JP2004351105A - Deodorization device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a deodorization device capable of efficiently decomposing an organic substance without sacrificing the efficiency of a fan or the decomposing capability with titanium oxide. <P>SOLUTION: The deodorization device 1 comprises a corona discharge device 4 for generating ozone and a metal-made rotary blade 2 disposed on the downstream side of the corona discharge device 4. The rotary blade 2 is fixed. The deodorization device also has a cylindrical casing 6 covering a space 9 formed on the upstream side of the rotary blade 2, a photocatalyst film 3 coating the surface of the rotary blade 2, a hygroscopic filter 11 disposed on the downstream side of the rotary blade 2, and a power source 5 with an anode connected to the casing 6 and a cathode connected to the rotary blade 2. Ozone, passing the interior of the space in the casing, decomposes odor material inside the space. Ozone left uncombined is adsorbed in the rotary blade, and decomposed into oxygen and nitric acid. Nitric acid is adsorbed in the hygroscopic filter, and oxygen, passing the hygroscopic filter, flows out of the deodorization device. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a deodorizing device for deodorizing clothes, shoes, and the like.
[0002]
[Prior art]
The corona discharge device includes a negative ionization needle and a positive dust collecting plate. The dust collecting plate has a counter electrode plate to which a high voltage is applied as a counter electrode of the ionization needle, and a filter unit that adsorbs suspended substances in the air without being charged.
When a high voltage is applied to the negative side ionization needle and the positive side dust collector, ozone is generated by the electric field between the ionization needle and the dust collector, and the surrounding air molecules are positively and negatively charged. . The electric field also positively charges dust, bacterial viruses, house dust mites, pollen and various odor components floating in the air, and causes these floating substances to be adsorbed to the filter portion of the dust collecting plate. Ozone also decomposes these odor components.
Ozone has a strong bactericidal action. In order to enhance the sterilizing effect of ozone, the voltage applied between the ionization needle and the dust collecting plate may be increased. In this case, the ozone generated in a large amount cannot be completely absorbed by the dust collecting plate, is sucked by the fan, and flows out downstream of the corona discharge device.
On the other hand, a photocatalyst such as titanium oxide has a function of decomposing water vapor or oxygen in the atmosphere by irradiation with ultraviolet light or visible light to generate active oxygen.
[0003]
Conventionally, devices that generate negative ions using a corona discharge device have been put to practical use. In addition, deodorants that deodorize and sterilize storage boxes such as closets and shoe boxes using the action of decomposing and sterilizing odorous substances with active oxygen generated by the photocatalyst have been put to practical use. Here, it is also conceivable to aim the photocatalytic filter downstream of the corona discharge device to enhance the deodorizing and sterilizing effect.
[0004]
Since the photocatalyst sterilizes by catalytic action, the range in which odor components and the like can be decomposed is limited to the vicinity of the photocatalyst. For this reason, a system in which a corona discharge device and a photocatalyst filter are arranged in a flow path has been adopted for a deodorizing device built in an air conditioner. A plurality of filters for an air conditioner or the like are used according to an action for dust collection, deodorization, or the like. On the other hand, a fan device is usually used to generate an airflow in the deodorizing device. However, since the odor component adheres to the rotating blades of the fan device, it is necessary to periodically clean the rotating blades. It is necessary to perform maintenance after removing the plurality of filters described above for the rotating blades. Therefore, if the number of filters is large, maintenance is troublesome.
Therefore, a reduction in the number of filters is required.
In recent years, in order to make effective use of the space in which the photocatalyst is arranged, a device has been developed in which a titanium oxide-containing coating material is applied to a blower fan by a dip method or the like to carry a titanium oxide-containing substance. (For example, see Patent Document 1).
[0005]
[Patent Document 1]
JP-A-2000-73991 (Pages 2-5, FIG. 1)
[0006]
[Problems to be solved by the invention]
However, the fan is a device that blows air by creating a pressure difference between the air by the rotating blades, and even if pressure is applied to the air, there is little air that directly contacts the rotating blades, and the catalytic action of titanium oxide on the surface of the rotating blades occurs There is a problem that it is difficult to do.
For this reason, Patent Literature 1 describes increasing the number of blades. However, increasing the number of blades causes a problem in that the air flow stops flowing smoothly and the efficiency of the fan deteriorates.
[0007]
In addition, since titanium oxide decomposes organic substances, it is necessary to use an inorganic binder to apply the titanium oxide to the rotating blades. However, if the titanium oxide is buried in the inorganic binder, the oxidation may occur. Since the catalytic action of titanium is not exhibited, there is also a problem that the deodorizing efficiency is drastically reduced.
[0008]
Accordingly, an object of the present invention is to provide a deodorizing apparatus capable of efficiently decomposing organic substances without sacrificing the efficiency of a fan and the ability to decompose by titanium oxide.
[0009]
[Means for Solving the Problems]
In order to solve the above problem, a deodorizing device of the present invention is a deodorizing device including a corona discharge device that generates ozone and a rotating blade made of metal disposed downstream of the corona discharging device. A cylindrical casing that fixes and covers a space formed on the upstream side of the rotary blade, a photocatalytic film that covers the surface of the rotary blade, and a hygroscopic filter provided on the downstream side of the rotary blade. And a power supply having an anode connected to the casing and a cathode connected to the rotating blades.
[0010]
The photocatalyst film refers to a substance which promotes a chemical reaction without being changed under light irradiation itself. Here, it refers to a substance which promotes an oxidation reaction such as titanium oxide.
[0011]
The coating of the photocatalytic film can be performed by a dipping method, adhesion, or the like, in addition to the physical vapor deposition method. In the case of bonding, inorganic primers can be used in addition to organic primers.
[0012]
The metal forming the rotating blades only needs to have a property of conducting electricity, and for example, a stainless steel plate, aluminum, or an alloy containing these is preferably used.
[0013]
When a high voltage is applied to the corona discharge device, ozone is generated by an electric field between the ionization needle on the minus side of the corona discharge device and the counter electrode of the dust collector on the plus side, and air ions that have been positively and negatively charged are further generated. appear. At the same time, the electric field positively charges dust, bacterial viruses, house dust mites, pollen and the like floating in the air. When the rotating blades are rotated, these positively charged floating components are efficiently adsorbed to the filter portion of the dust collecting plate and decomposed by ozone. The generated ozone and air ions flow out of the dust collecting plate.
[0014]
Ozone decomposes odorous substances and contaminants in the space while passing through the space in the casing. Ozone decomposes odorous substances, such as tobacco smoke, which cannot be removed only by a photocatalyst due to a strong oxidizing effect, and sterilizes bacteria several times to several tens times more efficiently than chlorine. The ozone and the positive and negative air ions remaining without being combined are sucked from the space by the rotating blade side and move to the downstream side. Positive ions and uncharged gas are adsorbed by the negatively charged rotating blades and do not flow downstream from the rotating blades. On the other hand, negative air ions are released to the outside without being adsorbed by the negatively charged rotating blades, and work effectively.
[0015]
Since a photocatalytic film is formed on the rotating blade, the adsorbed ozone and air are decomposed into water, oxygen, and carbon dioxide. Then, the moisture is adsorbed by the hygroscopic filter, and the oxygen flows out of the deodorizer through the hygroscopic filter.
[0016]
A deodorized substance can be stored in the space on the upstream side of the rotary blade. Since the odorous substance generated from the deodorized substance is exhausted after being adsorbed by the rotating blades, the odor is prevented from being diffused outside the deodorizing device. When the deodorized substances are not stored, the air purifier can be used as an air purifier for removing suspended matters such as nitrogen oxides in the outside air taken in.
[0017]
When the photocatalyst film is formed by a sputtering method or an ion plating method, a film having excellent adhesion can be formed without a binder. In addition, the structure of the photocatalytic film can be an anatase crystal having small particles and excellent decomposition efficiency. By using a sputtering method or an ion plating method, a structure in which the photocatalytic film contains 80% or more of anatase crystal can be obtained.
[0018]
If an airflow converging nozzle protruding toward the space is provided downstream of the corona discharge device, negative ions and ozone can be intensively passed through a narrow area.
[0019]
If a dehumidifier is provided on the upstream side of the corona discharge device, dry air can flow into the space.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described.
FIG. 1 is a schematic configuration diagram of a deodorizing device of the present invention. As shown in FIG. 1, a deodorizing device 1 of the present invention includes a rotating blade 2 made of a stainless steel plate and having a surface coated with a titanium oxide film 3 as an example of a photocatalytic film by a sputtering method, and a rotating blade 2 on the upstream side of the rotating blade 2. It has a corona discharge device 4 arranged and a power supply 5 containing a control device. A dehumidifier 13 is provided upstream of the corona discharge device 4.
[0021]
The corona discharge device 4 and the rotary blade 2 are provided at the upstream end and the downstream end inside the cylindrical casing 6, respectively. A space 9 is formed between the corona discharge device 4 and the rotary blade 2 so as to store deodorized substances such as shoes and clothes. An airflow converging nozzle 7 is provided downstream of the corona discharge device 4.
[0022]
The corona discharge device 4 has an ionization needle and a dust collecting plate (not shown), and is connected to a cathode and an anode of a power supply 5, respectively. A large voltage of several kV is applied between the ionization needle and the dust collecting plate.
[0023]
A partition 8 is provided immediately downstream of the corona discharge device 4, and the airflow converging nozzle 7 has an upstream end fixed to the partition 8. With this configuration, all the air on the upstream side of the partition wall 8 passes through the airflow converging nozzle 7 and moves to the space 9.
[0024]
The casing 6 is formed of a conductive metal plate such as stainless steel. The casing 6 can be formed by arranging a metal plate on the inner surface and arranging an insulator on the outer side. Alternatively, the casing 6 may be configured to cover both surfaces of the metal plate with the insulator.
[0025]
The rotating blade 2 is fixed to a rotating shaft of the fan motor 10. The shape of the rotating blade is arbitrary, and a sirocco fan or a cross flow fan can be used in addition to an axial fan. Note that a blower can also be applied as a part of the fan. When a sirocco fan or a cross flow fan is used, a guide member that converges the air flow and guides the air flow to the inner peripheral portion of the fan may be provided upstream of the rotating blades.
[0026]
Immediately downstream of the rotary blade 2, a hygroscopic filter 11 through which air can pass is provided.
[0027]
An ultraviolet lamp 12 is provided near the rotary blade 2. The ultraviolet lamp 12 can irradiate both surfaces of the rotating blade 2 with ultraviolet light during rotation. Note that the ultraviolet light lamp 12 may be provided on the upstream side of the rotary blade 2, or may be provided on the radially outer side of the rotary blade 2. Further, a reflecting member such as a mirror can be provided near the ultraviolet lamp 12 so that the rotating blades 2 are evenly irradiated with light.
Further, the ultraviolet lamp 12 may be provided at a position where only the surface of the rotary blade 2 on which the titanium oxide film 3 is formed is irradiated with ultraviolet light.
[0028]
The titanium oxide film 3 is formed on the surface of the rotary blade 2. When a sirocco fan or a cross flow fan is used, it is preferable to form a titanium oxide film on the inner peripheral surface.
[0029]
Since the titanium oxide film 3 is formed by sputtering, it can be formed into a high-purity thin film and has good adhesion. Further, since the crystal structure can be selected, it is possible to increase the number of anatase crystals having excellent decomposition efficiency by forming small particles.
The titanium oxide film 3 contains 80% or more of anatase crystal.
[0030]
The rotating blades 2 and the casing 6 are respectively connected to a cathode and an anode of the power supply 5, and a low voltage of, for example, 40 V or less is applied. The cathode is connected to the rotary blade 2 via, for example, a rotation shaft of a fan motor 10.
[0031]
Next, a manufacturing procedure of the deodorizing device 1 will be described.
The deposition of the photocatalyst on the rotating blades 2 is performed using a sputtering method. The sputtering method refers to a method in which ions in plasma generated by discharge are accelerated and hit against a material, and a film is formed on a substrate by atoms struck out of the material.
A magnetron sputtering device is prepared as a sputtering device. A heating device capable of heating up to 500 ° C. is provided inside the magnetron sputtering device. A bias RF power of up to 200 W can be applied to the substrate. Further, the supply amounts of argon and oxygen as sputter gases can be controlled independently.
[0032]
First, the rotating blades 2 are fixed to a substrate holder in a chamber, and the inside of the chamber is evacuated to start film formation.
The film formation conditions were, for example, a temperature of 250 ° C., a gas partial pressure of argon and oxygen of 1:10, a gas pressure of 5 Pa, and a time of 240 minutes.
Thus, a titanium oxide film having a thickness of about 0.2 μm is formed.
[0033]
Next, the corona discharge device 4, the partition 8 and the airflow converging nozzle 7, the fan motor 10, and the rotary blade 2 are fixed to the casing 6 using bolts or the like.
Then, the power supply 5 is electrically connected to the corona discharge device 4, the casing 6, the rotary blade 2 and the ultraviolet lamp. Thus, the deodorizing device 1 is manufactured.
[0034]
Next, the use state of the deodorizing device 1 will be described.
When the power supply 5 is turned on, ozone and positively and negatively charged air ions are generated from the corona discharge device 4. Further, the fan motor 10 rotates to flow air from the upstream side to the downstream side. Also, the ultraviolet lamp 12 emits light and irradiates the titanium oxide film 3 of the rotary blade 2.
[0035]
After the air is dehumidified by the dehumidifier 13, it passes through the inside of the corona discharge device 4 of the casing 6, is ionized, and has dust and bacterial viruses floating in the air, feces of house mites, pollen, and various odors. The components are positively charged, adsorbed on the uncharged portion of the dust collecting plate, and decomposed by ozone.
[0036]
Air containing ozone and ionized air particles flows out of the corona discharge device 4.
[0037]
The air flowing out of the corona discharge device 4 passes through the airflow converging nozzle 7 and flows into the space. When there is a deodorant such as shoes in the space, the odor component of the deodorant is decomposed by ozone. Air containing ozone and ionized air particles moves downstream.
[0038]
At this time, since the anode is connected to the casing 6 covering the outer periphery of the space 9, the positively ionized ozone does not adhere to the casing 6 and stay there.
[0039]
Since the rotating blade 2 is negatively charged, ozone near the rotating blade 2 is sucked into the titanium oxide film 3 on the surface of the rotating blade 2. The titanium oxide film 3 is activated by irradiation of the ultraviolet light lamp 12, and the ozone and air sucked are oxidized and decomposed into carbon dioxide, water, oxygen and the like. The generated moisture is adsorbed by the hygroscopic filter 11, and gases such as carbon dioxide, oxygen, and negative ions move downstream as they are and are released into the atmosphere.
Thus, air can be purified.
[0040]
When the casing is formed as the inner wall of the shoe box, the smell of shoes which is a deodorant can be removed, and when the casing is formed as the inner wall of the closet, the smell of clothes can be removed. Further, the casing can be provided in a storage part of a house such as a closet.
[0041]
In addition, when a visible light reactive type titanium oxide is used, the ultraviolet light lamp can be omitted by disposing the rotating blades at a position where light strikes from the outside. Further, by providing a translucent window in a part of the casing 6, the rotating blades can be irradiated with natural light.
[0042]
Note that the photocatalyst film can also be formed by using an ion plating method. By using the ion plating method, a large rotating blade can be manufactured in a short time.
[0043]
【The invention's effect】
According to the present invention, the following effects can be obtained.
(1) A deodorizing device of the present invention is a deodorizing device including a corona discharge device and a rotating blade made of metal, wherein a photocatalytic film covering the surface of the rotating blade and a space formed upstream of the rotating blade are formed. Since a cylindrical casing to be covered and a power supply in which an anode is connected to the casing and a cathode is connected to the rotating blade are provided, ozone and nitrogen oxides generated from the corona discharge device are reduced in pitch of the rotating blade. Even if it is not necessary, the suction can be performed, and the organic matter can be efficiently decomposed without sacrificing the efficiency of the fan and the decomposability of the photocatalytic film.
(2) When the photocatalyst film is formed by a sputtering method or an ion plating method, a film having excellent adhesion can be formed without intervening a binder, and the structure of the photocatalyst film is anatase crystal. Therefore, the decomposition ability of the photocatalyst can be improved, and ozone can be efficiently removed.
(3) If an airflow converging nozzle is provided on the downstream side of the corona discharge device, a large amount of negative ions and ozone can be passed through a narrow area to efficiently remove the odor component of the odorant disposed on the downstream side. it can.
(4) If a dehumidifying device is provided on the upstream side of the corona discharge device, dried air can flow into the space to perform deodorization and drying.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a deodorizing device of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Deodorizer 2 Rotating blade 3 Titanium oxide film (photocatalytic film)
Reference Signs List 4 Corona discharge device 5 Power supply 6 Casing 7 Airflow converging nozzle 8 Partition wall 9 Space section 10 Fan motor 11 Hygroscopic filter 12 Ultraviolet lamp

Claims (4)

In a corona discharge device that generates ozone, and in a deodorization device that has a rotating blade made of metal disposed downstream of the corona discharge device,
A cylindrical casing that fixes the rotating blades and covers a space formed on the upstream side of the rotating blades,
A photocatalytic film coated on the surface of the rotating blade,
A hygroscopic filter provided downstream of the rotating blades,
A deodorizing device comprising: a power source having an anode connected to the casing and a cathode connected to the rotating blades. The deodorizer according to claim 1, wherein the photocatalyst film is formed by a sputtering method or an ion plating method. The deodorizing device according to claim 1, wherein an airflow converging nozzle protruding toward a space is provided downstream of the corona discharge device. The deodorizer according to any one of claims 1 to 3, wherein a dehumidifier is provided upstream of the corona discharge device.

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