JP2008228831A - Deodorizing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a deodorizing apparatus which improves a deodorization efficiency by simplifying the structure of ozonolysis means and by promoting the adsorption and dissolution of an odorant by heating an ozonolysis catalyst. <P>SOLUTION: The deodorizing apparatus includes a deodorization mechanism 1 made of ozonation means 3 and ozonolysis means 4 in an air duct 2 of a body which has an air distribution fan 11, and a support for supporting the ozonolysis catalyst in the ozonolysis means is formed of conductive material, and the support is turned on and the ozonolysis catalyst is heated. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a deodorizing apparatus for deodorizing by decomposing odor components and harmful substances contained in the air.

  In recent years, the demand for air quality improvement in living spaces is increasing due to the progress of airtightness of houses and steady outdoor air pollution. Among the air qualities, there is a growing need for reducing the odor of tobacco smoke, metabolic odor in nursing care environments, etc., or removing harmful gas components typified by VOC (volatile organic substances) generated from building materials.

  As specific methods for these demands, (1) a method using an adsorbent typified by activated carbon. (2) A method of decomposing odorous substances using a catalyst. (3) A method of decomposing odorous substances by releasing ozone. (4) A method of decomposing odorous substances by deodorizing means comprising ozone and a catalyst is used.

  Among the prior arts, the deodorization and removal of harmful gas components by the adsorbent of (1) and the catalyst of (2) are limited in the amount of adsorption and decomposition, and therefore, when used over a long period, The exchange was essential. In addition, even during the lifetime of the deodorizing filter, there is a problem of odor generation due to the adsorbed odor component being released again at the end of the lifetime. On the other hand, as in the method (3), the method of reducing the odor by reacting the odor component with ozone to change the odor quality has a difficulty in controlling the emission amount when ozone is released to the odor environment. there were.

  Therefore, in order to solve these problems, as described in (4) above, a deodorizing method in which ozone and a catalyst are combined, for example, ozone and ultraviolet rays are generated by high-voltage discharge as described in Patent Document 1. Proposal of a deodorization device comprising a means, a photocatalyst module for decomposing odorous components and harmful substances contained in the air by photocatalytic action, and an ozone decomposing means for decomposing ozone generated by high voltage discharge means Has been.

In this method, an odorous substance or a harmful substance is adsorbed on the catalyst, and the adsorbed substance and ozone are brought into contact with each other, thereby increasing the contact area between the odorous substance and ozone, for example, compared with the method (3). Therefore, deodorizing and sterilizing effects can be obtained more effectively.
JP 2003-339839 A

  In order to further improve the deodorization performance by the method (4), there are methods of increasing the amount of ozone generated or improving the adsorption / decomposition performance of the catalyst. In the former case, a large amount of ozone is generated. Therefore, since the apparatus becomes large, the cost is high, and the method of increasing the latter catalyst adsorption amount is desirable in order to improve the deodorization performance easily.

  The present invention has been made in consideration of the above circumstances, and the deodorizing apparatus has improved the deodorization efficiency by promoting the adsorption and decomposition of odorous substances by heating the ozone decomposition catalyst with a simple structure of the ozone decomposition means. The purpose is to provide.

  In order to solve the above-mentioned problems, the deodorizing apparatus of the present invention comprises a deodorizing mechanism comprising an ozone generating means and an ozone decomposing means in a blowing path of a main body provided with a blowing fan, and carries an ozone decomposing catalyst in the ozone decomposing means. The support body to be formed is formed of a conductive member, and the ozone decomposition catalyst is heated by energizing the support body.

  According to the configuration of the present invention, the adsorption ability and decomposition ability of odorous substances or harmful substances in the ozone decomposition catalyst can be greatly increased, and the deodorization efficiency can be improved.

  Hereinafter, an embodiment of the present invention will be described. Odor generated during cooking in a kitchen in the home is ventilated by a range hood. However, exhausting these odorous substances to the outside without deodorizing is not preferable because the living environment is impaired. FIG. 1 is a schematic view of a deodorizing device attached to a range hood or the like in a kitchen, and a deodorizing device (1) is disposed in an air passage (2) provided in a target area where deodorization is performed.

  This deodorization apparatus (1) includes a photocatalyst module (3) and an ozone decomposition means (4), and adsorbs and deodorizes odor molecules and organic substances contained in the air flowing through the air passage (2). In the photocatalyst module (3), two photocatalyst filters (5) having photocatalyst particles typified by titanium oxide fixed on the surface of a substrate made of a porous ceramic such as alumina or silica are adjacent to each other. 5) Between (5), as a discharge portion, a discharge electrode (6) formed by etching a thin plate of stainless steel or the like into a mesh shape is erected, and the two photocatalytic filters (5) (5) Counter electrodes (7) and (7) formed in the same manner as the discharge electrode (6) are arranged on the windward and leeward sides, respectively.

  The photocatalyst filter (5) in the photocatalyst module (3) is not necessarily provided adjacent to the two, but if there are relatively few odor components and harmful substances, the counter electrode is provided before and after the one photocatalyst filter (5). (7) and the structure which provides a discharge electrode (6) may be sufficient.

  (9) is a high-voltage power supply device for applying a high voltage between the discharge electrode (6) and each counter electrode (7) (7) by a high voltage generator (10) such as a transformer. With this configuration, the discharge electrode (6) and the counter electrode (7) (7) function as a discharge means for generating ultraviolet rays, and discharge occurs between both electrodes to generate ultraviolet rays having a wavelength of 380 nm or less.

  (11) is a fan as a blower mechanism, and air circulation is promoted by arranging the photocatalyst module (3) and the ozone decomposition means (4) in the air passage (2) with the fan (11) on the leeward side. It promotes the deodorizing action. Although not particularly shown, a dust collection filter may be arranged on the windward side of the fan (11).

  The deodorizing device (1) is a corona between each counter electrode (7) and (7) by energizing the power supply device (9) and applying a high voltage from the high voltage generator (10) to the discharge electrode (6). The photocatalyst filter (5) (5) is irradiated with the generated ultraviolet rays to excite the photocatalyst, and the generated active oxygen flows down the air passage (2) to generate hydroxyl radicals (free radicals). The strong oxidative action of) decomposes the bonds of odorous gas components and organic compounds adhering to the surface of the photocatalytic filters (5) and (5), and deodorizes them by deodorizing or reducing the odor.

  Further, when the discharge electrode (6) and the counter electrode (7) are discharged, ozone is generated together with ultraviolet rays. Therefore, the photocatalyst module (3) functions also as an ozone generating means, and air containing an odor component. The odor component can be oxidatively decomposed and deodorized by mixing and reacting with the generated ozone.

  In the air path (2) on the lee side of the photocatalyst module (3), the ozone decomposition means (4) is installed at a predetermined distance from the photocatalyst module (3). The ozonolysis means (4) comprises an ozonolysis catalyst made of manganese dioxide supported on a support made of a honeycomb-shaped conductive ceramic, and the inside of the air passage (2) together with the photocatalyst module (3). An odorous substance contained in the flowing down air is adsorbed, reacted with ozone generated by the photocatalyst module (3), oxidatively decomposed, and deodorized.

  At this time, since the vicinity of the rotating fan (11) is turbulent, the photocatalyst module (3) which is the ozone generating means takes a sufficient distance from the fan (11), and the air flow is It is desirable to provide it at a position where it becomes a laminar flow. The ozone generating means is not limited to the one configured by the above-described space discharge mechanism by the photocatalyst module (3), but may be a creeping discharge type mechanism or an electrolytic method in which a creeping discharge electrode and a step-up transformer are combined.

  Thus, as described above, the support carrying the ozone decomposition catalyst in the ozone decomposition means (4) is electrically conductive, and the support is energized separately from the heating power supply (12). The ozonolysis catalyst supported on the support is heated. The heating temperature at this time is less than the baking temperature to the ceramic, which is the support of manganese dioxide as a support, in order to suppress the grain growth of the manganese dioxide particles forming the ozonolysis catalyst and effectively express the catalytic function. It is desirable that the temperature is low and the deodorizing component is not easily affected by heat, for example, about 50 ° C.

Then, the ozone decomposition means (4) carrying the manganese dioxide as the ozone decomposition catalyst supported on a conductive ceramic support is energized and heated, and the temperature of the ozone decomposition catalyst is raised to remove the odor substance from the ozone decomposition means. Adsorbs a large amount to (4) and promotes decomposition. As a specific example, acetoaldehyde, which is one of the main components of tobacco, is used as a sample gas for odorous substances, and this is blown by a fan (11). Acetaldehyde (CH ₃ CHO) at the inlet and outlet of the ozonolysis means (4) through the air channel (2) ) Was measured to determine the deodorizing performance.

  As a result, as shown in the graph of FIG. 2, the temperature dependency of the ozone catalyst deodorization performance decreases with time, but the removal rate of odorous substances decreases. The removal rate of odorous substances in the case of the above was always 3 to 4 times the odor removal effect as compared with the case of 25 ° C. at room temperature.

  In the above embodiment, the support of the ozonolysis catalyst in the ozonolysis means (4) is made of a conductive ceramic such as stabilized zirconia, and the shape thereof is a honeycomb, but this is into the air passage (2). In order to reduce the pressure loss due to the disposition and increase the contact area with odorous substances and harmful substances, a support based on highly conductive aluminum or copper as a main component is not required. May be used. In addition, ceramic support may be coated on a metal support, thereby improving the supportability of the ozone decomposition catalyst.

  The ozone decomposition catalyst is not only formed with manganese dioxide, but also contains a photocatalyst such as titanium oxide in manganese dioxide, which is effective for removing toxic gas components such as VOC (volatile organic substances). In addition, when noble metals such as platinum (Pt) and ruthenium (Ru) are contained in manganese dioxide, these noble metals act as a co-catalyst for improving the adsorptive decomposition performance of the catalyst, thereby further improving the deodorizing performance. be able to.

  In addition, as the operation control of the deodorizing apparatus, the input to the photocatalyst module (3) which is an ozone generating means is set to a predetermined ratio, for example, a ratio of on time to one on / off cycle for generating ozone. The duty ratio is set to%, and the ozone decomposition means (4) is energized and heated when the photocatalyst module (3) is operating.

  In relation to the above, ozone generated when the photocatalyst module (3) is operated reaches the ozone decomposing means (4) by the fan (11) and comes into contact with the adsorbed material to decompose it, but the odorous material adsorbed on the catalyst becomes ozone. If it is decomposed and is not brominated by this, unreacted ozone does not contribute to deodorization and is decomposed by the ozone decomposition catalyst.

  Therefore, increasing the adsorption performance of the ozone decomposition catalyst during ozone generation can improve the deodorization performance by more efficiently adsorbing and decomposing the ozone decomposition catalyst. To do.

  At this time, if the ozone decomposition means (4) is controlled so that the on time of the ozone decomposition means (4) is shifted backward by a predetermined time with respect to the time when the ozone generation means is turned on, the ozone flowing down the air passage (2) after the generation is Since the ozonolysis means (4) is installed when the adsorptive decomposition performance is increased, a more effective adsorptive decomposition action can be obtained.

  As described above, not only the photocatalyst module (3) and the ozone decomposition means (4), which are ozone generating means, are operated by duty control, but also the input to the fan (11) is operated by duty control. Also good. Odorous substances and harmful substances flow down the air passage (2) by the fan (11) and are adsorbed on the surface of the decomposition catalyst in the ozone decomposition means (4), but are not in contact with the ozone decomposition catalyst and have not been adsorbed. Is released outside the deodorizer (1), and in order to collect odorous substances more reliably, the adsorption performance of the ozone decomposition catalyst is increased when the fan (11) is operating. Therefore, it is controlled to energize the ozonolysis means (4) in synchronization with the operation of the fan (11), and the adsorption and decomposition capacity is increased by heating the ozonolysis catalyst. It is intended to improve the deodorizing performance.

  The present invention is configured as described above, and by attaching the deodorizing device (1) to a range hood in a kitchen, it is possible to reduce the outflow of odorous substances or harmful substances to the outdoors, especially during cooking, Although it has a great deodorizing effect against acetaldehyde produced by the decomposition of alcohol, the installation location of the deodorizing device (1) is not limited to the range hood in the kitchen of the above-mentioned domestic living space. It may be applied as a deodorizing device for removing food odor inside the cooling storage space in a household refrigerator. Further, the present invention can also be applied to a deodorizing device provided in a ventilation path in an air conditioner or a smoke separator placed in a public place.

It is a deodorizing system schematic diagram in the range hood which shows one Embodiment of this invention. It is a comparative graph showing 1 Example of this invention and the conventional deodorizing performance measurement result.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Deodorizing device 2 Air path 3 Photocatalyst module 4 Ozone decomposition means 5 Photocatalyst filter 6 Discharge electrode 7 Counter electrode 9 High voltage power supply device
11 fans
12 Power supply for heating

Claims (7)

  A deodorizing mechanism comprising ozone generating means and ozone decomposing means is provided in the air blowing path of the main body equipped with the blower fan, and a support member carrying the ozone decomposing catalyst in the ozone decomposing means is formed of a conductive member. A deodorizing apparatus, wherein the ozone decomposition catalyst is heated by energizing a support.   The deodorizing apparatus according to claim 1, wherein the support of the ozonolysis means is mainly composed of conductive ceramic.   The deodorizing apparatus according to claim 1, wherein the support of the ozonolysis means is mainly composed of aluminum.   2. A deodorizing apparatus according to claim 1, wherein the ozone generating means comprises a space discharge mechanism comprising a discharge electrode and a photocatalytic filter.   2. The deodorizing apparatus according to claim 1, wherein the input to the ozone generating means is duty controlled, and the ozone decomposing means is heated when the ozone generating means is operated.   2. The deodorizing apparatus according to claim 1, wherein the input to the blower fan is duty controlled to heat the ozone decomposition means when the blower fan is operated.   The deodorizing apparatus according to any one of claims 1 to 6, wherein the deodorizing apparatus is mounted in a ventilation path of a range hood.

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