KR101199552B1 - Induction electrical precipitator having honey comb electic charge part - Google Patents

Abstract

Induction voltage electrostatic precipitator having honeycomb charging unit of the present invention exhibits a dust collection efficiency of about 95 to 96% when the conventional induction voltage electrostatic precipitator is operated at 15,000 volts (V) in dust collection performance, but structurally higher dust collection efficiency The problem of difficulty in exerting efficiency and the problem of not exhibiting a constant dust collection efficiency in a place where the flow velocity is high or the flow rate change is very high. By forming a predetermined length in the flow direction, the collecting object can be sufficiently charged to increase the dust collection efficiency relatively, and the first collecting is performed at the honeycomb electric charging unit, and then the second collecting is performed at the dust collecting unit, thereby increasing the dust collecting efficiency relatively. It is a technical feature to increase.
Through the technical features as described above, the honeycomb charging unit having a relatively long charge section has an effect of improving the dust collection efficiency by 99% or more under the same voltage condition of 15,000 volts (V) compared to the conventional dust collector using the induced voltage. have. In addition, the dust collection efficiency does not decrease even in a place where the flow rate is high or the flow rate is severe, and it has an effect of providing a relatively high dust collection efficiency, and is collected first in the honeycomb electric field and then collected secondly in the dust collector. This has the effect of increasing the efficiency relatively.

Description

Induction voltage electrostatic precipitator with honeycomb charging unit {INDUCTION ELECTRICAL PRECIPITATOR HAVING HONEY COMB ELECTIC CHARGE PART}

The present invention is composed of a charging unit and a dust collecting unit to charge the dust by the corona discharge in the charging unit, the charged dust (electrical precipitator) is attracted to the dust collector by the Coulomb force is collected In particular, the dust collector is grounded, and relates to an induced voltage dust collector in which dust is collected by an induced voltage.

Briefly describing the electrostatic precipitating principle of the electrostatic precipitator, as illustrated in FIG. 1 for explaining the precipitating principle of the electrostatic precipitator, charges such as dust, dust, or water particles, which are collected in the contaminated gas, are charged. By virtue of this, a coulomb force (electrostatic force) is generated in the direction of the collecting electrode plate 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.

Electrostatic precipitator using the electrostatic precipitating principle is generally one-stage type and two-stage type, the one-stage dust collector is a discharge unit and the dust collector unit, and is called a Cotrell dust collector, which is the most common means of preventing air pollution. It is used as.

It is usually operated between 30,000V and 100,000V and is mainly installed in large industrial plants. In addition, the structure is simple and excellent dust collection performance has been widely used as an industrial dust emission prevention device to prevent the discharge of liquid and solid particles generated in various industrial plants.

Such single-stage dust collector is effective in preventing re-scattering because it repeatedly collects home appliances, but it is difficult to suppress reverse ionization, and a problem in that a high voltage is applied to the dust collecting electrode and a dust collecting ability is lost when the dust collecting electrode is discharged. There is a problem.

In addition, when the dust layer is collected to the dust collecting electrode to the thickness of about 8mm ~ 12.7mm, it is possible to continuously maintain the dust collecting capacity only by rapping the collected dust, so that a spraying device or a device that applies a mechanical shock or vibration is added. There is a problem that must be done.

If dedusting is not performed, reverse ionization occurs to neutralize charged dust, thereby greatly reducing dust collection performance, and the collected dust is also neutralized and re-spread.

The two-stage dust collector separates the discharge part and the dust collecting part and forms an electric field by the voltage difference between the discharge electrode of the discharge part and the dust collecting part of the dust collecting part, and when charged particles enter the electric field through the discharge part, the dust collecting part is discharged. It is collected by collecting it to the collecting electrode of.

Such a two-stage dust collector is mainly used for exhaust treatment having a relatively low concentration of dust because the discharge part, the dust collector and the electric field are separated, and there is a problem of discharging re- scattering dust as it is, but no reverse ionization occurs, and there is a relatively complicated structure. .

In order to solve the problems of the single-stage dust collector and the two-stage dust collector as described above, the prior art as shown in the drawings for explaining the configuration and basic principle of the electrostatic precipitator using the conventional induction voltage application No. 10-2005-0127542 A "electrostatic precipitator using induction voltage" has been disclosed.

As shown in FIG. 2, the protruding discharge electrode 10 is connected to a power source to receive charge at a high DC voltage of 11000 volts or more, and the charge applied at such a high voltage is applied at the protruding portion of the protruding discharge electrode 10. Charged and then discharged by the corona discharge phenomenon to form a charging region (A2).

The object to be collected 1, such as dust, dust or moisture, contained in the polluted air introduced from the outside is in an electrically neutral state, and the object to be collected in this neutral state 1 enters the charged region A2. Otherwise, it becomes a charged collection object 2 in a negative state by collision or adsorption with an anionic gas molecule in a neutral state.

The prior art further includes an induction voltage plate 20 which grounds the dust collecting electrode 30 and is independently present without electrical connection and generates an induced voltage induced by the protruding discharge electrode 10, and the dust collecting electrode 30 is collected. There is a technical feature of increasing the dust collection capability by forming an electrostatic field by installing between the 30 and adding a driving force to the charged dust attracted by the coulomb force to the grounded dust collecting electrode 30.

The prior art improves mechanical strength by replacing the conventional wire-shaped discharge electrode with the protruding discharge electrode 10 having a saw-like shape, and attaches charged dust to the dust collecting electrode 30 by grounding the dust collecting electrode 30. When the dust is neutralized and neutralized at the moment, the dust (3) is dropped by the gravity from the dust collecting electrode 30, the dust attached to the ground electrode by gravity without a separate dust removing means for removing the dust attached to the dust collecting electrode 30 It is possible to remove and easy maintenance, easy to assemble by simplifying the structure of the electric filter of the dust collector, there is an effect of reducing the manufacturing cost of the dust collector.

However, the electrostatic precipitator using the induced voltage exhibits an effect of improving the above problems compared to the single stage precipitator and the two stage precipitator, and when the dust collection performance is operated at 15,000 volts (V), it is about 95 ~. Although it exhibits a dust collection efficiency of 96%, there is a problem that it is difficult to exhibit a higher dust collection efficiency than the structural.

In particular, as shown in FIG. 2, the protruding discharge electrode 10 is vertically formed with respect to the direction in which air flows, so that the width of the charge region is relatively narrow, where the flow velocity of air is high, or the flow velocity of air. In the place where the change is severe, there is a problem that the dust collection efficiency is lowered due to the narrow charging region and insufficient charging of the collecting target.

The present invention has been made to solve the problems described above, and an object of the present invention is to provide an electrostatic precipitator using an induction voltage having a relatively improved dust collection efficiency under the same conditions as the conventional electrostatic precipitator using an induction voltage. An object of the present invention is to provide an electrostatic precipitator in which dust collection efficiency does not decrease even in a place where the flow rate is high or the flow rate is severe.

Solution to achieve the problem to be solved by the present invention as described above is as follows.

Induction voltage electrostatic precipitator using the honeycomb charging unit of the present invention is an electrostatic precipitator using an induction voltage, and is disposed in parallel with a direction in which air contaminated in a hexagonal tube shape of a metal material flows and is electrically grounded in a charge collecting tube in parallel. The charging unit assembly coupled to the plurality; and a metal plate relatively longer than the charging unit dust collecting tube to form a plurality of projections on both edges in the longitudinal direction, both ends to form a connection portion and twisted structure to provide a centrifugal force to the object to be collected A spin ionizer inserted into each of the collecting tubes and positioned at the center thereof, and positioned at the front and rear ends of the charging unit assembly and coupled with the connection portion of the spin ionizer to fix the spin ionizer and to be electrically connected to the power supply means. Honeycomb charging unit including; A plurality of dust collecting electrode plates electrically grounded in a plate shape of a metal material and disposed in parallel with the air flow direction, and disposed between the dust collecting electrode plates in a plate shape of a metal material and compared to the dust collecting electrode plate. A dust collecting part including a plurality of induction voltage plates protruding toward the honeycomb charging part and generating a voltage induced by the honeycomb charging part without an electrical connection; A housing including the honeycomb charging part and the dust collecting part and forming an appearance; And high voltage supply means electrically connected to the power supply support to provide a high voltage to the spin ionizer of the honeycomb charging unit.

In addition, the spin ionizer of the honeycomb charging unit is characterized in that formed a plurality of side projections in the longitudinal direction on both sides.

In addition, the spin ionizer has a width of 1/3 to 1/2 of the diameter of the charging unit dust collection tube for the generation of vortex, and the height of the projection to 1/10 to 1/8 of the diameter of the charging unit dust collection tube It is characterized by.

In addition, the charging unit assembly of the honeycomb charging unit is a non-combustible silicon-based material to wrap and insulate the entire outside and maintain the assembled state at the same time finish the outside to a predetermined thickness.

In addition, the dust collector is in communication with the lower portion of the lower housing and the dust collected in the dust collecting portion, etc., the collecting container for falling and stored by its own weight; characterized in that it further comprises;

Induction voltage electrostatic precipitator using the honeycomb electric charging unit of the present invention is capable of exhaust treatment with a relatively high dust concentration of the conventional induction voltage electrostatic precipitator, and has a high mechanical strength of the discharge electrode itself, and is grounded with an independent induction voltage plate without electrical connection. The dust collecting electrode plate has a simple structure and does not require a separate dust removing means such as a cleaning device or a chase device for removing the dust attached to the collecting electrode plate, thereby making it easy to maintain and further improve the electrical efficiency of the electric dust collecting device. The filter structure is easy to assemble and the manufacturing cost of the electrostatic precipitator is reduced, and the honeycomb charging unit with a relatively long charge section does not reduce dust collection efficiency even in a place where the flow rate is high or the flow rate is severe. There is an effect of providing a relatively high dust collection efficiency.

In addition, the first collecting in the honeycomb charging unit and the second collecting in the dust collecting unit thereafter has an effect of relatively increasing the dust collection efficiency.

1 is a view for explaining the basic principle of the electrostatic precipitator;
2 is a view for explaining the configuration and basic principles of the conventional electrostatic precipitator using an induced voltage,
3 is a view for explaining a characteristic configuration of the induction voltage electrostatic precipitator having the honeycomb charging unit of the present invention;
4 is a view for explaining the characteristics of the honeycomb charging unit of the induced voltage electrostatic precipitator having the honeycomb charging unit of the present invention;
5 is a view for explaining the characteristics of the charging unit assembly of the induced voltage electrostatic precipitator having the honeycomb charging unit of the present invention;
6 is a view for explaining an insulating layer of the charging unit assembly of the induction voltage electrostatic precipitator having the honeycomb charging unit of the present invention;
7 is a view for explaining the characteristics of the spin ionizer of the induced voltage electrostatic precipitator having the honeycomb charging unit of the present invention;
8 is a view for explaining the coupling structure of the spin ionizer of the induced voltage electrostatic precipitator having the honeycomb charging unit of the present invention;
9 is a view for explaining the housing of the induced voltage electrostatic precipitator having the honeycomb charging unit 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.

Technical characteristics of the induction voltage electrostatic precipitator having the honeycomb charging unit of the present invention is shown in FIG. 3 to explain the characteristic configuration of the induction voltage electrostatic precipitator having the honeycomb charging unit of the present invention. , The honeycomb charging unit 100 including the spin ionizer 120 and the power supply support 130, and the dust collecting unit 200 including the collecting electrode plate 210 and the induction voltage plate 220. The honeycomb charging unit 100 is disposed at the front end of the honeycomb charging unit 100 based on the inflow direction, and the dust collecting unit 200 is electrically grounded in a plate shape of a metal material and is installed in parallel with the air flowing direction. Located between the dust collecting electrode plate 210 and the collecting electrode plate 210 in the shape of a plate of a metal material and protrudes toward the honeycomb charging unit 100 as compared to the dust collecting electrode plate 210 without the electrical connection. It includes a plurality of induction voltage plate 220 for generating a voltage induced by the Nickel charging unit (100).

The dust collector 200 is disposed in series at the rear end of the honeycomb charging unit 100, and as shown in FIG. 3, the high voltage supply means 300 is electrically connected to the induction voltage plate 220. The honeycomb charging unit 100 is charged to a high voltage to cause an induction voltage of the negative electrode, and both grounded collecting electrode plates 210 are charged to the positive electrode by electrostatic induction and electrostatic discharge.

Therefore, an electric field is formed between the induction voltage plate 220 and each of the collecting electrode plates 210, and the charged object that flows into the electric field has an attractive force with the collecting electrode plate 210, and the induced voltage. Repulsive force acts on the plate 220 and accompanies the dust collecting electrode plate 210. At this time, the repulsive force and the attraction force is a force caused by Coulomb's law, and a detailed description thereof will be omitted.

Therefore, the collecting target contained in the contaminated air is sufficiently charged by the spin ionizer 120 which has a predetermined length in parallel with the flow of air while passing through the honeycomb charging unit 100 to cause corona discharge, Some charged collecting objects are collected in the honeycomb charging unit 100, and the charged collecting objects passing through the honeycomb charging unit 100 include a dust collecting unit 210 and an induction voltage plate 220. While passing through 200, the dust is collected on the electrode plate 210.

That is, the charged collecting target is first collected in the charging unit assembly 110-1 of the honeycomb charging unit 100, and the rest is collected secondarily in the dust collecting unit 200. As a result, in the present invention, both the honeycomb charging unit 100 and the dust collecting unit 200 perform a collecting function.

As described above, the honeycomb charging unit 100 and the dust collecting unit 200 are electrically connected to the high voltage supply unit 300 as illustrated in FIG. 3 to describe the housing of the induction voltage electrostatic precipitator having the honeycomb charging unit of the present invention. As shown in the drawings, it is installed in the enclosure 400 having a structure that can form the appearance of the present invention and can be inserted into the vent or exhaust port.

Such a housing 400 has a structure in which the lower portion of the housing 400 in which the dust collecting part 200 is located communicates downward, and is connected to the communication portion 410 of the housing 400 in the dust collecting part 200. The collected dust or the like is connected to the collecting container 500 which is dropped and stored by its own weight.

The collecting container 500 may have various shapes and structures. The collecting container 500 communicates with the inside of the housing 400 and has a structure that can be combined with and separated from the housing 400 as a means for storing a collecting object such as dust. .

Hereinafter, the honeycomb charging unit 100 which is a core configuration of the present invention will be described in more detail. The honeycomb charging unit 100 is characterized in that a part of the dust is made and provides a charge section parallel to the flow of air to achieve a sufficient charge on the object to be collected.

4 is a honeycomb charging unit 100 of the present invention honeycomb charging unit having a honeycomb charging unit, as shown in the drawing, the honeycomb charging unit 100 is a charging that assembled a plurality of charging unit dust collecting tube 110 in a plane A power supply which is inserted into each sub-assembly 110-1 and the charged dust collecting tube 110 to supply and supply power to the spin ionizer 120 and the spin ionizer 120 to form a charged region by generating a corona discharge. Characterized in that it comprises a supply support 130.

Through such a characteristic structure, a charge section parallel to the flow of air, that is, a horizontal charge section is provided, unlike a conventional vertical charge section, and collects some charged collecting targets through the folded charging part collecting pipe 110. .

The charging unit assembly 110-1 is shown in Figure 5 for explaining the characteristics of the charging unit assembly of the induced voltage electrostatic precipitator having the honeycomb charging unit of the present invention, the charging unit assembly 110-1 is Hexagonal tube-shaped tube using a metal material with high electrical conductivity, such as aluminum, has a predetermined length (L), and is located in parallel with the direction in which contaminated air flows, and a plurality of electrically charged dust collecting tubes 110 are electrically grounded. Combined and assembled in parallel. That is, as shown in FIG. 5, the plurality of charging unit dust collecting tubes 110 are assembled in a planar manner.

The length (L) of the charging unit dust collecting tube 110 is not particularly limited, but if the length (L) of the charging unit dust collecting tube 110 is longer, the dust collection performance is improved, while the energy consumption increases, so that the charging unit collecting pipe ( The length L of 110 is determined according to conditions such as the flow rate or the concentration of dust in the environment in which the electrostatic precipitator according to the present invention is installed.

In addition, as shown in FIG. 5, the charging unit assembly 110-1 is a non-flammable silicon-based material which insulates the entire outside and maintains the assembled state, and insulates the exterior with a predetermined thickness. Has a layer 140.

The insulating layer 140 insulates the grounded charging assembly 110-1 as shown in the drawing for explaining the insulating layer of the charging assembly of the induced voltage electrostatic precipitator having the honeycomb charging portion of the present invention. While maintaining the assembled state, and serves to fill the empty space generated between the outer side of the charging unit assembly 110-1 and the enclosure 400 due to the hexagonal tube shape.

The spin ionizer 120 is relative to the charged collector tube 110 as shown in FIG. 4 and FIG. 7 to explain the characteristics of the spin ionizer of the induced voltage electrostatic precipitator having the honeycomb charging unit of the present invention. A plurality of protrusions 122 are formed on both edges in the longitudinal direction by long metal plates, and both ends thereof form connection portions 126, and each of the charged collector tubes 110 has a twisted structure to provide a centrifugal force to a collecting object. Inserted and centered.

FIG. 8 illustrates a spin ionizer 120 between two fixed power supply supports 130 as shown in the drawing for explaining the coupling structure of the spin ionizer of the induced voltage electrostatic precipitator having the honeycomb charging unit of the present invention. By combining, it can be positioned in the center of the charging unit dust collecting tube 110, it is electrically connected through the high voltage supply means 300 and the power supply support 130.

As shown in FIG. 7, the spin ionizer 120 may further include a plurality of side protrusions 124 in the longitudinal direction on both sides thereof. The side protrusions 124 relatively increase the number of protrusions in which corona discharge occurs, so that the corona region and the charged region are relatively increased, so that the charge on the object to be collected can be made more smoothly.

The spin ionizer 120 as described above has a width of 1/3 to 1/2 compared to the diameter of the charging unit dust collecting tube 110 for the generation of vortices, and the height of the projections 122 and 124 is the charging unit collecting tube ( Compared to the diameter of 110) 1/10 ~ 1/8.

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 to be collected 2: charged target
3: neutralized dust 10: protruding discharge electrode
20: induction voltage plate 30: dust collecting electrode
100: honeycomb Daejeon 110: Daejeon dust collector
110-1: charging unit assembly 120: spin ionizer
122: projection 124: side projection
126: connection part 130: power supply support
140: insulating layer 200: dust collector
210: collecting electrode plate 220: induction voltage plate
300: high voltage supply means 400: enclosure
410: communication part 500: collecting container

Claims (4)

Non-combustible silicon that is placed in parallel with the direction of contaminated air in the shape of hexagonal tube of metal material and combines electrically charged ground collection pipes in parallel, wraps and insulates the entire exterior, and maintains the assembled state of the charging ground collection pipe. A charging unit assembly having a predetermined thickness outside of a series material; and a metal plate relatively longer than the charging unit dust collection tube, forming a plurality of protrusions on both edges in the longitudinal direction, and forming a connection site at both ends, and a centrifugal force on the object to be collected. It has a twisted structure to be inserted into each of the charged dust collecting tubes and is located at the center thereof. The width of the metal plate is 1/3 to 1/2 of the diameter of the charged dust collecting tubes for the generation of vortices, and the height of the projections is charged. Spin ionizer 1/10 to 1/8 of the diameter of the tube; and the spin ionizer located at the front and rear ends of the charging assembly The spin fixed ionizer in conjunction with the connection portion of the laser and at the same time the power supply support to electrically connect the power supply means; honeycomb charging zone comprising a; A plurality of dust collecting electrode plates electrically grounded in a plate shape of a metal material and disposed in parallel with the air flow direction, and disposed between the dust collecting electrode plates in a plate shape of a metal material and compared to the dust collecting electrode plate. A dust collecting unit including a plurality of induction voltage plates protruding toward the honeycomb charging unit and generating a voltage induced by the honeycomb charging unit without an electrical connection; A housing including the honeycomb charging part and the dust collecting part and forming an appearance; And a high voltage supply means electrically connected to the power supply support to provide a high voltage to the spin ionizer of the honeycomb electrification unit.
The honeycomb charged portion of the spin ionizer is formed with a plurality of side projections in the longitudinal direction on both sides; the induced voltage electrostatic precipitator having a honeycomb charged portion, characterized in that. delete delete The method of claim 1,
Induced voltage electrostatic precipitator having a honeycomb charging unit further comprises a; collecting tube for communicating with the lower part of the housing in which the dust collecting unit is located and the dust collected by the dust collecting unit is dropped by the own weight.

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