KR20090097012A - Condensation sampler for detecting airborne microorganisms - Google Patents

Abstract

A condensation sampler for measuring airborne microorganism is provided to minimize the damage of collected microorganism by maintaining enough humidity, quickly and accurately collect and measure the microorganism. A condensation sampler (100) for measuring airborne microorganism (10) comprises: a Nafion tube (110) in which the airborne microorganism is condensed by water molecule (20) and is discharged in condensed formed; a collector (120) which collects the condensed airborne microorganism and liquidizes the microorganism; a Nafion membrane layer (112) which forms internal space of tube and in which the airborne microorganism is inlet and outlet through the internal space; and a water layer (113) which is formed between the outer layer and Nafion membrane layer and in which water flows in and out.

Description

Condensation sampler for detecting airborne microorganisms

The present invention relates to a condensation collector for the measurement of airborne microorganisms, and more particularly, to a condensation collector for airborne microbial measurement to condense and collect the airborne microorganisms present in the air.

Background Art Various techniques for capturing and measuring suspended microorganisms present in the air have been proposed.

In this conventional case, the microorganisms are damaged at the time of collection or after the collection due to the impact force, drying, etc., so that accurate collection and measurement of the microorganisms cannot be made.

In addition, since the liquefaction is not performed at the same time as the collection, it is not easy to apply to the existing microbial measurement and analysis device as it is, and to facilitate this, a liquefaction process of the collected microorganism is required separately.

In addition, the collection and measurement technology of nano-sized suspended microorganisms (viruses, fungal spores, etc.) that can be efficiently and quickly do not exist.

The present invention was created in order to solve the above-mentioned problems, maintain sufficient humidity conditions during the collection of airborne microorganisms, less damage to the collected microorganisms, and at the same time the liquefaction at the same time to collect more accurate and faster to collect and measure The aim is to provide a condensation collector for suspended microbial measurements.

Condensation collector for measuring the airborne microorganism of the present invention for achieving the above object, the tube-shaped outer layer through both ends, is installed inside the outer shell layer so as to correspond to the shape of the outer shell layer to form the inner space of the tube and the inside The Nafion membrane layer into which the floating microorganism is introduced and discharged through the space, and a water layer formed between the outer layer and the Nafion membrane layer and flowing with water, flows into the interior space. Nafion tube condensed by water molecules of water passing through the membrane layer and discharged to the condensed suspended microorganisms; And a collector for collecting the condensed suspended microorganisms discharged through the Nafion tube and liquefying the suspended microorganisms during collection.

Here, it is preferable that the said water is water of 50 degreeC-70 degreeC temperature range.

The present invention may further include a water supply unit for supplying the water to the water layer.

According to the condensation collector for measuring the airborne microorganism according to the present invention, by using the feature that the mass diffusivity of water is larger than the heat diffusivity of the air, condensation of nano-size airborne microorganisms with water molecules to make it easier to collect by increasing the particle diameter It is possible to collect condensed state, so it can be used for environmental pollution detection and alarm.

In addition, it minimizes the impact force on the airborne microorganisms when it is collected by water molecules condensed around the airborne microorganisms, and maintains sufficient humidity conditions so that there is no drying phenomenon, so that the collected microorganisms are extremely damaged so that more accurate collection and measurement can be performed. In addition, accurate monitoring of indoor and atmospheric environments is achieved.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the present specification and claims should not be construed as being limited to the common or dictionary meanings, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that it can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

1 is a schematic configuration diagram of a condensation collector for measuring airborne microorganism according to an embodiment of the present invention, Figure 2 is a graph showing an embodiment of the particle size distribution change according to the condensation of airborne microorganisms.

As shown in FIG. 1, the condensation collector 100 for airborne microbial measurement according to the present invention includes a Nafion Tube 110 and a collector 120.

The Nafion tube 110 may be composed of an outer shell layer 111, a Nafion membrane layer 112 and a water layer 113.

The outer layer 111 is an outer shell having a tube shape through both ends thereof to form an outer surface of the Nafion tube 110 and to protect other layers therein.

In addition, the Nafion membrane layer 112 is installed inside the outer shell layer 111 so as to correspond to the shape of the outer shell layer 111 to form an inner space 40 of the tube 100 and floats into the inner space 40. The microorganism 10 is introduced and discharged.

The Nafion membrane layer 112 refers to a membrane made of Nafion (Nafion) material, the nature, characteristics, etc. of such a Nafion material is variously known in the art and will not be described in detail.

On the other hand, the water layer 113 is a portion formed between the outer shell layer 111 and the Nafion membrane layer 112 and the hot water flows in.

The Nafion tube 110 having the above configuration condenses the microorganisms 10 present in the air with water to increase the particle size thereof.

The condensation principle of the suspended microorganism 10 using the Nafion tube 110 is as follows.

The airborne microorganism 10 introduced into the inner space 40 of the Nafion tube 110 is condensed by water, that is, water molecules 20 that have passed through the Nafion membrane layer 112, and condensed airborne microorganisms ( 30) It is discharged to the outside in the form.

More specifically, hot water in a temperature range of 50 ° C. to 70 ° C. flows out of the Nafion membrane layer 112 in the Nafion tube 110, that is, the water layer 113 as shown in FIG. 1.

Here, in this temperature range of 50 ° C. to 70 ° C., the mass diffusivity of water is greater than the thermal diffusivity of air.

That is, the water molecules 20 of the water layer 113 pass through the Nafion membrane layer 112, whereas the air in the inner space 40 of the Nafion tube 110 is raised in temperature by the hot water. Therefore, the speed delivered to the inner space 40 of the Nafion tube 110 becomes even faster.

Accordingly, the inner space 40 of the Nafion tube 110 is in a state of overhumidity, and the floating microorganism 10 flowing into the inner space 40 of the Nafion tube 110 serves as a nucleus. Molecule 20 is condensed to form the condensed floating microorganism 30. That is, the introduced nano-sized floating microorganism 10 may be more easily collected later as the particle size thereof becomes larger due to the condensation of the water molecules 20 to become the size of the micro unit.

On the other hand, the temperature of the water flowing into the water layer 113 is preferably a temperature in the range of 50 ℃ to 70 ℃ as described above, which is less than 50 ℃ the mass diffusion degree can be reduced condensation efficiency, 70 This is because if the temperature is exceeded, the mass diffusivity is increased but the microorganisms are damaged or die, which causes the collection measurement to be impossible.

Figure 2 shows the change in particle size distribution according to the condensation of the airborne microorganisms, it can be seen that the airborne microorganisms having a particle size of the nano unit of less than 1㎛, it will be increased to the particle size of more than 1㎛ microunit through the above-mentioned condensation process have.

As described above, the present invention utilizes a feature in which the mass diffusivity of water is larger than the thermal diffusivity of air to condense the nano-sized suspended microorganism 10 with the water molecules 20 to increase the particle diameter thereof, thereby enabling easier collection. do.

In addition, while the existing collector is impossible to capture nano-sized suspended microorganisms (viruses, mold spores, etc.), the present invention is capable of collecting the condensed state to measure nano-sized suspended microorganisms, and thus detects and pollutes environmental pollution. It can be used.

On the other hand, the collector 120 is installed on the rear end of the Nafion tube 110 to collect the condensed floating microorganisms 30 discharged through the Nafion tube 110, the collected microorganisms thus collected is a part liquefied. .

Since the type of collector used to collect the microorganisms is known in various ways, a separate description of the detailed principles, types, etc. of the collector 120 will be omitted.

On the other hand, some of the shock-resistant microorganisms, such as Pseudomonas species, are often damaged by the impact force during the capture process.

However, in the case of the present invention, it is possible to reduce the damage of the microorganism as much as possible by relieving the impact force while being captured by the water molecules 20 condensed around the floating microorganism 10, to enable more accurate collection or measurement .

In addition, when the suspended microorganism 30 condensed by the water molecules 20 is collected through the collector 120, it becomes a liquid state.

Existing microbial measurement and analysis is almost all made of a liquid phase rather than a gaseous state when using the condensation collector 100 of the present invention, it is possible to make faster and easier microbial measurement and analysis.

For example, the airborne microorganisms collected in the liquid state in the collector 120 can be measured more easily and quickly by using an optical method or an ATP measuring device using a spectrophotometer or the like used for conventional microbial concentration measurement. It is possible to facilitate identification and characterization of suspended microorganisms using PCR, flow cytometer, etc., which are mainly used for existing biological analysis.

As described above, the present invention minimizes the impact force on the airborne microorganisms at the time of collection, maintains sufficient humidity conditions, and there is no damage of the collected microorganisms because there is no drying phenomenon so that more accurate collection and measurement can be made, and furthermore, accurate indoor Ensure that the environment and atmospheric environment are monitored.

On the other hand, the present invention, as shown in Figure 1, may further include a water supply unit 130 for supplying the water to the water layer 113.

The water supply unit 130 may be in the form of a pump for supplying water.

Water flowing into the water layer 113 flows through the Nafion membrane layer 112 and is continuously used for condensation of the floating microorganism 10, so that the amount thereof gradually becomes exhausted.

Therefore, the water supply unit 130 preferably supplies water to the water layer 113 continuously by the amount or speed of water reduced through the Nafion membrane layer 112 so that water is not completely consumed.

Industrialization possibilities for the present invention as described above are as follows.

First, from the technical point of view, the present invention can more easily and quickly measure microorganisms such as viruses, fungus spores, etc., which are difficult to measure due to their size, and thus, more precise and rapid detection of harmful microorganisms and alarms is achieved. It may be possible. In addition, according to the present invention, it is possible to build an artificial indoor air management system by interlocking with the floating harmful microorganism reduction technology, and can be utilized as a process test method for indoor floating microorganism regulation through securing sufficient reliability.

Next, in view of economic and social aspects, the present invention can realize the ease of indoor air quality management such as a multi-use facility by developing a simple and inexpensive airborne microbial measurement device. In addition, it is possible to prevent the economic loss caused by the breeding of harmful microorganisms in bird flu or food, and can be easily obtained and used by the general public, thereby contributing to the improvement of human welfare by monitoring real-time or near-real-time floating microorganisms.

Moreover, the development of a new concept of airborne microbial capture and measurement devices can fully replace the importation of expensive / large airborne microbial equipment.

As described above, although the present invention has been described by means of a limited embodiment and drawings, the present invention is not limited by this and the technical spirit of the present invention and the following by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

1 is a schematic configuration diagram of a condenser collector for measuring airborne microorganisms according to an embodiment of the present invention;

Figure 2 is a graph showing an embodiment of the particle size distribution change according to the condensation of airborne microorganisms.

<Explanation of symbols for the main parts of the drawings>

10 ... floating microbes 20 ... water molecules

30 ... Condensed suspended microorganisms 40 ... Inner space

100 ... condensation collector for floating microorganisms

110 Nafion tube 111 outer layer

112 Nafion membrane layer 113 Water layer

120 ... collector 130 ... water supply

Claims (3)

A tubular outer layer through which both ends penetrate, a nafion membrane layer installed inside the outer layer to correspond to the shape of the outer layer to form an inner space of the tube, through which the microorganisms are introduced and discharged, and the outer layer and b. Including a water layer formed between the pion membrane layer and flowing water, the airborne microorganisms introduced into the internal space are discharged to the airborne microorganisms condensed by the water molecules of the water passing through the Nafion membrane layer Pion tube; And Condensation collector for collecting the condensed airborne microorganisms discharged through the Nafion tube and includes a collector for liquefying the airborne microorganisms when collecting. The method of claim 1, wherein the water, Condensation collector for airborne microbial measurement, characterized in that the water in the temperature range of 50 ℃ to 70 ℃. The method according to claim 1 or 2, Condensation collector for airborne microbial measurement further comprises a water supply for supplying the water to the water layer.

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