KR20180032459A - Method for measuring Suspended Particle in air - Google Patents

Abstract

The present invention relates to a method for measuring suspended particles in air and, more specifically, to the method for measuring suspended particles in air, which detects scattered lights to measure the number and a size of the suspended particles wherein a detector reduces a detection interval of the scattered lights to obtain a plurality of the scattered lights with respect to a corresponding suspended particle, thereby calculating the width of the corresponding suspended particle together with the height (length) therethrough to enhance accuracy of measurement of the particle size. The present invention provides the method for measuring the suspended particles in air, which irradiates an internal space of a chamber, through which the suspended particles including dust are passed, with lights to make the detector detect energy of lights scattered by the suspended particles, thereby measuring the size and the number of the suspended particles in air. When the detector detects the scattered lights scattered by the suspended particles, the detector reduces the detection interval, reads a plurality of scattered lights with respect to one suspended particle, displays the read scattered lights on a display device, and simultaneously detects the height and the width of the corresponding suspended particle with the plurality of scattered lights to calculate an area.

Description

TECHNICAL FIELD The present invention relates to a method for measuring suspended particles in air,

The present invention relates to a method for measuring suspended particles in air, and more particularly, to a method for measuring suspended particles in air by measuring the number and size of suspended particles by shortening the detection interval of scattered light in the detector, (Length) of the suspended particles to thereby increase the accuracy of the particle size by calculating the width along with the height (length) of the suspended particles.

Generally, light scattering is used to measure suspended particles in air.

The above-described light scattering method is a technique using a laser beam. When laser light is straightened in the air and the straightened light meets particles in the air, light is scattered. The size and number of the light generated at this time, The number of particles is measured.

As shown in FIG. 1, a conventional optical structure of a light scattering method for measuring suspended particles according to the related art includes a laser 30 for directing laser light to enter the chamber 10 so that a focus is formed inside the chamber 10, A mirror 20 for reflecting the scattered light scattered on the dust 30 and an air inlet 40 for scattering air particles scattered by the laser 30 and the mirror 20, A detector 50 for measuring the size and the number of the laser beams, and a light extinction unit 70 for destroying the laser beam passing through the chamber 10.

The detector senses scattered light and measures the size and number of the particles with the sensed light. The size of the particles measured by the detector is usually determined by the length of the particles, that is, .

On the other hand, the present inventor has studied and developed a measurement sensor and a device for measuring the degree of contamination in the air to produce a product. For example, Korean Patent Registration No. 10-0985025 (registered on September 28, 2010) And a sensor for measuring suspended particles in a slim type air in Korean Patent Registration No. 10-1154236 (registered on June 01, 2012), and has been patented and commercialized as a product.

The inventor of the present invention has developed a fine dust measuring sensor and a measuring device for detecting the size and the number of particulate matter scattered in the irradiated laser light by a detector after forcibly introducing the air in the air into the sealed sensor unit , And displays the size and number of the particulate matter detected by the detector on the display device.

At this time, when the pollution degree of the space is detected by the floating particles displayed on the display device, only the particles whose height (length) is larger than the reference value among the respective particles displayed on the display device are selected and the degree of pollution is calculated by the number of the selected particles have. For example, in the graph of Fig. 2, when the particle selection reference value is set to 0.8 mu m, only particles having a particle height of 0.8 mu m or more are selected to calculate the contamination degree.

Therefore, it is impossible to accurately calculate the contamination degree due to the occurrence of errors due to the problem that the height of the particle is shorter than the reference value but the wide particle is excluded from the sorting object. Therefore, it is difficult to measure the contamination degree accurately corresponding to the clean room condition, And thus, there is a limit to the production of high-quality products in products requiring work in a clean room.

Registered Patent Publication No. 10-1063966 (2011.09.02, real-time dust measurement device) Registration Utility Model No. 20-0367121 (Oct. 30, 2004, Laser particle counter for fine particle measurement) Registered Patent Publication No. 10-1154236 (2012.06.01, Slim air suspended particle measurement sensor) Published Utility Model Publication No. 2000-0017757 (October 10, 2000, particle sensor)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a detector in which the detection interval of scattered light scattered by suspended particles is shortened to detect a plurality of scattered light for one suspended particle, And the width of the airborne particles is calculated at the same time so as to increase the accuracy of the size of the suspended particles and thereby to more precisely measure the contamination of the air in the space.

Also, the present invention provides a method for measuring suspended particles in air, which compares an initial value with a current value every set time, and self-corrects the difference to eliminate or minimize a measurement error caused by sensor contamination by dust .

According to an aspect of the present invention, there is provided a dust collecting apparatus including a dust collecting unit for irradiating light into an inner space of a chamber through which dust particles including dust pass, detecting light energy scattered by the dust particles in a detector, And detecting the number of particles in the air, wherein the detector detects the scattered light scattered by the suspended particles, reduces the detection interval, reads a plurality of scattered light for one suspended particle, and displays the scattered light on the display device And the height and the width of the suspended particles are detected by a plurality of scattered lights to calculate an area.

According to the method for measuring suspended particles in air having the above structure, the detection interval of the scattered light is reduced to obtain a plurality of scattered light for one suspended particle, so that the length and width of the suspended particle are detected by the respective scattered light, It is possible to accurately calculate the area and to accurately measure the degree of contamination of the space, thereby effectively managing the clean room, and in the case of a product requiring work in a clean room, it is possible to produce a higher quality product without defects .

In addition, since it has a self-correcting function, the accuracy can be maintained without generating an error even if it is used for a long time.

In addition, when the present invention is applied to a fine dust measuring instrument, it is possible to perform more accurate fine dust measurement by the scattered light measuring method.

1 is a schematic view showing a conventional suspended particle measurement device in air.
2 is a graph showing the size (height) and the number of scattered light detected in a detector of a conventional air suspended particle measuring apparatus.
3 is an enlarged graph of scattered light detected by a detector according to the present invention.
4 is a calibration flow chart of a suspended particle measurement sensor according to the present invention,
5 is a graph of scattered light measurement of a suspended particle measuring sensor before and after contamination according to the present invention.

Hereinafter, a method for measuring suspended particles in air according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Prior to the description, the sensor for measuring suspended particles used in the present invention can use a sensor having a known configuration. For example, a slim airborne suspended particle measuring sensor disclosed in Japanese Patent No. 1154236 owned by the present applicant can be used.

As shown in FIGS. 3 to 5, the present invention irradiates light into an inner space of a chamber through which suspended particles including dust are passed, detects light energy scattered by the suspended particles in the detector, In the airborne suspended particle measurement method for measuring the size and the number of particles, the detector detects the scattered light scattered by the suspended particles to reduce the detection interval, reads a plurality of scattered light on one suspended particle, displays the scattered light on a display device, And the height and width of the suspended particles are detected by a plurality of scattered lights to calculate the area.

In the present invention, the detector detects the scattered light for one suspended particle by shortening the detection time of the scattered light, and the detected scattered light has different heights. The width of the peak, that is, the length along with the peak value of the suspended particles can be detected by the plurality of scattered lights detected in this manner. Thus, the size of the suspended particles can be accurately detected. The pollution degree can be measured more accurately.

As a reason for shortening the detection interval of scattered light in the present invention, conventionally, since the detection interval of scattered light is long and only the height of scattered light is detected regardless of the width of suspended particles, To solve the problem that the accuracy is not high.

That is, according to the present invention, a plurality of scattered light is detected for one suspended particle, and the length and width of the suspended particle are detected through the respective scattered light to calculate the area. Thus, In order to increase the accuracy by minimizing the occurrence of errors, it is necessary to measure the contamination degree by detecting the scattered light.

Further, according to the present invention, the distribution of suspended particles in the space can be confirmed by calculating the length and width of the suspended particles with a plurality of scattered lights having different heights. That is, long and wide particles, long and narrow particles, small and wide particles, and small and narrow particles can be distinguished, respectively.

In the present invention, the detection interval of the scattered light in the detector is detected to be 40 占 퐏 or less.

When the detection time of the detector exceeds 40 mu s, the number of detected light beams scattered by one suspended particle is reduced, and the width and area of the suspended particle can not be accurately calculated, thereby increasing the error range.

In the present invention, an analog-to-digital converter (ADC) chip is used for detecting the scattered light in the detector.

The analog-to-digital converter chip converts an analog quantity into a digital quantity, and converts the analog signal of the scattered light measured by the photosensor into a digital signal.

At this time, the analog-to-digital converter (ADC) chip may be composed of an analog-digital converter built in a CPU of a detector and an analog-digital converter chip connected to a CPU.

In order to increase the performance of the analog digital converter built in the CPU, an analog digital converter chip is connected to be connected to the CPU separately as the CPU price increases.

The detector of the present invention may be installed at two or more different angles at different positions. The reason for doing this is for 3D stereoscopic measurement of the suspended particles in the inner space of the chamber, so as to detect the size of the suspended particles more accurately.

On the other hand, in the present invention, it is possible to measure the suspended particles by compensating the numerical value according to the degree of contamination.

For this purpose, the detector measures the internal space of the first chamber, stores the measured values in the DB, periodically measures the suspended particles existing in the chamber internal space for each set period, stores the measured values in the DB, If a difference is found after comparing with the numerical value, it is calculated by adding the difference value from the later measured value.

In order to store the measured values of the initial suspended particles and the measured values measured during the set period, DBs are provided in the suspended particle measurement sensor, and the detector compares the stored measured values and compensates for the difference.

Here, at the time of measurement of the suspended particles for numerical compensation, the air inlet portion of the chamber is cut off, and the measurement is made in a state in which no air flows into the internal space.

As described above, the detector periodically measures the suspended particles in the chamber while the air inlet is closed, and compensates for the difference value so that the measurement accuracy of the initial state can be maintained constantly.

For example, in the graph shown in FIG. 5, the signal measured by the floating particle measuring sensor before the first contamination and the signal measured by the floating particle measuring sensor contaminated by the use of the fixed period of time have a numerical difference of about 0.7 .

Therefore, the detector is calibrated to calculate by adding the difference of 0.7, so that the measurement accuracy of the first suspended particle can be maintained even in the contaminated state.

As described above, according to the present invention, the detection interval of the scattered light is reduced, and the height and width of the suspended particles are detected with a plurality of scattered lights to calculate the area of the suspended particles. Thus, the size of the suspended particles can be more accurately measured. It is a very useful invention that can improve measurement reliability by allowing measurement accuracy to be maintained even if contamination occurs for a long period of time through self calibration.

none

Claims (7)

There is provided a method for measuring suspended particles in air which irradiates light to an inner space of a chamber through which suspended particles including dust are passed and detects light energy scattered by the suspended particles in a detector to measure the size and number of suspended particles in the air ,
In the detector, when detecting scattered light scattered by suspended particles, the detection interval is reduced to read a plurality of scattered light for one suspended particle and displayed on the display device, and the height and width of the suspended particle are represented by a plurality of scattered light And calculating an area of the airborne particles in the air.
The method according to claim 1,
Wherein the detector detects floating particles having a height and an area larger than a reference value set in the detected floating particles and calculates the degree of contamination in the space.
The method according to claim 1,
Wherein the scattered light detection interval in the detector is 40 占 퐏 or less.
The method according to claim 1,
Wherein the detector uses an analog-to-digital converter (ADC) chip for detecting scattered light.
5. The method of claim 4,
Wherein the analog-to-digital converter (ADC) chip comprises an analog-to-digital converter incorporated in a CPU of a detector and an analog-digital converter chip connected to a CPU separately.
The method according to claim 1,
Wherein the detector is installed at two or more different angles at different angles to enable 3D stereoscopic measurement of the suspended particles existing in the inner space of the chamber.
The method according to claim 1,
In the detector, the air inflow portion of the chamber is blocked so as to prevent air from flowing into the internal space, the suspended particles existing in the internal space of the first chamber are measured, the measured values are stored in the DB, The suspended particles existing in the internal space are measured, and the measured values are stored in the DB. Then, the measured values are compared with the initial measured values to determine whether or not there is a difference. Then, when the difference occurs, Characterized in that the suspended particles in air are measured.

Images