KR101270424B1 - Separating device of micro particles and separation method of it - Google Patents

Abstract

The present invention relates to a separation device and a separation method for separating fine particles, and more particularly, a separation device for separating fine particles by passing a fluid containing the fine particles through a bubble generating tube capable of forming micro bubbles. It's about how.
The fine particle separator according to an aspect of the present invention includes a bubble generating tube, an inlet tube, and an outlet tube. The bubble tube generates bubbles when a plurality of grooves having a size of 1 to 1,000 micrometers are arranged along the inner circumferential surface of the fluid flow. The inlet pipe may include a first inlet formed to send a first fluid containing fine particles to the inner circumferential surface of the bubble generating tube, and a second fluid not containing the fine particles to a central portion of the bubble generating tube. It is provided at the inlet of the bubble generating tube having a second inlet formed. The outlet pipe includes a first outlet for discharging the first fluid flowing along the inner circumferential surface of the bubble generating tube, and a second outlet for discharging the second fluid flowing to the center of the bubble generating tube. Is installed at the exit.
According to the present invention, since the fine particles are separated by flowing a fluid containing the fine particles into the bubble generating tube in which the micro bubbles are formed, the fine particles can be separated regardless of the electrical properties of the fine particles.

Description

Separating device of micro particles and separation method of it}

The present invention relates to a separation device and a separation method for separating fine particles, and more particularly, a separation device for separating fine particles by passing a fluid containing the fine particles through a bubble generating tube capable of forming micro bubbles. It's about how.

In the case of DNA, protein, or blood, microparticles such as red blood cells and white blood cells in plasma can be separated without damage, making diagnosis of many diseases easier.

The fine particle separator is separated by being discharged to different outlets by the physical properties of the particles mixed in the fluid.

Conventionally, the nanoparticles are separated using a centrifuge or the like, but in this case, there is a problem that the productivity is low due to the small amount that can be separated per hour.

Alternatively, in the conventional case, two particles are separated using an electrical property of particles in an electric field in the case of particles charged with an anode and a cathode. In this case, when the particles do not have electrical properties, it is difficult to control such particles in a desired direction.

The present invention is intended to solve the above problems. It is an object of the present invention to provide a fine particle separation device and a separation method capable of separating particles according to physical properties even if the particles do not have electrical properties.

In addition, an object of the present invention is to provide a fine particle separator and a separation method capable of easily separating not only solid particles but also fine particles such as biological particles in a quick and simple manner.

The fine particle separator according to an aspect of the present invention includes a bubble generating tube, an inlet tube, and an outlet tube. The bubble tube generates bubbles when a plurality of grooves having a size of 1 to 1,000 micrometers are arranged along the inner circumferential surface of the fluid flow. The inlet pipe may include a first inlet formed to send a first fluid containing fine particles to the inner circumferential surface of the bubble generating tube, and a second fluid not containing the fine particles to a central portion of the bubble generating tube. It is provided at the inlet of the bubble generating tube having a second inlet formed. The outlet pipe includes a first outlet for discharging the first fluid flowing along the inner circumferential surface of the bubble generating tube, and a second outlet for discharging the second fluid flowing to the center of the bubble generating tube. Is installed at the exit.

In the fine particle separation device, the inner circumferential surface of the bubble generating tube is preferably coated with a hydrophobic material.

According to another aspect of the present invention, there is provided a method for separating fine particles by flowing a first fluid containing fine particles into an inner circumferential surface of a bubble generating tube having a plurality of grooves capable of generating bubbles on an inner circumferential surface thereof, and flowing the first fluid containing the fine particles into the center of the bubble generating tube. By flowing a second fluid containing no fine particles, the first fluid and the second fluid passed through the bubble generating tube is separated and flowed to separate the fine particles by size.

According to the present invention, the microbubble can flow the fluid containing the fine particles in the bubble generating tube to separate the fine particles such as biological particles as well as solid particles can be separated regardless of the electrical properties of the fine particles. .

1 is a conceptual diagram of one embodiment of a fine particle separation device according to the present invention;
2 is a flow chart of the fluid of the embodiment shown in FIG.
3 shows an example of the behavior of particles according to the number of stokes,
4 to 6 shows the behavior of the bubble generating tube of the fine particles according to the number of Stokes,
7 is a conceptual diagram for separating the fine particles using the embodiment shown in FIG.

1 and 2 will be described an embodiment of a fine particle separation apparatus according to the present invention. The fine particle separation device according to the present invention includes a bubble generating tube 10, the inlet tube 20, and the outlet tube (30). Bubble generation tube 10 is formed with a plurality of grooves 11 having a size of 1 to 1,000 micrometers along the inner circumferential surface. In this case, when the fluid flows inside the bubble generating tube 10, bubbles 13 are formed in the groove 11. That is, when the fluid flows inside the bubble generating tube 10, the groove 11 formed on the inner circumferential surface generates bubbles. At this time, in order for the bubble 13 to be smoothly formed, the inner circumferential surface of the bubble generating tube 10 is preferably coated with a hydrophobic material. In the present embodiment, only the groove 11 of the micrometer size is formed on the inner circumferential surface of the bubble generating tube 10, it is possible to provide the air pressure from the outside to the groove 11 using an air pressure generator. Then, the bubble 13 may be more smoothly generated in the groove 11 of the bubble generating tube 10.

The inlet pipe 20 is installed at the inlet of the bubble generating tube 10 to supply fluid to the bubble generating tube 10. In this case, the inlet pipe 20 includes a first inlet 21 and a second inlet 23. The first inlet 21 is formed so that the fluid flows along the inner circumferential surface of the bubble generating tube 10 when the fluid is supplied, and the second inlet 23 is the bubble generating tube 10 when the fluid is supplied. It is formed to flow to the center of the.

The outlet pipe 30 is installed at the outlet of the bubble generating tube 10 so that the fluid flowing in the bubble generating tube 10 flows out. At this time, the outlet pipe 30 has a first outlet 31 and the second outlet (33). The first outlet 31 is formed so that the fluid flowing along the inner peripheral surface of the bubble generating tube 10 flows out, the second outlet 33 is so that the fluid flowing in the center of the bubble generating tube 10 can flow out. Is formed.

When the fluid is supplied to the first inlet 21 and the second inlet 23, the fluid introduced through the first inlet 21 forms the first wire 25 along the inner circumferential surface of the bubble generating tube 10. Exit to the first outlet 31. At this time, since the groove 11 of the micrometer size is formed in the inner circumferential surface of the bubble generating tube 10, the bubble 13 is formed. The fluid introduced through the second inlet 23 exits to the second outlet 33 while forming the second wire 27 along the center of the bubble generating tube 10.

In this case, if the fluid contains fine particles, the fine particles flow along the streamline formed by the flow of the fluid. However, if you look at the behavior of the particles flowing along the streamline it can be seen that the movement according to the Stokes number of [Equation 1].

Where ρ _P is the particle density, d _P is the diameter of the particle, U is the velocity of the fluid, C _C is the sliding coefficient, μ is the fluid viscosity, and L is the diameter of the tube if the fluid flows along the grooved tube.

As can be seen from [Equation 1], as the density or size of the particles or the velocity of the fluid increases, the number of stocks increases, and conversely, the number of stocks decreases.

Looking at the behavior of the particles according to the number of Stokes as shown in FIG. 3 (a) shows a case where the number of stokes is much smaller than 1 (Stk << 1), and FIG. 3 (b) shows a case where the number of stokes is much larger than 1 (Stk >> 1). When the number of stokes is much smaller than 1, the particles 1 flow along the streamline 3 as shown in FIG. However, when the number of stokes is much larger than 1, as shown in (b) of FIG. 3, the particles 1 do not flow along the streamline 3 by inertia, but try to go straight by inertia. So it hits the obstacle 5 out of the streamline 3.

4 and 5 are the results of the computational analysis to see the behavior of the particles by flowing a fluid containing the fine particles in the bubble generating tube 10 by varying the number of stokes to separate the fine particles. 4 is a case where the particle size is 10 microns and the density of the particles is 1,080 kg / m ³ . 5 is a case in which the particle size is 10 microns and the particle density is 2,200 kg / m ³ . 4 and 5 are results of analyzing the behavior of the particles according to the difference in the density of the particles. If the particle density is low, the number of stokes is small, so the particle tries to flow along the path of the streamline. However, when the particle density is high, the number of stokes increases, so the particle tries to flow in a straight line by inertia rather than by the path of the streamline. In the case of FIG. 4, since the density is low and the number of stokes is small, the distribution of particles at the exit is evenly distributed as at the inlet because the particles flow along the streamline. However, in FIG. 5, since the density is high and the number of stokes is increased, the particle distribution at the outlet is collected at the center. That is, even if the particles are evenly distributed in the inlet, it passes through the bubble generating tube 10 and flows in a straight line by inertia without flowing along the streamline.

6 is a result of analyzing the behavior of the particles according to the size of the particles. Even if the particles have the same density, different particle sizes result in different stokes. FIG. 6 shows the results of computational analysis of the behavior of particles having the same density but having a size of 1 micron and 10 microns evenly distributed at the entrance. The bubble size in this case is 30 microns. Referring to FIG. 6, particles 1 micron in size at the outlet are evenly distributed as at the inlet. However, even though 10 micron-sized particles 38 are evenly distributed at the inlet, they are collected at the center at the outlet.

A method of separating fine particles using the behavior characteristics of the particles according to the Stokes number will be described with reference to FIG. 7.

The first fluid 41 flows through the first inlet 21 of the inlet pipe 20, and the second fluid 43 flows through the second inlet 23. Then bubbles are generated in the groove 11 of the bubble generating tube 10 and the first fluid 41 exits through the first outlet 31 and the second fluid 43 exits through the second outlet 33. At this time, the mixed particles 45 and 47 having different sizes are flowed to the first inlet 21 together with the first fluid 41. Then, since the first particles 45 having a small size have a small number of stokes, the first particles 45 move together with the first fluid 41 and exit through the first outlet 31. However, since the second particle 47 having a large size has a large number of stokes, the second particle 47 goes straight through the second outlet 33 because it moves straight inside the bubble generating tube 10 unlike the behavior of the first fluid 41. Thus, particles of different sizes can be separated. According to this embodiment, it is possible to separate microparticles having a size of 100 micrometers from 1 nanometer.

1: particle 3: streamline
5: obstacle 10: bubble generator tube
11: home 13: bubble
20: inlet pipe 21: the first inlet
23: second inlet 25: first wire
27: second wire 30: outlet pipe
31: outlet 1 33: outlet 2
41: first fluid 43: second fluid
45: first particle 47: second particle

Claims (3)

A bubble generating tube for arranging a plurality of grooves having a size of 1 to 1,000 micrometers along the longitudinal direction of the inner circumferential surface through which the fluid flows to generate bubbles when the fluid flows;
A first inlet formed to send a first fluid containing fine particles to the inner circumferential surface of the bubble generating tube, and a second inlet formed to send a second fluid not containing the fine particles to a central portion of the bubble generating tube An inlet pipe installed at the inlet of the bubble generating pipe,
A first outlet for discharging the first fluid flowing along the inner circumferential surface of the bubble generating tube and a second outlet for discharging the second fluid flowing to the center of the bubble generating tube and installed at an outlet of the bubble generating tube Fine particle separation device comprising an outlet pipe. The method of claim 1,
The inner circumferential surface of the bubble generating tube is fine particle separator characterized in that the coating with a hydrophobic material. A second fluid containing the fine particles flowing in the inner circumferential surface of the bubble generating tube having a plurality of grooves capable of generating bubbles along the longitudinal direction of the inner circumferential surface and not containing the fine particles in the center of the bubble generating tube; A fine particle separation method comprising flowing the fluid, separating the first fluid and the second fluid passed through the bubble generating tube and outflow to separate the fine particles by size.

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