KR101199554B1 - Induction electrostatic precipitator using multi-cross pin ionizer - Google Patents

Abstract

Induction voltage electrostatic precipitator using the multi-cross pin ionizer 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. By improving the structure of the protruding discharge electrode with a structure having side protrusions, the corona area where the corona discharge is generated and the charge area where the charge is charged to the dust collecting object are improved compared with the conventional protrusion type discharge electrode. It is a technical feature to relatively increase the dust collection efficiency of the dust collector by increasing.
Through the technical features as described above, the induction voltage electrostatic precipitating device has a relatively high dust concentration, which enables the exhaust treatment, the mechanical strength of the discharge electrode itself, the effect of simplifying the structure, and dust collecting by gravity without a separate dust removing means. It is possible to remove the dust attached to the electrode, which is easy to maintain and reduce the manufacturing cost of the electrostatic precipitator, and improves the dust collection efficiency of the dust collector to 99% or more under the applied voltage of 15,000 volts (V). It works.

Description

INDUCTION ELECTROSTATIC PRECIPITATOR USING MULTI-CROSS PIN IONIZER}

The present invention is composed of a discharge electrode and a dust collector, the dust is charged by the corona discharge (charged) is a device called an electrostatic precipitator (ESP) is a dust collected by the Coulomb force is attracted to the dust collecting electrode (Electrostatic Precipitator: ESP) In particular, the dust collection electrode is grounded, and relates to an induced voltage dust collecting device is a dust collection by the induced voltage.

Briefly looking at the electrostatic precipitating principle of the electrostatic precipitator (ESP), as shown in the figure for explaining the basic principle of the electrostatic precipitator, the object to be collected, such as dust, dust or water particles contained in the contaminated gas By charging, a coulomb force (electrostatic force) is generated in the direction of the collecting electrode to collect the charged particles.

An electrostatic precipitator using the same principle typically generates an electric field by a high voltage applied to a discharge electrode, and then a charge around the discharge electrode by corona discharge, a phenomenon in which a strong electric field is conductive by a high voltage between two electrodes. The formation and transfer of charges takes place, thereby charging dust.

The charged dust is subjected to the force by the Coulomb force generated in the direction of the collecting electrode in the electric field, and is finally collected by being attracted to the collecting electrode and attached to the surface.

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 application number 10-2005-0127542 has been disclosed in the prior art "electrostatic precipitator using induction voltage".

The prior art further includes an induction voltage plate which grounds the collecting electrode and independently exists without electrical connection and generates an induced voltage induced by the protruding discharge electrode, and forms an electrostatic field by interposing the collecting electrode. And, there is a technical feature to increase the dust collection capacity by adding a driving force to the charged dust attracted by the Coulomb force to the ground dust collecting electrode.

The prior art improves the mechanical strength by replacing the conventional wire-shaped discharge electrode with a projection type discharge electrode having a saw-like shape, and neutralizes the dust by neutralizing the moment when the charged dust adheres to the dust collecting electrode by grounding the dust collecting electrode. It is easy to maintain and remove dust attached to the ground electrode by gravity without separate dust removing means for removing dust attached to the dust collecting electrode by falling by gravity from the electrode. Simplification is easy to assemble, there is an effect to reduce the manufacturing cost of the electrostatic precipitator.

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.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an electrostatic precipitator using an induction voltage with improved dust collection efficiency under the same conditions as compared to the conventional electrostatic precipitator using induction voltage.

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

Induction voltage electrostatic precipitator using the multi-cross pin ionizer of the present invention is connected to a high voltage one or more projections having a predetermined length in the shape of a saw having a predetermined length to charge the fine particles by corona discharge in the longitudinal direction And a discharge electrode disposed at a rear end of the protruding discharge electrode and disposed in parallel with the protruding discharge electrode between the dust collecting electrode and the dust collecting electrode which collect charged microparticles in series. An electrostatic precipitator using an induced voltage, comprising: a dust collecting part including a plate-shaped induction voltage plate generating a voltage induced by the protruding discharge electrode without a connection, wherein the protruding discharge electrode causes corona discharge on both sides. Characterized in that the multi-cross pin ionizer formed a plurality of side projections in the longitudinal direction do.

At this time, the side protrusion of the multi-cross pin ionizer is formed by cutting the main body of the protruding discharge electrode into a protrusion shape and bending it.

In addition, the multicross pin ionizer forms a coupling hole on the upper side and the lower side, the power supply support for coupling the coupling hole to secure and electrically connect the multicross pin ionizer; characterized in that it further comprises a.

Induction voltage electrostatic precipitator using the multi-cross pin ionizer of the present invention is capable of performing exhaust treatment with a relatively high dust concentration of the conventional induction electrostatic precipitator, increasing the mechanical strength of the discharge electrode itself, and an independent induction voltage plate without electrical connection. The structure is simple with the grounded dust collecting electrode, and the grounding electrode is grounded to neutralize the charged dust when it is attached to the dust collecting electrode, so that the neutralized dust falls by the gravity from the dust collecting electrode to remove the dust attached to the dust collecting electrode. It is possible to remove the dust attached to the dust collecting electrode by gravity without separate dust removing means such as the cleaning device or the chase device for easy assembly and assembly of the electric filter structure of the electrostatic precipitator. With the effect of easy and reduced manufacturing cost of the electrostatic precipitator, By improving the structure of a conventional projection-type discharge electrode through the technical features of the present invention it has the effect of improving the dust collecting efficiency of the dust collector with more than 99% under an applied voltage of 15,000 volts (V).

1 is a view for explaining the basic principle of the electrostatic precipitator.
2 is a view for explaining the basic principle of the electrostatic precipitator using an induced voltage,
3 is a plan view illustrating the basic principle of the electrostatic precipitator using an induced voltage;
4 is a view showing a multicross pin ionizer of an induction voltage electrostatic precipitator using the multicross pin ionizer of the present invention;
5 is a view showing an embodiment of a multi-cross pin ionizer of the induced voltage electrostatic precipitator using the multi-cross pin ionizer of the present invention;
6 is a view for explaining the coupling form of the multi-cross pin ionizer of the induced voltage electrostatic precipitator using the multi-cross pin ionizer of the present invention;
7 is a view for explaining the overall configuration through an embodiment of the induced voltage electrostatic precipitator using the multi-cross pin 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.

As shown in FIG. 3 and a plan view illustrating the basic principle of the electrostatic precipitator using the induced voltage of FIG. 2, the protruding discharge electrode 10 is connected to a power source and charged at a high DC voltage of 11000 volts or more. The charge supplied to and applied at such a high voltage is charged at the protruding portion of the protruding discharge electrode 10 and then discharged by the corona discharge to form a charged region A2.

The fine particles 1, such as dust, dust, and water, contained in the contaminated air flowing from the outside are in an electrically neutral state, and the fine particles 1 in such a neutral state enter the charged region A2. In other words, charged or fine particles 2 in a negative state are generated by collision or adsorption with an anionic gas molecule in a neutral state.

Briefly describing the principle that the fine particles are charged, the protruding discharge electrode 10 forms a strong electric field around the protruding discharge electrode 10 through corona discharge, and such a strong electric field is formed around the protruding discharge electrode 10. Accelerate free electrons in the gas

Accelerated free electrons move at high speed and collide with other gas molecules, and gas molecules collided with these accelerated free electrons become positive ions, releasing one more free electron.

The gas molecules that become the cations thus formed move toward the protruding discharge electrode 10, which is the cathode, and collide with the gas molecules surrounding the discharge electrode 10 or the protruding discharge electrode 10 itself, and new freedom is generated. The electrons move along the electric field toward the grounded dust collecting electrodes 30 and 30-1, and when the free electrons move out of the corona region A1, the electric field becomes weak and the moving speed drops sharply, thereby ionizing gas molecules. The gas molecules are adsorbed on the surface of the gas molecules by collision with the gas molecules at a rate that does not allow them to form anionic gas molecules.

The anion-containing gas molecules collide with or adsorb to the microparticles 2 in the charged region A2 to charge the microparticles 2.

At the same time, the plate-shaped induction plate 20 spaced apart at predetermined intervals in parallel with the protruding discharge electrode 10 is charged to a high voltage by the protruding discharge electrode 10 to induce an induced voltage of the cathode, and both grounded The dust collecting electrodes 30 and 30-1 are charged to the anode by electrostatic induction and electrostatic discharge.

Therefore, an electric field is formed between the induced voltage plate 20 and each of the dust collecting electrodes 30 and 30-1, and the charged fine particles 2-1 introduced into the electric field are collected from the dust collecting electrodes 30 and 30-1. ) And the attraction force, the repulsive force acts on the induced voltage plate 20 is attached to the dust collecting electrodes (30, 30-1).

The fine particles 3 collected by being attached to and attached to the grounded dust collecting electrodes 30 and 30-1 become electrically neutral fine particles by losing electric charges.

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.

Hereinafter, the multicross pin ionizer which is a technical feature of the present invention will be described in detail.

Conventional protruding discharge electrode 10 has a predetermined length as shown in Figure 4 (a) of the multi-cross pin ionizer of the induced voltage electrostatic precipitator using the multi-cross pin ionizer of the present invention. It has a plurality of protrusions 110 along the longitudinal direction in the shape of a saw. Such projections 110 are intended to cause corona discharge at a relatively low contact pressure, and a plurality of protrusions are formed on both sides.

The multi-cross pin ionizer 80 of the present invention has a plurality of side protrusions 810 causing corona discharge in the longitudinal direction on both sides of the protruding discharge electrode 10 as shown in FIG. It is a discharge electrode characterized by the addition.

That is, when viewed from above, it has protrusions that cause corona discharge in four directions.

As shown in FIG. 4, the side protrusions 810 of the multicross pin ionizer 80 combine the side protrusions 810 on both sides by welding or the like. As shown in the drawing of an embodiment of a multi-cross pin ionizer of an induction voltage electrostatic precipitator using a pin ionizer, the main body of the protruding discharge electrode 10 may be formed by cutting it into a protrusion shape and bending it. have.

As described above, the multi-cross pin ionizer 80 is a type of projection discharge electrode that is an improvement of the conventional projection discharge electrode 10, thereby adding a plurality of side projections 810 causing corona discharge in the longitudinal direction. Corona area (A1) and the charged area (A2) of the relatively increases, through which the dust collection efficiency of the dust collector is relatively increased.

In addition, the multi-cross pin ionizer 80 has a coupling hole 820 as shown in Figure 5, Figure 6 multi-cross pin ionizer of the induced voltage electrostatic precipitator using the multi-cross pin ionizer of the present invention Has a power supply support 830 made of a high electrical conductivity metal material as shown in the drawings for explaining the coupling form of the.

5 and 6, the coupling hole 820 is formed at the upper side and the lower side of the multicross pin ionizer 80, and the power supply support 830 is at least one multicross pin ionizer 80. ) And at the same time electrically connect the high voltage supply means and the multicross pin ionizer 80.

That is, as shown in FIG. 6, the plurality of multicross pin ionizers 80 pass through the coupling holes 820 to a power supply support 830 that is electrically coupled to the multicross pin ionizers 80. The power supply support 40 is fixed and electrically coupled to a high voltage supply means, so that the plurality of multicross pin ionizers 80 supply charge at a high voltage through the power supply support 830.

7 is a view for explaining the overall configuration through an embodiment of the induced voltage electrostatic precipitator using the multi-cross pin ionizer of the present invention.

As shown in FIG. 7, the front end of the enclosure 60 in which the inlet and the outlet of the polluted gas are discharged is coupled to the power supply support 830 connected in parallel to the external high voltage supply means. A plurality of multicross pin ionizers 80 are installed, and a high voltage is induced by the multicross pin ionizer 80 without electrical connection with a plurality of grounding electrodes 30 grounded thereafter. The one consisting of the induction voltage plate 20 located between the electrodes 30 is installed.

That is, at the rear end of the multicross pin ionizer 80 that charges the dust collecting object, the dust collecting electrode 30 and the induction voltage plate 20 collecting the dust collecting object are alternately stacked in the horizontal direction.

Therefore, contaminated air including dust, etc., to be collected is introduced into the housing 60, and the dust collected in the contaminated air is charged while passing through the multicross pin ionizer 80, and then the dust is collected. When introduced into the electric field formed between the electrode 30 and the induced voltage plate 20 is attracted to the dust collecting pole 30 by the coulomb force and is collected.

Therefore, dust, dust, fine particles, and the like contained in the polluted gas are collected and the polluted gas is purified, and the thus purified gas is discharged through the outlet.

At this time, the dust collecting object such as dust or dust is neutralized at the moment of being attached to the dust collecting electrode 30 and stored in storage means such as the hopper 70 by gravity.

Although not shown in the drawings, a means such as a fan for generating air flows inside or outside the front to rear ends of the housing 60 may be included, and also for mechanically filtering dust or dust of relatively large particles. It may further comprise a pretreatment means.

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: fine particles 2: charged fine particles
3: collected fine particles 10: protruding discharge electrode
20: induction voltage plate 30: dust collecting electrode
60: enclosure 70: hopper
80: multicross pin ionizer
810: side projection
820: Combination Hole
830 power supply support

Claims (2)

One or more protruding discharge electrodes connected to a high voltage and having a predetermined length and having a plurality of protrusions along a length direction in the shape of a saw to charge the fine particles by corona discharge; and located at a rear end of the protruding discharge electrodes and grounded. Parallel plates are installed in series and between the dust collection electrode and the dust collection electrode to collect charged microparticles and parallel to the projection discharge electrode and generate a voltage induced by the projection discharge electrode without electrical connection. In the electrostatic precipitator using the induced voltage comprising a;
The projection type discharge electrode is a multi-cross pin ionizer formed in the longitudinal direction a plurality of side projections causing a corona discharge on both sides; the multi-cross pin ionizer is formed in the coupling hole on the upper side and the lower side Induction voltage electrostatic precipitator using the multi-cross pin ionizer further comprises a; and a power supply support for fixing and electrically connecting the multi-cross pin ionizer by combining with the coupling hole. The side protrusion of the multicross pin ionizer of claim 1, wherein
Induction voltage electrostatic precipitator using a multi-cross pin ionizer, characterized in that the main body of the protruding discharge electrode cut into a protrusion shape and formed by bending it.

Images