KR20220114163A - Clean Room Particle Management System - Google Patents

Abstract

Disclosed is a cleanroom particle integrated-management system. In accordance with one embodiment of the present invention, the cleanroom particle integrated-management system includes: at least one particle sensing device installed in a cleanroom, and sensing particles included in the air to count the quantity of the particles; a data management server connected with the at least one particle sensing device to be communicable, acquiring air cleanliness data in accordance with the quantity of the particles included in the measured air from the particle sensing device, and classifying and managing the acquired air cleanliness data; and a monitoring device connected with the data management server to be communicable to monitor the cleanliness of the air in the cleanroom in real time, thereby controlling the cleanliness of the air in the cleanroom. Therefore, the present invention is capable of more effectively controlling the cleanliness of the air in the cleanroom.

Description

Clean Room Particle Management System {Clean Room Particle Management System}

The present invention relates to a clean room particle integrated management system, and more particularly, by a particle sensing device having a simple and efficient structure, the particles contained in the air inside the clean room in which the semiconductor or display manufacturing process system is disposed. By accurately and effectively measuring the quantity, it is possible to accurately monitor the air cleanliness inside the clean room, and thus to a clean room particle integrated management system that can more effectively control the air cleanliness inside the clean room.

In recent semiconductor manufacturing processes that require integrated processes such as 8K high-resolution displays, flexible displays, MEMs, and microlenses, the defect rate due to the adsorption of fine particles has greatly increased by more than five times.

For example, an 8K display has four times the resolution compared to a conventional 4K display, resulting in a finer pixel size, making it more susceptible to dust absorption.

In addition, as the process time increases due to a complicated process, the probability of adsorbing impurity particles on the surface of the display panel is several times higher than the conventional one.

Similarly, since the wiring is miniaturized due to semiconductor integration, the presence or absence of impurity particles greatly affects the yield.

Accordingly, in order to lower the defect rate of the semiconductor or display manufacturing process, a system for maintaining the cleanliness of the air inside the clean room using a particle sensor that measures the quantity of finely sized impurity particles, ie, particles by size is required.

However, in the case of the particle measuring device used in the conventional integrated cleanroom particle management system, expensive foreign equipment is mostly used. This is a situation in which it is not easy to introduce.

Furthermore, it is necessary to accurately measure the quantity of particles for each location even in a clean room in which various equipment is arranged. However, it is costly to install a large amount of expensive particle measuring devices at various locations in the clean room. to be.

Republic of Korea Patent Registration No. 10-2101413, (2020.04.16)

Therefore, the technical problem to be achieved by the present invention is to accurately and effectively measure the number of particles contained in the air inside a clean room in which a semiconductor or display manufacturing process system is disposed by a particle sensing device having a simple and efficient structure, An object of the present invention is to provide an integrated cleanroom particle management system that can accurately monitor the cleanliness of the air inside the room and can more effectively control the cleanliness of the air inside the cleanroom.

According to an aspect of the present invention, at least one particle sensing device installed in a clean room and counting the quantity of the particles by detecting the particles contained in the air; Data management that is communicatively connected to the at least one particle sensing device, acquires air cleanliness data according to the quantity of particles included in the measured air from the particle sensing device, and classifies and manages the acquired air cleanliness data for server; and a monitoring device communicatively connected to the data management server to monitor the air cleanliness inside the clean room in real time, and control the air cleanliness inside the clean room accordingly. A management system may be provided.

Installed inside the clean room, further comprising a ventilation device for controlling the air cleanliness inside the clean room, the monitoring device is communicatively connected with the ventilation device to control the ventilation device in the clean room You can adjust the air cleanliness inside.

Each of the at least one particle sensing device includes a temperature and humidity measurement unit for measuring temperature and humidity inside the clean room, and the data management server includes the temperature and humidity measured by the temperature and humidity measurement unit. It is possible to acquire data, classify and manage the acquired temperature and humidity data, and predict a measurement defect rate by correcting the air cleanliness data acquired from the particle sensing device according to the temperature and humidity data.

It is installed inside the clean room, further comprising a temperature and humidity control device for controlling the temperature and humidity inside the clean room, the monitoring device, communicatively connected to the ventilation device and the temperature and humidity control device The temperature, humidity and air cleanliness inside the clean room can be adjusted by controlling the ventilation device and the temperature and humidity control device in consideration of the measurement defect rate.

Each of the at least one particle sensing device may include a device body; a particle measurement sensor provided inside the device body and configured to detect particles contained in the air and count the number of the particles; a measurement air storage unit provided inside the device body, which is disposed to surround the particle measurement sensor, and provides a particle measurement space of a predetermined size for storing a predetermined amount of measurement air; And it is coupled between the device body and the measurement air storage unit, sucks the external air outside the device body into the inside of the measurement air storage unit, the measurement air counted by the number of particles by the particle measurement sensor is said It may further include an air flow unit for flowing air to be discharged to the outside of the device body.

The measurement air storage unit seals and stores a predetermined amount of the measurement air for counting the quantity of particles for a predetermined time, and the particle measurement sensor stores the predetermined amount of the measurement air for a predetermined time stored in the measurement air storage unit for a predetermined time. The quantity of the particles may be counted by detecting the particles included in the measurement air based on the quantity of the measurement air.

The measuring air storage unit may include: a bulkhead type storage structure provided in the device body, disposed around the particle measuring sensor and having a predetermined height; a cover plate detachably coupled to an upper portion of the bulkhead-type storage structure; and a sealing member disposed between the partition wall storage structure and the cover plate to seal between the partition wall storage structure and the cover plate.

The air flow unit is coupled between the measurement air storage unit and one side of the device body, and communicates the inside of the measurement air storage unit and the outside of the device body to transfer air outside the device body into the measurement air storage unit. an inlet pipe forming a suction passage for sucking; A discharge flow path coupled between the measurement air storage unit and the other side of the device body, communicating the inside of the measurement air storage unit and the outside of the device body to discharge the measurement air counting the number of particles to the outside of the device body a discharge pipe to form; and a pump coupled to one side of the discharge pipe to form a flow of air from the inlet pipe to the discharge pipe through the measurement air storage unit.

The discharge pipe portion may include: a first discharge pipe disposed between the measurement air storage unit and the pump to form a first discharge flow path from the measurement air storage unit to the pump; and a second discharge pipe disposed between the pump and the other side of the device body to form a second discharge path from the pump to the outside of the device body.

The air flow unit may further include a particle filtering module coupled between the second discharge pipe and the device body and configured to filter particles present in the measurement air before discharging the measurement air.

a power supply unit provided on one side of the device body to supply power to the pump; a control unit for controlling the flow rate of the measurement air stored in the measurement air storage unit by controlling the output of the power supply unit and the output of the pump; a communication unit provided on one side of the device body to transmit a particle measurement result measured by the particle measurement sensor to the outside; and a display unit coupled to the device body and having at least a portion of the display area penetrated toward the outside of the device body to display a particle measurement result measured by the particle measurement sensor to the outside.

Embodiments of the present invention, by accurately and effectively measuring the quantity of particles contained in air inside a clean room in which a semiconductor or display manufacturing process system is disposed, by a particle sensing device having a simple and efficient structure, It is possible to accurately monitor the air cleanliness, and accordingly, it is possible to more effectively control the air cleanliness inside the clean room.

1 is a perspective view schematically illustrating a structure of a particle sensing device according to an embodiment of the present invention.
FIG. 2 is a view showing the inside of a prototype of the particle sensing device of FIG. 1 .
FIG. 3 is an enlarged view of FIG. 2 .
FIG. 4 is a diagram illustrating the display unit of FIG. 1 and information displayed on the display unit;
5 is a diagram schematically illustrating a cleanroom particle integrated management system according to an embodiment of the present invention.
6 is a diagram schematically illustrating the flow of data in the integrated cleanroom particle management system of FIG. 5 .
7 is a view for explaining a process of controlling the temperature, humidity, and air cleanliness inside the clean room by the monitoring device of FIG. 5 .

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the accompanying drawings. Like reference numerals in each figure indicate like elements.

1 is a perspective view schematically showing the structure of a particle sensing device according to an embodiment of the present invention, FIG. 2 is a view showing the inside of a prototype of the particle sensing device of FIG. 1, and FIG. 3 is an enlarged view of FIG. and FIG. 4 is a view showing the display unit of FIG. 1 and information displayed on the display unit.

As shown in these figures, the particle sensing device 10 according to an embodiment of the present invention includes a device body 100, a particle measuring sensor 200, a measuring air storage unit 300, and an air flow. It includes a unit 400, a power supply unit 500, a communication unit 700, a control unit (not shown), a display unit 800, and a temperature and humidity measurement unit (not shown).

First, the device body 100 is a part that forms the outer shape of the particle sensing device 10 , and an inner plate (not shown) may be provided so that all components are disposed at correct positions and coupled to each other.

In this embodiment, as shown in Figs. 2 and 3, it was manufactured as a prototype in the form of a box, but the present invention is not limited thereto, and it can be manufactured in various forms so as to be disposed in a specific place inside the clean room. There will be.

Meanwhile, the particle measuring sensor 200 is provided inside the device body 100 and serves to detect particles included in the air and count the number of particles.

The particle measurement sensor 200 detects impurity particles between 1um and 10um by the photometric method and has a resolution to classify 1um, 2.5um, 5um, and 10um, so the recent semiconductor integration and display evolving to 8K It can be applied not only to industries, but also to industries where impurity particles such as MEMs process and semiconductor process are closely related to the defect rate of products, and furthermore, it can be applied to clean rooms or small machine processes in schools and research institutes.

On the other hand, the measurement air storage unit 300 is provided inside the device body 100, is disposed to surround the particle measurement sensor 200, a particle measurement space of a predetermined size for storing a predetermined amount of measurement air serves to provide

Since a general particle measuring device measures air in a flowing state by an optical measuring method, there may be a difference in the quantity of particles between the external air and the internal measuring air of the particle measuring device.

However, according to the present invention, by providing a particle measurement space of a predetermined size for storing a predetermined amount of measurement air, the particles included in the measurement air in a state in which the measurement air stored in the measurement air storage unit 300 is stabilized Since the quantity of particles can be counted by sensing, data close to the actual quantity of particles in the external air of the particle measuring device can be obtained.

Of course, in the same manner as in a general particle measuring device, air in a flowing state may be measured by an optical measurement method, and the measurement method may be selectively changed according to a measurement environment.

To this end, the measurement air storage unit 300 may seal and store a predetermined amount of measurement air for a predetermined time for counting the quantity of particles, and at this time, the particle measurement sensor 200 is the measurement air storage unit 300 ), it is possible to count the number of particles by detecting the particles included in the measurement air based on a predetermined amount of measurement air stored for a predetermined time.

The measurement air storage unit 300 includes a bulkhead-type storage structure 310 , a cover plate 330 , and a sealing member (not shown).

The partition wall storage structure 310 is provided inside the device body 100 , is disposed around the particle measuring sensor 200 and has a partition wall structure having a predetermined height.

The cover plate 330 is detachably coupled to the upper portion of the bulkhead-type storage structure 310 , thereby enumerating the particle measuring space as needed to maintain the particle measuring sensor 200 inside the bulkhead-type storage structure 310 . i can close

A sealing member (not shown) is disposed between the partition wall storage structure 310 and the cover plate 330 to seal between the partition wall storage structure 310 and the cover plate.

On the other hand, the air flow unit 400 is coupled between the device body 100 and the measurement air storage unit 300, and sucks the external air outside the device body 100 into the inside of the measurement air storage unit 300, It serves to flow the air to discharge the measurement air counted by the number of particles by the particle measurement sensor 200 to the outside of the device body (100).

The air flow unit 400 includes an inlet pipe part 410 , an exhaust pipe part 420 , a pump 430 , and a particle filtering module 440 .

The inlet pipe part 410 is coupled between the measurement air storage unit 300 and one side of the device body 100, and communicates with the inside of the measurement air storage unit 300 and the outside of the device body 100 to the outside of the device body 100 A suction flow path for sucking the air of the measurement air storage unit 300 into the inside is formed.

The discharge pipe part 420 is coupled between the measurement air storage unit 300 and the other side of the device body 100, and the measurement air storage unit 300 communicates with the inside and the outside of the device body 100 to count the number of particles. An exhaust passage for discharging the measurement air to the outside of the device body 100 is formed.

The discharge pipe part 420 includes a first discharge pipe 421 and a second discharge pipe 422, the first discharge pipe 421 is disposed between the measurement air storage unit 300 and the pump 430, the measurement air storage unit A first discharge path from 300 to the pump 430 is formed, and the second discharge pipe 422 is disposed between the pump 430 and the other side of the device body 100 and from the pump 430 to the device body 100 . ) to form a second discharge path to the outside.

The pump 430 is coupled to one side of the discharge pipe part 420 and serves to form a flow of air from the inlet pipe part 410 through the measurement air storage unit 300 to the discharge pipe part 420 .

The particle filtering module 440 is coupled between the second discharge pipe 422 and the device body 100, and serves to filter the particles present in the measurement air before discharging the measurement air.

Referring to FIG. 3 , when describing the arrangement between the inlet pipe part 410 and the discharge pipe part 420 and the pump 430 and the particle filtering module 440 of the air flow unit 400 , first the inlet pipe part 410 . is connected from one wall of the device body 100 to the measurement air storage unit 300 to form a suction flow path arranged along the arrow A, and then the first discharge pipe 421 is pumped from the measurement air storage unit 300 It is connected to 430 to form a first discharge flow path arranged along the arrow B, and thereafter, the second discharge pipe 422 is connected from the pump 430 to the particle filtering module 440 to form a first discharge path arranged along the arrow C. Two discharge passages are formed, and finally, the particle filtering module 440 is directly connected between the second discharge pipe 422 and the inner wall of the device body 100 .

Description of the operation of the air flow unit 400 having this structure, when the pump 430 is operated, from the inlet pipe 410 through the inside of the measurement air storage unit 300 to the first outlet pipe 421 Since the suction force is generated until reaching the device body 100 , the air outside the device body 100 is sucked and supplied to the measurement air storage unit 300 .

At this time, it is possible to control the flow rate of the measurement air stored in the measurement air storage unit 300 by controlling the output of the pump 430 by a control unit (not shown) to be described later.

In addition, by controlling the operation of the pump 430, a predetermined amount of measurement air can be sealed and stored inside the measurement air storage unit 300 for a predetermined time, and at this time, the measurement air storage unit 300 inside the The number of particles may be counted by detecting particles included in the measurement air by the particle measurement sensor 200 .

Thereafter, the measurement air, in which the quantity of particles is measured, moves from the measurement air storage unit 300 to the pump 430 along the first discharge pipe 421 by the operation of the pump 430, and the second discharge pipe 422. is discharged to the outside of the device body 100 through the particle filtering module 440 along the

According to the present invention, by discharging the measurement air in which the quantity of particles is measured through the particle filtering module 440, it is possible to prevent defects in the manufacturing process that may occur inside the clean room due to the particles included in the discharged measurement air. there will be

On the other hand, the power supply unit 500 is provided on one side of the device body 100 and serves to supply power to the pump 430, as well as the pump 430, a control unit (not shown), a display unit 800, Power is supplied to all components that require power, such as a temperature and humidity measuring unit (not shown).

Meanwhile, the control unit (not shown) serves to control the flow rate of the measurement air stored in the measurement air storage unit 300 by controlling the output of the power supply unit 500 and the output of the pump 430 .

Therefore, it is possible to adjust the desired flow rate according to the characteristics according to the environmental conditions and the manufacturing process inside the clean room in which the particle sensing device 10 is disposed.

On the other hand, the communication unit 700 is provided on one side of the device body 100 and serves to transmit the particle measurement result measured by the particle measurement sensor 200 to the outside, at least one terminal for wired communication 710 and, It includes at least one communication module for wireless communication (not shown).

The at least one wired communication terminal 710 may include a USB external connection terminal 711 and a wired LAN external connection terminal 712, and a server for data management of the cleanroom particle integrated management system 1 to be described later through these terminals (20) may be communicatively connected to the wire.

In addition, at least one communication module for wireless communication (not shown) is a data management server ( 20) and may be connected wirelessly, and may be additionally connected to the monitoring device 30 of the integrated cleanroom particle management system 1 to be described later.

According to the present invention, as shown in FIG. 6 , it may be connected to the cloud-type data management server 20 using wireless communication, but may be wired according to the type of the clean room and the environment of the work site according to the demanding company. can also be provided, and a customized data transmission system can be built.

Meanwhile, the display unit 800 is coupled to the device body 100 , and at least a portion of the display area is disposed through the device body 100 toward the outside to display the particle measurement result measured by the particle measurement sensor 200 to the outside. serves to indicate

In the display area of the display unit 800 that is disposed toward the outside of the device body 100 shown in FIG. 4(a), as shown in FIG. Various information such as the number of counted particles, the temperature and humidity of the measured air, the connection state with the sensor, and the connection state with the data management server 20 are displayed.

Since the display unit 800 is provided to enable a touch input, it may also serve as a manipulation unit for manipulating the particle sensing device 10 .

On the other hand, the temperature and humidity measuring unit (not shown) serves to measure the temperature and humidity of the measurement air and inside the clean room in which the particle sensing device 10 is disposed, and the clean room particle integration to be described later by the collected data The data management server 20 of the management system 1 corrects the air cleanliness data acquired from the particle sensing device 10 according to the temperature and humidity data to predict the measurement defect rate.

In addition, in consideration of the measurement failure rate predicted by the data management server 20, the monitoring device 30 of the cleanroom particle integrated management system 1 to be described later, the ventilation device 40 and the temperature and humidity control device 50 By controlling the temperature, humidity and air cleanliness inside the clean room, the collected data is provided.

As described above, according to the present embodiment, while having a simple and efficient structure, by accurately and effectively measuring the number of particles contained in the air in the clean room in which the semiconductor or display manufacturing process system is disposed, the cleanliness of the air inside the clean room is improved. can be accurately monitored.

Meanwhile, FIG. 5 is a diagram schematically illustrating a cleanroom particle integrated management system according to an embodiment of the present invention, and FIG. 6 is a diagram schematically illustrating a flow of data in the cleanroom particle integrated management system of FIG. , FIG. 7 is a view for explaining a process of controlling the temperature, humidity, and air cleanliness inside the clean room by the monitoring device of FIG. 5 .

Hereinafter, a cleanroom particle integrated management system 1 including the aforementioned particle sensing device 10 will be described with reference to these drawings.

As shown in FIG. 5 , the cleanroom particle integrated management system 1 according to an embodiment of the present invention includes at least one particle sensing device 10 , a data management server 20 , and a monitoring device ( 30 ), and a ventilation device 40 , and a temperature and humidity control device 50 .

At least one particle sensing device 10 has the structure as described above, and is disposed at various positions inside the clean room to measure the size and quantity of particles contained in the air, and the temperature and humidity of the measurement air to acquire data and serves to upload the acquired data to the communicatively connected data management server 20 .

The data management server 20 is communicatively connected with at least one particle sensing device 10, and acquires air cleanliness data according to the quantity of particles included in the measured air from the particle sensing device 10, It serves to classify and manage air cleanliness data.

In addition, the server 20 for data management acquires the temperature and humidity data measured by the temperature and humidity measurement unit (not shown) of the particle sensing device 10, classifies and manages the acquired temperature and humidity data, and the temperature And by correcting the air cleanliness data acquired from the particle sensing device 10 according to the humidity data, it is possible to predict the measurement defect rate.

The monitoring device 30 is communicatively connected to the data management server 20 to monitor the air cleanliness level inside the clean room in real time, and thus serves to control the air cleanliness level inside the clean room.

The ventilation device 40 is installed inside the clean room, and serves to adjust the air cleanliness inside the clean room, and at this time, the monitoring device 30 is communicatively connected to the ventilation device 40 and the ventilation device ( 40), it is possible to adjust the air cleanliness inside the clean room.

The temperature and humidity control device 50 is installed inside the clean room, and serves to control the temperature and humidity inside the clean room.

As shown in Figure 5, the monitoring device 30 is communicatively connected with the ventilation device 40 and the temperature and humidity control device 50, in consideration of the measurement defect rate predicted by the data management server 20 By controlling the ventilation device 40 and the temperature and humidity control device 50, it is possible to adjust the temperature, humidity, and air cleanliness inside the clean room.

That is, as shown in FIG. 7 , when the air inside the clean room and the air outside the clean room are circulated by the ventilation device 40 and put back into the clean room, the temperature and humidity control device 50 is It is possible to adjust the temperature and humidity of the air introduced into the clean room while passing through it, and it is possible to adjust the quantity of particles contained in the air while passing through an air purifying device such as a HEPA filter 41 just before being introduced into the clean room. be able to

As described above, according to the present embodiment, by accurately and effectively measuring the quantity of particles contained in the air inside the clean room in which the semiconductor or display manufacturing process system is disposed, the clean room by the particle sensing device having a simple and efficient structure. It is possible to accurately monitor the air cleanliness inside the room, and accordingly, it is possible to more effectively control the air cleanliness inside the clean room.

In addition, in the server for data management, it is possible to predict the measurement defect rate by correcting the air cleanliness data obtained from the particle sensing device according to the temperature and humidity data measured by the temperature and humidity measuring unit of the particle sensing device.

Furthermore, it is possible to control the temperature, humidity and air cleanliness inside the clean room by controlling the ventilation device and the temperature and humidity control device in consideration of the measurement failure rate predicted by the data management server by the monitoring device.

As such, the present invention is not limited to the described embodiments, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Accordingly, it should be said that such modifications or variations are included in the claims of the present invention.

1: Cleanroom particle integrated management system 10: Particle sensing device
20: server for data management 30: monitoring device
40: ventilation device 50: temperature and humidity control device
100: device body 200: particle measurement sensor
300: measurement air storage unit 310: bulkhead storage structure
330: cover plate 400: air flow unit
410: inlet pipe 420: discharge pipe
421: first discharge pipe 422: second discharge pipe
430: pump 440: particle filtering module
500: power supply unit 700: communication unit
800: display unit

Claims (11)

at least one particle sensing device installed in the clean room and configured to detect particles contained in air and count the number of the particles;
Data management that is communicatively connected to the at least one particle sensing device, acquires air cleanliness data according to the quantity of particles included in the measured air from the particle sensing device, and classifies and manages the acquired air cleanliness data for server; and
Cleanroom particle integrated management comprising a monitoring device that is communicatively connected with the data management server to monitor the air cleanliness level inside the cleanroom in real time, and accordingly control the air cleanliness level inside the cleanroom system. According to claim 1,
Installed inside the clean room, further comprising a ventilation device for controlling the air cleanliness inside the clean room,
The monitoring device is
The cleanroom particle integrated management system, characterized in that it is communicatively connected with the ventilation device and controls the ventilation device to adjust the air cleanliness inside the clean room. 3. The method of claim 2,
Each of the at least one particle sensing device,
It includes a temperature and humidity measuring unit for measuring the temperature and humidity inside the clean room,
The data management server,
Acquires temperature and humidity data measured by the temperature and humidity measurement unit, classifies and manages the acquired temperature and humidity data, and corrects the air cleanliness data obtained from the particle sensing device according to the temperature and humidity data Cleanroom particle integrated management system, characterized in that it predicts the measurement defect rate. 4. The method of claim 3,
It is installed in the inside of the clean room, further comprising a temperature and humidity control device for controlling the temperature and humidity inside the clean room,
The monitoring device is
It is communicatively connected with the ventilation device and the temperature and humidity control device, and controls the ventilation device and the temperature and humidity control device in consideration of the measurement defect rate to control the temperature, humidity and air cleanliness inside the clean room Cleanroom particle integrated management system, characterized in that. 4. The method of claim 3,
Each of the at least one particle sensing device,
device body;
a particle measurement sensor provided inside the device body and configured to detect particles contained in the air and count the number of the particles;
a measurement air storage unit provided inside the device body, which is disposed to surround the particle measurement sensor, and provides a particle measurement space of a predetermined size for storing a predetermined amount of measurement air; and
It is coupled between the device body and the measurement air storage unit, sucks the external air outside the device body into the inside of the measurement air storage unit, and the measurement air that counts the number of particles by the particle measurement sensor is supplied to the device Cleanroom particle integrated management system, characterized in that it further comprises an air flow unit for flowing air to be discharged to the outside of the main body. 6. The method of claim 5,
The measurement air storage unit,
Sealing and storing a predetermined amount of the measurement air for a predetermined time for counting the number of particles,
The particle measuring sensor,
A cleanroom particle integrated management system, characterized in that by detecting particles included in the measurement air based on a predetermined amount of measurement air stored for a predetermined time in the measurement air storage unit, the number of particles is counted. 6. The method of claim 5,
The measurement air storage unit,
a partition wall storage structure provided inside the device body, disposed around the particle measuring sensor and having a predetermined height;
a cover plate detachably coupled to an upper portion of the bulkhead-type storage structure; and
and a sealing member disposed between the partition wall storage structure and the cover plate to seal between the partition wall storage structure and the cover plate. 8. The method of claim 7,
The air flow unit,
It is coupled between the measurement air storage unit and one side of the device body, and communicates the inside of the measurement air storage unit and the outside of the device body to form a suction passage for sucking air outside the device body into the inside of the measurement air storage unit an inlet pipe;
A discharge flow path coupled between the measurement air storage unit and the other side of the device body, communicating the inside of the measurement air storage unit and the outside of the device body to discharge the measurement air counting the number of particles to the outside of the device body a discharge pipe to form; and
and a pump coupled to one side of the discharge pipe to form a flow of air from the inlet pipe to the discharge pipe through the measurement air storage unit. 9. The method of claim 8,
The discharge pipe part,
a first discharge pipe disposed between the measurement air storage unit and the pump to form a first discharge passage from the measurement air storage unit to the pump; and
and a second discharge pipe disposed between the pump and the other side of the device body to form a second discharge path from the pump to the outside of the device body. 10. The method of claim 9,
The air flow unit,
The integrated cleanroom particle management system, coupled between the second discharge pipe and the device body, further comprising a particle filtering module for filtering particles present in the measurement air before discharging the measurement air. 9. The method of claim 8,
a power supply unit provided on one side of the device body to supply power to the pump;
a control unit for controlling the flow rate of the measurement air stored in the measurement air storage unit by controlling the output of the power supply unit and the output of the pump;
a communication unit provided on one side of the device body to transmit a particle measurement result measured by the particle measurement sensor to the outside; and
Clean characterized in that it further comprises a display unit coupled to the device body, at least a part of the display area is disposed through the outside of the device body to display the particle measurement result measured by the particle measurement sensor to the outside. Room particle integrated management system.

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