KR101180038B1 - Electrical precipitator including honey comb filter have multi-helix pin ionizer - Google Patents

Abstract

The present invention relates to an electrostatic precipitator including a honeycomb dust collecting unit having a multi-helix spin ionizer, and more particularly, to an electrostatic precipitating device including a plurality of dust collecting tubes. Electrostatic precipitator having a projection plate-type ionizer exhibits considerable dust collection efficiency at high flow rates, but at a low flow rate, a relatively low dust collection efficiency problem. It is formed by forming a plurality of secondary projections on both sides, and formed on both ends at the connecting portion, and to solve through a multi-helix spin ionizer of the twisted structure to provide centrifugal force to the object to be collected, Through this technical feature, the present invention is similar at high flow rate as well as low flow rate. It has the effect of exerting a dust collection efficiency, and the above-mentioned effect shows a constant dust collection efficiency without changing the dust collection efficiency in the place where the flow velocity is high, as well as the flow rate is slow or the flow rate changes a lot, the gas with a relatively high efficiency It is effective to purify, and it is not necessary to install many electric dust collectors according to the flow rate when building facilities for air purification in buildings, plants, subway stations, tunnels, etc. There is an effect that can be, and furthermore, there is an energy saving effect to reduce the energy consumption of operating the air purification equipment.

Description

ELECTRICAL PRECIPITATOR INCLUDING HONEY COMB FILTER HAVE MULTI-HELIX PIN IONIZER}

The present invention relates to an electrostatic precipitator for purifying a gas by applying an electric field to a collecting object suspended in a gas such as air, and collecting the charged collecting object with electrostatic force, in particular, the charged collecting. The present invention relates to an electrostatic precipitator having a honeycomb dust collector, in which a dust collector for collecting an object has a hexagonal tube shape and an ionizer for inducing a corona discharge is located therein.

Briefly describing the electrostatic precipitating method, as shown in the drawings for explaining the precipitating principle of the electrostatic precipitator, charges such as dust, dust, and water particles, which are collected in the contaminated gas, are charged. In addition, a coulomb force (electrostatic force) is generated in the direction of the collecting electrode to collect the charged particles.

An electrostatic precipitator using this principle typically generates an electric field by a high voltage applied to a discharge electrode, and then generates a corona discharge, a phenomenon in which a strong electric field is conductive by a high voltage between two electrodes, thereby causing a discharge around the discharge electrode. The generation and movement of charges takes place, thereby charging dust and the like. The charged dust and the like are subjected to the force by the Coulomb force generated in the direction of the dust collecting electrode in the electric field, and is collected by being attracted to the dust collecting electrode and attached to the surface by the Coulomb force.

The conventional electrostatic precipitator using the electrostatic precipitating principle has the following problems.

When the polluted gas passes through the electrostatic precipitator at high speed, the dust collection efficiency of particulate contaminants drops drastically. Whenever the flow rate of 1m / s at the limit flow velocity increases, the dust collection efficiency is about 5 ~ 10%, there is a problem, another problem is the limitation in maintaining the dust collection efficiency in the structure of the charging unit.

In general, the electrification part of the electrostatic precipitator uses a wire method and a saw method. However, when the gas flows at a high speed, the reaction structure area is small, so it is relatively limited to charge the collecting target. can not do it. In addition, a dust collector that adsorbs particulate matter generally uses an alternating plate and a stainless plate, which are limited in collecting and storing particulate contaminants in the form of a plate, and inefficient voltage. The efficiency is very low compared to the use of a lot of power consumption, there is a problem in that a large amount of combined plate structure to form a large amount of particulate contaminants in the form of a plate.

In addition, the conventional electrostatic precipitator has a structure in which a charging unit for charging particulate contaminants and a dust collecting unit for adsorbing and storing charged particulate contaminants are arranged in series, so that particulate contaminants pass through the charging unit. If the flow rate is high or the flow rate is not maintained, the particulate contaminants do not have sufficient charge, and thus there is a problem in that the efficiency does not decrease because sufficient Coulomb force does not occur.

In addition, since the charging unit is disposed at the front of the dust collecting means based on the direction in which the gas flows, it has a structure that can be used only in one direction. Therefore, the air can flow in both directions only when the air flows in a certain direction. There was a problem that can not be used.

In order to solve such a problem, the prior art Patent Application No. 10-2007-0085870 "bidirectional high-speed electric dust collector having an inner diameter corrugated dust collecting tube" has been disclosed.

The prior art has a plurality of dust collecting pipes (10) for collecting dust, which is referred to as a "honeycomb dust collecting part" 100, as shown in the figure for explaining the dust collecting principle of the electric dust collecting device including a conventional honeycomb dust collecting part (10) ) Is configured to combine in parallel.

In addition, an ionizer 20 positioned at the center of each dust collecting pipe 10 constituting the honeycomb dust collecting part 100 to generate a corona discharge to charge the collecting target 1, as shown in FIG. 2. The circuit is connected to the high voltage supply means 30 as well.

In particular, Figure 3 is a rotating projection plate-type ionizer 20 of the twisted structure to provide a centrifugal force to the collecting object (1) as shown in the figure showing a conventional rotary honeycomb dust collecting device including a dust collector. It is a technical feature.

Thus, the use of an electrostatic precipitator may be used in facilities such as a booster fan of a tunnel having a high flow rate and a ventilation opening of a subway station flowing in both directions.

Such a prior art is a strong vortex is generated by the rotary projection plate type ionizer 20 in a place where the flow velocity is high, such a strong vortex can provide a centrifugal force to the collecting target to increase the dust collection efficiency of the electrostatic precipitator relatively. There is an advantage.

However, in the place where the flow rate is severely changed or the flow rate is slow, sufficient vortices such as centrifugal force do not occur in the collecting object, so in this case, the centrifugal force does not work enough for the collecting object. There is a problem that the dust collection efficiency falls.

The present invention was devised to solve the above problems, and the electric dust collecting part collecting the charged collecting target as in the prior art has a honeycomb dust collecting part formed in a hexagonal tube shape and an ionizer inducing a corona discharge therein. An object of the present invention is to provide an electrostatic precipitator having a honeycomb dust collector which exhibits similar dust collection efficiency at high flow rate as well as low flow rate by improving the structure of the ionizer of the dust collector.

In addition, it is an object of the present invention to provide an electrostatic precipitator that exhibits a constant dust collection efficiency without changing the dust collection efficiency, even where the flow rate is high, as well as the flow rate is slow or the flow rate is severe.

Electrostatic precipitating device including a honeycomb dust collecting unit having a multi-helix spin ionizer of the present invention proposes the following technical features as a solution for achieving the above object.

The center of each dust collecting tube forming the honeycomb dust collecting unit is coupled to a honeycomb dust collecting unit and a power supply support which are coupled to a plurality of hexagonal tube-shaped dust collecting tube having a predetermined length in parallel and electrically grounded. An electrostatic precipitator comprising: an ionizer positioned at and configured to cause corona discharge; and a high voltage supply means connected to the power supply support circuit and providing a high voltage to the ionizer.

The ionizer is a metal plate that is relatively longer than the dust collecting tube and forms a plurality of primary protrusions on both edges in the longitudinal direction, a plurality of secondary protrusions on both sides, and formed at both ends at connection ends. It is characterized in that the multi-helix spin ionizer twisted structure to provide a centrifugal force.

In addition, the secondary protrusion of the multi-helix spin ionizer is formed by cutting the body of the multi-helix spin ionizer into a protrusion shape and bending it.

In addition, the multi-helix spin ionizer has a width of 1/3 to 1/2 compared to the diameter of the dust collecting tube for the generation of vortex, and the height of the primary and secondary protrusions 1 compared to the diameter of the dust collecting tube / 10 to 1/8; characterized by the.

In addition, each of the dust collecting tube is made of aluminum material corrugated dust collecting tube formed with a plurality of grooves in the longitudinal direction in the longitudinal direction for increasing the dust collecting area.

In addition, the honeycomb dust collecting unit further wraps and insulates the entire outside, and at the same time to maintain the assembled state of the plurality of dust collecting pipes and a finish insulating layer closed the outside with a predetermined thickness to a predetermined thickness.

According to the present invention, an electrostatic precipitator having a honeycomb dust collecting unit having an ionizer in which a dust collecting unit collecting a charged collecting target charged through a technical feature as described above is formed in a hexagonal tube and causing corona discharge is located at a high flow rate as well as a low flow rate. There is an effect that can exhibit a similar dust collection efficiency.

In addition, there is an effect that can purify the gas at a relatively high efficiency by exhibiting a constant dust collection efficiency without changing the dust collection efficiency, even in a place where the flow rate is fast, as well as a slow flow rate or a severe change in the flow rate.

In addition, there is no need to install a large number of electrostatic precipitators required according to the flow rate when building facilities for air purification in buildings, plants, subway stations, tunnels, etc. Furthermore, there is an energy saving effect to reduce the energy consumption of operating the air purification plant.

1 is a view for explaining the dust collecting principle of the electrostatic precipitator;
2 is a view for explaining the dust collecting principle of the conventional electrostatic precipitator including a honeycomb dust collector;
Figure 3 is a view showing a rotary projection plate-type ionizer of the conventional electrostatic precipitator including a honeycomb dust collector,
4 is a view for conceptually illustrating an electrostatic precipitator including a honeycomb dust collector having a multi-helix spin ionizer according to the present invention;
5 is a view for explaining a multi-helix spin ionizer of the electrostatic precipitator including a honeycomb dust collector having a multi-helix spin ionizer of the present invention;
6 is a view for explaining a corrugated dust collector of an electrostatic precipitator including a honeycomb dust collector having the present invention multi-helix spin ionizer;
7 is a view for explaining a honeycomb dust collector of the electrostatic precipitator including a honeycomb dust collector having a multi-helix spin ionizer of the present invention.

The following detailed description of the invention refers to the accompanying drawings, which illustrate, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the present invention with respect to one embodiment. In addition, it is to be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. The following detailed description, therefore, is not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims, along with the full scope of equivalents to which such claims are entitled. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily implement the present invention.

Electrostatic precipitating device including a honeycomb dust collecting unit having a multi-helix spin ionizer of the present invention is applicable to facilities for air purification, such as buildings, plants, underground facilities, subway stations, tunnels, etc. It can be installed and operated in various places, and the external shape can be modified according to the installation place, and various accessory devices such as a high speed fan, a dust recovery device, and a cleaning device can be combined as necessary.

For example, when the apparatus according to the present invention is coupled to a cylindrical booster fan provided in a tunnel, the present invention is a cylindrical shape of the outer enclosure, and coupled to or separated from the booster fan to remove collected dust and the like. It further comprises a coupling means configured to be possible, and further comprises a fixed support for coupling with the tunnel ceiling.

In addition, when the apparatus according to the present invention is coupled to the box-shaped ventilation opening of the subway station in which the direction of air flow is two-way, the outer box has a rectangular tube shape so as to be inserted into the box-shaped ventilation opening of the subway station, the entry and exit to the box-shaped ventilation opening It further comprises an insertion means for enabling it.

4 is a view for conceptually illustrating an electrostatic precipitator including a honeycomb dust collector having a multi-helix spin ionizer according to the present invention. As shown in FIG. 4, the present invention basically includes a honeycomb dust collecting part 100, a multi-helix spin ionizer 200, a high voltage supply means 30, and a power supply support 40.

The honeycomb dust collecting part 100 is composed of a honeycomb dust collecting part 100 by combining a plurality of hexagonal pipe-shaped dust collecting tube 10 having a predetermined length in parallel with a metal material having high electrical conductivity such as aluminum, and the honeycomb dust collecting part 100. 100 is electrically grounded.

At this time, the honeycomb dust collecting part 100 is a honeycomb dust collecting part 100 of the electrostatic precipitator including a honeycomb dust collecting part having the present invention multi-helix spin ionizer, the honeycomb dust collecting part 100 is a finishing insulating layer It is preferable to further include (110).

The finishing insulating layer 110 is formed of a predetermined thickness on the entire outer surface of the honeycomb dust collecting part with a synthetic resin such as a non-combustible silicon-based adhesive material, and a plurality of the insulation insulating layer 110 with the function of covering the entire outside of the honeycomb dust collecting part 100. The dust collecting tube 10 serves to maintain the assembled state of the honeycomb dust collecting unit assembled.

The dust collecting tube 10 constituting the honeycomb dust collecting part 100 is made of a metal material that is well energized, such as an aluminum metal material, and has a regular hexagonal cross section thereof. This is to prevent the empty space when the dust collector is configured by combining a plurality of dust collectors 10 in parallel as shown in FIG.

In addition, the dust collecting tube 10 is shown in Figure 6 for explaining the corrugated dust collecting tube of the electrostatic precipitator including a honeycomb dust collecting unit having a multi-helix spin ionizer of the present invention to increase the inner diameter of the dust collecting area. It is characterized in that the corrugated dust collector (10-1) formed a plurality of grooves 11 in the longitudinal direction on the surface.

That is, the corrugated dust collecting tube 10-1 has a plurality of grooves 11 having a predetermined depth in the flow direction (length direction) of the fluid on the inner diameter surface thereof, so that the dust collecting tube 10 having no groove 11 is relatively present. Compared to), the area of the inner diameter surface is increased and the dust collection area is increased due to the increase of the area of the inner diameter surface, which increases the dust collection efficiency.

The multi-helix spin ionizer 200 is a core configuration of the present invention in Figure 5 to explain the multi-helix spin ionizer of the electrostatic precipitator including a honeycomb dust collector having the present invention multi-helix spin ionizer. As shown in the drawing, a plurality of primary protrusions 210 are formed on both edges of the longitudinal direction with metal plates relatively longer than the dust collecting tube 10, and a plurality of secondary protrusions 220 are formed on both sides thereof. Both ends are formed in the connection portion 230, characterized in that the twisted structure to provide a centrifugal force to the object to be collected.

In this case, the secondary protrusions 220 may be formed by welding the metal pieces of the protrusion shape at predetermined intervals on both sides, or cutting the ionizer body into a protrusion shape and bending them.

The multi-helix spin ionizer 200 is inserted into each dust collecting tube 10 constituting the honeycomb dust collecting part 100 as shown in Figs. At this time, both ends of the connection portion 230 is exposed, and as shown in Figure 4 is coupled to the power supply support 40.

The power supply support 40 is made of a metal material with high electrical conductivity as shown in FIGS. 4 and 7 and is located in front and rear of the honeycomb dust collecting part and passes through the dust collecting tube 10 of the honeycomb dust collecting part. It is coupled to the Rickspin ionizer 200 to fix it, and is electrically connected to the high voltage supply means 30 to supply power to the plurality of multi-helix spin ionizers 200 coupled to the power supply support 40. Supply.

That is, the power supply support 40 is fixed to the multi-helix spin ionizer 200 and connected to the high voltage supply means 30 for supplying a high DC voltage of 11,000 volts or more.

At this time, the combination of the power supply support 40 and the multi-helix spin ionizer 200 is preferably to adjust the tension of the multi-helix spin ionizer 200 through a tension control means including a spring-like means. Do.

Such a shape of the power supply support 40 may be an assembly form of a vertical bar and a horizontal bar as shown in FIGS. 4 and 7, but is not necessarily limited thereto and may be variously modified as necessary.

The multi-helix spin ionizer 200 electrically connected through the power supply support 40 is charged with the high voltage applied from the primary protrusion 210 and the secondary protrusion 220 to be discharged by the corona discharge phenomenon. As a result, a charged area is formed, and neutral particles such as dust, dust, and moisture, which are contained in polluted air introduced from the outside, enter a charged area and are negative by collision or adsorption with an anionic gas molecule. Becomes a charged microparticle.

Accordingly, the multi-helix spin ionizer 200 further includes a secondary protrusion 220 as compared to the rotating protrusion plate ionizer of the prior art having only the primary protrusion of FIG. 3 to generate a relatively strong electric field around the ionizer. Form.

That is, the multi-helix spin ionizer 200 adds a plurality of secondary protrusions 220 that cause corona discharge to both sides in the longitudinal direction, thereby forming a corona region and a charged region as compared to the conventional ionizer having only primary protrusions. Relatively, thereby increasing the dust collection efficiency of the dust collector.

As a result, the flow rate is relatively low, so that even if sufficient centrifugal force does not occur in the object to be collected, the amount of charged charge is relatively increased, thereby allowing the Coulomb force to act relatively higher.

Referring to the structure of the multi-helix spin ionizer 200 in more detail, having a primary protrusion 210 and the secondary protrusion 220, given a rotational force for the gas flowing through a predetermined amount of vortex It has a width and has a twisted structure.

The width is 1/3 to 1/2 (D2) compared to the diameter of the dust collecting tube 10 for the generation of sufficient vortex and smooth gas flow, and the primary protrusion 210 and the secondary protrusion 220 The height is preferably 1/10 to 1/8 compared to the diameter of the dust collecting tube 10, and the number of twists is preferably one rotation (360 degrees), but may be two to three rotations as necessary.

Accordingly, the gas passing through the dust collecting tube 10 is rotated by the multi-helix spin ionizer 200 having a twisted structure, and the collecting target included in the rotating gas is charged and rotated at the same time.

In the above, the present invention has been described based on the preferred embodiments, but the technical idea of the present invention is not limited thereto, and modifications or changes can be made within the scope of the claims. It will be apparent to those skilled in the art, and such modifications and variations will belong to the appended claims.

1: target
2: charged target
10: dust collector
10-1: Corrugated Dust Collector
11: home
20: rotating projection plate type ionizer
30: high voltage supply means
40: power supply support
100: honeycomb dust collector
110: finishing insulation layer
200: Multi Helix Spin Ionizer
210: primary projection
220: secondary projection
230: connection area

Claims (5)

It is located in the center of each dust collecting tube forming the honeycomb dust collecting unit, which is electrically connected to the honeycomb dust collecting unit and the power supply support, which are electrically grounded by combining a plurality of hexagonal tube collecting tubes having a predetermined length in parallel. And an ionizer causing corona discharge; and a high voltage supplying means connected to the power supply support circuit to provide a high voltage to the ionizer and to surround and insulate the entire outside of the honeycomb dust collecting unit, and to assemble a plurality of dust collecting tubes. An electrostatic precipitator comprising: a finishing insulating layer finished with a synthetic resin to a predetermined thickness to maintain a state.
The ionizer is a metal plate that is relatively longer than the dust collecting tube, and the width is 1/3 to 1/2 of the diameter of the dust collecting tube, and a plurality of primary protrusions are formed on both sides of the metal plate in the longitudinal direction. In order to form a plurality of secondary projections, the height of the primary projections and secondary projections is 1/10 ~ 1/8 compared to the diameter of the dust collecting tube, both ends to form a connection portion to provide a centrifugal force to the object to be collected An electrostatic precipitator including a honeycomb dust collector having a multi-helix spin ionizer, wherein the multi-helix spin ionizer has a twisted structure. delete delete The method of claim 1, wherein each of the dust collecting pipes
An electrostatic precipitator including a honeycomb dust collector having a multi-helical spin ionizer, wherein the corrugated dust collector has a plurality of grooves formed in a longitudinal direction on an inner diameter surface thereof to increase the dust collecting area of the aluminum material. delete

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