KR102569244B1 - Air purifier for fine dust - Google Patents

Abstract

The present invention makes water into a mist state by electrostatic spraying to adsorb and remove fine dust and airborne bacteria, but make the water pressure in each capillary constant so that the mist particle size is uniform, and the mist that is discharged without sticking to the ground plate is liquid It relates to an air purifying device for fine dust in which untreated fine dust and airborne bacteria and viruses are finally filtered by installing a liquid droplet filter that reduces air pollution.
To this end, in the present invention, a water collection tank is provided at the lower part of the main body in which a duct is embedded, and a capillary frame receiving high voltage in an electrostatic spray method and a ground plate are provided at the entrance of the duct to be separated from each other, and the water in the water collection tank is disposed in the capillary frame. In the air purifier for fine dust, which is supplied to each capillary through a pump, and the ground plate is provided inside the duct so that fine dust passing through the duct is adsorbed while the mist through the capillary is directed to the ground plate , the capillary frame is provided with capillary chambers having the capillaries on both upper and lower sides of the central passage; Each of the capillaries of the capillary chamber is provided with an arc-shaped circumferential wall and a straight guide wall spaced apart from each other so that water is guided to each capillary, and each of the guide walls is formed longer toward the center from the end of the passage to each of the capillary chambers. The flow rate and the flow rate of the end and the center of the passage are in inverse proportion to keep the water pressure in each capillary constant; A droplet filter is provided at the rear of the duct to filter out mist that is not adsorbed to the ground plate. The droplet filter is formed as a long groove with a wide top and bottom and a narrow middle, so that the droplet enters the groove through expansion and compression of the mist. There is a feature that makes it stick to.

Description

Air purifier for fine dust {Air purifier for fine dust}

The present invention relates to an air purifying device for fine dust, and more particularly, by making water into a mist state by electrostatic spraying to adsorb and remove fine dust and airborne bacteria, but to make the water pressure in each capillary tube constant so that the mist particle size is uniform It also relates to an air purifying device for fine dust in which untreated fine dust and airborne bacteria and viruses are finally filtered by installing a droplet filter that converts mist discharged without sticking to a ground plate into droplets.

In general, most air purification systems using water spray water toward fine dust or allow fine dust to be adsorbed on the surface of water, and the removal efficiency of fine dust is high because fine dust in the air easily sticks to water. . In addition, a method of adsorbing and removing fine dust by spraying water into the inhaled air using an ultrasonic vibrator is also used.

Conventional Patent Publication No. 10-2009-0087560 consists of a main body having a humidifying unit, a dehumidifying unit, and an air cleaning unit, and sprays water into the room with an ultrasonic vibrator of the humidifying unit, and dehumidifies the indoor air with high humidity after flowing into the main body. It is a configuration in which fine dust in the indoor air is collected together in the process of removing moisture through condensation through the negative thermoelectric element.

However, since the conventional patent is a humidification method that sprays water directly into the room, it has the disadvantage of increasing the indoor humidity. There was the hassle of having to clean the floor at the same time.

Conventional Patent No. 2284715 proposed an air purifier using water electrostatic spray capable of removing fine dust in an eco-friendly way without frequent filter replacement by using an electrostatic spray method of spraying charged micro droplets.

However, the conventional patent has a complicated structure because it is necessary to additionally install an extraction plate to control the electrostatic spray for each nozzle in front of the microdroplet spraying unit and apply an independent voltage signal to each micronozzle to make the microdroplet more fine. In addition, there was a problem such as an increase in indoor humidity because fine droplets are discharged to the room when they do not stick to the electrode.

The present invention was developed in view of the problems of the prior art, and an object of the present invention is to adsorb and remove fine dust and airborne bacteria by making water into a mist state by electrostatic spraying, but to make the water pressure in each capillary tube constant so that the mist particle size can be reduced. It is to provide an air purifying device for fine dust in which untreated fine dust and airborne bacteria and viruses are finally filtered by installing a droplet filter that makes it uniform and converts mist discharged without sticking to the ground plate into droplets.

To this end, in the present invention, a water collection tank is provided at the lower part of the main body in which a duct is embedded, and a capillary frame receiving high voltage in an electrostatic spray method and a ground plate are provided at the entrance of the duct to be separated from each other, and the water in the water collection tank is disposed in the capillary frame. In the air purifier for fine dust, which is supplied to each capillary through a pump, and the ground plate is provided inside the duct so that fine dust passing through the duct is adsorbed while the mist through the capillary is directed to the ground plate , the capillary frame is provided with capillary chambers having the capillaries on both upper and lower sides of the central passage; Each of the capillaries of the capillary chamber is provided with an arc-shaped circumferential wall and a straight guide wall spaced apart from each other so that water is guided to each capillary, and each of the guide walls is formed longer toward the center from the end of the passage to each of the capillary chambers. The flow rate and the flow rate of the end and center of the passage are in inverse proportion to keep the water pressure in each capillary constant; A droplet filter is provided at the rear of the duct to filter out mist that is not adsorbed to the ground plate. The droplet filter is formed as a long groove with a wide top and bottom and a narrow middle, so that the droplet enters the groove through expansion and compression of the mist. There is a feature that makes it stick to.

According to the present invention, the capillary frame is configured by separating capillary chambers having a plurality of capillaries on both upper and lower sides of the capillary frame with a central passage in between, and water flows along the passage in a state in which the ends of both sides of the passage are connected to each capillary chamber. After being dispersed, it is supplied to each capillary chamber. In addition, each capillary is surrounded by an arc-shaped circumferential wall and a vertical induction wall, and water is introduced into the gap between them. Each induction wall is formed longer as it moves away from the end of the passage so that water is equally supplied to each capillary.

Therefore, since the water pressure of each capillary becomes constant, the mist particle size becomes uniform and dense, thereby improving the collection performance of fine dust and airborne bacteria. In addition, since the mist that does not stick to the ground plate is converted into droplets and collected in the process of repeating compression and expansion in the droplet filter, there is an advantage in making the room comfortable without affecting the indoor humidity.

1 is a conceptual diagram of an air purifying device according to an embodiment of the present invention
Figure 2 is an exploded perspective view of a capillary frame for an air purifier according to an embodiment of the present invention
3 is a plan view of a capillary frame for an air purifier according to an embodiment of the present invention
Figure 4 is an enlarged view of the capillary frame of Figure 3
5 is a perspective view of a droplet filter for an air purifier according to an embodiment of the present invention
6 is a cross-sectional view of a droplet filter for an air purifier according to an embodiment of the present invention

1 to 4, the air purifier of one embodiment of the present invention has a main body 10 having a “U”-shaped duct inside, and a suction fan 20 sucking external air at the beginning of the duct 11 It is provided to be rotated at high speed through this motor, and a suction port 12 connected to the suction fan 20 is provided at the lower part of the main body 10. In addition, a discharge port 13 connected to the end of the duct 11 is formed in the upper part of the main body 10, and a water collecting tank 14 connected to the lower part of the middle of the duct 11 through a hose is formed in the lower part of the main body 10. is provided

Inside the main body 10, a capillary frame 30 is provided at the beginning of the duct 11 to generate mist in an electrostatic spraying method. In the capillary frame 30, capillaries 32 are provided to face the inside of the duct 11, and a ground plate 40 is provided inside the duct 11 to face the capillaries 32. The capillary frame 30 has an open top and is sealed through a cover 35, and a capillary frame 30 has a plurality of capillaries 32 on both sides of the upper and lower sides with the passage 30a interposed therebetween. The tube chamber 31 is separated, and in a state where both ends of the passage 30a are connected to each capillary chamber 31, water is distributed to both sides along the passage 30a and then supplied to each capillary chamber 31. .

The cover 35 has an inlet 36 connected to the center of the passage 30a so that water in the water collecting tank 14 is sprayed into the passage 30a at high pressure through a pump 21 . In addition, each capillary tube 32 is surrounded by an arc-shaped circumferential wall 32 and a vertical induction wall 34, and the water in the capillary chamber 31 enters the gap between the circumferential wall 32 and the induction wall 34. this is introduced The guide wall 34 of each capillary chamber 31 is formed longer as it moves away from the end of the passage 30a, so that water is equally supplied to each capillary. Due to each guide wall 34 formed in each capillary chamber 31, the capillary chamber 31 becomes narrower as the passage 30a is farther from the end, so the flow rate and the flow velocity are in inverse proportion.

Therefore, since the flow rate and the flow rate of the capillary 32 that are far away from the capillary 32 at the end of the passage 30a are leveled while being inversely proportional, the water pressure of each capillary 32 becomes constant. In addition, since each capillary tube 32 is connected to each other through an auxiliary passage 30b, a differential pressure is not generated, and the water flowing into the gap between the circumferential wall 32 and the induction wall 34 and the water flowing in from the auxiliary passage 30b Since water passes through the capillary tube 32 rapidly while swirling while crossing each other, water stagnation does not occur.

The capillary frame 30 generates mist in an electrostatic manner. When DC high voltage from the power supply unit 22 is applied to the capillary frame 30 and the ground plate 40, water is sprayed into micro- and nano-sized mist. .

Electrostatic spraying is performed by setting a high voltage to be applied to the electrodes (capillary frame 30 and ground plate 40), setting the distance between both electrodes, and adjusting the water pressure inside the capillary 32. The above conditions are set by set values. When the water passes through the capillary tube 32, a Taylor cone is created at the discharge end of the capillary tube 32, and then the water particles are finely divided to enable electrostatic spray in the form of a Taylor jet.

When the inhaled air passes through the mist screen generated from the electrostatic spray cluster, fine dust, airborne bacteria and viruses are adsorbed to the charged mist. Thereafter, the mist reaching the ground plate 40 is collected in the form of droplets (water droplets), flows down, and is stored in the lower collection tank 14. At this time, the adsorbed airborne bacteria and viruses are removed by destroying the protein cell membrane by the hydroxyl group (OH radical) contained in the mist. Mist, untreated fine dust, airborne bacteria, and viruses that have not been converted into droplets through the above first-step removal step are mixed and converted into droplets inside the second-step droplet filter 50 and stored in the lower collection tank 14.

5 and 6 show a droplet filter 50 according to an embodiment of the present invention, and a pair of droplet filters 50 are overlapped at the rear of the duct 11. The droplet filter 50 is made of a metal material, and has a long groove 51 that is wide at the top and bottom and narrow at the middle, so that the top and bottom entrances are wide and the middle is narrow. Therefore, when these two droplet filters (50) are superimposed on each other, the inlet and outlet continuously meet and the air passage repeats the widening and narrowing pattern, and the mist repeats compression and expansion. Adheres in the form of droplets, forms water droplets, and is then returned to the collecting tank 14 at the bottom of the duct 11.

In the air purifier of one embodiment of the present invention configured as described above, fine dust, airborne bacteria and viruses in the inhaled air are adsorbed to the mist, collected on the ground plate 40, and then taken in the form of droplets while riding down the wall of the duct 11 It goes down and is stored in the collecting tank 14. The water collecting tank 14 is composed of an oblique line and has a multi-stage washable microporous filter 15 built in to remove the collected fine dust, so that the water is reused. In addition, since water is sprayed in the form of mist, fine dust and ultra-fine dust can be removed with only a small amount of water. Airborne bacteria and viruses are removed by electrostatic spraying without sterilizing chemicals, and bacteria and viruses are removed by hydroxyl groups generated during electrostatic spraying. Removed.

In this embodiment of the present invention, indoor and outdoor fine dust and various airborne bacteria and viruses are introduced into the duct 11 through the suction port 36 by the operation of the suction fan 20 . And when the high voltage from the power supply unit 22 is applied to the capillary frame 30 and the ground plate 40 and the water in the water collection tank 14 is supplied to the inlet 36 of the capillary frame 30 through the pump 21 After being dispersed on both sides in the passage 30a, it is put into each capillary chamber 31.

In each of the capillary chambers 31, a plurality of capillaries 32 are spaced apart at equal intervals, and each capillary 32 is surrounded by an arc-shaped circumferential wall 32 and a straight guide wall 34 so that there is a gap between them. water enters into In addition, each guide wall 34 is formed longer from the end of the passage 30a toward the inlet 36, so that each capillary chamber 31 gradually narrows. Accordingly, the water discharged from the end of the passage 30a is uniformly supplied to each capillary tube 32 so that the water pressure becomes constant. In addition, each capillary tube 32 passes through the capillary tube 32 as the water flowing into the gap between the circumferential wall 32 and the induction wall 34 and the water flowing in the opposite direction from the auxiliary passage 30b cross each other and vortex. There is no stagnation in the flow.

Therefore, the water creates a Taylor cone at the end of each capillary 32, and then the water particles are finely divided to form a mist in the form of electrostatic spray. Since it heads to the ground plate 40 from the duct 11, fine dust, airborne bacteria and viruses in the air passing through the duct 11 cannot escape and are adsorbed into the mist. Then, while taking the form of droplets on the ground plate 40, it flows down the duct 11, is collected in the water collection tank 14, and then reused.

In addition, mist passing through the duct 11 without being converted into droplets is converted into droplets while passing through the droplet filter 50 at the rear of the duct 11 . The droplet filter 50 has a narrow middle between the inlet and the outlet, and when the two droplet filters 50 are overlapped, the inlet and the outlet are continuous, and the mist passing through them repeats expansion and compression, so that it has a hemispherical shape in the form of a droplet. It sticks to the groove 51 and flows down the duct 11. Therefore, since clean air without mist is discharged through the discharge port 13, indoor air can be maintained comfortably.

10: body 11: duct
20: suction fan 30: capillary frame
30a: passage 30b: auxiliary passage
31: capillary chamber 32: capillary
33: peripheral wall 34: induction wall
40: ground plate 50: droplet filter
51: home

Claims (4)

A water collecting tank is provided at the lower part of the body with a built-in duct, and a capillary frame receiving high voltage in an electrostatic spray method and a ground plate are provided apart from each other at the entrance of the duct, and water in the water collecting tank is pumped to each capillary of the capillary frame. In the air purifier for fine dust, the ground plate is provided inside the duct so that the fine dust passing through the duct is adsorbed while the mist passing through the capillary is directed to the ground plate,
In the capillary frame, capillary chambers having a plurality of capillaries are separated on both sides of the upper and lower sides with a passage in between, and ends of both sides of the passage are connected to each capillary chamber, so that water is distributed to both sides along the passage, and then each supplied to the capillary chamber, and the capillaries of each of the capillary chambers are arranged in a row close to the passage;
Each of the capillaries is isolated from each of the capillary chambers through an arc-shaped circumferential wall and an induction wall erected vertically with respect to the passage, and between the circumferential wall and the induction wall to induce water to flow from the capillary chamber to the capillary gaps are provided;
the guiding walls of each of the capillary chambers are formed gradually higher along the flow direction of the water so that the water coming out of the passage does not stagnate and spreads widely in the capillary chamber to be supplied to each of the capillaries at a constant water pressure;
A droplet filter for filtering out mist that is not adsorbed to the ground plate is provided inside the rear of the duct away from the ground plate. An air purifier for fine dust, characterized in that it adheres to the inner wall of the groove as a droplet through compression. According to claim 1,
Each of the capillaries is connected to each other through an auxiliary passage passing through a lower end of the circumferential wall and a lower end of the induction wall;
Each of the capillaries is an air purifier for fine dust, characterized in that a portion of the water flowing into the gap between the circumferential wall and the induction wall flows toward the other capillary along the auxiliary passage so that a differential pressure is not generated. According to claim 1,
Each capillary chamber of the capillary frame has an open top, and a cover covering the open capillary chamber is provided on the top of the capillary frame, and an inlet for supplying water to the center of the passage is formed in the center of the cover. Air purifier for dust. According to claim 1,
The air purifier for fine dust, characterized in that the two droplet filters are composed of a pair and overlapped vertically, and each of the droplet filters has long-shaped grooves that are wide at the top and bottom and narrow at the center.