KR100810569B1 - An auto sampler for collecting and detecting microorganisms - Google Patents

Abstract

An auto-sampler for collecting and detecting microorganisms is provided to be convenient for carrying and moving, collect the microorganisms rapidly and easily and prevent collected sample from being contaminated and damage which occurs when the collected sample is put. An auto-sampler for collecting and detecting microorganisms, one side of which is connected to a vacuum pump(400) to discharge air compulsorily and the other side of which is connected to a detecting apparatus(300) for detecting the collected microorganisms comprises: (a) a reactor body(100) which includes a body upper part(110) having a cylindrical shape and a body lower part(120) assembled to a portion of the body upper part by insertion and having a square pillar shape to be directly coupled to the detecting apparatus; and a nozzle apparatus(200) which includes an air inlet(210) which shuts an upper end of the body upper part tightly and allows an outside air including the microorganisms and microparticles to be flown in, an air outlet(220) which is connected to the vacuum pump to discharge air compulsorily, and a nozzle(230) which is soaked in a reaction solution of the measuring apparatus and is communicated with the air inlet to spray the air containing the microorganisms and microparticles into the reaction inside, wherein the nozzle is formed by branching a plurality of pipes(231) where outlets of the pipes are radially placed with being spaced apart from one another having a predetermined central angle. The auto-sampler further comprises an air bubble generation preventing device at the center of the body upper part and an O-ring(121).

Description

{An Auto Sampler for Collecting and Detecting Microorganisms}

1 is a cross-sectional view of the reactor body of the automatic collector according to the present invention.

Figure 2 is a cross-sectional view of the nozzle device of the automatic collector according to the present invention.

Figure 3 is a cross-sectional view at the time of coupling the reactor body and the nozzle apparatus according to the present invention.

4 is an embodiment of the present invention.

** Description of the symbols for the main parts of the drawings **

100: reactor body

110: upper body 111: O-ring

112: bubble prevention device

120: lower body 121: O-ring

200: nozzle device

210: air inlet 220: air outlet

230: nozzle 231: pipeline

300: measuring device 400: vacuum pump

The present invention relates to a microorganism collecting and detection automatic harvester, and more particularly, to collect the spores of microorganisms present in the air to connect to the fluorescence detection system to detect the concentration of the microorganism collecting and detection automatic harvester It is about.

Bacteria, such as Bacillus, form endogenous spores during lack of growth essential factors or extreme stress. Bacteria spores are highly resistant to high temperatures, strong acids, strong alkalis, drying, radioactivity and chemicals, and thus are highly viable under extreme adverse conditions as described above. In particular, such microorganisms that form endogenous spores, such as anthrax, cause a lethal danger for living things such as humans or animals. Therefore, it is very important to detect spores of pathogenic microorganisms that are diffused in the air in a short time.

The method of measuring the microorganisms suspended in the known can be divided into the method of measuring the falling bacteria and the method of measuring the floating bacteria. Falling bacteria measurement is a more conventional method, in which the suspended microorganisms contaminated at the measuring site of interest are naturally dropped onto the plate medium. The plate medium is produced in a sterile state and opened for a predetermined time and placed in a specific position. The medium from which the microorganisms are collected is collected and the microorganisms dropped therefrom are cultivated, and thus, the number of colonies grown and multiplied is measured per unit time. The viable cell count of is calculated. The method has the advantage that it is simple and is not limited by time and place, and the collection itself does not require any specific equipment. However, since the collected sample must be collected and put into the analytical equipment, the result is very high until the result is obtained. The problem is that it takes a long time (usually more than a week). In addition, some microorganisms may be too small to fall, and some of the microorganisms may not be detected because they do not develop due to inadequate culture conditions. It is widely known that the results are not very reliable. In addition, such a conventional microbial detection method has a lot of problems, such as the difference in results may also occur depending on the measurement position to place the medium, which caused a great inconvenience to the user. Suspended bacteria measurement method is a method of forcibly sucking a certain amount of air to pass through the medium and culturing the microorganisms adsorbed on the medium. We did not solve the problem that the results vary depending on the location and the very long time to get the results.

In addition, the collection equipment currently commonly used is very bulky and very inconvenient to carry. In addition, after the sample is collected into the analysis system and collected, the sample must be transferred from the collection equipment to a container that can be placed in the analysis system. In this process, the sample may be contaminated or damaged, resulting in inaccurate results. In addition, in order to minimize this possibility, a separate equipment for safely transporting the sample is not required to be contaminated and damaged. Accordingly, there is a problem that various inconveniences and waste of manpower and cost occur. Korean Patent Registration No. 10-0549222 ("airborne microorganism collecting device", hereinafter referred to as the prior art) of the conventional microorganism collecting technology, the particles suspended in the air by injecting air to the collecting plate rotated by the nozzle Disclosed is a technique for easily collecting microorganisms in the field by inertial collision. According to the prior art, there is an advantage in that the collection efficiency of the microorganisms is improved and the microorganisms can be uniformly collected throughout the collecting plate. However, the prior art also basically because it has to collect the microorganisms in the collecting plate and transfer them to the culture equipment could not completely exclude the possibility of contamination and damage of the sample as described above. In addition, since the driving device for rotating the collecting plate, etc. should be included, the problem of inconvenience of carrying and moving due to the large equipment volume was still not solved.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, the object of the present invention is to carry and move, and to be able to quickly and easily take a sampling, as well as to put the sample collected in the detection system The present invention provides an automatic harvester for collecting and detecting microorganisms, in which contamination and damage of a collected sample generated at the time of removal are fundamentally removed.

The microorganism collection and detection automatic harvester of the present invention for achieving the above object, one side is connected to the vacuum pump 400 forcibly discharge the air, the other side measuring device 300 for detecting the microorganisms collected In the microorganism collection and detection automatic harvester connected to the), the upper body 110 formed in a cylindrical shape, a portion of the upper body 110 is inserted and assembled to form a square pillar shape measuring device 300 Reactor body 100 including a lower body 120 that can be directly coupled to; And an air inlet 210 which is accommodated in the reactor body 100 and seals an upper end of the upper body 110, and in which external air containing microorganisms and particulates is introduced therein, and is connected to the vacuum pump 400 to supply air. Air discharge port 220 forcibly discharged, immersed in the reaction solution in the measuring device 300 and communicated with the air inlet 210, the air containing the microorganisms and fine particles introduced into the air inlet 210 inside the reaction solution Nozzle device 200 comprising a nozzle 230 for spraying to; Characterized in that comprises a. At this time, the nozzle 230 is formed by branching into a plurality of thin conduits 231, characterized in that the outlets of the conduits 231 are radially spaced apart from each other with a predetermined center angle. In addition, the diameter of the pipe 231 is preferably determined to a value within the range of 0.1mm or more and 0.4mm or less.

In addition, the O-ring 121 is further provided at a portion of the cylindrical upper body 110 and the rectangular lower body body 120 that are assembled to each other and immersed in the reaction solution so that the gap is sealed. do.

In addition, in the middle of the upper body 110 is characterized in that the bubble generating device 112 for breaking the bubbles discharged from the reaction solution is further provided. At this time, the bubble generating device 112 is characterized in that formed in the shape of a metal body.

Hereinafter, with reference to the accompanying drawings, the automatic harvester for collecting and detecting microorganisms according to the present invention having the configuration as described above will be described in detail.

The automatic extractor 1000 according to the present invention is configured to be assembled, and the reactor body 100 and the nozzle device 200 are independently configured to be separated and assembled. First, Figure 1 is a cross-sectional view of the reactor body of the automatic extractor according to the present invention, the reactor body 100 is divided into the upper body 110 and the lower body 120, the upper body 110 is formed in a cylindrical shape and the body The lower part 120 is formed in a square pillar shape. The lower body 120 may be directly connected to and coupled to the measuring device, and the inlet shape of the sample container of the measuring device, which is widely used, may be formed in a rectangular column shape to increase convenience. The upper body 110 is preferably made of a transparent material to facilitate the user to check the interior during the reaction, and is preferably formed in a cylindrical shape to facilitate the observation of the inside, the shape of the upper body 110 Of course, it may vary depending on the manufacturing or use convenience. The upper body 110 and the lower body 120 are also independently formed to be assembled and separated, and the O-ring 121 is provided at the portion where the upper body 110 and the lower body 120 are coupled to prevent leakage. do. Since the O-ring 121 is an elastic body, even if the shape of the hole (square cross section) of the lower body 120 and the protruding portion (circular cross-section) of the upper body 110 are different from each other, the shape of the O ring 121 is appropriate. It can be deformed and tightly sealed without fear of leakage.

2 is a cross-sectional view of the nozzle apparatus of the automatic collector according to the present invention. The nozzle device 200 has an air inlet 210 and an air outlet 220 at one end thereof, and a nozzle 230 at the other end thereof. A path through which air flows is formed between the air inlet 210 and the nozzle 230, and the path is narrowed closer to the nozzle 230 to increase the pressure as shown in FIG. 2. Get the effect of speeding up the flow of. A plurality of very narrow conduits 231 are formed in the nozzle 230, so that the air flowing through the nozzle 230 becomes faster and is dispersed and sprayed in a plurality of directions.

3 is a cross-sectional view of the reactor body and the nozzle apparatus according to the present invention, the configuration and operation of the automatic extractor of the present invention by this figure will be described in more detail. First, as shown in FIG. 3, the reactor body 100 and the nozzle device 200 are coupled to each other in such a way that the nozzle device 200 is accommodated in the reactor body 100. O-ring 111 is provided at the upper end of the reactor body 100 and the upper end of the nozzle device 200, the O-ring 111 is to prevent the leakage of air pressure in the reactor body 100 is constant It serves to seal the reactor body 100 to be maintained at the level. The reactor body 100 and the nozzle device 200 assembled as described above are inserted and coupled to the measuring device 300, and a reaction solution accommodated in the measuring device 300 is provided in a part of the internal space of the reactor body 100. It comes in.

The air outlet 220 of the nozzle device 200 is provided with a vacuum pump 400, so that the air in the reactor body 100 to the air outlet 220 as the vacuum pump 400 sucks air Forced discharge. Accordingly, the pressure inside the reactor body 100 is lowered, and as a result, the level of the reaction solution flowing into the reactor body 100 from the measuring device 300 is increased, and the microorganism and the air inlet 210 are increased. Outside air containing fine particles flows in and flows along the nozzle device 200 accommodated inside the reactor body 100.

As described above, the nozzle 230 provided at the end of the nozzle device 200 has a plurality of very thin pipes 231 formed therein. Since the cross-sectional area of the conduit 231 is very small, the reaction solution does not flow back due to the principle of surface tension, but air may be injected into the reaction solution through the conduit 231. In particular, as the air flow path inside the nozzle apparatus 200 becomes narrower, the flow of air is faster and the flow of air is further accelerated while passing through the conduits 231 in the nozzle 230, so that the outside air is measured. It is injected while generating strong turbulence in the reaction solution contained in the device (300). The plurality of the conduits 231 are radially disposed so that not only the mixing with the entire reaction solution takes place effectively but also causes the generation of turbulence according to the principle described above, thereby allowing the reaction solution, air, and microorganisms and fine particles in the air to be much higher. Because of the good mixing, there is a big improvement in the reaction rate.

At this time, air containing microorganisms and fine particles is discharged out of the reaction solution in the form of bubbles. During the sampling process, the level of the reaction solution is located in the reactor body 100. There is a possibility that the reaction solution is splashed out of the process while bubbles are discharged to the surface of the reaction solution. Therefore, the inside of the reactor body 100 of the automatic collector of the present invention is provided with a bubble prevention device 112 so that the reaction solution does not splash a lot when the bubble bursts on the surface of the reaction solution by making the bubble smaller. The bubble preventing device 112 is preferably a sieve-shaped filter made of stainless steel, of course, any shape can be broken small bubbles can be any shape, and also easily filter without causing a reaction with the reaction solution Any material can be used as long as it can be manufactured.

Figure 4 conceptually illustrates one embodiment of measuring the microbial concentration using the automatic harvester of the present invention. As described in the description of FIGS. 1 to 3, the automatic extractor of the present invention effectively injects air containing microorganisms and fine particles into the reaction solution contained in the measuring device 300 to generate turbulent flow so that the reaction solution is mixed well in the reaction solution. . As such, reaction occurs by mixing microorganisms and fine particles in the reaction solution, and the light emitted from the Xe-lamp light source to the reaction solution that reacts with the microorganisms and fine particles is also detected by the detector through the optical filter. Will be Such a detection method is a method that is generally employed in a widely used microbial concentration measuring device, and the automatic harvester 1000 according to the present invention can be used directly connected to the microbial concentration measuring device so widely used for immediate collection and There is a huge advantage that detection can be made easily.

The present invention is not limited to the above-described embodiments, and the scope of application of the present invention is not limited to those of ordinary skill in the art to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Of course, various modifications can be made.

As described above, according to the present invention, unlike the conventional harvesting machine, the volume is small, and thus, the porting and moving is easy, and thus the collecting operation is very easy. In addition, the harvester according to the present invention can connect the harvester itself to the analysis system, thereby greatly eliminating the possibility of damage or contamination in the process of transferring the collected sample to another container, thereby greatly increasing the reliability of the results. have. In addition, the present invention can effectively collect microorganisms suspended in the air because it collects microorganism spores using a small vacuum pump, in particular, the harvester according to the present invention can continuously collect and monitor the sample concentration of microorganism spores in the air It is very effective to make it easy to know the time change and the diffusion rate of the.

Claims (6)

In one side is connected to the vacuum pump 400 forcibly discharge the air, the other side is connected to the measuring device 300 for detecting the microorganisms collected microorganism collection and detection automatic harvester, Body upper portion 110 is formed in a cylindrical shape, a portion of the body upper portion 110 is inserted and assembled and includes a lower body body 120 is formed in a rectangular pillar shape can be directly coupled to the measuring device 300 Reactor body 100 made; And It is accommodated in the reactor body 100 to seal the upper end of the body 110, connected to the air inlet 210, the vacuum pump 400, the outside air containing microorganisms and particulates is forced to force air The air outlet 220 to be discharged, immersed in the reaction solution in the measuring device 300 and communicated with the air inlet 210, the air containing the microorganisms and fine particles introduced into the air inlet 210 into the reaction solution A nozzle device 200 including a nozzle 230 for spraying; Automatic harvester for collecting and detecting microorganisms, characterized in that comprises a. The method of claim 1, wherein the nozzle 230 It is formed by branching into a plurality of thin conduits (231), the outlets of the conduits (231) is a microorganism collecting and detecting automatic harvester, characterized in that arranged radially spaced from each other with a predetermined center angle. The method of claim 1, The diameter of the conduit 231 is a microorganism collecting and detection automatic harvester, characterized in that determined by a value within the range of 0.1mm or more and 0.4mm or less. The method of claim 1, Microorganisms characterized in that the cylindrical upper body 110 and the rectangular body lower body 120 is assembled to each other and immersed in the reaction solution, the O ring 121 is further provided so that the gap is sealed. Automatic harvester for collection and detection. The method of claim 1, In the middle of the upper body 110, the microorganism collection and detection automatic harvester, characterized in that the bubble generation prevention device 112 for breaking the bubbles discharged from the reaction solution is further provided. The method of claim 5, The bubble generation prevention device 112 is a microorganism collecting and detecting automatic harvester, characterized in that formed in the shape of a metal body.

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