KR102337848B1 - Apparatus for measuring airborne microbial, measuring method using the same and air conditioning device having the same - Google Patents

Abstract

The present invention relates to a device for measuring airborne microorganisms, a measuring method using the same, and an air conditioner having the same. Airborne microorganism measuring apparatus includes a measuring case, a collecting unit in which airborne microorganisms are disposed, a light emitting unit irradiating light having a predetermined wavelength to the collecting unit, a first light receiving unit and the second light receiving unit receiving the light irradiated from the light emitting unit, and a first light-receiving filter and a second light-receiving filter for passing light having a predetermined wavelength; The unit, the collecting unit, the second light receiving filter, and the second light receiving unit are sequentially arranged on a straight line, and the first light receiving filter and the second light receiving filter are provided to pass different wavelengths.

Description

Airborne microorganism measuring device, measuring method using the same, and air conditioning device having the same

The present invention relates to a device for measuring airborne microorganisms, a measuring method using the same, and an air conditioner having the same.

Recently, as buildings minimize the introduction of external gas to save energy and become airtight, indoor air pollution is becoming more and more serious. Accordingly, various legal regulations on indoor pollutants are gradually being strengthened.

The indoor pollutants include (1) particulate pollutants such as fine dust and asbestos, (2) gaseous pollutants such as carbon dioxide, formaldehyde, volatile organic compounds (VOCs), and (3) viruses; Biological contaminants such as molds and bacteria may be included.

In particular, the biological contaminants may adversely affect the health of the user. Recently, a technology for measuring the amount of such biological pollutants and purifying indoor air based thereon has been developed.

Prior literature information related to this technology is as follows.

(1) 1st Prior Document: Registered Patent 10-1163641 (Registered on July 2, 2012), Real-time measurement device and method for airborne microorganisms in the gas phase using a microbial dissolution system

In the first prior document, airborne microorganisms are collected and the ATP (Adenosine triphosphate) reaction luminescent agent is collected in the collecting unit, and ATP extracted by the microbial dissolution system and microbial dissolution system capable of ATP extraction is collected in the collecting unit with the ATP reaction luminescent agent and It characterized in that it is configured to include a light receiving unit to detect the light generated in response.

(2) 2nd Prior Document: Registered Patent 10-1355301 (Registered on January 17, 2014), detection device and detection method for detecting biological particles in the air

The detection device of the second prior art is floating in the air based on the amount of fluorescence received by the light-emitting element, the light-receiving element for receiving fluorescence, and the light emitted from the light-emitting element when the light emitted from the light-emitting element is irradiated to the air introduced into the detection apparatus. It is characterized in that it comprises a calculation unit for calculating the amount of microbial particles.

According to the conventional airborne microorganism measuring apparatus according to such a prior document, the following problems occur.

(1) The conventional airborne microbes measure the concentration of airborne microbes, and the dead microbes are also measured. The subject of regulation is living microorganisms, and there is a problem that the concentration of airborne microorganisms including dead microorganisms may not be meaningful in measurement.

(2) In addition, in order to know the viability of airborne microorganisms that measure only living microorganisms through the conventional airborne microorganism measuring device, the measured airborne microorganisms need to be cultured, so it takes a long time (about 1 to 7 days). there was.

(3) In addition, the conventional airborne microbial measuring device requires a rather complicated structure and many parts, and has a problem in that expensive lasers and lenses are used, so that the cost of manufacturing the device must be high.

(4) And, since the conventional airborne microorganism measuring device has a large volume and has to be located in a specific place as a single device, there is a problem in that it is limited to be provided in a specific home appliance or portable device.

In order to solve this problem, the present embodiment aims to propose an apparatus for measuring airborne microorganisms for quickly measuring the viability of airborne microorganisms.

Another object of the present invention is to provide a method for measuring the viability of airborne microorganisms using the airborne microorganism measuring device, and an air conditioner provided with the airborne microorganism measuring device.

Airborne microorganism measuring apparatus according to the spirit of the present invention includes a measuring case, a collecting unit in which airborne microorganisms are disposed, a light emitting unit irradiating light having a predetermined wavelength to the collecting unit, and a first light receiving unit receiving the light irradiated from the light emitting unit. and a first light receiving filter and a second light receiving filter for passing the second light receiving unit and light having a predetermined wavelength, wherein the light emitting unit, the collecting unit, the first light receiving filter, and the first light receiving unit are formed in a straight line. are sequentially arranged, and the light emitting unit, the collecting unit, the second light receiving filter and the second light receiving unit are sequentially arranged in a straight line, and the first light receiving filter and the second light receiving filter are provided to pass different wavelengths do.

The first light receiving filter may be provided to pass light in a wavelength range of 200 to 300 nm, and the second light receiving filter may be provided to pass light in a wavelength range of 350 to 900 nm.

In the measurement case, an air flow path in which the collecting unit is disposed, a light input path in which the light emitting unit is disposed, a first light receiving path in which the first light receiving filter and the first light receiving unit are disposed, and the second light receiving filter and the second light receiving unit are provided. A second light receiving path to be disposed may be included.

The light incident path, the first light receiving path, and the second light receiving path may be arranged in a straight line with the air path interposed therebetween.

The first light receiving path and the second light receiving path may be formed inside the rotatably provided light receiving unit.

The light receiving unit may be installed in the measurement case so that the center of the light receiving path coincides with the center of the first light receiving path, and rotates so that the center of the light receiving path coincides with the center of the second light receiving path. .

The measurement case may include a blocking wall separating the first light receiving path and the second light receiving path.

The air passage may include an air inlet through which air is introduced, an air outlet through which air is discharged, an air filter installed in the air inlet, and a charging unit for charging airborne microorganisms flowing into the air passage.

The light emitting unit may include a first light emitting unit and a second light emitting unit for irradiating light of different wavelengths.

In addition, the air conditioner according to the spirit of the present invention includes the air-borne microorganism measuring device.

In addition, in the method for measuring airborne microorganisms according to the spirit of the present invention, airborne microorganisms are disposed in a collecting unit, light having a predetermined wavelength is irradiated from the light emitting unit toward the collecting unit, and the light passing through the collecting unit is transmitted through the first light receiving filter. and the second light-receiving filter passing through each of the second light-receiving filters, the light passing through the first light-receiving filter being received by the first light receiving unit, measuring the first measurement light, and passing light having a wavelength different from that of the first light-receiving filter The light passing through the light receiving filter is received by the second light receiving unit to measure the second measurement light.

When the airborne microorganisms are not disposed in the collecting unit, the first and second reference lights detected by the first light receiving unit and the second light receiving unit are measured, respectively, and a first transmittance of the first reference light and the first measured light are measured. , and a second transmittance may be calculated using the second reference light and the second measurement light.

A first optical density may be measured through the first transmittance, and a second optical density may be measured through the second transmittance.

Viability may be calculated for each type of airborne microorganism using the first optical density and the second optical density.

The first light receiving filter is provided to pass light in a wavelength region of 200 to 300 nm so that the first optical density has a value having a relatively large difference according to the viability, and the second optical density is determined according to the viability To have a value having a relatively small difference, the second light receiving filter may be provided to pass light in a wavelength range of 350 to 900 nm.

According to the proposed embodiment, there is an advantage in that the viability of airborne microorganisms can be measured in a relatively short time through the airborne microorganism measuring apparatus and the measuring method using the same.

In particular, there is an advantage that the viability of airborne microorganisms can be easily measured through one light emitting unit and two light receiving units.

In addition, as the light emitting unit and the light receiving unit are arranged on a straight line, there is an advantage in that the shape of the airborne microbial measuring device is simplified and miniaturized.

In addition, the airborne microorganism measuring device has an advantage in that it can easily collect the air flowing through the air flow path through which air flows, and the charging unit and the collecting unit installed in the air flow path.

In addition, the airborne microbes measuring device is miniaturized and equipped with various miniaturized airborne microbes measuring devices, and may be installed in the air conditioner, and may measure the viability of airborne microbes in the air sucked into the air conditioner.

In addition, there is an advantage that the air flow of the air-borne microorganism measuring device can be smoothly performed using a fan for forced convection of air provided in various air conditioners.

In addition, since the light emitting unit is configured using a laser diode, which is cheaper than a conventional light source (light emitting unit), there is an advantage that the manufacturing cost of the device can be reduced.

In addition, there is an advantage of reducing noise by increasing the transmittance of light by providing the collecting part made of a transparent glass material having electrical conductivity.

1 is a view showing an air conditioner according to an embodiment of the present invention.
FIG. 2 is a view illustrating a cross-section II′ of FIG. 1 .
3 is a diagram illustrating an apparatus for measuring airborne microorganisms according to an embodiment of the present invention.
4 is a diagram illustrating airborne microbes measurement using the airborne microbes measuring device according to an embodiment of the present invention.
5 is a diagram illustrating a method for measuring airborne microorganisms according to an embodiment of the present invention.
6 is a graph for a method for measuring airborne microorganisms according to an embodiment of the present invention.
7 is a view showing an apparatus for measuring airborne microorganisms according to another embodiment of the present invention.
8 is a view showing an apparatus for measuring airborne microorganisms according to another embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. However, the spirit of the present invention is not limited to the presented embodiments, and those skilled in the art who understand the spirit of the present invention will be able to easily suggest other embodiments within the scope of the same spirit.

FIG. 1 is a view showing an air conditioner according to an embodiment of the present invention, and FIG. 2 is a view showing a cross section I-I′ of FIG. 1 .

The air conditioner according to an embodiment of the present invention includes the air conditioner 10 capable of cooling, heating, or air purification operation. Although the air conditioner 10 is illustrated as an example of the air conditioner in FIGS. 1 and 2 , the air conditioner according to the spirit of the present invention may include various devices such as an air purifier, a humidifier, and a dehumidifier.

1 and 2 , in the air conditioner 10 , the case 11 forming the exterior and the case 11 are coupled to the front of the case 11 to form the front exterior of the air conditioner 10 . A front panel 20 is included.

The case 11 may be an indoor unit case disposed indoors in the case of a separate type air conditioner, and may be a case of the air conditioner itself in the case of an integrated air conditioner. Also, the front panel 20 may be understood as a part of the case 11 in a broad sense.

The case 11 is provided to form an inner space, and a heat exchanger 40 and a blowing fan 60 are disposed in the inner space.

The heat exchanger 40 is installed to exchange heat with air flowing through the inside of the case 11 . The heat exchanger 40 includes a refrigerant tube through which a refrigerant flows and a heat exchange fin coupled to the refrigerant tube to increase a heat exchange area.

In addition, the heat exchanger 40 is disposed to surround one side of the blowing fan 60 . For example, the heat exchanger 40 may include a plurality of bent heat exchange units. In addition, a drain part 80 in which condensed water generated in the process of heat exchange between air and refrigerant may be stored is provided at the lower side of the heat exchanger 40 .

The blowing fan 60 includes a fan body 61 as a fixing member, and a plurality of blades 65 fixed to one side of the fan body 61 and arranged to be spaced apart in the circumferential direction. That is, the plurality of blades 65 are arranged in a circumferential direction.

For example, the blowing fan 60 may be provided as a cross-flow fan for discharging the air sucked in the circumferential direction in the circumferential direction.

In addition, in the inside of the case 11, a flow guide is installed near the outer peripheral surface of the blowing fan 60 to guide the flow of air. The flow guide includes a rear guide 71 and a stabilizer 72 .

The rear guide 71 extends from the rear side of the case 11 to the suction side of the blowing fan 60 . Due to this structure, the rear guide 71 smoothly guides intake air toward the blowing fan 60 when the blowing fan 60 rotates. In addition, the rear guide 71 may prevent the air flowing by the blowing fan 60 from being separated from the blowing fan 60 .

The stabilizer 72 is disposed on the discharge side of the blowing fan 60 . The stabilizer 72 is installed to be spaced apart from the outer circumferential surface of the blowing fan 60 to prevent the air discharged from the blowing fan 60 from flowing backward toward the heat exchanger 40 . The rear guide 71 and the stabilizer 72 extend along the longitudinal direction of the blowing fan 60 .

In addition, the case 11 has an inlet 12 through which air is introduced, and an outlet 15 through which the air introduced through the inlet 12 exchanges heat with the heat exchanger 40 and then is discharged to the outside. is included

The suction port 12 may be formed with at least a part opening at an upper portion of the case 11 , and the discharge port 15 may be formed with at least a part opening at the lower side of the case 11 .

A discharge vane 25 provided movably to open or close the discharge port 15 is included at one side of the discharge port 15 . When the discharge vane 25 is opened, the air conditioned in the case 11 may be discharged into the indoor space.

For example, the discharge vane 25 may be provided to be rotatable at a predetermined angle, and as the discharge vane 25 rotates, the discharge port 15 may be opened or closed.

In the suction port 12, a suction grill 13 for preventing the inflow of foreign substances may be formed. In addition, a discharge grill (not shown) may be provided in the discharge port 15 .

In addition, a filter 30 for filtering foreign substances in the air sucked through the suction port 12 is provided inside the case 11 . The filter 30 is disposed inside the suction port 12 to surround the heat exchanger 40 . Air filtered by the filter 30 may flow toward the heat exchanger 40 .

The air conditioner according to the present invention further includes an airborne microorganism measuring device 100 for measuring airborne microorganisms. As shown in FIG. 2 , the airborne microorganism measuring device 100 may be installed inside the air conditioner 10 , in particular, at one side of the filter 30 .

Accordingly, at least a portion of the air filtered by the filter 30 may be introduced into the airborne microorganism measuring device 100 to measure airborne microorganisms. In addition, the airborne microorganism measuring apparatus 100 may be installed adjacent to the discharge port 15 to measure airborne microorganisms in the air discharged from the air conditioner 10 .

In addition, the air-borne microorganism measuring device 100 may be installed in various ways, such as outside the air conditioner 10 , and may be installed in other devices included in the air conditioner. In addition, the airborne microorganism measuring device 100 may be independently installed to measure airborne microorganisms in the air.

3 is a diagram illustrating an apparatus for measuring airborne microorganisms according to an embodiment of the present invention.

As shown in FIG. 3 , the airborne microorganism measuring apparatus 100 includes a measuring case 110 forming an external appearance. For example, the measurement case 110 is provided in the form of a box having an inner space.

A plurality of passages are provided inside the measurement case 110 . In particular, an air flow path 150 penetrating the measurement case 110 is formed inside the measurement case 110 .

3 shows the air flow path 150 extending from one side of the measurement case 110 to one side opposite to the side. However, this is an example, and the air flow path 150 may be formed in various shapes so that air can be introduced into and discharged from the measurement case 110 .

Both ends of the air flow path 150 are referred to as an air inlet 152 and an air outlet 154 . That is, the air inlet 152 and the air outlet 154 may be understood as openings formed in the measurement case 110 .

Referring to FIG. 3 , the air inlet 152 is formed at the right end of the air flow path 150 , and the air outlet 154 is formed at the left end of the air flow path 150 . This is exemplary, and may be provided differently depending on the flow direction of air.

As shown in FIG. 2 , when the airborne microorganism measuring device 100 is installed in the air conditioner 10 , the air forced convection by the blower fan 60 flows in the air flow path 150 . can be In addition, when the airborne microorganism measuring device 100 is installed in another air conditioner, air may flow by a fan provided in the device.

In addition, a fan may be separately provided in the airborne microorganism measuring apparatus 100 . Hereinafter, it is assumed that air flows by a fan provided in another device such as the blower fan 60 .

In addition, an air filter 153 may be provided in the air passage 150 . For example, as shown in FIG. 3 , the air filter 153 may be installed at the air inlet 152 . The air filter 153 may be provided with a mesh network or the like to prevent a relatively large foreign material from flowing into the air passage 150 .

In addition, the air filter 153 may be omitted by being replaced with the filter 30 installed in the air conditioner 10 .

In addition, the airborne microorganism measuring apparatus 100 includes a light input passage 120 and light receiving passages 130 and 140 formed on both sides with respect to the air passage 150 . That is, the light incident passage 120 and the light receiving passages 130 and 140 are provided on a straight line with the air passage 150 interposed therebetween.

Referring to FIG. 3 , the light input passage 120 is formed to extend upward from the air passage 150 , and the light reception passages 130 and 140 extend downward from the air passage 150 . At this time, although the air passage 150, the light input passage 120, and the light receiving passages 130 and 140 are illustrated as being vertically provided, respectively, this is exemplary and may be provided to have a predetermined angle.

In summary, the light incident passage 120 and the light receiving passages 130 and 140 are provided in a straight line with the air passage 150 interposed therebetween, and the light incident passage 120 and the light receiving passages 130 and 140 are It is provided to have a predetermined angle other than 0 degrees (horizontal) with the air flow path 150 .

In addition, the surfaces of the light incident passage 120 and the light receiving passages 130 and 140 may be made of an oxidation-treated material, for example, an oxidation-treated metal. Since each passage functions as a passage through which light travels, the surface is oxidized to prevent light reflection.

Oxidation treatment makes the surface matte or dark so that the diffusely reflected light is absorbed without being reflected. Since the diffusely reflected light is not reflected again, it does not affect the path of a predetermined light, and accordingly, it is possible to measure more accurately.

In this case, the light receiving path includes a first light receiving path 130 and a second light receiving path 140 . The first light receiving path 130 and the second light receiving path 140 are disposed in a straight line with the light receiving path 120 , respectively. In addition, a blocking wall 112 may be provided between the first light receiving path 130 and the second light receiving path 140 to distinguish them from each other.

Various components may be installed in each passage provided in this way.)

In the air passage, the charging parts 156 and 158 and the collecting part 160 spaced apart from the charging parts 156 and 158 are installed. The charging units 156 and 158 are disposed adjacent to the air inlet 152 through which air containing airborne microorganisms is introduced to charge the airborne microorganisms. In addition, the collecting unit 160 is disposed adjacent to the air outlet 154 to collect airborne microorganisms charged by the charging units 156 and 158 . That is, the collecting part 160 is disposed on the rear side of the charging parts 156 and 158 in the air flow direction.

The charging part includes a wire 158 and a pair of plates 156 disposed on both sides with respect to the wire 158 . For example, with reference to FIG. 3 , the wire 158 may be installed to extend from the front to the rear, and the pair of plates 156 may be disposed above and below the wire 158 , respectively.

In addition, a voltage generator (not shown) for applying a voltage to the wire 158 may be further included in the charging unit. The voltage generator (not shown) may be installed in the measurement case 110 or connected from the outside.

The collecting unit 160 may be provided in the form of a flat plate as shown in FIG. 3 . In particular, the collecting unit 160 is disposed between the light incident path 120 and the first light receiving path 130 and the second light receiving path 140 , and the first light receiving path 130 and the second light receiving path 140 . 2 is disposed to be in contact with the light receiving passage 140 .

In addition, the collecting unit 160 may be provided with an electrically conductive glass member. In particular, it may be a glass member coated with ITO (Indium Tin Oxide). Such an ITO glass member has high electrical conductivity and high light transmittance.

As the collecting unit 160 is made of a transparent or translucent material having high transmittance, light irradiated from the light emitting unit 122 to be described later may pass through the collecting unit 160 . Accordingly, the ratio of unnecessary light reflection is reduced, so noise is reduced, and airborne microorganisms can be measured more accurately.

Also, the collecting unit 160 may include a sapphire wafer. Since the sapphire substrate has a hydrophobic property, it is possible to prevent the water component contained in the air from being collected by the collecting unit 160 . And, since the sapphire substrate has a very high hardness, its wear is prevented.

A light emitting unit 122, a first light receiving unit 132, and a second light receiving unit 142 may be disposed in the light incident path 120, the first light receiving path 130, and the second light receiving path 140, respectively. have. Accordingly, the light emitting unit 122, the first light receiving unit 132, and the second light receiving unit 142 are respectively arranged on a straight line.

The light emitting unit 122 is installed in the light incident path 120 to irradiate light of a preset wavelength range. The light emitting unit 122 irradiates light toward the air passage 150 , specifically, the collecting unit 160 .

The light emitting part 122 includes a laser diode (LD). The laser diode may irradiate light of a set wavelength region. For example, the preset wavelength range may be 200 to 900 nm.

The output of the laser diode may have a value equal to or less than a set output. If the output of the laser diode becomes too high, there may be a problem in that the measurement object is destroyed before measurement. For example, the set output value may be 20 mW.

In addition, in the light incident path 120, a light incident lens (not shown) that collects the light irradiated from the light emitting unit 122 and a light incident filter (not shown) functioning to pass only light in a preset wavelength range are further provided. can be placed.

For example, the light irradiated from the light emitting unit 122 has a divergence angle of about 10°, and accordingly, the light irradiated from the light emitting unit 122 has a gradually diverging path while moving. . Accordingly, the light incident lens (not shown) may be installed on the exit side of the light emitting unit 122 to convert the irradiated light into parallel light.

A photodiode (PD) is included in the first light receiving unit 132 and the second light receiving unit 142 . The photodiode may detect light in a set wavelength region. In addition, the photodiode has a relatively short response time.

In this case, the first light receiving unit 132 and the second light receiving unit 142 are provided to detect light of different wavelength ranges. In detail, the first light receiving unit 132 is provided as a photodiode for sensing light corresponding to 200 to 300 nm. In particular, the first light receiving unit 132 may be provided to detect light having a wavelength of 230 nm.

In addition, the second light receiving unit 142 is provided as a photodiode that senses light corresponding to 350 nm to 900 nm. In particular, the second light receiving unit 142 may be provided to sense light having a wavelength of 670 nm.

As such, the first light receiving unit 132 detects light having a wavelength of a relatively short region, and the second light receiving unit 134 detects light having a wavelength of a relatively long region.

In addition, a first light receiving filter 134 and a second light receiving filter 144 are installed in the first light receiving path 130 and the second light receiving path 140 , respectively. The first light receiving filter 134 and the second light receiving filter 144 may perform a function of selectively passing light in a predetermined wavelength region.

At this time, the first light-receiving filter 134 and the second light-receiving filter 144 are provided to pass light of different wavelength ranges. In detail, the first light-receiving filter 134 is provided to pass light corresponding to 200 to 300 nm. In particular, the first light-receiving filter 134 may be provided to pass light having a wavelength of 230 nm.

In addition, the second light receiving filter 144 is provided to pass the light corresponding to 350nm ~ 900nm. In particular, the second light receiving filter 144 may be provided to pass light having a wavelength of 670 nm.

With reference to the configuration described above, the measurement of airborne microorganisms by the airborne microorganism measuring device 100 will be described in detail.

4 is a diagram illustrating airborne microbes measurement using the airborne microbes measuring device according to an embodiment of the present invention.

As shown in FIG. 4 , the outside of the airborne microbial measuring device 100 , that is, airborne microbial (A, airborne microbial) contained in the outside air is transferred to the air flow path 150 through the air inlet 152 . is brought in At this time, the foreign substances included in the external air passing through the air filter 153 may be removed.

In addition, the airborne microorganisms A introduced into the air passage 150 are charged in the charging units 156 and 158 . In detail, corona discharge may be generated by a voltage difference between the wire 158 to which a voltage is applied and the pair of plates 156 . In addition, negative ions (-) or positive (+) ions generated during the corona discharge are charged with airborne microorganisms in the air, and thus the airborne microorganisms may be charged.

The charged airborne microorganisms A1 continuously flow along the air passage 150 and are collected by the collecting unit 160 . In detail, a voltage of a polarity different from the voltage applied to the wire 158 may be applied to the collecting unit 160 to collect the charged airborne microorganisms A1 .

Air except for the trapped airborne microorganisms A2 is discharged to the outside of the measurement case 110 through the air outlet 154 . Meanwhile, the width of the air flow path 150 may be formed to become narrower from the air inlet 152 to the air outlet 154 . Due to the structure of the air passage 150 , the charging efficiency of the charging units 156 and 158 and the dust collecting efficiency of the collecting unit 160 may be improved.

Meanwhile, the light emitting unit 122 irradiates light L having a predetermined wavelength region toward the collecting unit 160 . In detail, the light L is irradiated toward the collecting unit 160 in which the collected airborne microorganisms A2 are provided.

The light irradiated from the light emitting unit 122 passes through the collecting unit 160 , at least a portion is irradiated to the first light receiving path 130 , and at least a portion is irradiated to the second light receiving path 140 .

At this time, the light L irradiated from the light emitting unit 122 passes through the airborne microorganism A2 provided in the collecting unit 160 to the first light receiving path 130 and the second light receiving path 140 . is investigated Accordingly, the intensity of the light L1 flowing into the first light receiving path 130 and the second light receiving path 140 is reduced than that of the light L irradiated from the light emitting unit 122 .

In addition, the light L1 having reduced intensity passing through the collecting unit 160 passes through the first light receiving filter 134 and the second light receiving filter 144, and only light in a specific wavelength region is transmitted through the first light receiving unit ( 132) and the second light receiving unit 142 is reached.

In particular, since the first light-receiving filter 134 and the second light-receiving filter 144 pass light of different wavelength ranges, the light L2 and the second light-receiving filter passing through the first light-receiving filter 134 . The light L3 passing through the filter 144 is different from each other. Such light is sensed by the first light receiving unit 132 and the second light receiving unit 142 , respectively.

In summary, airborne microorganisms (A) included in the outside air are charged in the charging units (155, 158) and are collected in the collecting unit (160). The light L irradiated from the light emitting unit 122 toward the captured airborne microorganism A2 passes through the collecting unit 160 , the first light receiving filter 134 and the second light receiving filter 144 . . The light L2 passing through the first light receiving filter 134 is sensed by the first light receiving unit 132 , and the light L3 passing through the second light receiving filter 144 is detected by the second light receiving unit 142 . is detected in

Hereinafter, a method for measuring airborne microorganisms using the airborne microorganism measuring apparatus 100 will be described in detail. In this case, the method for measuring airborne microorganisms may be referred to as a method for measuring the viability of airborne microorganisms.

5 is a diagram illustrating a method for measuring airborne microorganisms according to an embodiment of the present invention.

As described above, airborne microorganisms introduced into the measurement case 110 and charged in the charging units 156 and 158 are collected by the collecting unit 160 (S10). In addition, light is irradiated from the light emitting unit 122 toward the collecting unit 160 (S20), and predetermined light is detected by the first light receiving unit 132 and the second light receiving unit 142 (S30) .

In this case, the light detected by the first light receiving unit 132 is _{referred to as a first measurement light I 1} , and the light detected by the second light receiving unit 142 is referred to _{as a second measurement light I 2 .}

Meanwhile, in a state in which airborne microorganisms are not captured by the collecting unit 160 , the light emitting unit 122 may irradiate light to be detected by the first light receiving unit 132 and the second light receiving unit 142 . This is referred to as a reference value, the light detected by the first light receiving unit 132 is referred to as a first reference light (I _0,1 ), and the light detected by the second light receiving unit 142 is referred to _{as a second reference light (I 0,2 ).} .

In this way, the light detected in a state in which airborne microorganisms are not collected by the collecting unit 160 is compared with the light detected in a state in which airborne microorganisms are collected in the collecting unit 160, and transmittance (T, Transmittance) is compared as follows. ) can be calculated.

Accordingly, the first transmittance (T ₁ ) and the second transmittance (T ₂ ) may be calculated using this ( S40 ).

At this time, the transmittance (T) has the following relationship with the optical density (OD, Optical density).

Using such a relationship, the first optical density (OD ₁ ) and the second optical density (OD ₂ ) may be measured through a spectrophotometer ( S50 ). The spectrometer refers to a device for measuring optical density, and various commonly used devices may be used.

6 is a graph for a method for measuring airborne microorganisms according to an embodiment of the present invention. In detail, FIG. 6 is a graph showing the relationship between optical density and wavelength for each microorganism (source: Park et al. Aerosol and Air Quality Research 12 2012, 399-408p).

Here, (a) is B. subtilis, (b) is E. coli, (c) is Staphylococcus epidermidis (S. epidermidis), respectively. This is shown to show that each microorganism has the same tendency regardless of type, and it does not matter which microorganism each microorganism is.

In addition, the x-axis of each graph means the wavelength of light, and the y-axis means the optical density value. In this case, the optical density means a normalized optical density (NOD) averaged by a value obtained by calculating an average value according to the concentration.

Referring to FIG. 6 , when the wavelength of light is 200 to 300 nm, an optical density (NOD) value can be found. In this case, the optical density (NOD) has a different value depending on the viability of the microorganism. That is, as shown in the graph, when the viability is low at the same wavelength, the optical density is low, and when the viability is high, the optical density is high.

As described above, the first light receiving unit 132 detects light having a wavelength of 200 to 300 nm. Accordingly, the first transmittance (T ₁ ) and the first optical density (OD ₁ ) have a value corresponding to a wavelength of 200 to 300 nm. That is, the first optical density (OD ₁ ) has a relatively large difference depending on the viability of microorganisms.

On the other hand, when the wavelength of light is 350-900 nm, the optical density (NOD) value has almost the same value depending on the viability.

Also, the second light receiving unit 142 detects light having a wavelength of 350 to 900 nm. Accordingly, the second transmittance (T ₂ ) and the second optical density (OD ₂ ) have a value corresponding to a wavelength of 350 to 900 nm. That is, the second optical density (OD ₂ ) has a relatively small difference depending on the viability of microorganisms.

The viability (V, Viability) of microorganisms can be obtained as follows by using the values of the graph shown in FIG. 6 ( S60 ).

At this time, the A and B values have different values depending on the type of microorganism, which can be obtained through an experiment. For example, in the case of E. coli, A corresponds to 36.10 and B corresponds to 332.84.

In summary, the transmittance T is calculated through the light sensed by the first light receiving unit 132 and the second light receiving unit 142 , and the optical density OD is measured accordingly. By substituting this value into the above formula, A and B values for each microorganism can be put in to calculate the viability of each microorganism.

When airborne microorganisms are measured in this way, the viability of airborne microorganisms can be measured within a relatively short time (about 5 minutes). In addition, since the viability of each microorganism can be measured, it may be more useful when the target microorganism is present.

As such, the airborne microbes measuring apparatus according to the spirit of the present invention can quickly and accurately measure the viability of airborne microbes through a plurality of light receiving units that detect light having different wavelength values.

Such an airborne microorganism measuring device may be provided in various shapes. 7 and 8 illustrate an airborne microorganism measuring device provided in another form by way of example.

7 is a view showing an apparatus for measuring airborne microorganisms according to another embodiment of the present invention. FIG. 7 shows the front side of the measurement case for convenience of explanation and omits some components such as the light emitting part and the discharge part. In addition, the same parts as described above are denoted by the same reference numerals, and descriptions thereof are omitted.

As shown in FIG. 7 , the airborne microorganism measuring device further includes a rotatably light receiving unit 170 . A first light receiving path 174 and a second light receiving path 176 are formed inside the light receiving unit 170 . A first light receiving unit 132 and a first light receiving filter 134 are provided in the first light receiving passage 174 , and a second light receiving unit 142 and a second light receiving filter 144 in the second light receiving passage 176 . is provided

In addition, a rotation motor 172 for providing rotational power to the light receiving unit 170 may be provided on one side of the light receiving unit 170 . In addition, a collecting unit 160 is provided on the upper surface of the light receiving unit 170 so that it can be rotated together.

The light receiving unit 170 is to be installed in the measurement case 110 so that the center of the first light receiving path 174 or the second light receiving path 176 is arranged on a straight line with the center of the light receiving path 120 . can That is, at a point where the light receiving unit 170 rotates, the first light receiving path 174 and the light receiving path 120 are arranged in a straight line. In addition, at another rotating point, the second light receiving path 176 and the light receiving path 120 are arranged in a straight line.

In the airborne microorganism measuring apparatus described with reference to FIGS. 5 and 6 , the first light receiving unit 132 and the second light receiving unit 142 simultaneously sensed the light irradiated from the light receiving unit 122 . However, in the airborne microorganism measuring apparatus shown in FIG. 7 , the first light receiving unit 132 and the second light receiving unit 142 respectively sense the light irradiated from the light receiving unit 122 .

When the airborne microorganisms are measured by such an airborne microorganism measuring device, when airborne microorganisms are collected by the collecting unit 160, the first light receiving path 174 and the light receiving path 120 are arranged in a straight line. The light receiving unit 170 rotates. The light irradiated by the light receiving unit 122 is sensed by the first light receiving unit 132 along the first light receiving path 174 to obtain a predetermined signal.

Then, the light receiving unit 170 rotates so that the second light receiving path 176 and the light receiving path 120 are arranged in a straight line. The light receiving unit 122 irradiates the light again, and detects the light irradiated from the second light receiving unit 142 to obtain a predetermined signal.

In this case, the measurement sequence is exemplary, and it is natural that the second light receiving path 176 may be arranged on a straight line first, and the first light receiving path 174 may be arranged later.

As described above, as the first light receiving unit 132 and the second light receiving unit 142 measure each light, more accurate results can be obtained.

In addition, different light input filters may be installed in the light incident path 120 to replace the first light receiving filter 134 and the second light receiving filter 144 . In addition, by installing both the light receiving filter and the light input filter, light can be more accurately detected.

In addition, a plurality of light emitting units for irradiating different wavelengths may be provided. In FIG. 8 , an airborne microorganism measuring device having a plurality of light emitting units and light receiving units is illustrated as an example. The same contents as those described above are omitted, and the above description is cited.

8 is a view showing an apparatus for measuring airborne microorganisms according to another embodiment of the present invention.

As shown in FIG. 8 , the airborne microorganism measuring device 200 includes a measuring case 210 having an air flow path 250 formed therein. The air flow path 150 is formed to pass through the measurement case 210 and has one air inlet 252 and two air outlets 254a and 254b. That is, the air flow path 250 is branched inside the measurement case 110 . At this time, in FIG. 8 , the air outlet located at the upper part is divided into a first air outlet port 254a and the air outlet port located at the lower part is divided into a second air outlet port 254b.

The structure of such an air flow path is exemplary, and a plurality of air inlets 252 may also be provided to form the air flow paths 250 spaced apart from each other. In addition, although FIG. 8 shows that the air inlet 252 and the air outlets 254a and 254b are respectively formed on both sides of the measurement case 210, this is exemplary and may be disposed at various positions.

An air filter 253 and charging parts 256 and 258 are provided in the air flow path 250 adjacent to the air inlet 252 . The charging portion includes a wire 258 and a pair of plates 256 disposed on both sides of the wire 258 .

A first collecting part 260a is provided in the air flow path 250 adjacent to the first air outlet 254a, and a second collecting part 260a is provided in the air channel 250 adjacent to the second air outlet 254b. 260b) is provided. That is, the first collecting part 260a and the second collecting part 260b are respectively disposed in the branched air flow path 250 .

A first light incident passage 220a and a first light receiving passage 230 are formed on both sides of the first collecting portion 260a. The first light incident path 220a and the first light receiving path 230 are disposed on a straight line with the first collecting part 260a interposed therebetween. In addition, a first light incident part 222a is disposed in the first light incident path 220a, and a first light receiver 232 and a first light receiving filter 234 are disposed in the first light receiving path 230 .

In this case, the first light incident part 222a may be provided to irradiate light having a wavelength of 200 to 300 nm, in particular, a wavelength of 230 nm.

A second light incident passage 220b and a second light receiving passage 240 are formed on both sides with respect to the second collecting part 260b. The second light incident path 220b and the second light receiving path 240 are disposed on a straight line with the second collecting part 260b interposed therebetween. In addition, a second light incident part 222 is disposed in the second light incident path 220b , and a second light receiver 242 and a second light receiving filter 244 are disposed in the second light receiving path 240 .

In this case, the second light incident part 222b may be provided to irradiate light having a wavelength of 350 to 900 nm, in particular, a wavelength of 670 nm.

8, the first light receiving path 230, the first light receiving path 220a, the second light receiving path 220b, and the second light receiving path 240 are arranged in a straight line from the top to the bottom. did. However, it is not necessary for the first light receiving path 230 and the first light receiving path 220a to be arranged in a straight line with the second light receiving path 220b and the second light receiving path 240, and the arrangement flowchart It may be changed to be exemplary.

Through such a structure, airborne microorganisms may be collected by the first collecting unit 260a and the second collecting unit 260b, respectively. Accordingly, the first light incident part 222a and the second light incident part 222b irradiate light of different wavelengths, and the first light receiver 232 and the second light receiver 242 emit light of different wavelengths. light can be detected.

Accordingly, a more accurate signal can be obtained, so that the viability of airborne microorganisms can be more accurately known.

As such, the airborne microorganism measuring device may be provided in various shapes and configurations.

10: air conditioner 100: airborne microorganism measuring device
110: measurement case 120: light input path
122: light input unit 130: first light receiving path
132: first light receiving unit 134: first light receiving filter
140: second light receiving path 142: second light receiving unit
144: second light receiving filter 150: air flow path
160: collection unit

Claims (15)

measurement case;
a collecting unit in which airborne microorganisms are disposed;
a light emitting unit irradiating light having a predetermined wavelength to the collecting unit;
A first light receiving unit and a second light receiving unit for receiving the light irradiated from the light emitting unit; And
Includes; a first light-receiving filter and a second light-receiving filter for passing light having a predetermined wavelength;
In the measurement case,
An air inlet through which air is introduced is formed at one end, an air outlet through which air is discharged is formed at the other end, and a charging unit for charging airborne microorganisms introduced into the air inlet, and an air path in which the collecting unit is disposed;
a light incident path through which the light emitting unit is disposed; and
a first light receiving passage in which the first light receiving filter and the first light receiving unit are disposed; And
a second light-receiving passage in which the second light-receiving filter and the second light-receiving unit are disposed;
The light incident passage and the first light receiving passage are arranged in a straight line with the air passage interposed therebetween,
The light incident passage and the second light receiving passage are arranged in a straight line with the air passage interposed therebetween,
The airborne microorganism measuring device, characterized in that the first light receiving filter and the second light receiving filter are provided to pass different wavelengths. The method of claim 1,
The first light-receiving filter is provided to pass light in a wavelength range of 200 to 300 nm,
The second light-receiving filter is an airborne microorganism measuring device, characterized in that it is provided to pass the light in the wavelength range of 350 ~ 900nm. delete delete The method of claim 1,
The airborne microorganism measuring apparatus, characterized in that the first light receiving path and the second light receiving path are formed inside the rotatably provided light receiving unit. 6. The method of claim 5,
The light receiving unit is installed in the measurement case so that the center of the light receiving path is rotated to coincide with the center of the first light receiving path, and the center of the light receiving path is rotated to coincide with the center of the second light receiving path. Airborne microbes measuring device. The method of claim 1,
Airborne microorganism measuring device, characterized in that the measurement case includes a blocking wall separating the first light-receiving passage and the second light-receiving passage. The method of claim 1,
In the air flow path,
Airborne microorganism measuring device, characterized in that it includes an air filter installed in the air inlet. The method of claim 1,
The airborne microorganism measuring device, characterized in that the light emitting unit includes a first light emitting unit and a second light emitting unit for irradiating light of different wavelengths. [Claim 1] An air conditioner comprising the apparatus for measuring airborne microorganisms according to any one of claims 1, 2, and 5 to 9. A collecting unit for collecting airborne microorganisms is disposed inside the measurement case,
Light having a predetermined wavelength is irradiated from the light emitting unit toward the collecting unit,
The light passing through the collecting unit passes through the first light receiving filter and the second light receiving filter, respectively,
The light passing through the first light receiving filter is received by the first light receiving unit to measure the first measurement light,
The light passing through the second light-receiving filter that passes light of a wavelength different from that of the first light-receiving filter is received by the second light-receiving unit to measure a second measurement light,
In the measurement case,
An air inlet through which air is introduced is formed at one end, an air outlet through which air is discharged is formed at the other end, and a charging unit for charging airborne microorganisms introduced into the air inlet, and an air path in which the collecting unit is disposed;
a light incident path through which the light emitting unit is disposed; and
a first light receiving passage in which the first light receiving filter and the first light receiving unit are disposed; And
a second light-receiving passage in which the second light-receiving filter and the second light-receiving unit are disposed;
The light incident passage and the first light receiving passage are arranged in a straight line with the air passage interposed therebetween,
The method for measuring airborne microorganisms, characterized in that the light incident passage and the second light receiving passage are arranged in a straight line with the air passage interposed therebetween. 12. The method of claim 11,
When airborne microorganisms are not disposed in the collecting unit, the first and second reference lights detected by the first light receiving unit and the second light receiving unit are measured, respectively;
calculating a first transmittance with the first reference light and the first measurement light,
Airborne microorganism measuring method, characterized in that for calculating a second transmittance using the second reference light and the second measurement light. 13. The method of claim 12,
Measuring a first optical density through the first transmittance,
Airborne microorganism measuring method, characterized in that the second optical density is measured through the second transmittance. 14. The method of claim 13,
Airborne microorganism measuring method, characterized in that the viability is calculated for each type of airborne microorganisms using the first optical density and the second optical density. 15. The method of claim 14,
The first light receiving filter is provided to pass light in a wavelength range of 200 to 300 nm so that the first optical density has a value having a relatively large difference depending on the viability,
The method for measuring airborne microorganisms, characterized in that the second light receiving filter is provided to pass light in a wavelength range of 350 to 900 nm so that the second optical density has a relatively small difference according to viability.

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