KR101569583B1 - Apparatus for capturing moisture and dust - Google Patents

Abstract

And more particularly, to a moisture and dust collecting apparatus capable of effectively collecting fine dust and moisture present in the air by using a simple structure.
The apparatus for collecting moisture and dust according to the present invention comprises a plurality of elimers formed along a moving direction of a fluid and spaced apart from each other in a thickness direction thereof, A plurality of main plates protruding from the main plate to extend the movement distance of the fluid and an auxiliary plate bent at an end of the main plate.

Description

[0001] APPARATUS FOR CAPTURING MOISTURE AND DUST [0002]

The present invention relates to a water and dust collecting apparatus, and more particularly, to a water and dust collecting apparatus capable of discharging dust and moisture-free air by collecting fine dust and moisture present in the air.

Generally, in most industrial sites, dust is inevitably generated in the course of processing. Such dust is scattered into the air in the atmosphere, which not only harms the health of workers but also causes pollution of the environment.

It is common to use a dust collector to remove dust introduced into the air. When air containing dust is passed through the dust collector, only the dust is selectively removed and air is discharged separately.

However, in certain industrial sectors, not only dust but also moisture may be generated at the same time during the process. This moisture is not filtered by a dust collector, so it is common to install an additional water removal device.

Hereinafter, the finishing rolling process of a steel mill is described as a representative example to help understand the explanation.

During the operation of the hot rolling mill, an electrostatic precipitator is used to remove the dust generated in the finishing mill. The electrostatic precipitator removes the dust introduced into the air by using the corona discharge. At this time, water is sprayed to separate the dust and air collected by the electrostatic precipitator. The water particles are also moved together with the air by the blower which is a driving force for moving the air.

In addition, dust is not completely removed from the air passing through the electrostatic precipitator, and a small amount of dust is left. Such a small amount of dust and moisture are moved together.

If the dust and moisture-inflowing air is discharged to the outside of the plant as it is, it will not only cause environmental pollution, but also become a main cause of freezing the surrounding roads in the winter season. There is a problem that it is scattered to the outside.

A solution for solving such a problem is specifically known in the prior art "Eliminator structure of absorption refrigerator (Patent No. 10-0522201)" and "Eliminator (Patent No. 10-0623926)".

In the conventional "Elasticator structure of absorption type refrigerator (Patent Document 10-0522201)", a structure of an eliminator of an absorption type refrigerator having a plurality of blades arranged at regular intervals to provide a refrigerant vapor flow path has been proposed.

The absorption structure of this absorption type refrigerator has a structure in which a blade is formed at one side corresponding to the flow direction of the refrigerant vapor to introduce the refrigerant vapor and a droplet receiver is formed at a lower portion of the droplet hole and the blade for separating relatively heavy moisture And stores the moisture separated from the refrigerant vapor.

However, the initial refrigerant and refrigerant vapor will be filtered during the passage through the blades, but as the pressure of the refrigerant vapor increases over time, the refrigerant vapor as well as the refrigerant air will increase as the pressure increases. There is a problem that air is flowed and discharged to the outside air through the blower.

In addition, in the conventional "Eliminator (Patent No. 10-0623926)", the cooling towers, the air conditioner, the air cleaner, and the like are circulated and the fine foreign substances in the air are firstly filtered, And an eliminator capable of preventing fugitive emission is proposed.

Such an eliminator is formed so as to have a double V-shaped cross section, and the electromagnet itself is formed of a double wall body having a space and a rib in the inside thereof, so that not only the strength of the electromagnet can be greatly enhanced, It is possible to efficiently separate moisture from the air circulated or discharged by the blowing fan without forming a separate protruding structure on the inner and outer sides of the mineralizer and to prevent the water from splashing out and from splashing out from the water collecting tank Respectively.

However, since there is no step at the rib formed on the inner side of the eliminator, there is a problem that refrigerant liquid, refrigerant vapor, and dirty water flowing into the inner side of the eliminator are discharged to the outside air as they are along the rib.

Korean Patent No. 10-0522201 (October 10, 2005) Korean Patent No. 10-0623926 (September, 2006)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a water and dust collecting apparatus capable of effectively collecting fine dust and moisture present in air using a simple structure.

To achieve these and other advantages and in accordance with the purpose of the present invention, as embodied and broadly described herein, there is provided an apparatus for collecting moisture and dust, comprising: a plurality of eliminators formed along a moving direction of a fluid and spaced apart from each other in a thickness direction; A plurality of main plates protruding in the direction of the eliminator opposite to each other in each of the elimers to extend a moving distance of the fluid; And an auxiliary plate bent at an end of the main plate, wherein the auxiliary plate includes: a first auxiliary plate bent in the inflow direction of the fluid at an end of the main plate; The first auxiliary plate is bent in the main plate to form a first collecting chamber in the inflow direction of the fluid to delay the movement of the fluid, And the second auxiliary plate is bent at the main plate to form a second collecting chamber in a moving direction of the fluid to generate a swirling phenomenon of the fluid.

And the plurality of main plates are provided in a direction perpendicular to the longitudinal direction of the electromagnet.

And the plurality of main plates are spaced apart at equal intervals.

And each of the main plates adjacent to each other in the direction opposite to each other along the thickness direction of the electromagnet is provided so as to cross at equal intervals.

The length of the main plate is formed to be equal to or more than half the distance between the mutually facing and spaced-apart eliminators.

The auxiliary plate may be bent at an end of the main plate in an inflow direction of the fluid, and may be positioned horizontally with the eluent.

The auxiliary plate may be bent at an end of the main plate in a moving direction of the fluid, and may be horizontally positioned with respect to the elastic member.

The length of the auxiliary plate may be less than a half of a distance between the main plates facing each other in the longitudinal direction of the elevator.

And the surfaces of the above-mentioned elevator, main plate and auxiliary plate are all coated with a hydrophilic material or a hydrophobic material.

delete

The present invention has the following various effects.

First, the present invention can maximize the effect of removing moisture and dust by increasing the flow path of the introduced air.

Second, the present invention increases the area and probability of contact with moisture, thereby effectively removing moisture and dust.

Third, the present invention is simple in construction, and maintenance cost is reduced.

Fourth, the present invention prevents dust from remaining on the surface, and maintenance is easy.

1 is a plan view of a water and dust collecting apparatus according to the present invention,
2 is an enlarged view showing a fastening state according to the present invention,
3 is an enlarged view of another example according to the present invention,
4 is a perspective view of a moisture and dust collecting apparatus according to the present invention.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings, and the same reference numerals will be applied to the constituent elements described in the background art unless otherwise specified.

The description of the water and dust collecting apparatus of the present invention described below is a preferred embodiment of the present invention and is not limited to the embodiments but can be implemented in various forms.

1 and 4, the apparatus for collecting moisture and dust according to an embodiment of the present invention includes an eliminator 100, a main plate 200, and an auxiliary plate 300.

The eliminator 100 is elongated along the moving direction of the fluid, and a plurality of the eleniators 100 are provided so as to face each other along the thickness direction thereof. The fluid containing moisture and dust (hereinafter referred to as " air " for the sake of convenience of explanation) passes between the mutually opposing eliminators 100, and when the eliminator 100 is in contact with air, The contained water condenses on the (100) surface of the eliminator to form water droplets.

The water droplet adhering to the surface of the eliminator 100 adsorbs the dust contained in the air, the dust trapped in the water droplet can no longer move along the fluid, and falls along the surface of the eliminator together with water droplets.

Some of the water turned into water droplets fall along the surface as soon as they are attached to the eliminator 100, but others are not permanently attached to the surface. However, as time passes, the amount of dust adsorbed and the amount of condensed water increase, eventually dropping along the surface by self weight.

The phenomenon that the moisture is condensed and changes into water droplets is caused by the temperature difference between the air and the eliminator 100. According to the circumstances to which the present invention is applied, a separate cooling water or heater is employed to effectively generate the temperature gradient phenomenon It will be possible.

Since the length of the eliminator 100, which is elongated along the moving direction of the fluid, has a predetermined length, thickness, and width, the total length of movement of the air introduced into the eliminator 100 varies depending on the length of the eliminator 100, The length of the eliminator 100 is appropriately adjusted according to the situation.

In addition, since the total distance of condensed water falling according to the width of the eliminator 100 and the total amount of air that can be introduced into the eliminator 100 at a time are also different, this is also adjusted appropriately according to the situation.

A plurality of main plates 200 are protruded in the direction of the electromagnet 100 opposite to each other on the side surfaces of the sides of each of the electromagnets 100. The main plate 200 is connected to the electromagnet 100 The distance traveled by the air introduced into the space 100 increases.

That is, the air that vertically moves from the inlet to the outlet of the eliminator 100 is moved in a zigzag shape by the main plate 200, so that the moving distance increases exponentially.

When the main plate 200 and the air are in contact with each other, the water contained in the air is condensed due to the same principle as the above-described eliminator 100, thereby forming water droplets.

By increasing the moving distance of the air by providing the main plate 200, the area and probability of contact between the main plate 200 and the eliminator 100 and the air are increased. As a result, And the dust can be effectively removed.

In order to maximally increase the moving distance of the air within the limited space, it is preferable that the shape of the main plate 200 is formed in a direction perpendicular to the longitudinal direction of the eliminator 100.

In addition, it is preferable that the distance between the plurality of main plates 200 positioned to be spaced apart from each other so as to minimize the resistance when the air moves is formed to be constant, The moving direction of the air moving along the main plate 200 is uniform and the main plates 200 adjacent to each other in the direction opposite to the thickness direction of the electromagnet 100 in order to minimize the resistance 200 may be provided at an equal interval.

At this time, the length of the main plate 200 is set so that the inflow air moves in a zigzag shape and is spaced apart from the main plate 200 in order to maximize the area and probability of contact with the eliminator 100 and the main plate 200. [ Is preferably formed to be smaller than the space between the minuters (100) and at least half the space therebetween.

2, the auxiliary plate 300 may be bent at the end of the main plate 200 so that the condensed water can be agglomerated. (Hereinafter, 300 will be described as a first sub-plate 310 and a second sub-plate 320.)

The auxiliary plate 300 includes a first auxiliary plate 310 and a second auxiliary plate 320. The first auxiliary plate 310 is bent along the inflow direction of the air at the end of the main plate 200 The amount of the air flowing without contacting the main body 100 and the main body 100 can be drastically reduced in the whole air by being positioned horizontally with the eliminator 100.

That is, since the air that travels linearly along the main plate 200 meets and contacts the first auxiliary plate 310 formed in a direction perpendicular to the main plate 200, the first and second auxiliary plates 310 and 320 are bent and flow, Most of the air that has not contacted with the first auxiliary plate 310 comes into contact with the first auxiliary plate 310.

A first collecting chamber 410 is formed between the first auxiliary plate 310 and the main plate 200 so that air can not flow linearly. The water droplet that has been attached to the main plate 200 and then moved on the surface of the main plate 200 in accordance with the flow of air without dropping is attached to the first and second collecting chambers 420, The dust collecting chamber 410 is not allowed to advance any more and it flocculates due to its own weight. In the first collecting chamber 410, the amount of water droplets and the number of the water droplets are relatively larger than other portions.

At this time, it is preferable that not only the first auxiliary plate 310 but also the second auxiliary plate 320 is further provided at the end of the main plate 200.

The second auxiliary plate 320 is bent along the air moving direction at the end of the main plate 200 and horizontally positioned with respect to the elevator 100 so that the air that has moved along the first auxiliary plate 310 The contact area between the second auxiliary plate 320 and the second auxiliary plate 320 is increased and the condensed water droplet continuously moves along the air flow It has the effect of blocking things.

The second collecting chamber 420 is formed between the second auxiliary plate 320 and the main plate 200 and the second collecting chamber 420 is formed between the second auxiliary plate 320 and the second auxiliary plate 320, The air is temporarily trapped in the second collection chamber 420 by the vortex phenomenon. That is, the time and area in which the moving air is in contact with the main plate 200 and the second auxiliary plate 320 by the second collecting chamber 420 is increased, thereby effectively removing moisture and dust.

The first auxiliary plate 310 and the main plate 200 may be perpendicular to each other in the embodiment of the present invention. However, as shown in FIG. 3, As shown in FIG.

By providing the first auxiliary plate 310 so as to have a predetermined inclination, it is possible to increase the time taken for the introduced air to pass through the first collecting chamber 410, 1 can be effectively prevented from moving along the surface of the auxiliary plate 310.

 The lengths of the first and second auxiliary plates 310 and 320 are equal to or less than half the distance between the main plates 200 facing each other in the longitudinal direction of the electromagnet 100 .

That is, the interval between the first main plate 200 and the second main plate 200 is less than half of the interval between the first main plate 200 and the second main plate 200, When the length of the second auxiliary plate 320 and the second auxiliary plate 320 exceeds a half of the length of the auxiliary plate 320, the resistance of the air moves greatly and adversely affects the flow rate of the air, The people are also reduced.

On the other hand, it is preferable that the surfaces of the eliminator 100, the main plate 200, and the auxiliary plate 300 are coated with a hydrophilic material.

The hydrophilic material is coated on the surfaces of the eliminator 100, the main plate 200, and the auxiliary plate 300 to increase the amount of water adhering to each surface (increase the water removal effect) It is possible to maximize the adsorption rate of the dust by keeping it without falling easily.

Such hydrophilic materials include TiO ₂ , SiO ₂ , polyethylene glycol, polyvinyl alcohol, polyvinyl acetate and the like.

It is also possible to coat hydrophilic materials on the surfaces of the eliminator 100, the main plate 200, and the auxiliary plate 300.

By coating a hydrophobic material on the surfaces of the eliminator 100, the main plate 200 and the auxiliary plate 300, moisture adhering to the respective surfaces is quickly dropped without remaining, and accordingly, It is possible to prevent the surface from being contaminated even with the use of time. That is, the process of periodically cleaning the apparatus according to the present invention can be omitted.

Since most polymer materials have hydrophobicity, they can be coated with a polymer material to make them hydrophobic, or they can be surface-treated by using plasma or the like to make them hydrophobic.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited to the disclosed exemplary embodiments. It will also be appreciated that many modifications and variations will be apparent to those skilled in the art without departing from the scope of the present invention.

100: Eliminator 200: Main plate
300: auxiliary plate 310: first auxiliary plate
320: second auxiliary plate 400: collecting chamber
410: first collecting chamber 420: second collecting chamber

Claims (10)

A plurality of elimers formed along the moving direction of the fluid and spaced apart from each other in the thickness direction;
A plurality of main plates protruding in the direction of the eliminator opposite to each other in each of the elimers to extend a moving distance of the fluid; And
And an auxiliary plate bent at an end of the main plate,
The auxiliary plate includes a first auxiliary plate bent in a direction of the fluid flowing in the end of the main plate and a second auxiliary plate bent in a direction of movement of the fluid at an end of the main plate, ,
The first auxiliary plate is bent in the main plate to form a first collecting chamber in the inflow direction of the fluid to delay fluid movement. The second auxiliary plate is bent in the main plate, And a dust collecting device for forming a collecting chamber to generate a swirling phenomenon of fluid.
The method according to claim 1,
Wherein the plurality of main plates are provided in a direction perpendicular to the longitudinal direction of the eliminator.
The method of claim 2,
Wherein the plurality of main plates are spaced apart at equal intervals.

The method of claim 3,
Wherein the main plates adjacent to each other in the direction opposite to each other along the thickness direction of the electromagnet are provided at equal intervals.
The method of claim 4,
Wherein the length of the main plate is formed to be equal to or greater than half the distance between the mutually facing and spaced eliminators.
The method of claim 5,
Wherein the auxiliary plate is bent in an inflow direction of the fluid at an end of the main plate, and is positioned horizontally with the eliminator.
The method according to claim 5 or 6,
Wherein the auxiliary plate is bent in a moving direction of the fluid at an end of the main plate, and is positioned horizontally with the eliminator.
The method of claim 7,
Wherein the length of the auxiliary plate is less than half the distance between the main plates facing each other in the longitudinal direction of the elastic member.
The method of claim 8,
Wherein the surfaces of the elevator, the main plate, and the auxiliary plate are all coated with a hydrophilic material or a hydrophobic material.
delete

Images