KR101721190B1 - Microorganism Filter Test System - Google Patents

Abstract

The present invention relates to a microorganism filter test apparatus. According to the present invention, the number of microorganism particles can be measured in real time by a particle measuring unit, and thus microorganism filter performance evaluation can be quickly performed in real time and the accuracy of the result of the measurement can be improved. The accuracy of the result of the measurement can be further improved because the microorganism particles can be collected and cultured and then post-analyzed with an impactor module and the result of the analysis can be compared to and verified with respect to the result of the measurement of the particle measuring unit. In addition, verification operations with respect to test conditions currently executed can be quickly performed in real time. Furthermore, the accuracy of the performance evaluation with respect to a filter can be improved and testing can be facilitated because a filter holding unit is provided on which a test subject microorganism filter can be mounted in a sealed manner. Because a filter coupling part has a detachable configuration, in particular, stable mounting can be performed on finished filter products of various shapes as well as filter fabrics. Accordingly, various performance evaluations can be performed with respect to the finished filter products.

Description

[0001] Microorganism Filter Test System [

The present invention relates to a microbial filter test apparatus. More specifically, by measuring the number of microbial particles in real time through the particle measuring unit, performance evaluation of the microbial filter can be performed quickly in real time, accuracy of the measurement result can be improved, And after the analysis, it can be compared with the measurement result of the particle measuring unit, and it is possible to further improve the accuracy of the measurement result, and to perform the verification operation of the presently performed test condition in real time By providing a filter holding unit capable of sealingly mounting the microorganism filter to be tested, it is possible to improve the performance evaluation accuracy of the filter and perform the test more conveniently, and in particular, So that not only the filter fabric but also the filter having various shapes And it will also be fitted with a reliable product on the microbial filter testing device capable of a range of performance evaluation of the finished filter.

Recently, new diseases such as H1N1, high pathogenic avian influenza (HPAI) and severe acute respiratory syndrome (SARS) have been developing continuously, and these diseases are infectious And the spread and damage of the disease is becoming very serious.

In indoor air, indoor air that causes such diseases is flooded with various microorganisms such as bacteria, fungi, and viruses, and these floating microorganisms cause air infections and environmental diseases, which adversely affect health.

For these reasons, researches on microbial filters capable of filtering microorganisms such as bacteria, which cause diseases, have been actively conducted in recent years in order to prevent and prevent transmission of these diseases. The microbial filter is a filter capable of filtering all kinds of microorganisms such as bacteria, fungi, and viruses. Hereinafter, it is collectively referred to as a microbial filter.

Such a microbial filter is configured to filter microbial particles using medical fibers (here, the microbial particles include all of various microorganisms such as bacteria, fungi, and viruses, and they are all used in the same concept hereinafter) It can be developed in the form of mask type or gas mask filter, and it can be widely used in hospitals and laboratories.

It is very important to evaluate the performance of the microbial filter to determine the extent to which the microbial particles can be filtered. Currently, the performance evaluation of the filter against the globally recognized microbes is performed by the American Society for Testing (ASTM) testing and materials) F2101.

However, since the criteria for evaluating the performance of the microbial filter are merely a criterion that meets the minimum requirements for performance evaluation, development of a microbial filter test apparatus capable of performing performance evaluation more conveniently and accurately in a form suitable for such regulation However, the development level of the microbial filter has not been widely used due to its low level of development so far, and accordingly, the performance evaluation of the microbial filter has not been made.

In particular, the conventional microbial filter test apparatus according to the prior art samples the air that has passed through the microbial filter, collects the microbial particles contained in the extracted air using a separate microbial collector, And the number of microbial particles cultured is observed with a microscope and measured. Therefore, the test work takes a long time and inconvenience, and also the management personnel and the cost are increased, and the accuracy and reliability of the test result also deteriorates.

Korean Patent Laid-Open No. 10-2011-0097199

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the prior art, and it is an object of the present invention to provide a particle measurement unit for measuring the number of microbial particles in real time, It is possible to improve the accuracy of the measurement result, and after the microbial particles are captured and cultured through the impactor module, the microbial particles can be further analyzed and compared with the measurement results of the particle measuring unit, And to provide a filter test apparatus.

It is another object of the present invention to provide a filter holding unit capable of sealingly mounting a microbial filter to be tested, thereby improving the performance evaluation accuracy of the filter and more conveniently performing the test, The present invention provides a microbial filter test apparatus capable of stably mounting not only a filter fabric but also various filter finished products having various shapes so that various performance evaluations can be performed on finished filter products.

It is a further object of the present invention to provide a particle measuring unit capable of real-time measurement of the number of microbial particles, so that a verification operation for a currently performed test condition can be performed quickly in real time, The present invention also provides a microbial filter test apparatus capable of performing a quick and convenient adjustment operation for a microbial filter.

It is another object of the present invention to provide a biosafety case for preventing external leakage of microbial particles in a test process and disinfecting the microbial particles by mounting a sterilizing lamp in an internal space, The present invention provides a microbial filter test apparatus which can prevent an accident caused by leakage and can be used more safely.

The present invention relates to a microbial filter testing apparatus for testing the performance of a microbial filter capable of filtering microbial particles, comprising a microbial filter test apparatus for generating microbial particles in an aerosol form, mixing mixed microbial particles with clean air, A microorganism generating unit for supplying the microorganisms to the microorganisms; A filter holding unit in which mixed air supplied from the microorganism generating unit flows and flows, and in which the microbial filter is detachably mounted so that the mixed air passes through the microbial filter; A particle measuring unit for measuring in real time the number of the microbial particles contained in the mixed air while the mixed air passes through the filter holding unit; An impactor module configured to allow mixed air passing through the filter holding unit to pass therethrough and collecting the microbial particles contained in the mixed air while the mixed air passes through; And a main discharge pump arranged to communicate with the filter holding unit to generate a flow of the mixed air.

At this time, the particle measuring unit can extract the mixed air from the filter holding unit, introduce the mixed air, and measure the number of the microbial particles contained in the introduced mixed air in real time.

The particle measuring unit may include a first particle meter for measuring the number of the microbial particles by extracting the mixed air from a section before passing through the microbial filter in the filter holding unit.

The particle measuring unit may further include a second particle meter for measuring the number of the microbial particles by extracting the mixed air from the section after passing through the microbial filter in the filter holding unit, And the amount of change of the microbial particles in the front and rear sections of the microbial filter can be measured through the second particle meter.

Also, the filter holding unit may include an upper housing and a lower housing formed to allow the mixed air to pass through the inner space, and at least one of the upper housing and the lower housing may be moved up and down And the upper and lower housings may be mutually coupled to each other so that the microbial filter is sealed and interposed between the upper and lower housings.

The first particle meter is connected to the upper housing to extract the mixed air from the upper housing of the filter holding unit, and the second particle meter is connected to the upper housing to extract the mixed air from the lower housing of the filter holding unit. And can be connected to the lower housing.

The particle measuring unit may be configured to measure the number of living microbial particles among the microbial particles contained in the mixed air.

A microorganism collecting water tank capable of collecting microbial particles contained in the mixed air may be disposed between the filter holding unit and the main discharge pump.

The biosafety cabinet may further include a biosafety cabinet for accommodating the microorganism generating unit, the filter holding unit, the particle measuring unit, the impactor module, and the main discharge pump in an internal space, And a sterilizing lamp may be mounted in the inner space.

According to the present invention, the performance of the microbial filter can be evaluated in real time and quickly by measuring the number of microbial particles in real time through the particle measuring unit, the accuracy of the measurement result can be improved, After the particles are captured and cultured, the particles can be analyzed afterwards to be compared with the measurement results of the particle measurement unit, and the accuracy of the measurement results can be further improved.

Further, since the filter holding unit capable of sealingly mounting the microbial filter to be tested is provided, it is possible to improve the performance evaluation accuracy of the filter, perform the test more conveniently, and more particularly, Thus, it is possible to stably mount the filter finished product having various shapes as well as the filter fabric, thereby enabling various performance evaluations of the finished filter product.

In addition, since the particle measuring unit capable of measuring the number of microbial particles in real time is provided, it is possible to perform the verification operation for the test condition currently being performed in real time, and accordingly, So that it can be performed quickly and conveniently.

In addition, by providing a separate biosafety case, it is possible to prevent the leakage of microbial particles during the test process, and by disinfecting the microbial particles by mounting a sterilizing lamp in the internal space, an accident caused by external leakage of microbial particles So that it can be used more safely.

1 is a conceptual diagram schematically showing the overall configuration of a microbial filter test apparatus according to an embodiment of the present invention;
2 is a schematic view illustrating a configuration of a filter holding unit according to an embodiment of the present invention.
3 is a schematic view illustrating an operating state of the filter holding unit according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a conceptual diagram schematically showing the overall configuration of a microbial filter test apparatus according to an embodiment of the present invention.

The apparatus for testing a microbial filter according to an embodiment of the present invention is an apparatus for testing the performance of a microbial filter (BF) capable of filtering microbial particles. The apparatus includes a microbial generation unit 100, a filter holding unit 200, A measurement unit 300, an impact module 400, and a main discharge pump 500.

The microbial generation unit 100 is configured to generate microbial particles such as bacteria in the form of an aerosol, mix the generated microbial particles with clean air to generate mixed air, and supply the generated mixed air at a constant flow rate.

The microbial generation unit 100 includes a microbial particle generator 110 for generating microbial particles by spraying microbial particles into a nebulizer or an atomizer, A peristaltic pump 120 for supplying microbial particles in a quantitative manner, and a clean air supplier 130 for supplying clean air to the microbial particle generator 110. Accordingly, the microorganism generating unit 100 is configured such that microbial particles are supplied from the peristaltic pump 120, clean air is supplied from the clean air feeder 130, and the microbial particles are mixed and sprayed through the microbial particle generator 110 Mixed air containing mixed microbial particles is supplied to a filter holding unit 200 to be described later.

The filter holding unit 200 is formed so that mixed air supplied from the microorganism generating unit 100 flows and flows. In the middle section, a microbial filter BF to be tested is detachably mounted, and the microbial filter BF).

A separate particle feed pipe 140 is formed in the filter holding unit 200 so that mixed air can be supplied from the microbial cell generating unit 100. The particle feed pipe 140 is formed in such a manner that microbial particles contained in the mixed air The temperature and the humidity are appropriately adjusted so that the environment of the inner space is suitable for the survival of the microorganisms. Therefore, the particle supply pipe 140 may be provided with a temperature and humidity control device (not shown) for controlling the temperature and humidity of the internal space, and may also include a temperature sensor (not shown) And a humidity sensor (not shown). The particle supply pipe 140 may be formed in a shape fixed to the shape of a glass tube and the particle supply pipe 140 and the microorganism generating unit 100 may be connected through a separate flexible connection pipe 141.

The particle measuring unit 300 is configured to measure in real time the number of microbial particles contained in the mixed air in the process of passing the mixed air through the filter holding unit 200. That is, the mixed air passes through the microbial filter BF installed in the intermediate section during the passage through the filter holding unit 200. At this time, the microbial particles contained in the mixed air are partially filtered by the microbial filter BF , The number of microbial particles in the upstream and downstream portions of the microbial filter (BF) is different according to the flow of the mixed air, and the particle measuring unit 300 is configured to measure the number of such microbial particles.

At this time, the particle measuring unit 300 extracts and introduces the mixed air from the filter holding unit 200, and measures the number of the microbial particles contained in the introduced mixed air. The number of the particles is measured in real time do.

The impactor module 400 is configured to allow mixed air passing through the filter holding unit 200 to pass therethrough and to collect the microbial particles contained in the mixed air during the passage of the mixed air. An impactor is a device that can collect particles by size using the difference in flow inertia of a flowing particle, and is generally widely used. The impactor module according to an embodiment of the present invention is capable of collecting microbial particles in stages A multi-stage impactor 410 may be used, and the inside of the multi-stage impactor 410 may be equipped with a chalet equipped with a medium so that microbial particles can be captured and cultured. The multi-stage impactor 410 may include a separate suction pump (not shown) to allow the mixed air to flow into the multi-stage impactor 410. However, as shown in FIG. 1, the main discharge pump 500 ) So that the airflow inside the multi-stage impactor 410 is generated by the operation of the main discharge pump 500. The impact module 400 may be connected to the downstream side of the filter holding unit 200 so that the mixed air passing through the filter holding unit 200 may be introduced into the impactor module 400, After the microbial particles are further cultured, the number and type of microbial particles can be confirmed by microscopic observation or the like.

The main discharge pump 500 is connected to the filter holding unit 200 so that the flow of the mixed air is generated in a constant direction from the microorganism generating unit 100 through the filter holding unit 200 and the impact module 400 , The impactor module 400 may be disposed between the filter holding unit 200 and the main discharge pump 500. The main discharge pump 500 is connected to the filter holding unit 200 and the impact module 400 through a separate discharge pipe 501. The main discharge pump 500 is provided on the discharge pipe 501 in such a manner that the discharge flow rate of the mixed air can be controlled A flow regulator 510 may be mounted.

The microbial particles contained in the mixed air are prevented from being discharged to the outside in the process of discharging the mixed air through the main discharge pump 500 on the discharge pipe 501 between the main discharge pump 500 and the impactor module 400, A microorganism collecting water tank 520 capable of collecting particles can be disposed. In this case, a separate discharge port 502 may be formed in the discharge pipe 501 connected between the filter holding unit 200 and the impactor module 400, A separate connection pipe may be coupled to the microorganism collecting water tank 520 as shown in FIG. Through this piping connection structure, if necessary, the flow of air by the main discharge pump 500 passes through the microbiological collection water tank 520 directly through the connection pipe without passing through the impactor module 400 from the filter holding unit 200 . This flow of mixed air can be utilized in the warm-up process at the start of operation of the apparatus.

According to such a configuration, the apparatus for testing a microbial filter according to an embodiment of the present invention may be configured such that the microbial filter BF to be tested is mounted on the filter holding unit 200, The mixed air is generated and supplied to pass through the filter holding unit 200. In this process, the amount of change in the number of microbial particles contained in the mixed air (the microbial filter BF upstream and downstream of the microbial filter BF) Particle number variation) can be measured in real time, so that the performance of the microbial filter (BF) can be conveniently measured in real time. Further, after the microbial particles are captured and cultured through the impactor module 400, the number and type of the microbial particles can be analyzed afterwards, and the results measured through the particle measurement unit 300 can be verified again have.

Therefore, the microbial filter testing apparatus according to an embodiment of the present invention can perform the performance evaluation of the microbial filter in real time by measuring the number of microbial particles in real time through the particle measuring unit 300, The microbial particles can be collected and cultured through the impactor module 400 and then analyzed and compared with the measurement results of the particle measurement unit 300 to further improve the accuracy of the measurement results .

The microbial filter testing apparatus according to an embodiment of the present invention includes all of the components described above, namely, the microorganism generating unit 100, the filter holding unit 200, the particle measuring unit 300, the impactor module 400, And a separate biosafety cabinet 600 for accommodating the discharge pumps 500 in the internal space as shown in FIG.

The biosafety cabinet 600 is formed to be sealed so as to prevent the leakage of microbial particles, and an internal sterilizing lamp 610 for sterilizing microbial particles may be installed in the internal space. The sterilizing lamp 610 may be an ultraviolet or infrared lamp.

Next, the detailed configuration of the present invention will be described in detail.

FIG. 2 is a view schematically showing a configuration of a filter holding unit according to an embodiment of the present invention, and FIG. 3 is a view schematically showing an operating state of a filter holding unit according to an embodiment of the present invention.

The filter holding unit 200 according to an embodiment of the present invention may include an upper housing 210 and a lower housing 220 formed to allow mixed air to pass through an inner space.

At least one of the upper housing 210 and the lower housing 220 may be vertically movably mounted so as to move close to each other and to be sealed. For example, as shown in FIGS. 2 and 3, the lower housing 220 can be fixedly mounted on a separate base frame 202, and the upper housing 210 can be mounted up and down.

At this time, a separate moving module 230 for moving the upper housing 210 up and down may be further provided. That is, the moving module 230 is configured to move the upper housing 210 in the vertical direction so that the upper housing 210 and the lower housing 220 can be sealed or separated from each other. Of course, the upper housing 210 may be fixed, and the lower housing 220 may be movably mounted in the vertical direction. At this time, the moving module 230 may be configured to move the lower housing 220 in the vertical direction have.

For example, the upper housing 210 may be mounted on a separate guide (not shown) so as to be movable up and down, and a separate hydraulic or pneumatic cylinder (not shown) And the upper housing 210 is moved up and down through the upper housing 210. Of course, it can be changed in various ways through various machine elements.

The upper housing 210 and the lower housing 220 are sealed or separated from each other according to this structure. As shown in FIG. 3 (a), the upper housing 210 and the lower housing 220 are mutually separated The microbial filter BF to be tested is disposed on the upper surface of the lower housing 220 in the spaced apart state, more specifically, the upper housing 210 When the upper housing 210 and the lower housing 220 are moved close to the lower housing 220, the microbial filters BF are inserted into the upper housing 210 and the lower housing 220 in close contact with each other and sealed.

At this time, a separate sealing member 205 may be mounted on the mutually close contact surface of the upper housing 210 and the lower housing 220 for sealing connection with the microbial filter BF. So that the mixed air in the inner space of the upper housing 210 and the lower housing 220 can be completely discharged to the outside through the microbial filter BF in close contact with the upper housing 210 and the lower housing 220, .

The upper housing 210 and the lower housing 220 may be arranged such that the mixed air supplied from the microorganism generating unit 100 flows through the upper housing 210 and is discharged through the lower housing 220. That is, the mixed air supplied from the microorganism generating unit 100 may be arranged to flow into the upper housing 210 and be discharged through the lower housing 220.

2 and 3, the upper housing 210 is provided with an upper flow development portion 211 for allowing mixed air to flow to form a completely developed flow, and a lower flow development portion 211 disposed below the upper flow development portion 211 And an upper filter coupling portion 212 that is hermetically coupled to the lower housing 220. Likewise, the lower housing 220 includes a lower filter coupling 222 and a lower filter coupling 222, which are hermetically coupled to the upper housing 210 to allow the mixed air to flow from the upper housing 210, And a lower flow development part 221 formed to allow the mixed air to be introduced and discharged from the lower filter coupling part 222.

Accordingly, the mixed air introduced into the upper housing 210 from the microorganism generating unit 100 can flow in the upper flow development part 211 of the upper housing 210, so that a stable laminar flow can be formed. And passes through the microfibre filter BF mounted between the lower housing 220 and the upper filter coupling part 212 in the stabilized flow state. The mixed air having passed through the microbial filter BF is discharged from the filter holding unit 200 through the lower flow coupling part 221 of the lower housing 220 and the lower flow developing part 221. Thereafter, after passing through the impactor module 400, the microbial particles remaining in the mixed air are collected through the microbial collection water tank 520 and discharged through the main discharge pump 500.

Since the mixed air flows through the upper flow development part 211 in a stabilized state in the course of passing through the microbial filter BF mounted on the filter holding unit 200, the performance evaluation for the microbial filter BF The accuracy can be further improved.

The upper filter coupling part 212 is formed to be detachably coupled to the upper flow development part 211 and the lower filter coupling part 222 is formed to be detachably coupled to the lower flow development part 221 So that various types of microbial filters BF can be stably sealed between the upper housing 210 and the lower housing 220.

That is, the microbial filter BF can be formed in various forms such as a mask, a respiratory filter, and a respiratory clean filter. The microbial filter BF can be formed by simply connecting the fabric of the microbial filter BF to the upper housing 210 and the lower housing 220 It is more accurate to perform the filter performance test on various finished products such as a filter and a mask which are finally fabricated by using a fabric. In this case, in order to perform the filter performance test on the finished product, the finished product should be interposed between the upper housing 210 and the lower housing 220. The filter holding unit 200 according to an embodiment of the present invention may have various Performance evaluation of various finished product filters is also convenient by allowing the upper filter coupling portion 212 and the lower filter coupling portion 222 having a shape corresponding to the finished product to be hermetically fitted to the filter finished product, .

Meanwhile, the particle measuring unit 300 is configured to measure the number of microbial particles in the upstream and downstream sections of the microbial filter BF mounted in the intermediate section in real time while the mixed air passes through the filter holding unit 200 , A method of extracting and introducing mixed air from the filter holding unit (200), and measuring the number of microbial particles contained in the introduced mixed air in real time.

In more detail, the particle measurement unit 300 may include a first particle meter 310 and a second particle meter 320. The first particle measuring instrument 310 extracts the mixed air from the section (for example, the inner space of the upper housing 210) before passing through the microbial filter BF in the filter holding unit 200, And the second particle measuring instrument 320 is configured to extract the mixed air from the section (for example, the inner space of the lower housing 220) after passing through the microbial filter BF in the filter holding unit 200 And is configured to measure the number of microbial particles in real time.

The first particle meter 310 is connected to the upper housing 210 to extract the mixed air from the upper housing 210 and the second particle meter 320 is connected to the lower housing 210 to extract the mixed air from the lower housing 220, And is connected to the housing 220.

When the number of microbial particles in the upstream and downstream sections is measured in real time around the microbial filter BF through the first particle meter 310 and the second particle meter 320 in this way, It is possible to know how much is filtered in the course of passing through the microbial filter (BF), so that the filtering performance of the microbial filter (BF) can be evaluated.

For example, if the number of microbial particles measured by the first particle meter 310 is 100 and the number of microbial particles measured by the second particle meter 320 is 5, then the microbial filter BF is 95% It can be evaluated as having performance.

Particularly, since the particle measuring unit 300 according to an embodiment of the present invention can perform the measurement of the number of microbial particles in real time, the microbial particles can be collected and cultured as in the prior art, The measurement result can be obtained very quickly and conveniently compared to what can be obtained.

By directly measuring the number of microbial particles in the upstream and downstream sections of the microbial filter BF through the first particle meter 310 and the second particle meter 320, The verification of the test condition currently being performed through the first particle meter 310 can also be performed.

For example, in the case where 1000 microbial particles are generated and supplied under the test conditions and the filtering performance is to be tested, whether or not the number of microbial particles generated from the microbial generation unit 100 is actually 1000 or not is determined by microorganisms It can be known by sampling the mixed air of the upper housing 210, which is a section before passing through the filter BF, and measuring the number of the microbial particles contained therein, which is performed through the first particle meter 310 . Particularly, since the first particle meter 310 can measure the number of microbial particles in real time as described above, the verification operation for these test conditions can also be performed quickly in real time, It is possible to set it more accurately and quickly.

That is, the conventional microbial filter testing apparatus according to the prior art can collect the microbial particles of the mixed air and cultivate the microbial particles for a few days, and then analyze the number of microbial particles to measure the number of actual microbial particles. If the test condition is not satisfied, the microorganism generation unit 100 is adjusted to regenerate microbial particles. After the microbial particles are again collected and cultured, the microbial particles The number is counted, so that again a few days will pass. There is a problem that a considerable time elapses until the correct test conditions are met and the accuracy thereof is not high due to the repetition of the adjustment operation and the number measuring operation. However, in an embodiment of the present invention, since the number of microbial particles currently generated through the first particle meter 310 can be measured in real time, if the microbial particle generation unit 100 does not meet the test conditions, It is possible to adjust the test condition immediately by adjusting it, so that the setting operation of the test condition can be performed more quickly, and the verification operation of these test conditions can also be continuously monitored in real time.

In the particle measuring unit 300, various kinds of instruments capable of measuring the number of microbial particles can be applied. In one embodiment of the present invention, the number of particles is measured using light reflected and scattered by microbial particles An optical particle meter can be used. That is, the particle measuring unit 300 irradiates inspection light to the mixed air extracted and introduced into the internal space of the particle measuring unit 300 from the filter holding unit 200 through the light source. At this time, And the reflected light or scattered light is detected to measure the number of microbial particles. Such an optical particle counter is an apparatus for measuring the number of particles by using reflected light or scattered light of light and is widely used, so that detailed description thereof will be omitted.

However, the particle measuring unit 300 according to an embodiment of the present invention is configured to measure the number of live microbial particles, which can be achieved by using a fluorescence source as a light source for irradiating inspection light. Whereas living microbial particles have a characteristic of reacting to a fluorescent substance, dead microbial particles or general inanimate particles do not react to fluorescent substances, so that the number of living microbial particles can be measured independently have.

As described above, the particle measuring unit 300 is connected to the upper housing 210 and the second particle meter 320 is connected to the lower housing 220, An air extraction port 203 is formed in the lower housing 210 and the lower housing 220 for connecting the first particle meter 310 and the second particle meter 320 respectively and the upper housing 210 and the lower housing 220 The mixed air flowing through the respective internal spaces is extracted through the air extraction port 203 and flows to the first particle meter 310 and the second particle meter 320, respectively.

It is preferable that the extraction of the mixed air through the air extraction port 203 is performed in a region where the mixed air is stabilized in the internal space of the filter holding unit 200, The upper flow development portion 211 of the housing 210 and the lower flow development portion 221 of the lower housing 220, respectively.

Although the first particle measuring device 310 and the second particle measuring device 320 are all mounted on the particle measuring unit 300 in the above description, the first particle measuring device 310 or the second particle measuring device 320 may be mounted. In the case where only the first particle measuring instrument 310 is mounted, the number of microbial particles is measured upstream of the microbial filter BF of the filter holding unit 200 to easily monitor the verification condition of the test condition in real time as described above In the case where only the second particle measuring instrument 320 is installed, the number of microbial particles can be measured downstream of the microbial filter BF in the process of passing the mixed air through the microbial filter BF of the filter holding unit 200 Thus, the microbial filtering performance of the microbial filter (BF) can be monitored in real time under specific test conditions.

In addition, the filter holding unit 200 may be equipped with a differential pressure sensor 201 for measuring the pressure difference formed between the upstream and downstream of the microbial filter BF, through which the mixed air is supplied to the microbial filter BF, It is possible to confirm whether the pressure drop phenomenon occurs during the process of filtering the microbial particles through the microbial filter (BF). In general, when the air passes through the filter, foreign matter is filtered through the filter, so that a pressure drop occurs in the air passing through the filter. When the microbial filter (BF) (BF) It may be difficult for the wearer to breathe. Therefore, it should be manufactured in such a form as to allow only a pressure drop below a certain range. Therefore, it is preferable to confirm in real time the magnitude of the differential pressure occurring between upstream and downstream of the microbial filter BF through the differential pressure sensor 201.

The differential pressure sensor 201 may be connected to the upper housing 210 and the lower housing 220. For this purpose, the pressure difference sensor 201 may be connected to the upper housing 210 and the lower housing 220, A sensing port 204 may be formed.

The foregoing description is merely illustrative of the technical idea of the present invention and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

100: Microorganism generating unit 200: Filter holding unit
201: differential pressure sensor 203: air extraction port
204: pressure sensing port 205: sealing member
210: upper housing 211: upper flow development part
212: upper filter coupling part 220: lower housing
221: lower flow development part 222: lower filter coupling part
230: Moving module 300: Particle measuring unit
310: first particle meter 320: second particle meter
400: impactor module 410: multi-stage impactor
420: Suction pump 500: Main discharge pump
510: Flow regulator 520: Microorganism collection tank
600: Bio-safety case 610: Disinfection lamp

Claims (9)

A microbial filter test apparatus for testing the performance of a microbial filter capable of filtering microbial particles,
A microorganism generating unit for generating microbial particles in an aerosol form and mixing the generated microbial particles with clean air to supply a mixed air formed at a constant flow rate;
A filter holding unit in which mixed air supplied from the microorganism generating unit flows and flows, and in which the microbial filter is detachably mounted so that the mixed air passes through the microbial filter;
A particle measurement unit for measuring the number of the microbial particles contained in the mixed air flowing in the microbial filter, respectively, from the front and rear sections of the microbial filter during the passage of the mixed air through the filter holding unit, unit;
A main discharge pump arranged to communicate with the filter holding unit through a discharge pipe to generate a flow of the mixed air; And
Wherein the filter holding unit is mounted on a discharge pipe connecting the filter holding unit and the main discharge pump so that the mixed air passing through the filter holding unit flows therethrough and the microorganisms contained in the mixed air, Impactor module to capture particles
Wherein a microorganism collecting water tank is disposed on a discharge pipe between the impact module and the main discharge pump so as to collect microbial particles contained in the mixed air while the mixed air is discharged through the main discharge pump,
A separate connection pipe is connected to the discharge pipe between the filter holding unit and the impactor module and connected to the microorganism collecting water tank,
The mixed air having passed through the filter holding unit is discharged through the discharge module through the impact module and the microorganism collection water tank through the main discharge pump or through the microbiological collection tank through the connection pipe without passing through the impact module And the microbial filter can be discharged through the main discharge pump.
delete The method according to claim 1,
The particle measuring unit
And a first particle meter for extracting the mixed air from the section before passing through the microbial filter in the filter holding unit to measure the number of the microbial particles.
The method of claim 3,
The particle measuring unit
Further comprising a second particle meter for extracting the mixed air from the section after passing through the microbial filter in the filter holding unit to measure the number of the microbial particles,
Wherein the amount of change of the microbial particles in the front and rear sections of the microbial filter is measured through the first particle meter and the second particle meter.
5. The method of claim 4,
The filter holding unit
And an upper housing and a lower housing formed to pass the mixed air through the inner space,
At least one of the upper housing and the lower housing is mounted so as to move close to each other so as to be sealingly engaged with each other. As the mutual engagement parts of the upper housing and the lower housing move closer to each other, Wherein the microbial filter is formed to be sealed-engaged in a state interposed therebetween.
6. The method of claim 5,
Wherein the first particle meter is connected to the upper housing to extract the mixed air from the upper housing of the filter holding unit and the second particle meter is connected to the upper housing to extract the mixed air from the lower housing of the filter holding unit, Wherein the microbial filter test apparatus is connected to the microbial filter test apparatus.
7. The method according to any one of claims 1 to 6,
Wherein the particle measuring unit is configured to measure the number of living microbial particles among the microbial particles contained in the mixed air.
delete 7. The method according to any one of claims 1 to 6,
A bio-safety cabinet for accommodating the micro-organism generating unit, the filter holding unit, the particle measuring unit, the impactor module,
Wherein the biosafety cabinet is formed to be sealed to prevent external leakage of the microbial particles, and a sterilizing lamp is mounted in the internal space.

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