KR20140125535A - Apparatus for Sampling Microorganisms from Air - Google Patents

Abstract

The present invention relates to a sampling apparatus for floating microorganisms in the air, which can collect various floating microorganisms such as germs and fungus in the air, can minimize the loss or degradation of survivability of the floating microorganisms due to collisions during the collecting process of floating microorganisms, can continuously perform a sampling work by minimizing repetitive disinfection work of the sampling apparatus, and can improve the reliability in measuring the concentration of floating microorganisms by preventing contamination of the sampling apparatus. The provided sampling apparatus for floating microorganisms in the air comprises: a main body (10) where a nozzle (14) for air entry is formed; a tube (20) which is positioned vertically below the nozzle (14) and stores a buffering solution (100); and a tube support (30) which fixates the tube (20) at a vertically standing state. Air flowing into the nozzle (14) circulates by entering the inside of the tube (20) and then being discharged to the outside of the main body (10). Floating microorganisms (2) in the air fall into the buffering solution (100) to be captured when the air circulates the inside of the tube (20). In particular, the tube support (30) can rotate and multiple tubes (20) are installed in order to continuously capture the floating microorganisms using the multiple tubes.

Description

[0001] The present invention relates to a sampling apparatus for floating microorganisms in air,

The present invention relates to a sampling device for a floating microorganism in the air. More particularly, the present invention relates to a sampling device for sampling floating microorganisms such as bacteria and fungi floating in the air. In the process of collecting floating microorganisms, It is possible to minimize the loss of viability or weaken the viability due to the impact caused by the collision and at the same time to minimize the repetitive disinfection operation of the sampling device so that continuous sampling operation can be performed and contamination of the sampling device can be prevented, And more particularly, to a floating microbial sampling device configured to improve reliability of the concentration measurement of microorganisms.

In the case of multi-use facilities where many people live, such as the history of subway, it is very important to properly manage the concentration of suspended microorganisms floating in the air in the room. The Ministry of Environment has established the management standards for the concentration of suspended microorganisms in the indoor air for multi - use facilities through laws and ordinances.

In order to control the concentration of suspended microorganisms suspended in the indoor air, it is first necessary to collect suspended microorganisms. As a conventional sampling apparatus for trapping suspended microorganisms, a technique using a solid medium is known, An example of this is disclosed in Japanese Patent Application Laid-Open No. 10-2012-128619. However, in the case of the conventional technology using the solid medium, the floating microorganisms collide with the solid medium during the sampling process, so that the floating microorganisms lose the viability or the viability of the microorganisms due to the impact, And the reliability of the concentration measurement result of the collected suspended microorganisms is deteriorated.

Another prior art is the so-called "impinger" sampling device, wherein a schematic cross-sectional view of the configuration is shown in Fig.

In the conventional impinger type sampling apparatus, as shown in the drawing, a liquid buffer solution 100 is contained in a collecting container 101, and an air inlet pipe 102 separated from the collecting container 101 and separated from the collecting container 101 And is disposed in the collection container 101 so that its end portion is immersed in the buffer solution 100. Therefore, the air introduced through the air inlet pipe 102 is discharged through the outlet 103 of the collecting container 101 after passing through the buffer solution 100. In addition to the air, the airborne microorganisms The air is left in the buffer solution 100 in the course of flowing through the buffer solution 100 as described above. The buffer solution (100) is collected separately, and the suspended microorganisms are isolated through a filter paper and then grown on the medium to measure the concentration of suspended microorganisms.

However, in the above-described conventional impinger-type sampling apparatus, since the collection container 101 is required for each collection of the floating microorganisms and the inside of the collection container 101 is to be sterilized after the collection of the floating microorganisms is completed, The use of the sampling device is interrupted due to the progress of the operation, and consequently continuous collection is impossible. That is, when the floating microorganisms are collected for a predetermined period of time, the operation of transferring the buffer solution 100 contained in the collection container 101 to another container and the operation of sterilizing the inside of the collection container 101 must be performed, Once the capture of the suspended microorganisms is completed, the additional microbes must be collected only after having the temporal voids according to the above-mentioned essential tasks.

Particularly, in the conventional impinger type sampling apparatus, since the end portion of the air inflow pipe 102 is always immersed in the liquid buffer solution 100, the air inflow pipe 102 is in a state of being contaminated already in the previous collecting process There is a fear that it will be reused in the new collection process. In order to prevent such a danger, it is necessary to thoroughly clean and disinfect the air inflow pipe 102 and then to use it in a new collection process. The additional effort and cost for cleaning and disinfecting the air inflow pipe 101 It takes more time and there is therefore a temporal gap between the collection process performed previously and the subsequent collection process. As a result, it is impossible to perform continuous collection of the suspended microorganisms in the conventional impinger sampling device .

Furthermore, in the case of the conventional impinger-type sampling device, it is necessary to perform troublesome work to disinfect the collecting container 101 every time to perform a new collecting operation, and to collect the buffer solution 100 separately, There is also a disadvantage that it comes with a lot.

See Korean Patent Publication No. 10-2012-128619 (published Nov. 27, 2012).

The present invention has been developed in order to overcome the limitations and problems of the prior art as described above, and it is an object of the present invention to provide a floating microorganism which minimizes the loss of viability or the weakening of viability of floating microorganisms due to impact caused by collision during sampling, Thereby reducing the occurrence of error in the concentration measurement and improving the reliability of the concentration measurement result.

The present invention also provides a method and apparatus for measuring the concentration of suspended microorganisms by using a liquid buffer solution but not requiring the operation of separating the suspended microorganisms from the liquid buffer solution through the filter paper and then propagating on the medium, The purpose is to make.

Furthermore, the present invention makes it possible to continuously carry out the collection of suspended microorganisms by using a new buffer solution, without time-consuming due to the disinfection and cleaning of contaminated devices, To be used in advance.

In order to accomplish the above object, according to the present invention, there is provided an air conditioner comprising: a top plate on which an air inlet nozzle is formed; and a discharge port through which air is sucked and discharged by a suction force, A tubular main body; A tube positioned within the body and immediately below the nozzle and containing a buffer; And a tube support which is provided in the main body at an interval from an inner wall surface of the main body and supports the tube so that the tube is vertically erected and fixed; The air introduced into the nozzle circulates through the inside of the tube and then exits again and then passes through a gap between the main body and the tube support and is discharged through the discharge port to the outside of the main body. The air is dropped into the buffer solution when the air circulates inside the tube, and is trapped in the buffer solution to be collected.

In the sampling apparatus of the present invention, the tube support is rotatably provided in the body; The tube support may be mounted with a plurality of tubes; A shielding plate is vertically installed on the upper surface of the tube support so as to partition the space in which the plurality of tubes are arranged in the tube support, And a plurality of tubes are sequentially disposed under the vertical straight portion of the nozzle while the tube support is rotating so that the floating microorganisms are captured in the buffer solution contained in each tube. In particular, in this case, the tube support may be configured to be stepwise rotated by a stepping motor to a predetermined angle such that each tube is automatically positioned at a position directly below the nozzle.

According to the present invention, the impact caused by the collision does not greatly affect the floating microorganisms during the trapping of the floating microorganisms, so that the floating microorganisms lose their survivability or their viability is minimized due to the impact. Therefore, according to the sampling device of the present invention, it is possible to prevent the occurrence of errors in the concentration measurement of the floating microorganisms due to the dead or viability of the floating microorganisms and to prevent the reliability of the concentration measurement results from being lowered.

Particularly, according to the present invention, since any member communicating with air in the process of collecting floating microorganisms is not immersed in the buffer solution, unlike the conventional impinger type sampling apparatus, there is no need to clean and disinfect the air inflow pipe, And the time for disinfection can be saved, and contamination due to poor cleaning and disinfection operations can be prevented.

Further, in the present invention, since floating microorganisms are trapped in the buffer solution and the floating microorganisms can directly be propagated by using such a buffer solution, there is a need to separately perform additional operations such as separation of suspended microorganisms through filtration and transplantation into a medium So that it is possible to carry out the concentration measurement work more quickly and easily by collecting the suspended microorganisms.

Above all, the sampling device according to the present invention is very easy to deform into an apparatus having a structure for continuous execution of the floating microorganism collecting operation, and furthermore, is also advantageous for automating such continuous running, According to the present invention, the operation of collecting floating microorganisms by using a plurality of tubes can be performed sequentially and continuously, and furthermore, it is possible to carry out the operation very easily and quickly.

Particularly, in performing a continuous sequential collection operation using such a plurality of tubes, it is possible to prevent the contamination of the buffer contained in the tube that has not yet started the collection operation by using the shield plate, The advantage of being able to perform the work is exerted.

1 is a schematic cross-sectional view showing the construction of a floating microbial sampling device of the impinger type according to the prior art.
2 is a schematic perspective view of a floating microbial sampling device according to an embodiment of the present invention.
Figs. 3 and 4 are schematic cross-sectional perspective views, respectively, along line AA of Fig. 2 showing the internal configuration of the sampling apparatus shown in Fig.
FIG. 5 is a schematic cross-sectional view taken along the line AA of FIG. 2, showing a state in which air is sucked in the sampling device of the present invention according to the embodiment shown in FIG. 2 to FIG. 4 to collect floating microorganisms.
6 is a schematic perspective view of a sampling device according to another embodiment of the present invention, which has a configuration capable of continuously capturing floating microorganisms using a plurality of tubes.
FIG. 7 is a schematic cross-sectional perspective view along line BB of FIG. 6 showing the internal configuration of the sampling device shown in FIG. 6;
8 is a schematic cross-sectional view along line CC of FIG. 6 showing the internal configuration of the sampling device shown in FIG.
FIG. 9 is a schematic perspective view of a sampling apparatus according to another embodiment of the present invention, which is capable of continuously collecting suspended microorganisms using a plurality of tubes.
FIG. 10 is a schematic cross-sectional perspective view corresponding to FIG. 7 showing the internal configuration of the sampling apparatus shown in FIG.
Fig. 11 is a schematic cross-sectional view corresponding to Fig. 8 showing the internal configuration of the sampling apparatus shown in Fig.
FIG. 12 is a schematic cross-sectional view along line BB of FIG. 6 showing a state in which floating microorganisms are collected in the sampling apparatus shown in FIG.
FIG. 13 is a schematic cross-sectional view corresponding to FIG. 12 showing a state in which floating microorganisms are collected in the sampling apparatus shown in FIG.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiments shown in the drawings, it is to be understood that the technical idea of the present invention and its essential structure and operation are not limited thereby.

2 is a schematic perspective view of a floating microbial sampling device 1 (hereinafter abbreviated as "sampling device") according to an embodiment of the present invention, and FIGS. 3 and 4 show a perspective view FIG. 3 shows a disassembled state that has not been assembled, and FIG. 4 shows a state in which the assembly is completed . FIG. 5 is a schematic cross-sectional view showing a state in which air is sucked by the sampling device 1 of the present invention according to the embodiment shown in FIG. 2 to FIG. 4 to collect floating microorganisms.

As shown in the drawing, the sampling device 1 of the present invention is provided with a finishing plate 11 having a nozzle 14 on which air is introduced, and a suction force (not shown) Which is located immediately below the vertical position of the nozzle 14 in the main body 10 and which is provided with a liquid buffer solution A tube 20 for containing air from the nozzle 14 and circulating the inside of the nozzle through the upper opening and discharging the air to the upper opening; And a tube support 30 for supporting and supporting the tube 20.

Specifically, the main body 10 is formed of a tubular member having an inner space, and a discharge port 12 is formed at a lower end thereof, and the discharge port 12 is communicated with the suction pump. A finishing plate 11 is provided at an upper end of the main body 10, and a nozzle 14 is formed through the finishing plate 11. In the embodiment shown in the drawing, the nozzle 14 protrudes in the bottom direction of the finishing plate 11 so that air can be concentratedly supplied to the inside of the tube 20. However, in the present invention, Is not limited to such a protruding configuration, but may be formed in the form of a simple hole passing through the finishing plate 11.

A tube support 30 is provided in the body 10. Between the tube support 30 and the inner surface of the body 10 there is a gap to allow air to flow in the direction of the outlet 12. A rod-like connecting member 31 is protruded from the inner wall surface of the main body 10 and the protruding end of the connecting member 31 is coupled to the tube support 30 The tube support 30 can be provided inside the main body 10 with an interval from the inner wall surface of the main body 10. However, the shape of the connecting member 31 is not limited to such a rod-shaped projecting member but may be formed in a different shape. Further, the tube support 30 may be provided inside the main body 10 with an interval from the inner wall surface of the main body 10 through another configuration without using the connecting member 31. [ In yet another embodiment, substantially the lateral side surface of the tube support 30 is in close contact with the inner wall surface, but a penetrating portion is formed in the tube support 30 to allow air to flow through the penetrating portion . Thus, the presence of a gap between the tube support 30 and the inner wall surface of the body means that the lateral side surface of the tube support 30 is in close contact with the inner wall surface, but the tube support 30 itself has a through- Through the penetrating portion and flow through the penetrating portion.

The tube support 30 includes a mounting portion 32 to which the tube 20 can be coupled. As shown in the drawing, the mounting portion 32 may be formed in the shape of a concave groove, . ≪ / RTI > That is, in the present invention, the mounting portion 32 may be formed in any other configuration as long as the tube 20 is installed.

The tube 20 may be made of, for example, glass, a synthetic resin, or a metal tube. The liquid buffer solution 100 is contained in the tube 20, and the upper end is open. In the illustrated embodiment, the tube 20 is disposed within the body 10 in an upright position coupled to the tube support 30 such that the open upper end is located directly beneath the nozzle 14.

In the sampling device 1 of the present invention having such a configuration, when the suction motor is operated, the air in the main body 10 escapes to the discharge port 12, and the air outside the main body 10 flows through the nozzle 14 And flows into the interior of the main body 10. [ At this time, the suspended microorganisms contained in the air also flow into the interior of the main body 10. Since the open upper end portion of the tube 20 is located just below the nozzle 14, the air containing airborne microorganisms Is immediately introduced into the interior of the tube (20) as it enters through the nozzle (14). The air introduced into the tube 20 is circulated through the tube 20 and then exits through the upper end of the tube 20 and then the air flows between the body 10 and the tube support 30 And is discharged out of the main body 10 through the discharge port 12 through the gap. The arrow in FIG. 5 shows the flow of air as described above.

The airborne microorganisms 2 contained in the air fall down into the buffer solution 100 contained in the tube 20 and flow into the buffer solution 100 in the circulation process in which the air enters the inside of the tube 20 and then exits again. Will be left behind. That is, in the sampling apparatus 1 according to the present invention, the air containing the floating microorganisms flows into the tube 20, and then the floating microorganisms fall down into the buffer solution 100 due to their own weight It remains in the buffer solution 100 and is collected. Therefore, unlike the conventional technology using solid medium, in the present invention, impact due to collision is not greatly applied to the floating microorganisms, and the suspension microorganisms lose their viability or their viability is minimized due to the impact. That is, according to the present invention, it is possible to prevent an error in measurement of the concentration of suspended microorganisms due to mortality or weakness due to the impact of the suspended microorganism, and to prevent the reliability of the concentration measurement result from being lowered.

Particularly, unlike the conventional impinger-type sampling device, the sampling device 1 of the present invention is not immersed in the liquid buffer solution 100 in any member communicating air in the process of collecting floating microorganisms. As described above, in the conventional impinger-type sampling apparatus, since the end portion of the air inflow pipe is always immersed in the liquid buffer, the air inflow pipe is likely to be reused in a new collection process, In order to prevent this, it is necessary to thoroughly wash and disinfect the air inlet pipe. However, in the case of the present invention, since any member for sucking and supplying air is not immersed in the buffer solution and does not touch the buffer solution at all, unlike the conventional impinger sampling apparatus, the cleaning and disinfection operation of the air inflow tube Is not necessary, and thus can save time for cleaning and disinfection.

Further, in the present invention, since floating microorganisms are collected in the buffer solution (100) and the floating microorganisms can be directly propagated by using the buffer solution (100), separation of floating microorganisms through filtration and transplantation operation into a medium There is no need for additional work of the microorganisms, so that it is possible to carry out the concentration measurement work more quickly and easily by collecting the suspended microorganisms.

Furthermore, in the sampling device 1 of the present invention, once the floating microorganism collecting operation is completed, the existing tube is removed and a new buffer solution is attached to the tube support 30 to newly perform the following trapping operation It is possible to carry out the operation immediately. That is, if only the tube 20 is replaced without replacement or cleaning of the main body 10, a new buffer solution can be used to newly start the floating microorganism collecting operation, so that the floating microorganism collecting operation can be performed quickly and continuously There are advantages to be able to perform. Particularly, as described above, since the cleaning and disinfection operation of the air inlet pipe is not necessary and the time for washing and disinfection is not consumed, there is little time gap between the preceding and subsequent collection processes, It is easy to continuously carry out the collecting operation.

Above all, the sampling device 1 according to the present invention replaces only the tube 20 to continuously perform the floating microorganism collecting operation as described above, so that the continuous execution of the floating microorganism collecting operation is performed as in another embodiment described later It is very advantageous to automate such a continuous operation.

6 shows a schematic perspective view of a sampling device 1 having a configuration capable of continuously capturing floating microorganisms using a plurality of tubes 20 as another embodiment of the present invention, Fig. 8 is a schematic cross-sectional perspective view (Fig. 7) according to line BB of Fig. 6 and a schematic cross-sectional view (Fig. 8) according to line CC of Fig. 6 showing the internal construction of the sampling device 1 shown in Fig. 6 Respectively.

The sampling apparatus 1 according to the embodiment shown in FIGS. 6 to 8 has a configuration in which a plurality of tubes 20 can be mounted. 6 to 8, the tube support 30 may be attached to the upper surface of the tube support 30 and the upper surface of the tube support 30, And the tube support 30 is configured to be rotatable.

The tube support 30 includes a plurality of mounting portions 32 to which the tubes 20 can be coupled so that the tubes 20 can be individually mounted on the respective mounting portions 32. [ The tube support 30 can also be rotated, in the case of the embodiment illustrated in the figures, the body 10 is cylindrical and the tube support 30 is also in the form of a disc, (33). Although not shown in the drawing, a rotary motor may be provided to rotate the tube support 30 about the rotary shaft 33. For example, the rotating motor may rotate the rotating shaft 33, or the rotating shaft 33 may be fixed, but the tube support 30 itself may be rotated. Further, a user other than the rotary motor may rotate the tube support 30 directly.

On the other hand, in the embodiment shown in Figs. 6 to 8, a shielding plate 34 is provided on the tube support 30. That is, the positions where the plurality of mounting portions 32 are formed on the tube support 30 are divided and partitioned so that one mounting portion 32 is positioned between the two shielding plates 34 disposed adjacent to each other in the circumferential direction The shielding plate 34 is vertically provided on the upper surface of the tube support 30. The upper end of the shielding plate 34 is brought into contact with the lower surface of the finishing plate 11 and the lateral outer surface of the shielding plate 34 is brought into contact with the inner wall surface of the main body 10. In the embodiment shown in Figs. 6 to 8, the lateral inner side surfaces of the shield plate 34 are coupled to each other. 6 to 8 in which the rotary shaft 33 is not elongated on the upper surface of the tube support 30, the rotary shaft 33 is supported by the tube support 30, as in the embodiment of FIGS. In this case, the lateral inner side surface of the shielding plate 34 may be coupled to the rotary shaft 33. The embodiments of Figs. 9 to 11 will be described later.

When the shielding plate 34 is provided on the tube support 30 as described above, when the tube 20 is mounted on the mounting portion 32 of the tube support 30 and the tube 20 is vertically erected, The two regions of the shield plate 34 disposed adjacent to each other in the circumferential direction with the lower surface of the finishing plate 11 interposed therebetween and the body 10 between the two shield plates 34, A space is formed between the inner wall surfaces of the two shielding plates 34 and the lateral inner side surfaces of the two shielding plates 34 so as to be separated from the space where the neighboring tubes 20 are located. Even if the shielded space is formed as described above, the space between the tube support base 30 and the inner wall surface of the main body 10 still exists. Therefore, the space partitioned by the two shielding plates 34 is substantially The side surface is closed and the lower surface is opened. 6 to 8, reference numeral 35 denotes a shaft support 35 for rotatably supporting the rotary shaft 33. Reference numeral 36 denotes a shaft support 35 which is spaced from the inner wall surface of the body 10 Is a cross-linking member (36).

9 to 11 are views corresponding to FIGS. 6 to 8, respectively. Unlike the embodiments shown in FIGS. 6 to 8, the rotary shaft 33 is extended from the upper surface of the tube support 30 . 9 is a perspective view of a sampling device according to an embodiment of the present invention in which the rotating shaft 33 is elongated on the upper surface of the tube supporter 30 so as to be capable of continuously collecting floating microorganisms using the plurality of tubes 20. [ 10 and 11 are schematic cross-sectional perspective views (FIG. 10) corresponding to FIG. 6 showing the internal structure of the sampling device 1 shown in FIG. 9 and schematic views corresponding to FIG. 7 Sectional view (FIG. 11). 9 to 11, when the rotary shaft 33 is elongated on the upper surface of the tube support 30, the lateral inner surface of the shield plate 34 is coupled to the rotary shaft 33, An area in which the tube 20 of the tube 20 is located is divided into a lower surface of the finishing plate 11 and two shielding plates 34 disposed adjacent to each other in the circumferential direction (rotation direction) with the tube 20 therebetween, The inner wall surface of the body 10 between the shielding plates 34 and the portion of the shielding plate 34 connected to the rotation axis by the lateral inner surface of the shielding plate 34 are shielded Space is formed.

12 is a schematic cross-sectional view showing the state of FIG. 7, and FIG. 13 is a schematic cross-sectional view showing the state of FIG. 10, wherein the embodiments of FIGS. 6 to 8 and FIGS. 9 to 11 In the embodiment, when a suction motor (not shown) is activated with the tube 20 positioned directly beneath the nozzle 14, the external air is supplied to the nozzle 14, And the inflow air enters the inside of the tube 20 through the open upper end of the tube 20. [ The air that has flowed into the interior of the tube 20 passes through the upper end of the tube 20 and is then discharged outside the body 10 through the gap between the body 10 and the tube support 30 . 2 to 5, the airborne microorganisms 2 contained in the air are introduced into the tube 20 through the buffer 20 contained in the tube 20, (100) and left in the buffer solution (100).

6 to 11, the space in which the tube 20 is located is shielded by the shielding plate 34. In this case, Therefore, even if a plurality of tubes 20 containing the buffer solution 100 are previously mounted on the tube support base 30, the tubes 20 other than the tubes 20 immediately below the nozzles 14 Air forcedly introduced through the nozzle 14 is prevented from entering. That is, the air forced into the main body 10 from the outside through the nozzle 14 is only supplied to the inside of the tube 20 located just below the nozzle 14 and passes through the shielding plate 34 It is not forcibly supplied to the tube 20 located in the other shielded space. The buffer solution 100 of the other tube 20 located in the region separated by the shielding plate 34 and not located directly below the nozzle 14 is still in a state in which the floating microorganisms through the air suction and circulation process are not collected State, that is, a fresh state in which cross-contamination does not occur.

When the process of remaining the floating microorganisms 2 in the buffer solution 100 through the air circulation process is completed with respect to the tube 20 located immediately below the nozzle 14, the tube support table 30 is rotated The new tube 20 located beyond the shielding plate 34 is again positioned directly below the nozzle 14. [ That is, a new tube 20 containing the buffer solution 100 which has not yet been contaminated by the shielding plate 34 is moved to a position immediately below the nozzle 14 by the rotation of the tube support 30 And the suction of the floating microorganisms is carried out through circulation of the air and the falling of the suspended microorganisms into the buffer solution through the operation of the suction motor as well as the operation of the suction motor.

As described above, in the present invention, a plurality of tubes 20 are provided on the tube support 30, and the tubes 20 are maintained in a state of preventing cross contamination between the tubes 20 through the shielding plate 34, ) Is rotated so that the operations of collecting the floating microorganisms by using the respective tubes 20 can be carried out sequentially and continuously, furthermore, very easily and quickly. That is, a plurality of suspended microorganism collecting operations can be continuously performed without any time gap.

As mentioned above, the rotation of the tube support 30 can be automatically performed by a motor or the like. Particularly, when the step motor is used as the motor, the tube support 30 can be rotated stepwise in accordance with the predetermined angle, so that each tube 20 is sequentially and automatically positioned immediately below the nozzle 14 As shown in FIG. However, the rotation of the tube support 30 may be manually performed by the experimenter.

The nozzle 14 may be formed as a simple hole formed in the finishing plate 11 as shown in FIGS. 6 to 12, but in order to allow external air to be concentratedly supplied to the inside of the tube 20 It may have a downward protruding shape. If the nozzle 14 has such a downwardly protruding shape, the shielding plate 34 may be caught by the nozzle 14 and the rotation of the tube support 30 may not be smooth. In this case, the tube support base 30 is rotated while the finishing plate 11 is lifted up so that the nozzle 14 is located at a position where it is not caught by the upper end of the finishing plate 11, So that the collection of the suspended microorganisms can be performed. In this way, the experimenter can directly perform the work of lifting and lowering the finishing plate 11, but it is also possible to make the finishing work of the finishing plate 11 automatic. In particular, in the case of the embodiment in which the rotating shaft 33 is extended upward as shown in Figs. 9 to 12, it is very easy to automate the lifting and lowering work of the finishing plate 11. Fig. For example, when the lifting / lowering shaft is arranged inside the rotary shaft 33 and the cam member is provided on the lifting / lowering shaft, when the rotary shaft 33 starts to rotate, When the plate 11 is lifted and the operation of placing the new tube 20 under the nozzle 14 is completed, the lifting and lowering side is lowered by the operation of the cam member again so that the finishing plate 11 is lowered again It can also be configured. However, automating the lifting and lowering operation of the finishing plate 11 is not limited to this example, and various other methods can be used.

10: Body
11: Finishing plate
14: Nozzle
20: tube
30: tube support
100: Buffer

Claims (3)

A tubular main body 10 having a top plate 11 on which a nozzle 14 for introducing air is formed and an outlet 12 through which air is sucked and discharged by a suction force, ;
A tube (20) located in the interior of the body (10) immediately below the nozzle (14) and containing the buffer solution (100);
And a tube support 30 provided inside the main body 10 with an interval from an inner wall surface of the main body 10 and formed with a mounting portion 32 for fixing and supporting the tube 20;
The air introduced into the nozzle 14 flows into the tube 20 and then flows out again and then passes through the gap between the main body 10 and the tube support 30 to discharge the air through the outlet 12 The suspended microorganisms 2 contained in the air fall out into the buffer solution 100 and are trapped in the buffer solution 100 when the air circulates inside the tube 20 The sampling device for the suspended microorganisms in the air.
The method according to claim 1,
The tube support 30 is rotatably disposed within the body 10;
A plurality of mounting portions 32 are provided so that a plurality of tubes 20 can be mounted on the tube support 30;
A shielding plate 34 is vertically installed on the upper surface of the tube support 30 so as to partition the spaces where the plurality of tubes 20 are disposed in the tube support 30, A shielding plate 34 is provided so that one tube 20 is positioned between two shielding plates 34 disposed adjacent to each other in the rotation direction;
The tube support 30 rotates and a plurality of tubes 20 are sequentially arranged under the vertical straight line of the nozzle 14 to collect the floating microorganisms in the buffer solution 100 contained in each tube 20 The sampling device for the suspended microorganisms in the air.
3. The method of claim 2,
Characterized in that the tube support (30) is configured to be rotated stepwise by a step motor to a predetermined angle so that each tube (20) is automatically positioned at a position directly below the nozzle (14) A sampling device for airborne microorganisms.

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