KR100686021B1 - Air cleaner with Yuttria - Google Patents

Abstract

The present invention relates to an air purifier, and more particularly, by coating yttrium oxide (Y ₂ O ₃ ) on the outer circumferential surface of the discharge electrode and using it as an optoelectronic emission material, the removal rate of harmful gases is increased.

To this end, the present invention applies a discharge electrode coated with yttrium on the outer circumferential surface of the line electrode coaxially installed between the ground electrodes, a ground electrode installed through the discharge electrode, and applying a high voltage current to the discharge electrode and the ground electrode. It is to provide an air purifying device using yttrium oxide, including a power supply device.

Preferably, the present invention includes a ground electrode 10 facing each other, a discharge electrode 20 formed by coating yttrium oxide (Y 2 O 3) on an outer circumferential surface of a line electrode coaxially disposed between the ground electrodes, and the discharge electrode and ground. It is to provide an air purifier using yttrium oxide including a power supply for applying a high voltage to the electrode.

Yttrium oxide (Y2O3), discharge electrode, photoelectron emitter

Description

Air cleaner using yttrium oxide (Ｙ2Ｏ3) {Air cleaner with Yuttria}

1 is a schematic cross-sectional view of a conventional air purifying apparatus using a plasma generation method

2 is a schematic cross-sectional view showing an air purifying apparatus of the plasma generating method according to the present invention.

Figure 3 is a graph showing the removal rate of harmful gases according to the reaction time when the present invention and the conventional discharge electrode is used

Explanation of symbols of main part of drawing

1, 10: ground electrode 2, 20: discharge electrode

21: yttrium oxide 4, 40: electric field lines

3, 30: power supply device 22: wire electrode

The present invention relates to an air purifier, and more particularly, to an air purifier that generates plasma of high density using a yttrium-coated discharge electrode.

Today, various kinds of harmful substances are generated from power generation facilities, waste incinerators, semiconductor factories, and automobiles, and harmful substances cause environmental problems such as acid rain, so the need for exhaust gas treatment technology is increasingly important to solve such environmental problems. .

As part of such efforts, a method of treating exhaust gas using discharge plasma has been attracting attention, and the discharge plasma method generates reactive species, which are highly reactive in combustion or normal temperature exhaust gas, to remove harmful substances contained in air. It is a method of eliminating harmful gas by harmless chemical reaction.

A plasma discharge apparatus for executing the discharge plasma method is schematically illustrated in FIG. 1, and is formed between a pair of opposed ground electrodes 1 formed in a flat plate shape and spaced apart from each other by a predetermined interval, and between the ground electrodes 1. A corona discharge electrode 2, which is a line electrode, and a power supply device 3 for applying a high voltage to the ground electrode 1 and the discharge electrode 2 are provided.

As a high voltage is applied from the power supply device to the ground electrode 1 and the discharge electrode 2, electric fields 4 facing each other toward the ground electrode are formed around the discharge electrode 2, and are close to the discharge electrode 2. The corona is advanced at a rate of 0.1 cm / ns between the electrodes toward the ground electrode (1) having a cathode from to form a high field.

In these high fields, the accelerated electrons collide with the heavy molecules in the exhaust gas to generate various active species.

In addition, the active species is collected by the Coulomb force between the positive electrodes (1, 2) on the ground electrode (1), which is a collecting electrode, to make harmful gases harmless.

However, noxious gases such as NOx have a limited processing concentration only by the plasma discharge method, and are not completely removed by conventional plasma alone.

In addition, when the voltage applied to the discharge electrode and the ground electrode is increased to overcome the processing concentration limit of the gas, safety problems such as mis-discharge are raised, and when the voltage is increased, spark discharge occurs instead of corona discharge and ozone is generated by the plasma. (O ₃ ) is generated in large quantities.

Accordingly, since a separate treatment device for treating ozone (O ₃ ) that is harmful to the human body needs to be installed, the reliability of the user's purifier is reduced, and the manufacturing labor is increased.

In order to solve the above problems, the present invention is to coat the yttrium oxide on the discharge electrode in which the electric field is concentrated, to form a high-density plasma using the rise of the discharge start voltage and the photoelectron emission effect, thereby improving the harmful gas removal rate There is this.

To this end, the present invention is a discharge electrode formed by applying yttrium oxide (Y 2 O 3) to the outer circumferential surface of the ground electrode facing each other, the line electrode is installed coaxially between the ground electrode, and to apply a high voltage to the discharge electrode and the ground electrode An air purifier using yttrium oxide including a power supply is provided.

More preferably, the present invention provides a ground electrode coated with yttrium oxide (Y 2 O 3) on an outer circumferential surface or an inner surface thereof facing each other, a discharge electrode that is a linear electrode installed coaxially between the ground electrodes, and a high voltage applied to the discharge electrode and the ground electrode. It is to provide an air purifying device using yttrium oxide including a power supply device to be applied.

Referring to the accompanying drawings the configuration and operation of the air purifying apparatus according to the present invention will be described in detail.

2 is a cross-sectional view showing an air purifying apparatus according to the present invention, Figure 3 is a graph showing the discharge current characteristics according to the material of the ground electrode.

The air purifying apparatus according to the present invention includes a pair of opposing ground electrodes 10 formed in a cylindrical shape or a flat plate and yttrium oxide on the outer circumferential surface of the line electrode 22 installed to penetrate longitudinally between the ground electrodes 10. 21 is coated with a discharge electrode 20, a corona discharge electrode 20 installed in the reactor and a power supply device 30 for applying a high voltage to the ground electrode.

At this time, yttrium oxides 21 and Y2O3 applied to the outer circumferential surface of the line electrode 22: Yttria) is one of the rare earth oxides, which has recently been spotlighted as a constituent material used in fuel cells. Since it has an oxygen attacker mechanism, it exhibits excellent ion conductivity.

And, the yttrium oxide 21 is a pure white equiaxed crystal system, specific gravity is 5.03, melting point is about 2410 ℃, insoluble in cold water, hot water, soluble in acid, insoluble in alkali, when heated at 900 ~ 1000 ℃ Surface color changes to light blue.

The yttrium oxide 21 has the highest ion conductivity when combined with other types of materials in an amount of about 9%.

However, as the content of yttrium oxide 21 increases, the distribution of yttrium molecules becomes more regular and the ion conductivity decreases.

Therefore, yttrium oxide is used for zirconia stabilization, boron nitride sintering aids, oxygen sensors, multilayer capacitors, and the like.

The yttrium oxide (21) is pulverized by zenotime ore (zenotime) ore, decomposed by adding a large amount of NaOH, filtered and washed with water to prepare a hydrate, and dissolved by adding HCl to the prepared rare earth hydrate and by adding Oxalic acid to the solution After preparing with oxalic acid salt, it is dried and calcined to produce yttrium concentrate.

In addition, it is known that yttrium acid 21 is obtained by dissolving the concentrate by adding HCl or NHO ₃ , extracting the solution through a solvent extraction tank, and then adding oxalic acid to the extract to precipitate, filter, dry and calcinate with a salt. .

Such yttrium 21 is coated on the outer circumferential surface of the discharge electrode 20 rather than the ground electrode 10 because more electrons can be generated where the electric field is concentrated.

At this time, the yttrium oxide 21 may be a thin film coated on the discharge electrode by applying a powder form, such as painting, screen printing, silkscreen printing technology, oxygen is introduced into the reactor during plasma deposition or sputtering May be deposited.

After coating the outer circumferential surface of the yttrium oxide 21, the electrode is sintered to thermally decompose or burn the binder and the solvent, and the porosity is controlled by appropriately adjusting the sintered state.

When a current is applied to the yttrium oxide 21, when a current of a predetermined range or less flows, it is used as an insulating material, but above that range, photoelectrons are emitted from the inside.

In the air purifier according to the present invention to which the yttria 21 is coated, a high voltage is applied from the power supply device 30 to the discharge electrode 20 and the ground electrode 10.

A high electric field is formed between the discharge electrode 20 and the ground electrode 10, and a streamer is generated by the discharge across the electrodes, and a large amount of electrons are emitted from the surface of the ground electrode to the discharge electrode side by the high energy of the streamer. do.

At this time, since the yttrium oxide 21 coated on the outer circumferential surface of the discharge electrode 20 forms an insulating layer, the resistance between the discharge electrode 20 and the ground electrode 10 increases, so that the discharge start voltage at which discharge occurs is conventional. Higher.

However, due to the rise of the discharge start voltage, creeping discharges having higher energy generated at higher voltages than the corona discharges are generated on the surface of the discharge electrode 10 in the electric field generated between the discharge electrode 20 and the ground electrode 10. do.

A large amount of ultraviolet light is emitted by the creeping discharge, and a large amount of energy is introduced into the yttrium oxide 21 coated on the surface of the discharge electrode 20.

Therefore, photons with a large amount of energy strike the electrons of the yttrium oxide, so that many photoelectrons are emitted from the surface of the yttrium oxide 21, and the density of the plasma composed of ions and electrons is increased.                     

On the other hand, since a large amount of current flows through the discharge electrode 20 due to the increase in the discharge start voltage, the yttrium oxide 21 is converted from the insulator to the photoelectron emitting material, thereby emitting a large amount of electrons.

That is, although the discharge start voltage of the air purifier according to the present invention is higher than the conventional discharge start voltage using the electrode to which the yttrium oxide 21 is not applied, the yttrium oxide 21 may be applied even after the discharge is started. Since a large amount of electrons are emitted from the surface of the discharge current, more current flows in the discharge electrode.

Therefore, since the electron density of the plasma is increased and the movement of electrons is actively performed, ionization of the noxious gas is accelerated, and the ionized noxious gas is collected in the ground electrode 10 which is a parallel plate type electrode.

That is, since the increased photoelectrons collide with the gas molecules to ionize the gas molecules more, the density of the plasma is increased to increase the amount of gas collected at the ground electrode, thereby improving the gas removal performance.

At this time, the voltage applied to the electrode from the power supply device 30 is supplied with a current within the range and the application time of the voltage required to generate a corona, so that arc discharge does not occur.

However, in the air purifier according to the present invention, even when the same voltage is applied to the electrode due to the insulator, the discharge start voltage between the electrodes is increased because the capacitance of both electrodes increases.

On the other hand, the density of the plasma generated by the discharge (partial discharge) between the discharge electrode 20 and the ground electrode 10 is the distance between the discharge electrode 20 and the ground electrode 10 and the magnitude of the voltage applied to the positive electrode Depends on.

In addition, since the density of the plasma due to the creeping discharge generated on the surface of the discharge electrode increases as the radius of the discharge electrode 20 decreases, the thickness of the coating layer of the yttrium oxide 21 can emit a large amount of electrons while the amount of plasma It is limited to the range which does not reduce.

This result is also well shown in the graph of FIG. 3 comparing the purifying capacity of the air purifying apparatus according to the present invention and the conventional air purifying apparatus using the electrode coated with yttrium oxide 21 on the discharge electrode 20.

As shown in Figure 3, the x-axis represents the reaction time, the y-axis represents the TMA smell concentration, which is a fish rotting smell.

That is, as shown in the graph, the longer the reaction time, the TMA odor concentration is almost completely eliminated since it approaches zero through the air purifier according to the present invention, and the removal amount is improved by about 15 to 20%. will be.

This means that the smell of TMA, which is frequently used in the performance test of air purifiers, is completely removed by the high density plasma formed by the large amount of electron emission from the yttrium oxide 21.

As described above, in the present invention, by coating yttrium oxide on the outer circumferential surface of the discharge electrode where the electric field is concentrated, a large amount of electrons are generated in yttrium oxide, thereby increasing the removal rate of harmful gas.

Further, even when the same voltage as the conventional one is applied to the air purifier, the removal time of the harmful gas is shortened, thereby improving energy efficiency.

In addition, since the discharge start voltage of the discharge electrode is increased, safety problems such as erroneous discharge are solved, and generation of ozone (O ₃ ) due to the increase in voltage is suppressed, thereby improving the reliability of the user's purifier.

Claims (3)

A ground electrode facing each other, A discharge electrode formed by coating yttrium oxide (Y 2 O 3) on an outer circumferential surface of the line electrode provided in the coaxial direction between the ground electrodes; An air purifier using yttrium oxide including a power supply unit for applying a high voltage to the discharge electrode and the ground electrode. The method of claim 1, Yttrium oxide (Y2O3) is applied to the inner surface of the ground electrode facing each other, characterized in that the air purifier using yttrium. Discharge electrode coated with yttrium oxide on the outer circumferential surface of the line electrode provided in the coaxial direction between the ground electrodes; A ground electrode through which the discharge electrode is installed; An air purifier using yttrium oxide including a power supply unit for applying a high voltage to the discharge electrode and the ground electrode.

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