KR102389530B1 - Hybrid Dust Collector - Google Patents

Abstract

The present invention provides a composite dust collector. In the composite dust collector according to the present invention, an inner space is formed between the lower air inlet 110 and the upper air outlet 120, and the drain 130 connected to the inner space is formed at the bottom of the casing 100. ); a cyclone dust collecting unit 200 disposed in the lower region of the inner space and configured to perform primary dust collection while rotating the air introduced through the lower air inlet 110 along the inner wall surface; and an electric dust collecting unit 300 disposed in the upper region of the inner space and performing secondary dust collection while ionizing pollutants in the air that has passed through the cyclone dust collecting unit 200 . do it with

Description

Hybrid Dust Collector

The present invention relates to a complex type dust collector, and more specifically, to improve dust collection efficiency through a combination of a cyclone dust collecting unit and an electric dust collecting unit, and to provide a structure in which the electric dust collecting unit is controlled according to the ozone concentration generated. It relates to a complex type dust collector that maintains the amount of ozone generated below a specified value.

Particulate Matter (PM) refers to dust that is so small that it is invisible to the naked eye floating in the atmosphere. It consists of ion components such as nitrate (NO ₃ ^- ), ammonium ion (NH ₄ ⁺ ), sulfate (SO ₄ ^2- ), carbon compound, and metal compound.

Generally, when the diameter is 10㎛ or less (PM 10), it is called fine dust (suspended particles), and it is subdivided into dust with a diameter of 2.5㎛ or less (PM 2.5) and dust with a diameter of 1㎛ or less (PM 1.0) However, in Korea, airborne dust with a PM of 10 or less is called fine dust, fine dust with a PM of 2.5 or less is called ultra-fine dust, and fine dust with a PM of 1.0 or less is also classified as ultra-fine dust. In addition, there is condensable fine dust that is smaller than ultrafine dust, which is discharged as a gas and then cools to become dust. Natural gas such as LPG generates less fine dust and fine dust during combustion, but condensable fine dust is generated a lot when polluting gases such as carbon monoxide and carbon dioxide are burned.

When exposed to fine dust for a long period of time, immunity is rapidly lowered, leading to exposure to respiratory diseases such as colds, asthma and bronchitis, as well as various diseases such as cardiovascular diseases, skin diseases, and eye diseases. In particular, fine dust with a diameter of 2.5 μm or less easily penetrates deep into the bronchial tubes and lungs in the human body, causing various diseases by attaching to the bronchial tubes and lungs.

Accordingly, the installation of air filtration devices is continuously increasing in order to create comfortable indoor air in living spaces and to protect human health. Recently, the number of installations in buildings and underground facilities is increasing.

Although wet cleaning devices are used to purify these harmful exhaust gases, effective reduction techniques using wet electric dust collectors have been developed and applied due to limitations in their treatment efficiency and structural problems. 'Wet Electric Dust Collector (Registration No.: 10-2032028)' discloses a wet electric dust collector that allows washing water to be evenly sprayed throughout the dust collecting pipe. Such a technique can be expected to solve the problem of incomplete removal of contaminants caused by drying of the dust collecting tube by constantly spraying the washing water evenly on the inner wall of the dust collecting tube while minimizing the risk of spark-over phenomenon. .

However, in the 'wet electric dust collector', a coupling cylinder having a washing water receiving part coupled to each dust collecting tube must be separately provided, and in order to improve dust collection efficiency, the dust collector must be widely distributed, so there was a problem in that the volume of the dust collector becomes large. There was a limit that could not solve the problem caused by ozone generated at the time.

KR 10-2032028 B1

Therefore, in order to improve the problems of the prior art, the present invention improves the dust collection efficiency by using the cyclone dust collection method and the wet electric dust collection method, and controls the electric dust collection unit according to the ozone concentration to maintain the ozone generation amount below the specified value. An object of the present invention is to provide a composite dust collector made as possible.

In the present invention for achieving the above object, an inner space is formed between the lower air inlet 110 and the upper air outlet 120, and the drain 130 connected to the inner space is formed at the bottom of the casing 100. ; a cyclone dust collecting unit 200 disposed in the lower region of the inner space and configured to perform primary dust collection while rotating the air introduced through the lower air inlet 110 along the inner wall surface; and an electric dust collection unit 300 disposed in the upper region of the inner space and performing secondary dust collection while ionizing contaminants in the air that have passed through the cyclone dust collection unit 200; The dust collecting unit 300 includes: a discharge electrode 310 disposed in a vertical direction in the center of an upper region of the inner space of the casing 100 and generating a corona discharge by applying a high voltage; a dust collecting electrode 320 arranged in a cylindrical shape along the inner wall surface of the casing 100 on which the discharge electrode 310 is disposed, and collecting contaminants ionized by corona discharge; and an insulating plate 330 disposed on the upper and lower portions of the discharge electrode 310 and the dust collecting electrode 320 to insulate and fix it, and the contaminants inside the electric dust collecting unit 300 are combined with the washing water. It is characterized in that the composite dust collector, characterized in that the droplets.

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The cyclone dust collecting unit 200 of the composite dust collector according to the present invention as described above, the cyclone dust collecting unit 200 applies a centrifugal force to the air introduced through the lower air inlet 110 by centrifugal collision. a first cyclone dust collecting subunit 210 for collecting dust; A second cyclone dust collecting subunit 220 for forming a polling layer in which a sprayer 221 for spraying washing water is disposed on the upper portion; may have a structure including a.

The temperature at which the composite dust collector according to the present invention is formed at a set height on the upper side of the electric dust collecting unit 300 and discharges air to the upper air outlet 120 made of the open upper surface of the casing 100 . It is configured to further include a reduction discharge unit 400, the temperature reduction discharge unit 400 is provided with a blower fan 410 at the bottom to induce suction and temperature reduction of the air that has passed through the electric dust collecting unit 300 can have a structure that

The composite dust collector according to the present invention includes: an ozone sensor 500 disposed near the upper air outlet 120 and measuring the ozone concentration in the air that is purified and discharged while passing through the composite dust collector; and a controller for controlling the cyclone dust collecting unit 200 and the electric dust collecting unit 300 according to the ozone concentration measured by the ozone sensor 500 .

According to the composite dust collector of the present invention, since the cyclone dust collecting method and the wet electric dust collecting method are used in combination, there is an effect of improving the dust collecting efficiency. And by controlling the dust collector according to the ozone concentration so that the ozone generation amount is maintained below a specified value, there is an effect that can solve the problem caused by ozone.

In addition, according to the composite dust collector of the present invention, since the purified air is discharged in a reduced temperature state, there is an effect that the increase in the ambient temperature of the dust collector is minimized.

Additionally, the composite dust collector of the present invention has a structure that sequentially collects large and heavy pollutants, and as it passes through the cyclone dust collecting unit, some pollutants are collected, and the air primarily purified flows into the electric dust collecting unit. As compared to the case of using only the dust collecting method, there is no need for the dust collecting tube to be widely distributed and a separate configuration is not required.

1 is an exemplary configuration diagram of a composite dust collector according to an embodiment of the present invention.
2 is an exemplary configuration diagram of an electric dust collecting unit according to an embodiment of the present invention.
3 is an exemplary configuration diagram of a composite dust collector according to another embodiment of the present invention.
4 is a flow analysis graph of exhaust air purified through a complex type dust collector according to an embodiment of the present invention.
5 is a graph of the experimental results of fine dust removal efficiency of the composite dust collector according to an embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings 1 to 5 . On the other hand, in the drawings and detailed description, the drawings and descriptions of configurations and actions that can be easily recognized by those skilled in the art from a general cyclone dust collector, an electric dust collector, a dust collector, a discharge electrode, etc. are simplified or omitted. In particular, in the drawings and detailed description, detailed descriptions and illustrations of specific technical configurations and actions of elements not directly related to the technical features of the present invention are omitted, and only the technical configurations related to the present invention are briefly illustrated or described. did

A composite dust collector according to an embodiment of the present invention includes a casing 100, a cyclone dust collecting unit 200, an electric dust collecting unit 300, a temperature reduction discharge unit 400, an ozone sensor 500, and a controller. composed of

The casing 100 has an internal space in which air containing fine dust is introduced and purified, and the cyclone dust collecting unit 200 and the electric dust collecting unit 300 are disposed in the inner space as shown in FIG. 1 .

A lower air inlet 110 through which external air containing fine dust is introduced is formed on the lower outer circumferential surface of the casing 100, and an upper air outlet 120 through which purified air is discharged is formed on one upper side of the casing 100. do. In the embodiment of the present invention, the upper air outlet 120 is formed on the open upper surface of the casing 100 to facilitate the discharge of purified air.

A drain 130 for collecting and discharging the collected pollutants is formed in the center of the lower end of the casing 100 . The drain 130 is most preferably in the shape of a hopper so that the collected contaminants can be easily discharged.

The cyclone dust collecting unit 200 is disposed in the lower region of the inner space of the casing 100, and a centrifugal force is applied to remove fine dust inside the rotating air. Here, the cyclone dust collecting unit 200 according to an embodiment of the present invention is composed of a first cyclone dust collecting subunit 210 and a second cyclone dust collecting subunit 220 .

The first cyclone dust collecting sub-unit 210 forms the lower part of the cyclone dust collecting unit 200, and the dust particles introduced from the outside through communication with the lower air inlet 110 are on the inner wall of the casing 100 by centrifugal force. It is configured to collect dust so that it collides and is collected by the drain 130 . Accordingly, dust particles of PM 10 or less, which are heavy and large pollutants, can be primarily removed.

The first cyclone dust collecting sub-unit 210 is an eccentrically arranged lower air inlet 110 and an air pump that can be installed in an air supply pipe connected to the lower air inlet 110. It induces rotational flow.

The second cyclone dust collecting subunit 220 constitutes the upper part of the cyclone dust collecting unit 200 , and is disposed on the upper part of the first cyclone dust collecting subunit 210 to receive the air from which the primary dust has been removed. The second cyclone dust collecting subunit 220 is configured to include a sprayer 221 and a polling layer structure 222 .

The atomizer 221 is configured to supply washing water to the inner space of the casing 100 . While passing through the first cyclone dust collection subunit 210, some It is to supply cleaning water to the purified air.

The polling layer structure 222 is configured so that the washing water is evenly sprayed into the inner space of the casing 100 . Therefore, it is preferable that the polling layer structure 222 has a plate shape that is spread while being inclined so that the washing water sprayed from the sprayer 221 can be sprayed evenly while riding.

Accordingly, in the second cyclone dust collecting sub-unit 220 , a polling layer is formed in which some of the dust particles that have rotated and flowed with air combine with the washing water sprayed from the atomizer 221 and fall.

That is, as the air introduced from the outside passes through the cyclone dust collecting unit 200 , large and heavy dust particles are collected by centrifugal collision and combination with washing water, and partially purified air is introduced into the electric dust collecting unit 300 . . Due to this coupling structure, the amount of dust particles contained in the air flowing into the electric dust collecting unit 300 can be reduced compared to the case where dust is collected only by the conventional electric dust collecting method. Therefore, if the same amount of pollutants is collected in the electric dust collecting unit 300, the amount of pollutants included in the air that is finally purified and discharged through the upper air outlet 120 is reduced, so the dust collection efficiency is improved. .

The electric dust collecting unit 300 is disposed in an upper region of the inner space of the casing 100 . The electric dust collecting unit 300 is configured to ionize fine dust particles in the form of dust or mist by corona discharge using electrostatic power, and to move them to the electrode surface by an electric field to collect dust.

The electric dust collecting unit 300 includes a discharge electrode 310 , a dust collecting electrode 320 , and an insulating plate 330 .

The discharge electrode 310 is configured to perform corona discharge by applying a high voltage. In order to facilitate discharge, the discharge electrode 310 preferably has a pointed shape such as a pin rather than a wide plate shape. Accordingly, it is arranged in the inner center of the electric dust collecting unit 300 .

The dust collecting electrode 320 is preferably formed in a plate shape along the inner circumferential surface of the casing 100 so as to spread over a wide area in order to increase dust collecting efficiency.

The insulating plate 330 is configured to fix and insulate the discharge electrode 310 and the dust collecting electrode 320 . The insulating plate 330 is formed on the upper and lower portions of the electric dust collecting unit 300 , respectively.

This electrostatic precipitation unit 300 can be used in a dry or wet manner, and mainly uses a wet electrostatic precipitation method that removes contaminants using washing water rather than a dry electrostatic precipitation method to solve the limitations on processing efficiency and structural problems. .

In the embodiment of the present invention, since the sprayer 221 for supplying the washing water to the cyclone dust collecting unit 200 is provided, it is not necessary to be separately provided on the upper part of the electric dust collecting unit 300 . Since the atomizer 221 is disposed on the upper end of the cyclone dust collecting unit 200 to supply washing water, the second cyclone dust collecting subunit 220 forms a polling layer by dropping contaminants into droplets and at the same time forming the electric dust collecting unit There is an effect that the air flowing into the 300 is mixed with the washing water and introduced.

The temperature reduction discharge unit 400 is configured to further facilitate the discharge of air. The temperature reduction discharge unit 400 is formed at a set height on the upper side of the electric dust collecting unit 300 so that the air passing through the electric dust collecting unit 300 is not discharged immediately, but is discharged by reducing the temperature. In addition, the temperature reduction discharge unit 400 may have a blower fan 410 disposed at the lower end to forcibly suck air. It is possible to smoothly discharge the air forcedly sucked by the blower fan 410 and reduce the temperature of the internal air as shown in FIG. 4 . When the purified air is discharged through the upper air outlet 120 while passing through the electric dust collecting unit 300 by this coupling structure, the air is not easily discharged because it is located far from the cyclone dust collecting unit 200. This has the effect of minimizing the increase in the ambient temperature of the dust collector as the air is discharged in a reduced temperature state.

The ozone sensor 500 is disposed near the upper air outlet 120, and is a device for measuring the amount of ozone in the air that passes through the complex type dust collector and is discharged.

When ozone is generated by the corona discharge in the electric dust collecting unit 300, it may combine with oxygen in the air to corrode the device, and may become the main culprit of environmental pollution. In order to solve this problem, when the ozone concentration in the exhaust air measured by the ozone sensor 500 is out of the prescribed range, the controller controls the pressure of the cyclone dust collecting unit 200 or the corona discharge of the electric dust collecting unit 300 . do.

Therefore, the composite dust collector according to the embodiment of the present invention is provided with the ozone sensor 500 and the controller, so that the ozone generation amount can be maintained below the prescribed value.

In the composite dust collector according to the embodiment of the present invention configured as described above, the external air containing pollutants such as NOx, SOx, and harmful gas passes through the cyclone dust collecting unit 200 to collect primary dust, and the electric dust collecting unit As it passes through 300 and provides a device configuration that collects secondary dust and purifies the air in stages, it is possible to effectively reduce fine dust as shown in FIG. 5 . In addition, since the dust collector is controlled according to the generated ozone concentration, the ozone generation amount is maintained below a prescribed value, thereby solving the problem caused by ozone. In addition, when the purified air is discharged, there is an effect that the increase in the ambient temperature of the dust collector is minimized due to the temperature reduction effect.

As described above, although the composite dust collector according to the embodiment of the present invention has been illustrated according to the above description and drawings, this is merely an example and various changes and modifications within the scope not departing from the technical spirit of the present invention It will be well understood by those skilled in the art that this is possible.

100: casing
110: lower air inlet
120: upper air outlet
130: drain
200: cyclone dust collection unit
210: first cyclone dust collection unit
220: second cyclone dust collection unit
221: atomizer
222: polling layer structure
300: electric dust collection unit
310: discharge electrode
320: dust collecting pole
330: insulation plate
400: temperature reduction exhaust unit
410: blow fan
500: ozone sensor

Claims (5)

a casing 100 in which an inner space is formed between the lower air inlet 110 and the upper air outlet 120, and a drain 130 connected to the inner space is formed at the lower end;
a cyclone dust collection unit 200 disposed in the lower region of the inner space and configured to perform primary dust collection while rotating the air introduced through the lower air inlet 110 along the inner wall surface; and
It is disposed in the upper region of the inner space, the electric dust collecting unit 300 for performing secondary dust collection while ionizing the pollutants in the air that has passed through the cyclone dust collecting unit 200; and
The electric dust collecting unit 300,
a discharge electrode 310 disposed in a vertical direction in the center of an upper region of the inner space of the casing 100 and causing corona discharge by applying a high voltage;
a dust collecting electrode 320 arranged in a cylindrical shape along the inner wall surface of the casing 100 on which the discharge electrode 310 is disposed and collecting contaminants ionized by corona discharge; and
The discharge electrode 310 and the dust collecting electrode 320 are respectively disposed on the upper and lower portions of the insulating plate 330 for insulating and fixing;
Composite dust collector, characterized in that the contaminants inside the electric dust collecting unit (300) are combined with the washing water to form droplets. According to claim 1,
The cyclone dust collection unit 200,
a first cyclone dust collecting sub-unit 210 for collecting dust by centrifugal collision by applying a centrifugal force to the air introduced through the lower air inlet 110;
A second cyclone dust collecting sub-unit 220 for forming a polling layer with a sprayer 221 for spraying washing water on the upper part; a composite dust collector comprising: a. According to claim 1,
It is formed at a set height on the upper side of the electric dust collecting unit 300, and further comprises a temperature reduction discharge unit 400 for discharging air to the upper air outlet 120 made of an open upper surface of the casing 100. ,
The temperature reduction discharge unit (400) is provided with a blower fan (410) at the bottom of the combined dust collector, characterized in that the suction and temperature reduction of the air that has passed through the electric dust collecting unit (300). According to claim 1,
an ozone sensor 500 disposed near the upper air outlet 120 and measuring the ozone concentration in the air that is purified and discharged while passing through the complex type dust collector; and
and a controller for controlling the cyclone dust collecting unit 200 and the electric dust collecting unit 300 according to the ozone concentration measured by the ozone sensor (500). delete

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