KR100426275B1 - Cascade Impactor for Measuring Droplet Size Distribution - Google Patents

Abstract

The present invention relates to a multi-stage impactor for droplet size distribution measurement. The multi-stage impactor according to the present invention includes a multi-impact impactor for droplet size measurement including a plurality of impactors, each impactor including a collision substrate on which droplets collide. In one embodiment, the impingement substrate is characterized in that the upper surface is covered with paper, and the inside is filled with an absorbent so that absorption of the droplets collected on the impingement substrate is continued. A multistage impactor that can be measured can be provided. Specifically, it is possible to measure quantitative mass distribution by solving the problem that droplets collided on the surface of the collision substrate are easily evaporated by making the collision substrate absorbable enough to prevent evaporation of the droplets for a certain period of time. In addition to quantitative measurement of even the smallest droplet size passing through the last stage of the multi-stage impactor, a more quantitative mass distribution measurement can be achieved by using a droplet collector that can take the place of the final filter.

Description

Cascade Impactor for Measuring Droplet Size Distribution

The present invention relates to a multi-stage impactor capable of quantitatively measuring the mass distribution of the droplets present in air by artificial manipulation such as natural phenomenon or nozzle injection. More specifically, the present invention relates to a multi-stage impactor capable of quantitatively measuring the mass distribution of droplets by preventing the droplets from evaporating by improving the structure and material of the collision substrate in which the droplets collide.

Aerosols refer to solid or liquid particles of size 0.002 to 100 μm suspended in air, which are present in various forms such as dust, mist, fume or smog. These aerosols have a significant impact on industrial and human health in various fields such as energy, environment and health. Therefore, the importance of research on the size and characteristics of aerosols is becoming increasingly important.

Aerosols are produced by various mechanisms such as nucleation, condensation, flocculation, rupture, or combustion, and are transported and deposited on surfaces by Brownian motion, convective diffusion, external forces (gravity, temperature gradients, electric fields, etc.). Since these phenomena depend on characteristics such as aerosol size and concentration, and chemical composition, a measurement technique capable of characterizing the aerosol is very important.

Aerosols are generally non-spherical and have a wide variety of aerosols, and therefore the size of aerosols is defined using geometrical characteristics, particle scattering phenomena, electrophoretic or aerodynamic mobility. . The aerosol concentration, which represents the amount of particles per unit volume, is expressed in water concentration or mass concentration. For mass concentration, coarse particles are important, and in water concentration, fine particles are important.

More precise information about aerosols such as particle size distribution or water concentration of atmospheric aerosols is needed to accurately identify problems such as large-scale smog, long-distance travel of aerosols, yellow dust or global climate change. Therefore, the current measurement trend of aerosol is changing from mass concentration to water concentration, from total concentration to concentration by particle size, from coarse particles to fine particles, and from concentration to chemical composition and shape.

The impactor is designed such that large particles with sufficient inertia hit the surface and small, small inertia forces flow along the air when the air containing the particles is directed through the nozzle to the impact surface. In other words, the impactor is a device that separates particles of a specific size or more by using the inertial force of the particles.

In order to measure the particle size distribution by separating aerosols of various sizes by size, a cascade impactor made by connecting a plurality of impactors in series is used. The multi-stage impactor is composed of a plurality of stages consisting of nozzles and impingement substrates and an after filter (back-up filter). The multi-stage impactor is designed to reduce the size of the nozzle as it moves down, increasing the speed of the jet through the nozzle so that smaller particles can be trapped on the impact substrate as it goes down. To this end, the cut size of the stage becomes smaller as it goes to the lower stage, and very small particles which are not collected in the last stage are collected in the final filter.

In general, the impactor adopts the principle of classifying the particle size of the aerosol by using the inertia of the particle. Therefore, the impactor is mainly used for classifying coarse particles having a size of 1 μm or more. Multi-stage impactors that can classify microparticles using -pressure or micro-orifice have been developed and used.

However, in the multi-stage impactor designed to quantitatively measure the mass distribution of the aerosol by size, it is difficult to quantitatively measure the mass distribution because droplets collided on the surface of the collision substrate are easily evaporated.

The present invention is to solve the above problems, an object of the multi-stage impactor according to the present invention is to provide a multi-stage impactor capable of quantitatively measuring the mass distribution of each droplet size. Specifically, it is possible to measure quantitative mass distribution by solving the problem that droplets collided on the surface of the collision substrate are easily evaporated by making the collision substrate absorbable enough to prevent evaporation of the droplets for a certain period of time. In addition to using a drop collector that can take the place of the final filter to quantitatively measure the size of even the smallest droplets passing through the last stage of the multi-stage impactor, the aim is to enable more quantitative mass distribution measurements. It is done.

1 is a block diagram of a multi-stage impactor for droplet size measurement according to the present invention.

Figure 2 is a detailed view of the impact substrate for collecting droplets constituting the multi-stage impactor for droplet size distribution measurement according to the present invention.

Description of the main parts of the drawing

1: inlet nozzle tube 2: inlet collision board

3: nozzle 4: collision board

5: final filter 6: outlet

7: absorber tube 8: absorbent

9: flow control valve 10: vacuum pump

11: pressure hole 12: differential pressure gauge

13: impactor base 14: fixed plate

15: fixing plate center groove 16: fixing plate peripheral groove

17: fixed plate central groove 18: paper

19: absorbent 20: impingement handle

21: O-ring

In order to achieve the above object, the multi-stage impactor according to the present invention, in the multi-stage impactor for droplet size distribution measurement comprising a plurality of impactors, each impactor is provided with a collision substrate to collide with the droplets, the impact substrate Silver is characterized in that the upper surface is covered with paper, the inside is filled with the absorbent, and the absorption of the droplets collected on the impingement substrate is continued.

In the multi-stage impactor for droplet size distribution measurement according to the present invention, the impingement board is provided with a handle at the bottom and an O-ring at the side.

In the multi-stage impactor for droplet size distribution measurement according to the present invention, it characterized in that it further comprises a fixing plate for fixing the impact substrate to the impactor, the impact substrate is cylindrical and the fixing plate is a removable disk shape, The fixed plate is a multi-stage impactor for droplet size measurement, characterized in that it has a groove around the central portion and the disc.

In the multi-stage impactor for droplet size distribution measurement according to the present invention, the absorbent is characterized in that the silica gel or calcium chloride.

In the multi-stage impactor for droplet size distribution measurement according to the present invention described above, the multi-stage impactor is characterized by having an impinger for collecting fine droplets passing through the final impactor downstream of the final impactor.

In the multi-stage impactor for droplet size distribution measurement according to the present invention, the multi-stage impactor is characterized in that the first separation of the droplet occurs in the fluid inlet phase by providing a collision substrate in the lower portion of the inlet serving as a nozzle.

Hereinafter, with reference to the accompanying drawings, the multi-stage impactor according to the present invention will be described in more detail.

1 shows a configuration diagram of a three-stage impactor as a preferred example of a multi-stage impactor according to the present invention. The three-stage impactor of FIG. 1 is largely composed of a main body, impingers 7 and 8, flow control devices 9, 11 and 12, a vacuum pump 10 and an impactor support 13. The main body consists of inlets 1 and 2, a plurality of stages including the nozzle 3 and the impingement substrate 4, the final filter 5 and the outlet 6, respectively. The inlet consists of an inlet nozzle tube (1) serving as a nozzle at the same time as the inlet and an inlet impingement substrate (2) located immediately downstream of the inlet nozzle tube (1) to introduce droplets of a specific size or more into the multi-stage impactor according to the present invention. It separates from the stage in advance. Determine the size of the nozzle at each stage to filter out droplets of the size you want to separate. If it is not necessary to measure the amount of droplets passing through the last stage, it is also possible to simply measure the mass distribution of the droplets by simply installing the final filter 5 without using an impinger.

The impinger is to collect and quantify the fine droplets passing through the last stage of the impactor. When the impinger is used, the impinger is connected to the outlet 6 without using the final filter 5. Into the absorber tube 7 of the impinger is added to the absorbent (8), such as silica gel or calcium chloride to easily collect the fine droplets contained in the air passing through. In order to suck the air containing the droplets to the multi-stage impactor according to the present invention, a vacuum pump 10 is used downstream of the impinger. The flow regulating device 9, 11, 12 consists of two pressure holes 11, a differential pressure gauge 12 for measuring the pressure difference between the positions where the pressure holes are drilled, and a flow control valve 9 for adjusting the suction flow rate. .

Figure 2 is a detailed view of the impact substrate for collecting droplets used in the multi-stage impactor according to the present invention. Fixing plate 14 for fixing the impingement substrate 4 in the impactor is made of a thin disk shape of the shape that can be easily removable in the impactor. The fixed plate 14 is provided with a fixed plate center groove 15 for allowing the air exiting from the nozzles in each stage to collide, and a fixed plate circumferential groove 16 for allowing the air to flow naturally into the next stage. Since the fixed plate circumferential groove 16 is grooved out of the collision substrate so that air can flow to the next stage after the droplets collide with the collision substrate, it is preferable to make the groove of the largest area possible. The fixing plate center groove 15 has a slight jaw 17 at the top of the fixing plate height to keep the gap between the impact substrate 4 and the nozzle 3 constant and to be placed on the surface of the impact substrate 4. Also fix (18).

In order to absorb the collected droplets for a predetermined time, the impingement substrate 4 is made into a cylindrical shape shallow in depth so as to contain an absorbent 19 such as silica gel and calcium chloride. After the absorbent is contained in the cylinder, the surface of the upper part of the impingement substrate 4, such as paper 18, is smoothed to smooth the surface of the impingement substrate 4 to minimize the change of air flow near the surface of the substrate and to prevent evaporation of droplets. Cover with material. It is preferable that paper is excellent in water absorption and a smooth surface. A cylindrical handle 20 is provided at the lower portion so that the impact substrate can be easily handled. In addition, an O-ring 21 is inserted around the collision substrate cylinder containing the absorbent to fix the collision substrate 4 to the fixed plate 14.

In order to calculate the mass distribution according to the size of the droplets, the difference in weight before and after the air passage of the impingement substrate 4 including the absorbent and the paper is measured with an electronic balance, or the air passage of the fixed plate 14 with the impingement substrate 4 fitted therein. Measure the weight difference before and after. However, since the impact substrate 4 or the fixed plate 14 weighs more than the collected droplets, it is preferable to make the collision substrate 4 and the fixed plate 14 made of a light material such as aluminum alloy to reduce measurement errors. Do.

By using the multi-stage impactor according to the present invention, it is possible to provide a multi-stage impactor capable of quantitatively measuring the mass distribution for each droplet size as much as possible. Specifically, it is possible to measure quantitative mass distribution by solving the problem that droplets collided on the surface of the collision substrate are easily evaporated by making the collision substrate absorbable enough to prevent evaporation of the droplets for a certain period of time. In addition to quantitative measurement of even the smallest droplet size passing through the last stage of the multi-stage impactor, a more quantitative mass distribution measurement can be achieved by using a droplet collector that can take the place of the final filter.

Claims (6)

In the multi-stage impactor for droplet size measurement comprising a plurality of impactors, Each impactor is provided with a collision substrate to collide with droplets, The impingement substrate, A multi-stage impactor for measuring droplet size distribution, wherein the upper surface is covered with paper and the inside is filled with an absorbent so that absorption of droplets collected on the impingement substrate is continued. The method of claim 1, The impingement substrate, Droplet size distribution multi-stage impactor, characterized in that the handle is provided on the lower side and the O-ring on the side. The method of claim 1, The multi-stage impactor, characterized in that further provided with a fixing plate for fixing the impingement substrate to the impactor, The impingement substrate is cylindrical and the fixing plate is a removable disk shape, The fixed plate has a multi-stage impactor for droplet size distribution, characterized in that having a groove around the central portion and the disc. The method of claim 1, The absorbent is a multi-stage impactor for droplet size measurement, characterized in that the silica gel or calcium chloride. The method of claim 1, The multi-stage impactor is a multi-stage impactor for measuring the droplet size distribution, characterized in that the impinger for collecting the fine droplets passing through the final impactor downstream of the final impactor. The method of claim 1, The multi-stage impactor, A multi-stage impactor for measuring droplet size distribution, characterized in that the impingement substrate is provided below the inlet serving as a nozzle to separate the droplets in the inflow stage of the fluid.