KR102678870B1 - Composite bio-aerosol collection device - Google Patents

Abstract

The present invention relates to a complex bioaerosol collection device capable of simultaneous bioaerosol sampling using a sampler with two characteristics when sampling microorganisms in the air. For this purpose, the complex bioaerosol collection device of the present invention consists of a bioaerosol sampling cassette and an air pump. The lower part can be mounted on the air intake part of the air pump to provide air suction force, and the upper first cassette coupling part extends in a straight line. It includes an air intake pipe body integrally formed with a second cassette coupling portion branched at an oblique inclination angle in the middle portion of one side, and the air intake pipe body is a filter type unit connected to the first cassette coupling portion and the second cassette coupling portion. The first sampling cassette and the second sampling cassette (impactor type) can be selectively installed simultaneously, so that bioaerosol of the filter type and impact type can be generated through the first and second sampling cassettes by the air suction force of one air pump. (Bioaerosol) can be collected simultaneously; The first sampling cassette is provided with a filter storage space on a filter stand inside an upwardly opened filter case, and a first coupling nozzle protruding through the bottom of the filter case can be coupled to the first cassette coupling unit or the second cassette coupling unit. And, a mesh capable of filtering particles of 100 μm or more is formed on the surface of the cover covering the upper surface of the filter case; The second sampling cassette is provided with an impact plate with a support protrusion formed on the bottom and a media storage space in an upwardly opened media case, and a second coupling nozzle protruding through the bottom of the media case is connected to the first cassette coupling part or the second cassette. It is capable of being coupled to a coupling portion, and is characterized in that ventilation holes are formed on the surface of the cover covering the upper surface of the badge case.

Description

Composite bio-aerosol collection device {Composite bio-aerosol collection device}

The present invention relates to a composite bioaerosol collection device. In particular, it is a composite bioaerosol collection device capable of simultaneous bioaerosol sampling using a sampler with two characteristics when sampling microorganisms in the air.

In general, bioaerosol has a biological origin, a compound word of the words bio and aerosol. Particulate matter suspended in the air, that is, biological agents, is contained in a gaseous environment. It refers to a state dispersed as particles (Exists both viable, living and nonviable states).

The properties of bioaerosol are based on the physical properties of a colloidal solution and contain both biological particles (viable state: capable of being cultured in the laboratory) and non-living particles (non-viable: not cultured but causing a sensitive response to the human body). Includes. This includes not only microorganisms and viruses such as bacteria and mold, but also pollen and mites that cause allergies. They have a very diverse range of size distribution: 0.02 to 0.3 μm for viruses, 0.3 to 10 μm for bacteria, 0.5 to 30 μm for fungal spores, and 10 to 100 μm for pollen. They exhibit the characteristic of increasing in number by breeding under specific temperature and humidity conditions.

These via aerosols are particles containing the organism itself or toxins, secretions, excretions, or dead bodies produced by the organism, or things that are not cultured and cause a sensitive reaction to the human body, suspended in the air. Includes all factors that can cause health problems by being absorbed or penetrated into the human body. Basically, since bioaerosol is a part of aerosol, its behavioral characteristics are influenced by general physical characteristics, such as particle size, Brownian motion, gravitational sedimentation, electrical characteristics, and diffusion. These characteristics determine the amount and amount in a specific part of the human body. The effect varies depending on the form in which it is deposited. The American Council of Industrial Hygienists (ACGIH) considers biologically derived substances in the form of aerosols, gases, and vapors to be biological pollution if they cause disease indoors or have adverse health effects on humans. , In addition, even bioaerosols that exist outdoors are considered biological pollution when the concentration is relatively high. The U.S. Environmental Protection Agency (EPA) has designated bioaerosols as the causative agent of asthma, infectious diseases, etc. among airborne biological contaminants. Therefore, bioaerosols exist everywhere in nature and are in the human living environment. The form of occurrence and concentration may vary depending on the activity, and the behavioral characteristics depend on the physical and biological characteristics of the aerosol itself.

Recently, due to energy issues and high-rise buildings, ventilation of indoor air is limited, and as the environment inside the building always maintains a constant temperature and humidity, the indoor environment is an appropriate environment for microorganisms to proliferate and the concentration of bioaerosol to increase. is providing. These bioaerosols are generated from animals such as cats and dogs, carpets, people, humidifiers, refrigerators, air purifiers, etc., and increase depending on indoor environmental conditions, playing a role in transmitting infectious diseases or directly causing skin diseases, allergic diseases, and bronchial diseases. It causes asthma, etc.

Infectious diseases may be caused by microorganisms in the warm, borderless air. In other words, if the air is contaminated, it is a potentially dangerous culture that can arise from contact with anything, including people, livestock, facilities, and equipment. Polluted air is very closely related to our living environment. Meanwhile, due to the harmful nature of bioaerosols to the human body, the Ministry of Environment’s “Indoor Air Quality Management Act for Multi-Use Facilities, etc.,” implemented on May 30, 2004, limits the concentration of bioaerosols to 800 CFU/m in medical institutions, childcare facilities, elderly medical facilities, and postnatal care centers. It is kept below ³ . To meet these maintenance standards, various technologies have been developed, and research and development is in progress.

Diseases caused by viral aerosols are transmitted very quickly to other host animals due to the nature of the transmission route. Accordingly, if we do not respond properly in time, there is a high risk that it will escalate into a biological disaster. In order to cause or prevent biological disasters, it is important to find and analyze information about causative bacteria in the air. However, this process is not easy. Virus aerosols must first be collected, and skilled technicians and expensive equipment are required for analysis after collection. It takes several days from collection to analysis. In particular, since most recognition of the presence of viruses in the air is made after the outbreak of a disease, rapid response is urgently needed, considering the incubation period of the virus in the host and the time it takes to measure it after the onset of the disease.

Bioaerosol sampling methods are mainly used in three ways: Filter type, Impactor type, and Impinger type. The filter type collects all microorganisms, and is a method of separating and removing bioaerosols floating in particle form from the flow using a filter. The impactor type is capable of cultivating microorganisms that collide with the installed nutrient medium, and the inertial impactor uses particle inertia to collect particles by the inertia of particles moving with the air. It can sample and classify aerosols, and is the most widely used particle size selection sampler. And the impinger type can collect bacteria and viruses, so it is widely applied to bio-aerosol collection devices.

Figure 1 is a diagram schematically showing a typical conventional bioaerosol collection device. Looking at the existing bioaerosol collection device with reference to FIG. 1, it is provided with a cylindrical collection cassette (C) opened up and down, and external air passes through the inside of the cassette due to the suction force of the pump (P) connected to the cassette through piping. Bioaerosols in the air can be collected using built-in collection means (filter, impactor, etc.). However, depending on the bioaerosol collection method (filter type, impactor type, impinger type), each collection cassette (C) must be provided separately and must be replaced for each sampling operation, which is impractical, such as delaying work time and lowering productivity. There was a problem. In particular, even when sampling and collecting at a certain location and under the same conditions, the specifications (sizes) of the collection equipment are different and there are many difficulties in installation and handling. In addition, impactor devices that measure airborne microorganisms using existing impact methods have diverse design variables, are difficult to process, and are expensive, which increases the economic burden.

The purpose of the present invention is to solve the above-mentioned problems and provide a complex bioaerosol collection device that can simultaneously sample a wide range of airborne microorganisms through one suction pipe by mounting separate cassettes each with a built-in filter or impactor on one suction pipe. is to provide.

In order to achieve the above object, the complex bioaerosol collection device of the present invention consists of a bioaerosol sampling cassette and an air pump. The lower part can be mounted on the air intake part of the air pump to exert air suction force, and the upper part extends in a straight line. It includes an air intake piping body integrally formed with a first cassette coupling portion and a second cassette coupling portion branched at an oblique inclination angle in the middle portion of one side, wherein the air intake piping body is connected to the first cassette coupling portion and the second cassette coupling portion as a filter. Filter type first sampling cassette and impactor type second sampling cassette can be selectively installed simultaneously, and filter type through the first and second sampling cassettes by the air suction force of one air pump. Bioaerosol can be collected simultaneously using the impact method; The first sampling cassette is provided with a filter storage space on a filter stand inside an upwardly opened filter case, and a first coupling nozzle protruding through the bottom of the filter case can be coupled to the first cassette coupling unit or the second cassette coupling unit. And, a mesh capable of filtering particles of 100 μm or more is formed on the surface of the cover covering the upper surface of the filter case; The second sampling cassette is provided with an impact plate with a support protrusion formed on the bottom and a media storage space in an upwardly opened media case, and a second coupling nozzle protruding through the bottom of the media case is connected to the first cassette coupling part or the second cassette. It can be coupled to the coupling portion, and ventilation holes are formed on the surface of the cover covering the upper surface of the badge case; The filter stand and the upper surface of the impact plate within the filter case are provided with a storage portion capable of accommodating a filter or culture medium, and the storage portion is formed to have a size of 47 mm or 60 mm; The air intake pipe body is formed such that an inclination angle between the first cassette coupling portion in the vertical direction and the second cassette coupling portion in the diagonal direction is within the range of 40 to 60 degrees; It further includes an air flow rate control valve provided at each end of the first cassette coupling portion and the second cassette coupling portion, wherein the air flow rate control valve is configured to control air flow rate that passes through the first sampling cassette or the second sampling cassette depending on the conditions of the collection site. We propose a composite bioaerosol collection device configured to vary the air flow rate.

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According to the complex bioaerosol collection device proposed by the present invention, it is possible to simultaneously collect a wide range of airborne microorganisms from bacteria and fungi floating in the air using filter and impact methods, so bioaerosol collection efficiency is excellent and the sampling time is reduced to the upper end. It can be partially shortened and complex sampling is possible under the same conditions, making it easy to compare experimental results, increasing sampling reliability, and providing the effect of standardization.

In the present invention, the filter mounting portion and the culture medium mounting portion have a storage portion that can accommodate filters or culture media of 47 mm and 60 mm in size, so that various filters and culture media of existing products (standards) can be mounted, thereby increasing versatility. There is.

The present invention also has the advantage of facilitating the collection of bioaerosols by setting a flow rate suitable for each collection cassette by applying each flow rate separately through a flow rate controller.

Figure 1 is a diagram schematically showing a typical conventional bioaerosol collection device.
Figure 2 is an exploded perspective view of the composite bioaerosol collection device 100 according to a preferred embodiment of the present invention.
Figure 3 is a front view showing an separated complex bioaerosol collection device 100 according to a preferred embodiment of the present invention.
Figure 4 is a front view showing a composite bioaerosol collection device 100 according to a preferred embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings. If it is judged that a detailed description of known functions or configurations related to this may unnecessarily obscure the gist of the present invention, the detailed description will be omitted, and the same reference numerals in the drawings refer to the same elements.

First, before describing the present invention in detail, it should be understood that the present invention is not intended to be limited to specific embodiments, but includes all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

In this specification, terms such as "include" or "have" are intended to indicate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features or It should be understood that this does not exclude in advance the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

In addition, when describing with reference to the accompanying drawings, identical or related reference numerals will be given to identical or related elements regardless of the reference numerals, and overlapping descriptions thereof will be omitted. In describing the present invention, if it is determined that a detailed description of related known technologies may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

The present invention is a complex bioaerosol collection device consisting of a bioaerosol sampling cassette (120, 130) and an air pump (P), wherein the lower end can be mounted on the air intake part (IN) of the air pump (P), so that air suction force is applied. , an air intake pipe body 110 in which an upper first cassette coupling portion 111 extending in a straight line and a second cassette coupling portion 112 branched at an oblique inclination angle (A) in the middle portion of one side are formed integrally; , the air intake pipe 110 is provided with a filter type first sampling cassette 120 and an impactor type second sampling cassette 120 in the first cassette coupling part 111 and the second cassette coupling part 112. The sampling cassette 130 can be selectively installed at the same time, so that filter-type and impact-type bioaerosol is generated through the first and second sampling cassettes 130 by the air suction force of one air pump (P). Simultaneous collection is possible; The first sampling cassette 120 is provided with a filter (F) storage space on the filter stand 121 inside the upwardly opened filter case 121, and has a first coupling nozzle 122 protruding through the bottom of the filter case 121. ) can be coupled to the first cassette coupling portion 111 or the second cassette coupling portion 112, and can filter particles larger than 100 μm on the surface of the first cover 124 covering the upper surface of the filter case 121. A mesh (125, Mesh) is formed; The second sampling cassette 130 is provided with an impact plate 136 with a support protrusion 137 formed on the bottom and a badge (G) storage space in an upwardly opened badge case 131, and a badge (G) storage space is provided on the bottom of the badge case 131. A second coupling nozzle 132 protruding through can be coupled to the first cassette coupling part 111 or the second cassette coupling part 112, and a second cover 134 covering the upper surface of the badge case 131. It is characterized in that ventilation holes 135 are formed on the surface.

The complex bioaerosol collection device 100 of the present invention having the above-described features will be described in detail below with reference to the accompanying drawings showing preferred embodiments of the present invention.

Figure 2 is an exploded perspective view of the composite bioaerosol collection device 100 according to a preferred embodiment of the present invention. And Figure 3 is a front view showing the composite bioaerosol collection device 100 according to a preferred embodiment of the present invention, and Figure 4 is a separate front view of the composite bioaerosol collection device 100 according to a preferred embodiment of the present invention. This is a front view.

According to the drawing above, the complex bioaerosol collection device 100 of the present invention is capable of simultaneously collecting bioaerosols by filter and impactor methods, and has a filter and an impactor (culture medium) in the air suction pipe 110 where the air suction force acts. The first and second sampling cassettes 120 and 130, respectively, can be mixed and demounted at the same time, making it possible to simultaneously collect filter-type and impact-type bioaerosols using the air suction power of a single air pump (P).

For this purpose, the complex bioaerosol collection device 100 of the present invention includes an air intake pipe 110 having a first cassette coupling portion 111 and a second cassette coupling portion 112, and a first sampling of a filter type. It can be composed of a cassette 120, an impactor type second sampling cassette 130, and an air pump (P) that generates air suction force.

The air intake pipe 110 extends up and down in a straight line, and its lower end can be coupled to the air intake portion (IN) of the air pump (P), so that air suction force through the internal passage can act as the first cassette coupling portion (111). The air intake pipe 110 can selectively attach or detach the first sampling cassette 120 or the second sampling cassette 130 to the first cassette coupling portion 111 formed at the top. The second cassette coupling portion 112 is branched at an oblique inclination angle (A) in the middle portion of one side of the air suction conduit 110, so that air suction force is applied to the internal passage and the first sampling cassette 120 or the second sampling The cassette 130 can be selectively mounted or removed. In addition, the air pump (P) can be configured to be attachable and detachable from the lower pump coupling portion 113 of the air intake pipe 110.

That is, the air intake pipe 110 is connected to the first cassette coupling part 111 and the second cassette coupling part 112 with a filter type first sampling cassette 120 and an impactor type second sampling cassette. The cassette 130 can be selectively installed simultaneously, and the air pump (P) is combined at the bottom, so that the filter-type first sampling cassette 120 and the impact-type first sampling cassette 120 are connected by the air suction force provided by the single air pump (P). 2 Complex bioaerosols can be collected simultaneously through the sampling cassette 130.

The air intake pipe 110 can be formed so that the inclination angle (A) between the first cassette coupling part 111 in the vertical direction and the second cassette coupling part 112 in the diagonal direction is within the range of a minimum of 30 degrees to a maximum of 90 degrees. Air can be sucked in simultaneously from the side of the suction pipe. At this time, under the condition that the pipe diameters of the first cassette coupling portion 111 and the second cassette coupling portion 112 are the same, the angle is preferably within the range of 40 to 60 degrees in consideration of smooth air flow through the internal passage, flow speed, air volume, etc. In addition, it is appropriate for the air intake pipe 110 to have an inclination angle A of the second cassette coupling portion 112 of about 45 degrees within a range where the first and second sampling cassettes 130 do not interfere with each other.

Meanwhile, the first and second cassette coupling parts 111 and 112 hold the air intake pipe 110 and the first and second sampling cassette 130 cases by hand and connect the lower first and second coupling nozzles 122 and 132. ) and the first and second cassette coupling portions 111 and 112 may be assembled by inserting them into each other or, conversely, may be assembled by sliding them so that they can be separated.

Next, the first sampling cassette 120 can be composed of a filter case 121 having a first cover 124 and a filter (F) built into the filter case 121. The filter case 121 is provided with a concave upwardly open storage space on the upper surface, and a filter stand 121 is formed inside the storage space, so that the filter F can be placed on the filter stand 121. The filter stand 121 has rod-shaped bars arranged in a radial or lattice form to support the medium G evenly and allow air to pass through smoothly.

The filter case 121 has a first coupling nozzle 122 on the bottom communicating with the storage space that protrudes downward and can be selectively and detachably coupled to the first cassette coupling unit 111 or the second cassette coupling unit 112. . The first cover 124 is fitted inside the upper surface of the filter case 121 to cover the storage space and forms a mesh 125 on the surface to provide primary filtration of airborne particles and foreign substances. This mesh 125 has a grid size (particle size) sufficient to filter particles larger than 100 μm in the air. Meanwhile, the filter (F) is capable of collecting fine dust particles of 100 μm or less by adsorbing them, and includes a generally known filter for collecting bioaerosols.

The second sampling cassette 130 may be composed of a badge case 131 having a second cover 134, an impact plate 136 built into the badge case 131, and a badge (G). The badge case 131 is provided with a concave upwardly open storage space on the upper surface, and the badge G can be placed on the upper surface of the impact plate 136 by inserting the impact plate 136 inside the storage space. In addition, a second coupling nozzle 132 communicating with the storage space on the bottom of the badge case 131 protrudes downward and can be selectively and detachably coupled to the first cassette coupling unit 111 or the second cassette coupling unit 112. . The second cover 134 is fitted inside the upper surface of the badge case 131 to cover the storage space, and air can flow in through the ventilation holes 135 formed on the surface. The ventilation hole 135 may be provided with a separate mesh (not shown) to provide primary filtration of particles or foreign substances larger than 100 μm.

The impact plate 136 has a cross-sectional area smaller than the cross-sectional area of the storage space of the badge case 131, so that air passes through the empty air at the edge of the storage space, and the supporting protrusions 137 protruding from the bottom are seated on the bottom of the case. A predetermined air passage can be formed between the furnace bottom surface and the plate. A fixing groove (not shown) into which the support protrusion 137 can be inserted is formed on the inner bottom surface of the badge case 131 to prevent the impact plate 136 from being separated. The impact plate 136 is a Petri dish containing a microbial culture medium (G), that is, a medium container can be installed to collect fine particles of 10 μm or less, and is a generally known medium for collecting bioaerosols. Includes containers.

Meanwhile, although not shown in a separate drawing, the impact plate 136 may be provided with a badge receiving portion and a badge fixing means on the upper surface to prevent the badge G from leaving. The media fixing means may include an adhesive that exerts an adhesive force on the bottom of the media container, or a one-touch elastic clip or fixing protrusion that exerts a fixing force on the edge of the media container and is detachable, or a clamp band.

In addition, the upper surface of the filter stand 121 and the impact plate 136 in the filter case 121 is provided with a storage portion that can accommodate a filter (F) or culture medium (G) of generally standardized sizes of 47 mm and 60 mm, so that the existing It has the versatility to be equipped with various filters and culture media of the product (standard).

According to the present invention, the air intake pipe 110 is configured to include an air flow control valve 140 provided at each end of the first cassette coupling portion 111 and the second cassette coupling portion 112. do. That is, the air intake pipe 110 is provided with flow control valves 140 at the ends of the first cassette coupling portion 111 and the second cassette coupling portion 112, respectively, to control the collection site conditions (temperature, humidity, climate change, etc.). Accordingly, bioaerosol sampling may be possible in optimal conditions by varying the air flow rate passing through the first sampling cassette 120 or the second sampling cassette 130.

In this way, the complex bioaerosol collection device 100 of the present invention includes a filter type first sampling cassette (Filter type) in the first cassette coupling portion 111 and the second cassette coupling portion 112 of the air intake pipe 110. 120) and the second sampling cassette 130 of the impactor type can be selectively installed at the same time, allowing simultaneous collection of filter-type and impact-type bioaerosol with one air pump (P) as well as bioaerosol Aerosol sampling time can be significantly shortened and microbial particles of various sizes, from bacteria to mold, can be collected.

100: Composite bioaerosol collection device 110: Air intake duct
111: first cassette coupling portion 112: second cassette coupling portion
120: first sampling cassette 121: filter case
124, 134: Cover 125: Mesh
130: Second sampling cassette 131: Badge case
135: ventilation hole 136: impact plate
140: Flow control valve
F: Filter G: Badge

Claims (2)

In a complex bioaerosol collection device consisting of a bioaerosol sampling cassette and an air pump,
The lower part can be mounted on the air pump air intake section to provide air suction power, and the air intake pipe body is formed by integrally forming a straight upper first cassette coupling part and a second cassette coupling part branched at an oblique angle in the middle of one side. Contains,
The air intake pipe can selectively simultaneously mount a filter type first sampling cassette and an impactor type second sampling cassette to the first cassette coupling portion and the second cassette coupling portion. Bioaerosol can be collected simultaneously through filter and impact methods through the first and second sampling cassettes by the air suction power of the air pump;
The first sampling cassette is provided with a filter storage space on a filter stand inside an upwardly opened filter case, and a first coupling nozzle protruding through the bottom of the filter case can be coupled to the first cassette coupling unit or the second cassette coupling unit. And, a mesh capable of filtering particles of 100 μm or more is formed on the surface of the cover covering the upper surface of the filter case;
The second sampling cassette is provided with an impact plate with a support protrusion formed on the bottom and a media storage space in an upwardly opened media case, and a second coupling nozzle protruding through the bottom of the media case is connected to the first cassette coupling part or the second cassette. It can be coupled to the coupling portion, and ventilation holes are formed on the surface of the cover covering the upper surface of the badge case;
The filter stand and the upper surface of the impact plate within the filter case are provided with a storage portion capable of accommodating a filter or culture medium, and the storage portion is formed to have a size of 47 mm or 60 mm;
The air intake pipe body is formed such that an inclination angle between the first cassette coupling portion in the vertical direction and the second cassette coupling portion in the diagonal direction is within the range of 40 to 60 degrees;
It further includes an air flow control valve provided at each end of the first cassette coupling portion and the second cassette coupling portion,
The air flow control valve is a complex bioaerosol collection device characterized in that it is configured to vary the air flow rate passing through the first sampling cassette or the second sampling cassette depending on the conditions of the collection site. delete