claim 1,

    The second dust passage is

    A second housing defining an accommodation space and including a third hole through which the fluid flows in and a fourth hole through which the fluid introduced through the third hole flows out;

    An inflow passage branched from the first dust passage to introduce the fluid into the third hole;

    And an outlet passage through which the fluid flows from the fourth hole to the second hole.

    The second housing

    And a third hole and a fourth hole, facing the symmetry plane, so that dust flows along a straight path crossing the second housing.
11. The method of claim 10,

    The dust sensing unit

    A light source irradiating light from one surface of the second housing; And,

    A detection unit provided on the other surface of the second housing and receiving scattered light;

    The light source is

    And dust irradiating light toward the straight path through which the dust flows.
12. The method of claim 11,

    The third hole

    It has a diameter smaller than the width of the area for receiving the light scattered by the detector,

    And a straight path through which the dust flows is provided on one surface of the second housing so as to pass through the center of the area receiving the scattered light.
13. The method of claim 11,

    The third hole

    Dust measuring apparatus, characterized in that having the same diameter or smaller diameter than the fourth hole.
14. The method of claim 1,

    And a flow rate flowing into the second dust passage corresponds to half of a flow rate flowing through the first hole.
15. The method of claim 1,

    The dust sensing unit

    Dust measuring apparatus, characterized in that for measuring the number of dust compared to the unit flow rate flowing into the second dust passage.
16. The method of claim 1,

    The specific fraction is

    Dust measuring device, characterized in that corresponding to the fraction of PM (Particular Matter) absorbed into the alveoli of the human body.
17. The method of claim 1,

    The second dust passage is

    A dust measuring device, characterized in that formed in the first dust path and the angle of more than 120 degrees and less than 150, based on the first dust path and the dust flow direction.
18. The method of claim 1,

    The dust measuring device

    Further comprising a temperature sensor for measuring the temperature of the fluid flowing through the first hole,

    The fan is

    Dust measuring apparatus, characterized in that for varying the flow rate flowing into the first hole in response to the temperature measured by the temperature sensor.

Images