KR101032613B1 - Electric Dust Collector using carbon fiber - Google Patents

Abstract

The present invention relates to a single stage electrostatic precipitator using carbon fiber that can suppress the generation of ozone, reduce power consumption, and can treat polluted air contained in a large amount of acidic gas.

More specifically, the single-stage electrostatic precipitator using carbon fiber is made of carbon fiber which can suppress ozone generation, reduce power consumption, and have durability to acid gas by using carbon fiber that can generate ions even at a lower voltage than corona discharge. It is about.

The first stage electrostatic precipitator using the carbon fiber of the present invention includes an electrostatic precipitator for collecting fine particles by charging polluted air, comprising: a voltage applying device; An ion generating device made of carbon fibers for generating ions to charge the fine particles by applying a high voltage from the voltage applying device; It consists of a dust collecting part for collecting the fine particles charged by the ion generating device, the ion generating device is formed inside the dust collecting part, the protection device is installed to protect the carbon fibers of the ion generating device from the fine particles .

The protection device is to prevent air from being contaminated with carbon fibers by reducing air contact with the carbon fibers and the fine particles by supplying air around the carbon fibers as much as possible.

Electrostatic Precipitator, Ozone, Carbon Fiber

Description

Electric Dust Collector using carbon fiber

The present invention relates to a single stage electrostatic precipitator using carbon fiber that can suppress the generation of ozone, reduce power consumption, and can treat polluted air contained in a large amount of acidic gas.

There are various devices that remove harmful substances such as fine particles from polluted air and treat them as clean air. Recently, the most widely used devices charge fine particles in contaminated air by corona discharge with good dust collection efficiency. Electrostatic precipitator for collecting dust is widely used.

A general electrostatic precipitator charges particles (fine particles) in air contaminated by corona discharge generated between discharge electrode and ground electrode by applying high high voltage, and collects the charged fine particles having the polarity by moving them into the electric field. , The first stage electrostatic precipitator using corona discharge is a charge unit comprising a discharge electrode which generates corona discharge to charge fine particles, a ground electrode corresponding to the discharge electrode, and a high voltage generator that applies a high voltage to the discharge electrode, It is composed of a dust collecting unit for collecting charged fine particles, a pre-treatment filter which is installed at the front end of the charged portion to pre-treat the contaminated air, and a post-treatment filter which is installed at the rear end of the dust collecting unit and finally processed.

The electrostatic precipitator primarily processes relatively large fine particles in the pretreatment filter, and contaminated air including the fine particles passing through the pretreatment filter is disposed between the discharge electrode and the ground electrode by a current applied from the high voltage generator of the charge unit. Corona discharge is generated, and the fine particles contained in the contaminated air introduced by the corona discharge are charged. The charged microparticles are introduced into the dust collecting unit, the introduced microparticles are collected in the dust collecting plate by the electric field, and the rest are discharged to the outside through the post-treatment filter.

The conventional electrostatic precipitator which generates a corona discharge in the discharge electrode part by applying a high voltage of the positive electrode or the negative electrode between the discharge electrode and the counter ground electrode has a good dust collection efficiency, but has various disadvantages as follows.

That is, the conventional electrostatic precipitator ionizes the air (fine particles) by corona discharge generated by high voltage, firstly, generates a large amount of ozone, and secondly, in the process of ionizing harmful gases when treating other harmful gases. Secondary pollutants such as NOx, SOx, acidic substances or aldehydes are generated. Third, the higher the voltage is applied to the discharge electrode for the particle collection efficiency, the current also increases as the voltage rises and the power consumption increases. There are many disadvantages. Fourth, there is a disadvantage that a metallic discharge electrode and a ground electrode are required for corona generation. That is, since the discharge electrode and the ground electrode are metallic, corrosion is easily caused by the strong acidic harmful gas from the semiconductor or LCD manufacturing process, which causes a lot of problems in durability, and thus causes the use of the electrostatic precipitator.

Like the first disadvantage, there is a disadvantage that the utilization range is not wide because it is not used in the indoor space by a large amount of ozone generated by the corona discharge. That is, the first stage electrostatic precipitator using the corona discharge has the disadvantage that it cannot be introduced into the room by purifying the indoor air such as indoor space and subway station.

If the conventional electrostatic precipitator is to be installed in a place where a lot of people gather, there is a disadvantage in that a post-treatment device that treats ozone must be installed separately. Since the filter used in the device is not permanent and needs to be replaced periodically, the cost of maintenance increases.

In addition, the conventional single stage electrostatic precipitator using corona discharge requires a discharge electrode of metal and a ground electrode of a corresponding metal to generate corona discharge. There is a disadvantage.

The present invention has been invented to solve the above disadvantages, it is conventionally contaminated by generating a large amount of ions even at a voltage lower than the high voltage applied to the discharge electrode and the ground plate corresponding to the discharge electrode is installed to charge the fine particles through a corona discharge Provides a one-stage electrostatic precipitator using carbon fiber, which is made to charge the fine particles in the air to suppress ozone generation, reduce power consumption, and can be used for exhaust gas containing strongly acidic gas causing corrosion. The purpose is to.

In order to achieve the above object, the first stage electrostatic precipitator using the carbon fiber of the present invention includes an electrostatic precipitator which collects fine particles by charging polluted air, comprising: a voltage applying device; An ion generating device made of carbon fibers for generating ions to charge the fine particles by applying a high voltage from the voltage applying device; It consists of a dust collecting part for collecting the fine particles charged by the ion generating device, the ion generating device is configured to be formed inside the dust collecting part.

As described above, the ion generating device generating ions does not generate ions even at a relatively low voltage and uses carbon fibers that do not generate ozone, thereby reducing anxiety and power consumption for ozone generated during corona discharge.

A protective device may be installed to prevent the carbon fiber of the ion generating device from being contaminated with fine particles to reduce the generation of ions. The protection device usually uses clean air. That is, by continuously supplying clean air around the carbon fiber, the carbon fiber and the fine particles are prevented from contacting each other, thereby preventing the carbon fiber from being contaminated by the polluted air. Alternatively, clean air may be intermittently supplied to the carbon fibers to remove and regenerate fine particles attached to the carbon fibers.

In this way, the air supplied to protect the carbon fiber may use external air or exhaust air treated and discharged from the present electrostatic precipitator.

The ion generating device may be composed of one or a bundle of carbon fibers formed of one or a bundle of ions to generate ions at an end portion, or may be formed of carbon wire of a long wire.

Alternatively, the ion generator may be formed of a rod installed in the longitudinal direction of the dust collecting part and a plurality of ion generators installed on the rod.

The ion generator is disposed in the rod in the radiation direction, and a plurality of ion generators are installed in the longitudinal direction of the dust collector. The number of the ion generators is determined according to the capacity of the electrostatic precipitator.

The dust collecting unit is formed of a dust collecting plate is installed inside the square body or the circular body, the dust collecting plate is formed of a non-metal material layer of plastic material on the outside of the metal plate, or an electrostatic filter, or a carbon reinforced plastic (CFRP) that is charged on the surface It may be made of a variety of materials.

The single stage electrostatic precipitator using the carbon fiber made as described above uses an ion generator consisting of a single strand or a bundle of carbon fibers, or by using long wire carbon fibers to generate ions even at a lower voltage than the conventional electrostatic precipitator to generate fine particles. By charging, ozone can be prevented and power consumption can be reduced. By removing the generation of ozone as described above there is an advantage that can be installed even without a special additional device for treating ozone even in places where people such as subway stations, indoor spaces.

In addition, the carbon fiber has the advantage that it can be used even in the presence of a strong acidic harmful gas by conventionally do not need a metallic discharge electrode and the corresponding metallic ground electrode during the corona discharge.

In addition, the protective device for the carbon fiber is installed, it is characterized in that the carbon fiber is prevented from deterioration of ions generated by contamination by the fine particles.

In addition, since the dust collecting plate of the dust collecting part is made of a corrosion resistant material, the dust collecting plate is prevented from being corroded by acidic gas, so that the dust collecting plate can be used in a place where strong acidic gas is discharged.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the present specification and claims should not be construed as being limited to the ordinary or dictionary meanings, and the inventors should properly explain the concept of terms in order to explain their invention in the best way. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

1 is a schematic diagram of a single stage electrostatic precipitator using carbon fibers showing a preferred embodiment of the present invention, and FIGS. 2 to 4 are side schematic views of a single stage precipitator using carbon fibers shown in FIG. 1.

1 stage electrostatic precipitator using the carbon fiber of the present invention as shown in Figure 1 largely composed of ion generator 11 consisting of carbon fiber 12, and ions generated in the ion generator 10 The dust collecting part 20 collects the fine particles charged by the battery, and the voltage applying device 30 applies a voltage to the ion generating device 10.

A pretreatment filter (not shown) and a post treatment filter (not shown) may be further installed at the front and rear ends of the dust collecting part 20.

The ion generator 10 generates (+) ions or (−) ions according to the type of current applied from the voltage applying device 30, and is a single strand or several strands of the carbon fiber 12 in a single line. The strands are formed of ion generators 11 in bundles. As such, when voltage (current) is applied from the voltage applying device 30 to the ion generator 11, ions are generated at the end of the carbon fiber 12 to charge the fine particles contained in the contaminated air supplied.

When ions are generated by applying a voltage (current) to the ion generator 11 made of the carbon fibers 12, the carbon fibers 12 are more than the corona discharge generated by applying a high voltage between the discharge electrode and the corresponding ground electrode. By generating a large amount of ions even at a low voltage, ozone is suppressed and power consumption is reduced. In addition, the carbon fiber 12 is characterized by not requiring a ground electrode when generating ions by applying a voltage (current), and has a feature that corrosion does not occur even in strong acidity.

The dust collecting unit 20 collects fine particles charged by installing a dust collecting plate 22 inside the body 21 for transporting contaminated air, and the body 21 has a quadrangular and circular shape as shown in FIGS. 2 to 4. It is formed of a tube such as, etc., the dust collecting plate 22 is installed inside, the dust collecting plate 22 has a polarity opposite to the ions generated from the ion generator 10. Therefore, the dust collecting plate 22 is usually connected to the ground electrode as shown in FIGS. 1 to 4.

In addition, the body 21 may serve as a dust collecting plate by connecting to the ground electrode.

The body 21 is usually formed of a non-metallic material such as plastic series (PVC, PE, PP, etc.) in order to prevent corrosion by the gas of the strong acid, the dust collecting plate 22 to prevent corrosion by the gas of the strong acid. In order to form the non-metallic layer 24 on the outer side of the metal plate (23). The nonmetallic layer 24 is made of a plastic-based material, and is formed by coating a metal plate 23 or by inserting a metal plate into a nonmetallic plate.

2 shows that the dust collecting plate 22 is installed on all inner surfaces of the rectangular body 21, and FIG. 3 shows the dust collecting plate 22 is installed on two surfaces corresponding to the inner surface of the rectangular body 21. 4 shows that the dust collecting plate 22 is installed on the inner circumferential surface of the circular body 21.

The voltage applying device 30 applies a voltage (current) to the ion generating device 10 to generate ions in the ion generating device 10, and the ground electrode is connected to the dust collector 20 to be opposite to the charged fine particles. Charged fine particles are collected by having a polarity.

The one-stage electrostatic precipitator using the carbon fiber according to the embodiment of the present invention made as described above is introduced with polluted air containing fine particles toward the inlet, and the fine particles contained in the introduced polluted air are ion generators. Charged by the ions generated in (10), the charged fine particles are collected in the dust collecting plate 22 of the dust collecting unit 20 by the electric force. That is, a voltage (current) is applied from the voltage applying device 30 to generate ions of either positive or negative charges in the carbon fiber 12 of the ion generating device 10, and the generated ions are contained in the contaminated air. In combination with the microparticles, the microparticles are charged. The charged fine particles are grounded with the ground electrode of the voltage applying device 30 and are collected in the dust collecting plate 22 having the opposite polarity to the ions.

The one-stage electrostatic precipitator using the carbon fiber according to one embodiment of the present invention can deal with a strong acid gas since the discharge electrode of the metal material required for corona discharge and the ground electrode of the metal material corresponding thereto are not required. In addition, there is a feature that can simplify the configuration. In particular, since the ion generating device 10 is installed inside the dust collector 20, the fine particles are charged and collected in the dust collector 20, thereby simplifying the configuration and reducing the volume.

5 is a schematic diagram of a single stage electrostatic precipitator using carbon fibers showing another embodiment of the present invention, and FIGS. 6 to 10 are side schematic views of a single stage precipitator using the carbon fibers shown in FIG. 5.

As shown in FIG. 5, the one-stage electrostatic precipitator using the carbon fiber according to another embodiment of the present invention includes an ion generator 10 including an ion generator 11 made of carbon fibers 12 and the ion generator ( The dust collecting unit 20 collects the fine particles charged by the ions generated by 10) and the voltage applying device 30 applies a voltage to the ion generating device 10.

The ion generating device 10 is installed inside the dust collecting unit 20 by generating ions to charge fine particles in contaminated air, and according to the type of current applied from the voltage applying device 30, positive ions Or (-) ions.

The ion generator 10 is formed of an ion generator 11 consisting of a single strand or a bundle of several strands of carbon fiber 12 of a single line, the ion generator 11 is both sides of the dust collector 20 It is attached to the rod 13 for installing the ion generator 11 installed in the heat transfer support 14 installed in the.

The rod 13 is formed of a metallic material and is installed in the length (horizontal) direction of the dust collecting part 20 and is installed in the central portion, and the ion generator 11 installed in the rod 13 is shown in FIGS. 6 and 7. Likewise, a plurality of radiation rods are installed, and a plurality of rods 13 are installed in the longitudinal direction of the rod 13. The quantity of the ion generator 11 installed in the rod 13 is determined according to the throughput of contaminated air. An electrostatic force acts between the rod 13 and the dust collecting plate.

The dust collecting unit 20 collects fine particles charged by installing a dust collecting plate 22 inside the body 21 for transporting contaminated air, and the body 21 is as shown in FIGS. 6 and 8 to 10. It is formed of a tube such as a rectangle, a circle, and the like, and a dust collecting plate 22 is installed inside thereof, and the dust collecting plate 22 has a polarity opposite to that of ions generated from the ion generator 10. Therefore, the dust collecting plate 22 is connected to the ground electrode.

6 shows the dust collecting plate 22 installed on both inner surfaces of the rectangular body 21, and FIGS. 8 and 9 show the dust collecting plate 22 on two sides corresponding to the inner surface of the rectangular body 21. FIG. 10 shows that the dust collecting plate 22 is installed on the inner circumferential surface of the circular body 21.

The dust collecting plate 22 installed inside the body 21 may be made of various materials as shown in FIG. 17.

As shown in FIG. 17A, the dust collecting plate 22 is formed by inserting the metallic thin film 23 into the plastic plate 24 or by coating the plastic coating material 24 of the plastic material on the metal plate 23. Alternatively, as shown in (b) of FIG. 17, the dust collecting plate 22 is formed of an electret (electrostatic) filter having a charge on the surface, and as shown in (c) of FIG. 17, the dust collecting plate 22 is conductive to the plastic plate 24 '. Various materials such as those formed by coating the material 23 'or carbon fiber reinforce plastic (CFRP) are used.

When the polluted air does not contain strong acidic gas, the material of the dust collecting plate 22 may be a normal metal plate.

The voltage applying device 30 applies a voltage (current) to the ion generating device 10 to generate ions in the ion generating device 10, and the ground electrode is connected to the dust collector 20 to be opposite to the charged fine particles. Charged fine particles are collected by having a polarity.

11 is a schematic diagram of a single stage electrostatic precipitator using carbon fibers according to another embodiment of the present invention, and FIGS. 12 and 13 are side schematic views of a single stage precipitator using carbon fibers shown in FIG. .

As shown in FIG. 11, the single stage electrostatic precipitator using a carbon fiber according to another embodiment of the present invention includes an ion generator 10 consisting of carbon fibers 15 of a long wire, and the ion generator 10. The dust collecting unit 20 collects the fine particles charged by the generated ions, and the voltage applying device 30 applies a voltage to the ion generating device 10.

The ion generating device 10 is installed inside the dust collecting unit 20 by generating ions to charge fine particles in contaminated air, and according to the type of current applied from the voltage applying device 30, positive ions Or (-) ions.

The ion generator 10 is installed on the support 16 in which the long wire carbon fiber 15 is installed on both sides of the dust collecting unit 20.

The carbon fiber 15 of the long wire is installed in the length (horizontal) direction of the dust collecting part 20 and is installed in the central portion, usually formed in a single line, but may be formed in two or more double lines.

When a voltage (current) is applied from the voltage applying device 30 to the carbon fiber 15 of the long wire, ions are generated in the radiation direction as shown in FIGS. 12 and 13.

The dust collecting unit 20 collects fine particles charged by installing a dust collecting plate 22 inside the body 21 for transporting contaminated air, and the body 21 is rectangular and circular as shown in FIGS. 12 and 13. It is formed of a tube such as, etc., the dust collecting plate 22 is installed inside, the dust collecting plate 22 has a polarity opposite to the ions generated from the ion generator 10. Therefore, the dust collecting plate 22 is connected to the ground electrode.

14 to 16 is a schematic diagram of a single stage electrostatic precipitator using carbon fibers showing another embodiment of the present invention.

The first stage electrostatic precipitator using the carbon fiber of the present invention shown in FIGS. 14 to 16 is further provided with a protective device 40 for protecting the carbon fibers 12 and 15.

The protection device 40 supplies the air supplied from the air supply pipe 41 through the nozzle 42 to prevent the fine particles from adhering to the carbon fibers 12 and 15 to reduce the generation of ions. Continuous supply of air supplied from (42) to prevent contaminated air from contacting the carbon fibers 12, 15 to prevent the fine particles in the contaminated air from adhering to the carbon fibers 12, 15 or , Or intermittently supplied to remove and regenerate the fine particles attached to the carbon fibers (12, 15).

When the fine particles are attached to the carbon fibers 12 and 15, the carbon fibers 12 and 15 may be contaminated and thus the generation of ions may be reduced, and thus the processing capacity may be reduced.

The treated air discharged from the dust collecting part 20 of the present invention used for the protection device 40 is used, or purified external air is used. In other words, clean air is used.

When using the treated air discharged from the dust collector 20, the air inlet is formed at the outlet through which the treated air is discharged to move the air supply pipe 41 to the air introduced from the air inlet.

The air supplied through the nozzle 42 is continuously supplied to isolate the carbon fibers 12 and 15 and the contaminated air, or intermittently sprayed at a predetermined pressure and attached to the carbon fibers 12 and 15. The fine particles may be removed to regenerate the carbon fibers 12 and 15.

1 is a schematic diagram of a one-stage electrostatic precipitator using carbon fibers showing a preferred embodiment of the present invention.

Figure 2 is a side schematic view of a one-stage electrostatic precipitator using the carbon fiber shown in FIG.

Figure 3 is a side schematic view of a single stage electrostatic precipitator using the carbon fiber shown in FIG.

Figure 4 is a side schematic view of a single stage electrostatic precipitator using the carbon fiber shown in FIG.

Figure 5 is a schematic diagram of a one-stage electrostatic precipitator using carbon fibers showing another preferred embodiment of the present invention.

Figure 6 is a side schematic view of a single stage electrostatic precipitator using the carbon fiber shown in FIG.

7 is a detailed schematic view of the ion generating device shown in FIG.

8 is a side schematic view of a single stage electrostatic precipitator using the carbon fiber shown in FIG.

9 is a side schematic view of a single stage electrostatic precipitator using the carbon fiber shown in FIG.

10 is a side schematic view of a single stage electrostatic precipitator using the carbon fiber shown in FIG.

Figure 11 is a schematic diagram of a one-stage electrostatic precipitator using carbon fibers showing another preferred embodiment of the present invention.

12 is a side schematic view of a single stage electrostatic precipitator using the carbon fiber shown in FIG.

FIG. 13 is a side schematic view of a single stage electrostatic precipitator using the carbon fiber shown in FIG.

Figure 14 is a schematic diagram of a one-stage electrostatic precipitator using carbon fibers showing another preferred embodiment of the present invention.

Figure 15 is a schematic diagram of a one-stage electrostatic precipitator using carbon fibers showing another preferred embodiment of the present invention.

Figure 16 is a schematic diagram of a one-stage electrostatic precipitator using carbon fibers showing another preferred embodiment of the present invention.

17 is a cross-sectional view showing the type of dust collecting plate.

DESCRIPTION OF THE REFERENCE NUMERALS

10 ion generator 11 ion generator

12, 15: carbon fiber 13: rod

20: dust collector

30: voltage applying device

40: protection device

Claims (12)

In the electrostatic precipitator to collect the fine particles by charging the contaminated air, A voltage application device 30; An ion generating device (10) made of carbon fibers for generating ions to charge the fine particles by applying a high voltage from the voltage applying device (30); A dust collecting part 20 made of a dust collecting plate 22 having a non-metallic layer 24 formed outside the metal plate 23 for collecting fine particles charged by the ion generator 10; It consists of a protective device 40 to supply air around the carbon fiber of the ion generating device 10 to protect the carbon fiber from the fine particles, The ion generator 10 is a one-stage electrostatic precipitator using carbon fibers, characterized in that formed on the inside of the dust collector (20). In the electrostatic precipitator to collect the fine particles by charging the contaminated air, A voltage application device 30; An ion generating device (10) made of carbon fibers for generating ions to charge the fine particles by applying a high voltage from the voltage applying device (30); A dust collecting part (20) comprising a dust collecting plate (22) formed of an electret (electrostatic) filter or carbon reinforced plastic (CFRP) for collecting fine particles charged by the ion generator 10; It consists of a protective device 40 to supply air around the carbon fiber of the ion generating device 10 to protect the carbon fiber from the fine particles, The ion generator 10 is a one-stage electrostatic precipitator using carbon fibers, characterized in that formed on the inside of the dust collector (20). In the electrostatic precipitator to collect the fine particles by charging the contaminated air, A voltage application device 30; An ion generating device (10) made of carbon fibers for generating ions to charge the fine particles by applying a high voltage from the voltage applying device (30); A dust collecting part (20) comprising a dust collecting plate (22) formed by coating a conductive material on a plastic plate for collecting fine particles charged by the ion generating device (10); It consists of a protective device 40 to supply air around the carbon fiber of the ion generating device 10 to protect the carbon fiber from the fine particles, The ion generator 10 is a one-stage electrostatic precipitator using carbon fibers, characterized in that formed on the inside of the dust collector (20). The method according to any one of claims 1 to 3, The ion generator 10 is a single-stage electrostatic precipitator using a carbon fiber, characterized in that the carbon fiber of a single line is formed of one or a bundle of ion generator 11 formed to generate ions at the end . The method according to any one of claims 1 to 3, The ion generator 10 is a one-stage electrostatic precipitator using carbon fibers, characterized in that formed of carbon fibers of a long wire (wire). The method of claim 4, wherein The ion generator 11 is a one-stage electrostatic precipitator using carbon fibers, characterized in that installed in the two or more in the longitudinal direction (air flow direction) of the dust collector (20). The method according to any one of claims 1 to 3, The ion generator 10 is a first stage using a carbon fiber, characterized in that consisting of a rod 13 installed in the longitudinal direction of the dust collector 20, and a plurality of ion generators 11 installed on the rod (13) Electrostatic precipitator. delete delete delete delete delete

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