KR20230173329A - Dust scavenger enhanced of scavenging capability - Google Patents

Abstract

The present invention relates to a dust collector with improved collection performance, and more specifically, to a dust collector having an upper and lower narrow shape and having an open upper and lower portion; a dust injection portion formed on one side of the chamber; a liquid droplet injection portion formed on the other side of the chamber; A suction unit installed at the top of the chamber, provided with a filter, and sucking air into the chamber by a motor; and a dust recovery unit provided at a lower portion of the chamber to collect moistened dust flowing along a side wall of the chamber.

Description

Dust scavenger enhanced of scavenging capability}

The present invention relates to a dust collector with improved collection performance, and more specifically, in a cyclone type collector for collecting dust, air containing dust is injected to one side and fine droplets are sprayed to the other side, while simultaneously spraying fine droplets on the inner wall of the collector chamber. A dust collector is provided to adjust the injection pressure of air containing dust according to the pressure on the air.

Technologies for controlling fine particles existing in the air or under specific environments are widely applied in various fields of science and technology and also occupy an important industrial position. In particular, fine particles present in the air are air pollutants that deteriorate visibility and can have fatal effects on the human body, so technologies to remove them are continuously being developed. Fine particle removal technologies include technologies that electrically charge dust, transform it into particles of a certain size through artificial agglomeration, and technologies that artificially control and separate the behavior of particles. In addition to existing air pollution prevention technologies, this is being used as the basic mechanism of dust removal devices, which have recently attracted attention. In other words, the technology to remove fine particles in the air basically uses the principle of separating fine particles by artificially applying an external force or installing an obstacle in the air flow.

Among these, the method of cleaning and separating dust with water includes a cleaning tower, spray tank, scraper, etc., and related devices can remove mist, soluble gas, vapor, etc. in addition to hydrophilic dust and fume. Particulates are separated and collected through droplets, liquid films, and bubbles, and inertia, diffusion, cohesion, and gravity are used. The inertial force and gravity increase as the particle size increases, and the dust collection efficiency for diffusion and cohesion increases as the particle size decreases. However, wet dust collection devices have the disadvantage of handling the cleaning liquid and the risk of corrosion of the device due to the cleaning liquid.

Centrifugal force dust collection uses the principle of rotating dust-containing air within a cylinder and using the centrifugal force to separate the dust to the outside. In general, the amount of air treated increases in proportion to the square of the diameter, and as the diameter increases, the size of the limiting particles that can be collected also increases. Therefore, in order to collect fine particles, the required number of small cyclones must be installed in parallel, and this method of using multiple small cyclones is called ‘multi-cyclone’. Cyclones have a relatively simple structure and are easy to maintain, so they are widely used, but they have the disadvantage of high pressure loss during operation, high energy consumption, and vulnerability to abrasive dust.

Republic of Korea Patent Publication No. 2011-0045676 (May 4, 2011)

The present invention was developed to solve the problems of the prior art described above. The present invention has the effect of condensing dust by adding fine droplets in a cyclone-type collector, and gives weight to allow the dust to fall by gravity. , providing a dust collector with improved dust collection performance that allows it to flow and descend along the inner wall of the collector chamber, and increases the effectiveness of dust collection by adjusting the pressure of the collector chamber by considering the pressure of the inner wall of the collector and the injection pressure of air containing dust. The purpose is to

In addition, the present invention determines the level of pressure within the collector and, if it is below the standard pressure, injects water through the water injection part to clean the inside of the collector, thereby providing a dust collector with improved collection performance that prevents backflow due to excessive pressure during the water injection process. It is done for a different purpose.

In order to achieve the above-described object, the present invention includes a chamber having an upper-lower-contrast shape and open upper and lower ends; a dust injection portion formed on one side of the chamber; a liquid droplet injection portion formed on the other side of the chamber; A suction unit installed at the top of the chamber, provided with a filter, and sucking air into the chamber by a motor; and a dust recovery unit provided at a lower portion of the chamber to collect moistened dust flowing along a side wall of the chamber, wherein a through hole is formed in the side wall of the chamber to connect a water injection unit, and the water injection unit is connected to a water injection unit. A dust collector with improved collection performance is provided, wherein water is controlled to be injected when the injection pressure of the dust injection unit or the pressure inside the chamber decreases below a standard value to clean dust accumulated on the side wall.

When increasing the injection pressure of the dust injection unit, as a result of measuring the internal pressure of the chamber, if it rises above the standard value, the suction pressure of the suction part is increased to prevent backflow of the injected dust, and if it falls below the standard value, the suction pressure of the suction part is lowered. However, it is preferable that the suction pressure of the suction part is automatically controlled by the controller according to the pressure inside the chamber, and that the liquid droplet injection amount of the liquid droplet injection part is linked to the injection pressure of the dust injection part.

According to the present invention as described above, by adding fine droplets into the cyclone type collector, there is an effect of coagulating dust, and by giving weight, the dust falls by gravity, but flows along the inner wall of the collector chamber, and the dust The effect of dust collection can be increased by adjusting the pressure of the collector chamber by considering the pressure of the inner wall of the collector and the injection pressure of the air containing.

In addition, by determining the level of pressure within the collector and if it is less than the standard pressure, water is injected through the water injection part to clean the inside of the collector, thereby preventing backflow due to excessive pressure during the water injection process.

1 is a diagram showing a dust collector with improved collection performance according to an embodiment of the present invention.
Figure 2 is a diagram showing the pressure of each part of a dust collector with improved collection performance according to an embodiment of the present invention.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts that are not related to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

Throughout the specification, when a part is said to “include” a certain element, this means that it may further include other elements rather than excluding other elements, unless specifically stated to the contrary.

Additionally, terms such as “… unit” and “… unit” used in the specification refer to a unit that processes at least one function or operation.

Figure 1 is a diagram showing the dust collector 100 with improved collection performance according to an embodiment of the present invention, and Figure 2 is a diagram showing the pressure of each part of the dust collector 100 with improved collection performance according to an embodiment of the present invention. This is the drawing shown.

As shown, the collector 100 of the present invention has an upper and lower narrow shape and includes a chamber 120 with open upper and lower ends; a dust injection unit 110 formed on one side of the chamber 120; a liquid droplet injection part 130 formed on the other side of the chamber 120; A suction unit 140 installed at the top of the chamber 120, provided with a filter, and sucking air into the chamber 120 by a motor 150; and a dust recovery unit 160 provided at the lower part of the chamber 120 to collect moistened dust flowing along the side wall of the chamber 120.

Here, the collector 100 forms an upper and lower narrow structure in the form of a cyclone. In addition, dust is mainly fine dust of less than 100㎍/m³, but dust larger than that is not limited.

Inside the chamber 120, air and liquid droplets containing dust can be introduced, and a dust recovery unit 160 is installed at the upper part through which the introduced air flows out, and at the lower part where dust meeting the liquid droplets flows and is received. A suction device for sucking air is further attached to the top, and a motor 150 is attached to the suction device, so the suction process is performed by driving the motor 150.

The droplets collide with the dust, agglomerate the dust, increase its weight, and move it to the side wall of the collector 100 by centrifugal force. The coarsened dust that hits the side wall naturally descends and is recovered in the dust recovery unit 160.

The introduced air and dust create a whirlwind at the center of the cyclone, and the air moves to the upper suction part 140 through the central part of the collector 100. At this time, the dust is separated by centrifugal force and only very small dust and air are collected. It is sucked into the upper part. In the case of very small dust contained in the air sucked into the upper part, it is filtered by a filter and then discharged outside.

The droplets are preferably the fine droplets used in a humidifier, and when they are introduced into the collector 100, they naturally combine with the dust while flowing along with the flow of the injected dust and air. Afterwards, it moves to the side wall of the collector 100 together with the dust and is discharged to the outside through the lower part.

Meanwhile, as shown in FIG. 2, the necessary portion of the injection pressure of the dust injection unit 110, the injection amount or injection force of the droplet injection unit 130, the suction pressure of the suction unit 140, and the internal pressure of the chamber 120 The pressure can be measured. Although not shown, various conventional sensors for measuring pressure may be installed, and a control unit that receives signals from these may be further included.

A sensor attached to at least one part of the chamber 120 measures the pressure generated inside the chamber 120 by dust flowing in. If the injection pressure of the dust injection unit 110 increases, the internal pressure of the chamber 120 may increase, and in this case, dust may flow back or an excessively large vortex may be formed. Therefore, the dust is increased by increasing the suction pressure of the suction unit 140. Avoid backflow into the dust injection unit 110. At the same time, the amount of liquid droplet injection from the liquid droplet injection unit 130 also increases proportionally. The amount of droplet injection can be adjusted by measuring the pressure at which the droplet is injected from the droplet injection unit 130 or by using a flow meter.

In addition, through holes are formed in various parts of the side wall of the chamber 120 of the present invention, a water injection part 170 is connected to this, and a hose is connected to the pipe so that water can be injected. The amount of water injected is enough to cause the dust on the side wall to flow downward, and this serves to wash the side wall of the chamber 120 with water because it may be difficult to completely discharge the moistened dust with only the natural flow.

The water injection timing can be, for example, measured by measuring the pressure inside the chamber, and water can be injected when the pressure is below a reference value. This is because water can also flow back. That is, the operation of the water injection unit 170 and the injection pressure of the dust injection unit 110 or the internal pressure of the chamber 120 are interconnected, and the water injection time of the water injection unit 170 is determined by the dust injection unit 110. It starts when the injection pressure made in decreases or the pressure inside the chamber 120 decreases below the standard value, and when it becomes greater than the standard value, water is not supplied.

The water injection unit 170 can be freely placed without blind spots in washing away dust from the top to the bottom of the side wall of the chamber 120.

For example, after the side wall of the chamber 120 is cleaned by injecting water, the pressure on the side wall of the chamber 120 may increase again, and in this case, the dust injection unit 110, the droplet injection unit 130, and the suction unit 140 ) can also be adjusted in conjunction with pressure.

Since the dust recovered from the recovery unit is mixed with water, there is an advantage in that dust can be recovered without dust scattering. In this case, the use of liquid droplets has the effect of evenly moistening the dust. The present invention is herein. has significance.

It should be noted that the above-described embodiments are for illustrative purposes only and are not intended for limitation. Additionally, an expert in the technical field of the present invention will understand that various embodiments are possible within the scope of the technical idea of the present invention.

100: dust collector 110: dust injection unit
120: Chamber 130: Droplet injection unit
140: suction part 150: motor
160: dust recovery unit 170: water injection unit

Claims (2)

A chamber having the shape of an upper and lower narrowing chamber and having the upper and lower parts open;
a dust injection portion formed on one side of the chamber;
a liquid droplet injection portion formed on the other side of the chamber;
A suction unit installed at the top of the chamber, provided with a filter, and sucking air into the chamber by a motor; and
a dust recovery unit provided at a lower portion of the chamber to collect moistened dust flowing along a side wall of the chamber;
Including,
A through hole is formed in the side wall of the chamber to connect a water injection unit, and the water injection unit is controlled to inject water when the injection pressure of the dust injection unit or the pressure inside the chamber decreases below a standard value to clean dust accumulated on the side wall. A dust collector with improved collection performance. According to paragraph 1,
When increasing the injection pressure of the dust injection unit, as a result of measuring the internal pressure of the chamber, if it rises above the standard value, the suction pressure of the suction part is increased to prevent backflow of the injected dust, and if it falls below the standard value, the suction pressure of the suction part is lowered. lowered, but the suction pressure of the suction part is automatically controlled by the control unit according to the pressure inside the chamber.
A dust collector with improved collection performance, wherein the liquid droplet injection amount of the liquid droplet injection unit is linked to the injection pressure of the dust injection unit.