JP4075869B2 - Purification device - Google Patents

Description

  The present invention relates to a purification device for gas, liquid, solid and the like.

  Conventionally, using active particles such as ions and ozone, food-related items such as food and cooking utensils, the surface of objects where microorganisms are problematic in public health, and the microorganisms that exist in the space where these objects are stored There are known methods for preventing the propagation of potatoes.

  For example, by controlling a discharge current when ionizing and ozonizing a gas such as air to the ionization chamber, a gas containing a predetermined low concentration of ozone and high concentration of ions is generated, and the ionization chamber or the ionization chamber is generated. There is a method and apparatus for preventing microbial growth in which microorganisms are prevented from growing by synergistic effects of ozone and ions by blowing a gas generated in an ionization chamber in a communicating space or on an object (for example, Patent Document 1). reference).

In addition, by supplying tap water to the water tank and immersing the water-absorbing electrode in the supplied water, this water and the discharge between the electrode and the counter electrode can be used to provide a longer-life oxidizing power in the discharge region. There is a discharge atomization technology applied purification device that generates high radicals, ions, and the like and fine water particles containing them, and discharges them downstream of the discharge region, and sterilizes, deodorizes, and removes harmful substances from the discharged region.
JP-A-9-108313

  However, although the above-described conventional method and apparatus for preventing microbial growth are intended to treat microorganisms present on the surface of the object or the storage space, the generated ions are very unstable, There is a problem that the lifetime is very short and the substance changes to a stable substance before spraying on an object, and the propagation of microorganisms cannot be sufficiently prevented.

  In addition, the above-described conventional discharge atomization technology applied purification device must supply water, and it is necessary to bother the user to supply and supply water when there is no water. there were.

  The present invention solves the above-mentioned problem, and by making one or both of the discharge electrode and the counter electrode more efficiently below the dew point with water generating means, a heat sink, and a windbreak wall, water can be supplied without water supply. Using the water and discharge generated between the electrodes, a large amount of radicals and ions that have a longer life in the discharge region, high oxidizing power, and fine water particles containing them are generated, and downstream of the discharge region. And a purification device for disinfecting, deodorizing, and removing harmful substances.

  That is, an object of the present invention is to provide a purification device capable of deodorizing and sterilizing attached odors, viruses, fungi, etc. on indoor wall surfaces, curtains, etc. without having to bother the user's hand. It is.

In order to solve the above problems, a purification device of the present invention includes a discharge electrode, a counter electrode disposed opposite to the discharge electrode, a high voltage application device that applies a high voltage between the electrodes, a heat dissipation surface, A Peltier element having a cooling surface; a heat sink provided in the Peltier element; and a wall portion disposed so as to surround at least a part of the periphery of the discharge electrode. Provided in close contact, the discharge electrode is brought to a temperature below the dew point to generate condensed water on the surface of the discharge electrode, and a high voltage is applied between the discharge electrode and the counter electrode by the high voltage applying means. It is configured in such a way that it does not bother the user's hands, uses water and discharge generated between electrodes without water supply, and in the discharge region, includes radicals, ions, etc., and fines containing them. Large amount of water particles Produced can be released into the discharge region downstream.

  As described above, according to the present invention, there is provided a purification device capable of deodorizing and sterilizing attached odors, viruses, fungi and the like on indoor wall surfaces and curtains without having to bother the user. Can be provided.

A first invention includes a discharge electrode, a counter electrode disposed opposite to the discharge electrode, a high voltage applying device that applies a high voltage between the electrodes , a Peltier element having a heat dissipation surface and a cooling surface , A heat sink provided in the Peltier element; and a wall portion disposed so as to surround at least a part of the periphery of the discharge electrode. The cooling surface is provided in close contact with the discharge electrode, and the discharge electrode is provided. Condensed water is generated on the surface of the discharge electrode at a temperature lower than the dew point, and a high voltage is applied between the discharge electrode and the counter electrode by the high voltage applying means. Without bothering the hands of the person, using water and discharge generated between the electrodes without water supply, generating a large amount of fine water particles containing radicals and ions, etc., and them in the discharge region, Released downstream of the discharge area It can be.

In the second invention, an opening is provided on the discharge electrode side of the wall, and an ion wind is efficiently generated toward the open portion of the counter electrode, and a larger amount of radicals, ions, etc. in the discharge region, and generating and generates a fine water particles containing them, it can be heavily discharged into the discharge region downstream.

The third invention has subjected to antistatic treatment to the wall, it is possible to suppress the fine water particles adhering to the wall portion, including radicals and ions, and their more heavily discharge region Fine water particles can be generated and generated, and released further in the downstream of the discharge region. Further, the shape of the windbreak wall is configured as a circle, an ellipse, an airfoil, or the like. Thereby, the purification unit passing air flow and the like can be passed efficiently.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.

  1 and 2 are a schematic view and a cross-sectional view of a purification device according to an embodiment of the present invention. In addition, although gas, such as air, is demonstrated below, it is the same also with solid.

  The purification unit 1 is arranged in a gas flow path, a discharge electrode 21 is arranged, a counter electrode 31 is arranged opposite to the discharge electrode 21, and between the discharge electrode 21 and the counter electrode 31. A discharge region 9 is formed. Reference numeral 7 denotes the purification unit upstream airflow, and 8 denotes the purification unit downstream airflow.

  The high voltage application device 4 has an electrode (plus or minus) 41 connected to the discharge electrode 21 and a ground electrode 42 connected to the counter electrode 31, and discharges between the discharge electrode 21 and the counter electrode 31. A high voltage that can be generated is applied. As the high voltage application device 4, an electrical circuit that is boosted by a high voltage transformer is used. However, any device capable of applying a desired high voltage can be used without being limited to this.

The water generating means 5 generates water without supplying water, such as a Peltier element, and is provided in close contact with the discharge electrode 21. Thereby, when the discharge electrode 21 becomes a temperature below the dew point, the dew condensation water 10 is generated on the surface of the discharge electrode 21. For example, when the temperature is 22 ° C. and the humidity is 30%, dew condensation water 10 is generated on the surface of the discharge electrode 21 when the discharge electrode 21 reaches a dew point, that is, a temperature of 3.6 ° C. or lower. Note that a Peltier element may be provided in close contact with the counter electrode 31.

  Furthermore, the heat sink 6 is provided in close contact with the water generating means 5. For example, if the water generating means 5 is a Peltier element, if one is a cooling surface, the other is a heat radiating surface. The heat sink 6 is in close contact with the heat radiating surface, so that the discharge electrode 21 is efficiently brought to a temperature below the dew point.

  Reference numeral 12 denotes a windbreak wall disposed so as to surround the periphery of the discharge electrode 21. Due to the windbreak wall 12, the environment around the discharge electrode 21 is limited. That is, even if the temperature of the airflow from the purification unit upstream 7 is high, when the discharge electrode 21 is cooled by the water generating means 5, for example, a Peltier element, the surrounding environment is also cooled efficiently because of the windbreak wall 12. The discharge electrode 21 becomes a temperature below the dew point.

  Hereinafter, the operation of the above configuration will be described.

  A high voltage is applied between the discharge electrode 21 and the counter electrode 31 by the high voltage application device 4, and condensed water 10 is generated on the discharge electrode 21 by the water generating means 9. By using the discharge generated between the electrodes and the dew condensation water 10, and by the effect of the windbreak wall 12, a large amount of radicals, ions, and the like and fine water particles 11 containing them are generated in the discharge region 9, It can be discharged downstream of the discharge region, ie downstream 8 of the purification unit.

  For example, if simplified

As a result of this reaction, downstream of the discharge region 9, OH radicals and ions, H ₂ O ₂ radicals and ions, etc., radicals and ions with high oxidizing power, and water particles 11 containing them may be generated in abundance. it can.

  The generated radicals and ions and the water particles 11 containing them have high oxidizing power, can destroy the outer wall and protein of the microorganism, and the microorganism is killed or inactivated. That is, by releasing the generated OH radicals and ions, H 2 O 2 radicals and ions, radicals and ions having high oxidizing power, and water particles 11 containing them, the discharged region is discharged downstream. It can be sterilized, deodorized, harmful substances removed and purified.

  The high voltage to be applied is a high voltage that can efficiently generate discharge, and varies depending on the size of the gap between the discharge electrode 21 and the counter electrode 31 and the temperature and humidity environment of the discharge region, for example, facing the discharge electrode 21. When the gap with the electrode 31 is about 4 mm, the temperature is 22 ° C., and the humidity is 40%, a high voltage of about 4 kV or more is required.

  Further, by applying a negative high voltage, negative ions can be generated in the discharge region 9, and it is possible to provide a relaxing atmosphere by supplying clean air containing negative ions as the downstream airflow 7. Become.

  FIG. 3 is a schematic view of the windbreak wall 121 with an opening provided with an opening in the windbreak wall 12. FIG. 4 is a cross-sectional view including the in-unit airflow 13 when the windbreak wall 12 is provided, that is, when no opening is provided. FIG. 5 is a cross-sectional view including the in-unit airflow 14 when the windbreak wall 121 is provided with an opening in the windbreak wall 12.

  As shown in the in-unit airflow 13 in FIG. 4 and the in-unit airflow 14 in FIG. 5, an ion wind is efficiently generated toward the open portion of the counter electrode 31 by using the windbreak wall 121 with an opening. be able to. Therefore, radicals, ions, etc., and fine water particles containing them can be generated and generated in a larger amount in the discharge region 9.

  In addition, about the opening part of the windbreak wall 121 with an opening part, the influence of the ion wind by discharge can be considered as mentioned above, A radical, ion, etc. and the fine water particle containing them are produced | generated and generated in a larger quantity. As long as it can be used, for example, the shape and number of circular openings are not limited.

Further, the Bofukabe 12, for example, coating or antistatic agents, etc. provide an antistatic sheet, configured to perform anti-static treatment. The water particles 11 having high oxidizing power are negatively charged if the discharge electrode 21 is negative. Therefore, by performing the antistatic treatment Bofukabe 12, by Bofukabe 12 is charged, highly oxidative water particles 11 are pulled by the Coulomb force, will adhere to Bofukabe 12, higher amounts produced , It can be prevented from being generated.

FIG. 6 is a schematic diagram of the windbreak wall configured as a circle, an ellipse, an airfoil, and the like. The shape of the windbreak wall is configured like a circle, an ellipse, an airfoil, etc., like the circular windbreak wall 122 with an opening. Thereby, the purification unit passing air flow and the like can be passed efficiently.
In addition, if it is a shape which can pass the purification | cleaning unit passage airflow etc. efficiently, it will not be limited at all.

  In addition, if this purification apparatus is mounted in an air cleaner or an air conditioner having a large air volume, for example, the purification performance can be further improved.

Schematic of the purification device in one embodiment of the present invention Side sectional view of the purification device of FIG. Schematic of another purification apparatus in one embodiment of the present invention Side sectional view of the purification device including the air flow in the unit when no opening is provided in the wall Side sectional view of the purification device including air flow in the unit when an opening is provided in the wall Schematic of other purification equipment

Explanation of symbols

4 High voltage application device 5 Water generating means 6 Heat sink 12 Windbreak wall (wall part)
21 Discharge electrode 31 Counter electrode

Claims (3)

A discharge electrode, a counter electrode disposed opposing the discharge electrode, and a high voltage applying unit for applying a high voltage between the electrodes, a Peltier element having a heat radiating surface and a cooling surface is provided on the Peltier element A heat sink and a wall portion disposed so as to surround at least a part of the periphery of the discharge electrode , the cooling surface is provided in close contact with the discharge electrode, and the discharge electrode is set to a temperature equal to or lower than a dew point. A purification apparatus configured to generate condensed water on a surface of the discharge electrode and to apply a high voltage between the discharge electrode and the counter electrode by the high voltage applying unit . The purification apparatus according to claim 1, wherein an opening is provided on a discharge electrode side of the wall. Purifying apparatus according to claim 1, wherein subjected to antistatic treatment to the wall.

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