KR102620777B1 - Apparatus for sampling bio-aerosol in air with condenser - Google Patents

Abstract

According to the present invention, it relates to a device for collecting bio-aerosols such as viruses floating in the air and a monitoring system including the same. According to one embodiment of the present invention, a condensation unit 102 including a cooling member 140 disposed on the air movement passage 130; A discharge unit 200 including a discharge member 210 disposed around the circumference adjacent to the air outlet 132 of the condensation unit 102, and a plurality of discharge protrusions 211 protruding outward from the discharge member 210. ); and a collection unit 300 that is spaced apart from the lower part of the discharge unit 200 and includes a collection liquid (W) and a ground electrode 340, and the cooling member 140 of the condensation unit 102. A bio-aerosol collection device 20 in the air is provided, which cools the air moving along the air movement passage 130 to condense moisture in the air by using the bio-aerosol P in the air as condensation nuclei. According to the present invention, before collection, the bio-aerosol is used as a condensation nucleus to cause moisture condensation to enlarge the bio-aerosol. By increasing the charge number of the bio-aerosol due to corona discharge, the electric dust collection effect is excellently improved, and the condensation phenomenon of moisture increases the bio-aerosol's bio-aerosol size. A water film is formed in the aerosol, which can protect it from impact.

Description

Apparatus for collecting bio-aerosol in the air including a condenser {Apparatus for sampling bio-aerosol in air with condenser}

The present invention relates to a device for collecting bio-aerosols in the air.

Harmful infectious viruses such as Severe Acute Respiratory Syndrome (SARS), new influenza, and COVID-19 viruses that have recently emerged worldwide are dispersed in the air and cause infection in the form of droplets or particles, not only threatening human life but also causing economic loss. It also continues. Accordingly, there is a need for detection and monitoring technology that can detect and respond to airborne infectious viruses at an early stage.

Currently, all technologies for detecting viruses use liquid virus samples. Therefore, in order to detect viruses, technology to collect viruses in the air in liquid form is essential.

Previously, inertial force, impact force, and electric fields were used as methods to capture viruses in the air. However, these methods require a very large amount of energy and have the problem that the virus is physically or chemically damaged by impact during the capture process. It is difficult to detect viruses that have been physically or chemically damaged in this way. Accordingly, there is a need to develop technology to completely capture bio-aerosols in the air.

One object of the present invention is to provide a device that can capture bio-aerosols such as viruses and bacteria floating in the air without damage and with excellent capture efficiency.

Another object of the present invention is to provide a device for monitoring bio-aerosol in the air with improved detection performance of bio-aerosol by including the above-described collection device.

According to one aspect of the present invention, a condensation unit including an air inlet 131, an air movement passage 130, a cooling member 140 disposed on the air movement passage 130, and an air outlet 132 ( 102); A discharge unit 200 including a discharge member 210 disposed around the air outlet 132 of the condensation unit 102 and a plurality of discharge protrusions 211 protruding from the discharge member 210; A collection liquid accommodating part 320 located at a distance from the lower part of the discharge unit 200 and containing the collecting liquid W, and a ground electrode 340 located adjacent to the bottom surface of the collecting liquid accommodating part 320. A collection unit 300 including; And a power supply unit 220 that electrically connects the discharge protrusion 211 of the discharge unit 200 with the ground electrode 340 and supplies voltage to form an electric field between them, and the cooling member 140 The air moving along the air movement passage 130 of the condensation unit 102 is cooled to condense the moisture in the air using the bio-aerosol (P) in the air as a condensation nucleus, and the bio-aerosol (P) coated with the condensed moisture is formed. A device (20) for collecting bio-aerosol in the air is provided, in which P) reaches the discharge unit (200), becomes charged, falls down the discharge unit (200) along an electric field, and is collected in the collection liquid (W).

According to one embodiment of the present invention, the collection device 20 further includes a temperature and humidity control unit 101 for humidifying or warming and humidifying the incoming air, and the air passing through the temperature and humidity control unit 101 is It may flow into the air inlet 131 of the condensation unit 102.

According to another embodiment of the present invention, the temperature and humidity control unit 101 may supersaturate the air.

According to another embodiment of the present invention, the air movement passage 130 of the condensation unit may be located in a direction perpendicular to the water surface of the collected liquid.

According to another aspect of the present invention, a monitoring system 10 for bio-aerosol in the air is provided, including the above-described device for collecting bio-aerosol in the air and a detection device for detecting the bio-aerosol collected by the capture device.

According to the present invention, the nano-sized bio-aerosol can be enlarged by causing moisture condensation to occur by using the bio-aerosol as a condensation nucleus before air is introduced into the collection unit and collection occurs. In this way, when the surrounding moisture condenses and the size of the bio-aerosol increases, the number of charges increases when the bio-aerosol is charged by ions from corona discharge, thereby improving the dust collection effect in electric dust collection. In addition, a water film is formed on the bio-aerosol due to the condensation of moisture centered on the floating bio-aerosol, and this moisture film serves as a protective film that protects the floating bio-aerosol. The protective film minimizes the impact on suspended bio-aerosols and minimizes damage to captured microorganisms. According to the present invention, as described above, both damage in the air and damage during liquefaction can be prevented, so it is possible to completely capture bio-aerosol, which ultimately has the advantage of increasing the detection efficiency of bio-aerosol.

1 is a monitoring system for bio-aerosol in the air including a pretreatment unit 100 including a temperature and humidity control unit 101 and a condensation unit 102, a discharge unit 200, a collection unit 300, and a detection unit 400. This is a schematic diagram showing (10).
Figure 2 is a diagram schematically showing the temperature and humidity control unit 101 according to an embodiment of the present invention.
Figure 3 is a diagram schematically showing the condensing unit 102, the discharging unit 200, and the collecting unit 300 according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail.

The terms used in this application are merely used to describe specific embodiments and are not intended to limit the invention. Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the technical field to which the present invention pertains.

Throughout the specification, when it is said that a part "includes" or "contains" a certain component, this means that it may further include other components, unless specifically defined otherwise.

In addition, when describing with reference to the accompanying drawings, like symbols will be assigned to like components and overlapping descriptions thereof will be omitted. In the drawings, for example, the size and shape of members may be exaggerated for convenience and clarity of explanation, and in actual implementation, variations in the depicted shape may be expected. Accordingly, embodiments of the present invention should not be construed as limited to the specific shape of the area shown herein.

Terms such as first and second are used to distinguish one component from another component, and the components are not limited by the above-mentioned terms.

When a part is said to be “on” or “on” another part, it means that it is “directly above” or “directly on” another part, meaning that one part is in contact with another part, as well as another part in between. Including cases where it exists. Conversely, when a part is said to be “directly above” or “directly on” another part, it means that there is no other part in between.

As used herein, “bioaerosol” refers to microorganisms suspended in the air, specifically both viruses and bacteria. Viruses herein include droplet-borne or airborne viruses, such as severe acute respiratory syndrome (SARS) virus, influenza viruses, including new influenza, coronaviruses such as COVID-19 virus, tuberculosis virus, measles virus, and chickenpox virus. etc. can be mentioned. Additionally, the bacteria may include S. aureus, which can float in the air.

First, when the present invention is described with reference to FIG. 1, the apparatus 20 for collecting bio-aerosol in the air of the present invention includes a pretreatment unit 100, a discharge unit 200, and a collection unit 300. If necessary, the collection device 20 may further include a bio-aerosol concentrator (not shown) for concentrating the liquid bio-aerosol collected in the bio-aerosol collection unit 300 to a higher concentration.

As described above, the collection liquid in which bio-aerosol in the air is collected in liquid form in the collection device 20 can be used to detect bio-aerosol in the bio-aerosol detection unit 400 by separately recovering and transporting it or transporting it through a liquid passage, etc. Accordingly, according to the present invention, a monitoring system 10 for bio-aerosol in the air can be provided, which includes both the bio-aerosol collection device 20 in the air and the bio-aerosol detection unit 400. Here, the bio-aerosol detection unit 400 may include a reagent that can specifically detect only the virus desired to be detected. Accordingly, by checking whether the bio-aerosol P collected from the bio-aerosol collection device 20 is detected by the corresponding reagent, it is possible to know whether the desired bio-aerosol is present in the air.

Meanwhile, the collection liquid containing bio-aerosol collected in the collection device 20 does not necessarily have to be used only for detection of bio-aerosol, and can also be separately recovered from the device 20 and used for various purposes, such as experiments using bio-aerosol. there is. Accordingly, only the collection device 20 may be used without connecting the detection unit 400.

The above-described device 20 for capturing bio-aerosol in the air will be described in more detail with reference to FIGS. 2 and 3 as follows.

In the collection device 20, the preprocessing unit 100 may include a temperature and humidity control unit 101 and a condensation unit 102, as shown in FIG. 1. According to one embodiment of the present invention, the condensing unit 102 is an essential component, and the temperature and humidity control unit 101 communicates with the condensing unit 101 to pre-process the air prior to the condensing unit 102 as necessary. You may or may not need to install it.

To describe the temperature and humidity control unit 101 in more detail with reference to FIG. 2, the temperature and humidity control unit 101 supplies air to the condensation unit 102 in order to facilitate moisture condensation in the condensation unit 102. It is installed arbitrarily as needed for the purpose of controlling the temperature or humidity or temperature and humidity of the air before it is introduced.

The temperature and humidity control unit 101 includes a first air movement passage 110, wherein the first air movement passage 110 includes a first air inlet 111 through which air from the outside flows in, and a first air inlet 111 through which air moves inside. It may include a space portion and a first air outlet 112 that discharges air that has been pretreated for temperature and humidity control. The first air movement passage 110 may include a blower (not shown) provided to move air. The blower may be, for example, a blowing fan or an air pump.

The temperature and humidity control unit 101 may include at least one heating and humidifying member 120. According to Figure 2, the heating and humidifying member 120 may include both a heating member 121 and a humidifying member 122. According to another embodiment, the heating and humidifying member 120 may include only one of the heating member 121 and the humidifying member 122 depending on the surrounding environmental conditions where the incoming air was present. Alternatively, after installing both the heating member 121 and the humidifying member 122, only one of them may be operated as needed. Additionally, according to another embodiment, instead of installing the heating member and the humidifying member separately, only the heating and humidifying member 120, which has both a heating function and a humidifying function, may be installed.

The heating and humidifying member 120 is installed along the direction in which air moves within the first air movement passage 110, and may preferably supersaturate the air. By supersaturating the air in this way, condensation of moisture in the air can occur more easily using bio-aerosols as condensation nuclei in the subsequent condensation step. The heating member 121 serves to increase the temperature of the air to supersaturate the air as described above. This is because supersaturation occurs more easily when the air temperature is high. To this end, the heating member 121 may be installed so that air passes through it before the humidifying member 122. Of course, as described above, heating and humidification may occur simultaneously. The heating member 121 may be a heating coil or a heat wire. The humidifying member 122 serves to increase humidity in the air to supersaturate the air. According to one embodiment, the humidifying member 122 may include a water vapor outlet (not shown) for discharging water vapor into the space of the first air movement passage 110, and according to another embodiment, the first air movement passage 110 1 The humidifying member 122 may be implemented by putting at least a portion of the wall surface of the air movement passage 110 in a wet state.

In addition, according to one embodiment of the present invention, the temperature and humidity control unit 101 includes the heating member 121 and/or the humidifying member 122 to prevent bio-aerosols in the air from being damaged due to sudden changes in temperature/humidity. ) can be installed long or several short can be installed so that the air can be gradually warmed and humidified. Accordingly, according to one embodiment, the temperature and humidity control unit 101 may include a plurality of the heating member 121 and/or the humidifying member 122. Additionally, according to one embodiment, depending on the installation space, each of the plurality of heating members 121 or humidifying members 122 may be arranged in series or parallel, spaced apart from each other at a predetermined distance.

Next, if the condensing unit 102 is described in detail with reference to FIG. 3, the condensing unit 102 has a second air inlet 131 through which air that passes through or does not pass through the temperature and humidity control unit 101 enters. and a second air movement passage 130 including a second air outlet 132. The condensation unit 102 includes at least one cooling member 140, and the cooling member 140 may be installed along the direction in which air moves along the second air movement passage 130. When supersaturated air flows into the condensation unit 102 and is cooled by the cooling member 140, moisture in the air condenses using the bio-aerosol floating in the air as a condensation nucleus. This is because the mass diffusivity of water is greater than the thermal diffusivity of air. In this way, moisture is condensed using floating bio-aerosols as condensation nuclei, thereby causing nano-sized bio-aerosols to become larger. As the size of the floating bio-aerosol increases, the number of charges increases during subsequent charging, allowing collection by electrostatic dust collection to occur more smoothly and accurately, and thus collection efficiency can be improved. Additionally, the moisture film can act as a protective layer that protects bio-aerosols such as viruses. In other words, the moisture film can minimize damage that may occur to the bio-aerosol due to collision with ions that occur during subsequent charging, the influence of electric fields, shock from falling, and shock from collision with the collection liquid. Contributes to complete capture. The cooling member 140 may be installed at an appropriate length to allow sufficient moisture condensation to occur.

The discharge unit 200 includes a discharge member 210 disposed around the circumference adjacent to the air outlet 132 of the condensation unit 102 and a plurality of discharge protrusions 211 protruding from the discharge member 210. Condensed bioaerosols and air flow through the air outlet 132. Largely condensed bioaerosols escape the air streamline and are easily collected in the collection unit, but relatively small condensed bioaerosols move along the air streamline and are captured. Since it goes beyond section 300, it is difficult to collect it using only the flow rate. Accordingly, the discharge unit 200 can be used to collect small bioaerosols that may escape along the streamline due to corona discharge. The discharge unit 200 charges the particles so that the bio-aerosol in the air has a specific charge and collects the charged particles into the collection liquid W of the collection unit 300 at a desired location by electrostatic attraction. do.

The discharge member 210 is installed adjacent to the air outlet 132 of the condensation unit 102 and along the circumference. According to one embodiment, the discharge member 210 may be formed on the second air outlet 132 along the perimeter of the second air outlet 132 to charge the bio-aerosol in the air discharged from the condensation unit. there is. Here, the circumferential length of the second air outlet 132 can be appropriately adjusted considering the degree of charge of the bio-aerosol, electrostatic attraction, etc. However, if the circumferential length is too small, it is not suitable for processing high-capacity bio-aerosol, so if possible, the circumferential length of the second air outlet 132, that is, the circumferential length of the discharge member 210, is adjusted to the second air movement passage ( It may correspond to the circumferential length of the passage cross section of 130) or may be slightly smaller.

Meanwhile, according to one embodiment, the discharge unit 200 of the present invention uses corona discharge, which refers to a phenomenon in which air molecules in a gas are ionized when an electric field is formed between two electrodes. Here, the corona discharge uses an electric field formed between two electrodes of different sizes. When an electric field is applied, a plasma area is formed around the smaller electrode due to the shape of the electrode, and discharge begins. This electrode is usually called a discharge electrode. In addition, ions are generated at the discharge electrode and move along the electric field to the opposite pole, and at this time, the opposite pole is usually called a ground (i.e., ground) electrode.

According to one embodiment of the present invention, the present invention can charge and collect bio-aerosol using the above-described corona discharge, and therefore the electrode of the discharge unit 200 and the ground electrode 340, which will be described later, must have different sizes. do. To this end, according to one embodiment of the present invention, the discharge unit 200 may include a plurality of discharge protrusions 211 protruding from the discharge member 210. The discharge protrusion 211 may include a sharp tip and, for example, may have the shape of a discharge pin. Meanwhile, according to the present invention, the ground electrode 340 is located adjacent to the bottom surface of the collecting liquid receiving part 320 in the collecting part 300, which will be described later. According to one embodiment, the ground electrode 340 may have a shape and area corresponding to the bottom surface of the collecting liquid accommodating part 320. According to one embodiment of the present invention, the discharge protrusion 211 of the discharge unit 200 or the discharge member 210 and the discharge protrusion 211 are connected to a voltage between the ground electrode 340 by the power supply unit 220. This is applied, they are electrically connected, and an electric field is formed between them.

The discharge member 210 and the discharge protrusion 211 face each other and the ground electrode 340. According to one embodiment of the present invention, the direction in which they face each other allows air to flow from within the second air movement passage 130. It can correspond to the direction of flow. Accordingly, the direction of the outflowing air flow and the electric field may coincide with each other rather than crossing each other. In this way, by matching the direction of the electric field with the air flow flowing out from the air movement passage, the amount of bio-aerosol lost from the air flow can be reduced. For this configuration, the collection unit 300 including the ground electrode 340 is positioned spaced apart from the lower part of the discharge unit 200. Accordingly, the bio-aerosol containing condensed moisture flowing out from the air outlet 132 of the condensation unit 102 reaches the discharge unit 200, is charged, and falls down the discharge unit 200 along the electric field. do. According to one embodiment of the present invention, the condensation unit 102 including the discharge unit 200, specifically, the air movement passage 130 of the condensation unit 102 is the collected liquid of the collection unit 300 ( W) Can be located in a direction perpendicular to the water surface. By positioning the condensation unit in the vertical direction in this way, the bio-aerosol, especially the bio-aerosol that has become larger and heavier due to moisture condensation, receives the force of the flow movement falling from the top to the bottom after being charged, thereby combining the air and air after flowing out of the air passageway. They do not spread together and can be well captured without loss.

The discharge protrusion 211 and the ground electrode 340 interact to form an electric field. When the electric field is formed in this way, a corona discharge occurs and a portion of the air is ionized to generate ions. The ions come into contact with the bio-aerosol (P) in the air and charge the bio-aerosol (P). Since this charged bio-aerosol (P) is electrically polarized, it accelerates in the direction of the opposite electrode due to electrostatic attraction caused by the electric field. Here, the opposite electrode is the ground electrode 340, and the charged bio-aerosol can be collected in liquid form in the collection liquid (W) adjacent to the ground electrode.

The bio-aerosol collection unit 300 includes a collection liquid accommodating part 320 containing a collecting liquid W, and the ground electrode 340 is located adjacent to the bottom surface of the collecting liquid accommodating part 320. The collection liquid receiving part 320 has a collecting liquid inlet 310 that supplies the collecting liquid (W) to the collecting liquid receiving part 320, and the collecting liquid (W) from the collecting liquid receiving part 320. It includes a collection liquid discharge unit 330 for discharging.

The collection liquid receiving part 320 accommodates the collection liquid (W) for collecting the liquid bio-aerosol (P). This allows the ground electrode 340 to be placed adjacent to the bio-aerosol (P) so that it can be collected by electrostatic attraction. Specifically, the ground electrode 340 may be placed on the bottom of the collecting liquid accommodating part 320, or alternatively, the collecting liquid accommodating part 320 may be installed on the ground electrode 340.

The collection liquid (W) may contain distilled water or a buffer solution. At this time, the buffer may be a buffer used in cell culture, for example, a PBS buffer, and the PBS buffer may have calcium chloride or magnesium chloride added as needed.

The collected liquid discharge unit 330 may be connected to a bio-aerosol concentrator (not shown) through a connection pipe or connected to a collected liquid recovery unit (not shown) so that the collected liquid containing bio-aerosol is immediately recovered. . Alternatively, the collected liquid discharge unit 330 may be connected to the detection unit 400, and at this time, the collected liquid is transferred between the collected liquid discharge unit 330 and the detection unit 400 through the above-mentioned concentration unit (not shown). ) and/or a pump (not shown), for example, a peristaltic pump. By continuously injecting the collection liquid (W) in which the bio-aerosol (P) is collected into the detection unit 400, bio-aerosol in the air can be monitored in real time. At this time, the bio-aerosol detection means in the detection unit 400 may use a known means, for example, PCR.

Although the present invention has been described above with reference to embodiments, those skilled in the art may make various modifications and changes to the present invention without departing from the spirit and scope of the present invention as set forth in the following patent claims. You will be able to understand that it exists.

10: Monitoring system for bio-aerosols in the air
20: Device for capturing bio-aerosol in the air
100: preprocessing unit 200: discharging unit
300: collection unit 400: detection unit
101: Temperature and humidity control unit
111: first air inlet 110: first air movement passage
112: first air outlet 121: heating member
122: Humidifying member 120: Heating and humidifying member
102: condensation unit
131: second air inlet 130: second air movement passage
132: second air outlet 140: cooling member
210: Discharge member 211: Discharge protrusion
220: power unit
310: Collection liquid inlet 320: Collection liquid receiving part
330: Collection liquid discharge unit 340: Ground electrode
A: Air P: Bio-aerosol
W: Collected liquid

Claims (5)

a condensing section including an air inlet, an air moving passage, a cooling member disposed on the air moving passage, and an air outlet;
A room including a discharge member disposed along a circumference adjacent to the air outlet of the condensation unit to form a plane in a direction perpendicular to the direction in which air moves in the air movement passage, and a plurality of discharge protrusions protruding from the discharge member. entire;
a collection portion spaced apart from a lower portion of the discharge unit and including a collection liquid accommodating portion containing the collecting liquid and a ground electrode located adjacent to the bottom surface of the collecting liquid accommodating portion; and
A power supply unit that electrically connects the discharge protrusions of the discharge unit to the ground electrode and supplies voltage to form an electric field between them,
The cooling member cools the air moving along the air movement passage of the condensation unit to condense moisture in the air by using bio-aerosols in the air as condensation nuclei,
The bio-aerosol coated with the condensed moisture reaches the discharge unit, becomes charged, falls along the electric field below the discharge unit, and is collected in the collection liquid.
A device for capturing bio-aerosols in the air. The bio-aerosol in the air according to claim 1, further comprising a temperature and humidity control unit for humidifying or warming and humidifying the incoming air, wherein the air passing through the temperature and humidity control unit flows into the air inlet of the condensation unit. collection device. The apparatus of claim 2, wherein the temperature and humidity control unit supersaturates the air. The apparatus of claim 1, wherein the air movement passage of the condensation unit is located in a direction perpendicular to the water surface of the collected liquid. A monitoring system for bio-aerosol in the air, comprising the device for collecting bio-aerosol in the air according to claim 1 and a detection device for detecting the bio-aerosol collected by the capture device.