JP2008183326A - Deodorizing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a deodorizing device, maintaining enough gas quantity while ensuring deodorizing and bactericidal performance by high-density photocatalyst structure in simple constitution. <P>SOLUTION: This deodorizing device 1 includes: means 6, 7 for generating ozone and ultraviolet rays by high-voltage discharge; a photocatalyst module 3 for decomposing the odor component and toxic substance contained in the air by the photocatalyst action of ultraviolet rays generated by the high-voltage discharge means; and an ozonolysis means 4 for decomposing ozone generated by the high-voltage discharge means. The deodorizing device 1 is disposed in a blowing passage 2' of a product body 12 including a blowing mechanism 11, and the high-voltage discharge means is energized in the non-driven state of the product body function. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a deodorizing apparatus for deodorizing by decomposing odor components and harmful substances arranged in a blower mechanism of a product.

  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 home appliances used in the living space in such an environment, attention has been focused on products that can reduce odors and airborne bacteria released from the products. The odor substance at this time includes a musty odor that grows inside the product itself in addition to the odor in a normal living space.

  Regarding the reduction of these odorous substances, there are conventional methods of deodorizing with an adsorbent typified by activated carbon or decomposing odorous components with a catalyst. In order to increase the deodorization performance of either method, it is necessary to have a high-density structure in order to increase the probability of collision with odor components, but installing a high-density structure in the airway is a pressure. There was a drawback that the loss was increased and the overall air volume was reduced. In addition, the deodorization method using activated carbon or a catalyst can reduce odorous substances, but cannot remove floating bacteria. Therefore, in order to remove this, it is necessary to install a separate sterilization mechanism.

  On the other hand, a deodorizing apparatus having a means for generating ozone and ultraviolet rays by high-voltage discharge and a photocatalyst module for decomposing odorous components and harmful substances contained in the air by photocatalytic action (for example, Patent Document 1) Reference) exists.

It is widely known that the photocatalyst in this deodorization apparatus is capable of decomposing most organic substances and effective in decomposing harmful substances because it is excited by ultraviolet rays and has a strong oxidizing power. In addition, ozone generated by discharge in the air can also decompose organic substances by its oxidizing action. Furthermore, both the photocatalyst and ozone have a sterilizing effect, and it is known that a deodorizing apparatus using both functions is excellent in a sterilizing function.
JP 2003-339839 A

  However, since the deodorization apparatus shown in Patent Document 1 has both functions of ozone and a photocatalyst deodorization and sterilization, the above-described drawback of installing two configurations of a deodorization mechanism and a sterilization mechanism is Although it is possible to solve this problem, a structure with a high photocatalyst density is required in order to achieve a high level of deodorization and sterilization performance. It was still not possible to solve the conflicting performance problem of lowering.

  The present invention has been made in consideration of the above circumstances, and provides a deodorizing apparatus that can maintain a sufficient air flow while ensuring deodorization and sterilization performance by a high-density photocatalyst structure with a simple configuration. For the purpose.

  In order to solve the above-described problems, the deodorizing apparatus of the present invention includes means for generating ozone and ultraviolet rays by high-voltage discharge in a blowing path of a product body provided with a blowing mechanism, and ultraviolet rays generated by the high-voltage discharging means. A deodorizing device provided with a photocatalyst module that decomposes odorous components and harmful substances contained in the air by photocatalytic action by means of, and an ozone decomposition means that decomposes ozone generated by the high-voltage discharge means The high-voltage discharge means is energized when the product main body function is not driven.

  According to the configuration of the deodorizing apparatus of the present invention, the excitation of the photocatalyst having a high density structure by high-voltage discharge provides a deodorizing and sterilizing effect with a long life and excellent performance, and a simple structure to the deodorizing apparatus. Sufficient air volume can be secured.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a schematic basic configuration diagram of a deodorizing device (1) attached to an electric device such as a home air conditioner, a vacuum cleaner, a humidifier, or a dehumidifier. For example, it is provided in a target area where deodorization is performed in a cleaner body. Is disposed in the air path (2). This deodorization apparatus (1) includes a photocatalyst module (3) and an ozone decomposition catalyst (4), and adsorbs and deodorizes odor molecules and organic substances contained in the air flowing through the air passage (2). is there.

  In the photocatalyst module (3), two photocatalyst filters (5) in which photocatalyst particles typified by titanium oxide are fixed are adjacent to the surface of a substrate made of a porous ceramic such as alumina or silica. The discharge electrodes (6) are erected, and counter electrodes (7a) (7b) formed in the same manner as the discharge electrodes are provided on the upwind and leeward sides of the two photocatalytic filters (5a) (5b), respectively. It is composed by arranging.

  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 (7a) (7b) by a high voltage generator (10) such as a transformer. With this configuration, the discharge electrode (6) and the counter electrodes (7a) and (7b) 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, which promotes air circulation by arranging the photocatalyst module (3) and the ozone decomposition catalyst (4) with the fan (11) on the leeward side in the air passage (2). 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 (7a) and (7b) 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 filters (5a) and (5b) are irradiated with the generated ultraviolet rays to excite the photocatalyst, and the generated active oxygen flows down the air path (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 (5a) and (5b) and deodorizes them by deodorizing or reducing the odor.

  In addition, the bacterial cell membrane is embrittled and antibacterial, and the oxidative degradation action suppresses the growth of microorganisms on the surface of the photocatalyst filters (5a) and (5b), in particular aerobic bacteria, so Decompose and remove dirt.

  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) has a function of decomposing organic substances by generation of active oxygen due to ultraviolet rays, and ozone. It also functions as a generating means, and the odor component can be oxidatively decomposed and deodorized by mixing and reacting with the generated ozone with the air containing the odor component.

  On the lee side of the photocatalyst module (3), an ozone decomposing catalyst (4) made of a honeycomb-shaped sintered body mainly composed of manganese dioxide is provided at a predetermined distance, and it remains as it is without reacting with odorous substances. Excess ozone exceeding a predetermined value that flows down is decomposed. The ozone generating means is not limited to the one using the photocatalyst module (3), but may be a combination of a creeping discharge electrode and a high voltage transformer or an electrolytic method.

  FIG. 2 shows a configuration in which the deodorizing device (1) is disposed in the main body (12) of a vacuum cleaner, and is a product having a dust suction air passage (13). When the switch for driving the main body (12) is in an OFF state, the high-voltage power supply device (9) is energized, and a high voltage is applied from the high voltage generator (10) to the discharge electrode (6) of the photocatalyst module (3). The deodorizing device (1) is operated by applying high voltage discharge.

  That is, when the vacuum cleaner is taken out of the storage place to clean the room, the cord plug is pulled out and the tip plug is connected to the power outlet, the power source (9) is energized, and the electrodes (6) (7 ) Is discharged by supplying a high voltage between them and irradiating the photocatalyst filters (5a) and (5b) with UV light to activate the photocatalyst. The fan (11 ') is also driven.

  The energization action to the high-voltage power supply device (9) that performs this deodorizing operation is controlled so that the user operates the hand switch of the cleaner body (12) to start the dust suction operation and ends at the same time. ing.

  At this time, a bypass air passage (2 ') is provided in a part of the dust suction air passage (13) of the cleaner body (12), and the deodorizing device (1) is disposed in the bypass air passage (2'). Is arranged. The air inlet (15) and the air outlet (16) formed at both ends of the bypass air passage (2 ') for communicating the bypass air passage (2') and the dust suction air passage (13). Each has a damper (17) (18) pivotally supported at one end, and the dust suction air passage (13) located between the dampers (17) (18) A suction fan (11 ') and a dust collecting part (19) for sucking in dust from the floor and the like are arranged.

  When the dampers (17) and (18) are cleaned by operating a vacuum cleaner, the air inlet (15) and the outlet (16) are closed, and the power plug is connected to an outlet. When the hand switch of the cleaner main body (12) is turned off, it is rotated to close the dust suction air passage (13) as shown in FIG.

  Therefore, when the power plug is inserted into the power outlet in order to use the vacuum cleaner, the fan (11 ') of the vacuum cleaner body (12) is driven and the deodorizing device (1) is activated. The dampers (17) and (18) are in the state shown in FIG. 3, the dust suction air passage (13) is closed, the air inlet (15) and the outlet (16) are opened, and the bypass circuit (2 ') side is opened. As the fan (11 ') is rotated, the air in the air passage is changed to the dust suction air passage (13) blocked by the damper (17) (18) and the bypass air passage (2') by the rotation of the fan (11 '). ), The odorous substance from the dust collecting part (19) is deodorized by passing through the deodorizing device (1) without flowing out to the outside.

  Next, when the user turns on the hand switch of the cleaner body (12) to start the cleaning work, the energization to the high-voltage power supply device (9) of the deodorizing device (1) is terminated, and the deodorizing action is performed. Simultaneously with the stop, the dampers (17) and (18) are rotated to close the bypass air passage (2 ') and open the dust suction air passage (13).

  By this action, the flow of wind in the air passage is switched, and a straight air flow as shown by the arrow in FIG. 2 is formed in the dust suction air passage (13), so that the waste sucked from the suction port of the vacuum cleaner. Is sucked with a strong force without receiving air resistance caused by passing through the deodorizing device (1) and accumulated in the dust collecting part (19).

  At this time, air sucked from the outside due to blockage of the bypass air passage (2 ') by the dampers (17) and (18) does not flow into the deodorizing device (1) portion, thus preventing dust and the like from adhering, A decrease in performance can be suppressed.

  In this way, by performing the deodorizing operation before the vacuum cleaner operation, the odor in the vacuum cleaner body (12) can be removed, so when the vacuum cleaner is operated as before, the odor accumulated inside It is possible to prevent an unpleasant feeling by diffusing outside the main body at once, and it is particularly effective for deodorizing a musty odor having a generation source inside the main body.

  When the cleaning operation is further stopped, that is, when the user turns off the hand switch of the vacuum cleaner main body (12) with the power plug connected by moving the place, the damper (17) (18) each time If the deodorizing device (1) is operated at the same time as opening and closing the door, the deodorizing operation removes the odor of the dust accumulated in the dust collecting part (19) and leaks bad odors into the room. It can be cleaned in a comfortable atmosphere and can suppress unpleasant odors when the dust accumulated in the dust collector (19) is discarded after cleaning, and the cleaner body (12) During the operation, it is not necessary to perform a complicated operation of removing or reattaching the deodorizing device (1) from the air passage each time, and effective cleaning and deodorizing operations can be performed.

  In addition, according to the said deodorizing apparatus (1), not only the odor of the dust collecting part (19) can be removed by the photocatalytic action and the generated ozone, but also the odor inside the cleaner body (12) can be reduced, Since it also has a sterilizing action, it is possible to effectively suppress the propagation of germs even if the vacuum cleaner is not used.

  Next, a second embodiment of the present invention will be described with reference to FIG. The present embodiment does not use the bypass air passage (2 ') and the dampers (17) and (18) as compared with the above embodiment, and the dust collecting portion (19) and the fan (11') in the dust suction air passage (23). ) A concave portion (25) is provided between the installation portion and the deodorizing device (1) similar to the above-described embodiment can be accommodated and removed from the concave portion (25). .

  When the cleaner body (22) is operated and cleaned, as shown in FIG. 4, the deodorizing device (1) is housed in the recessed portion (25) so that the dust suction air passage (23 ) Is prevented from projecting in, and the air resistance is decreased to increase the dust absorption force.

  When the deodorizing device (1) is operated, by turning off the hand switch of the cleaner body (22) with the power plug inserted into the outlet, the deodorizing device ( 1) projecting from the recess (25) so as to be located in the dust suction air passage (23) and applying a high voltage to the deodorizing device (1) to activate the deodorizing action by the photocatalyst. As shown in FIG. 5, the odorous substance of the dust sucked into the dust collecting part (19) by the fan (11 ') flows downstream and the deodorizing device is driven. By passing through (1), it is deodorized and becomes odorless air and flows out of the cleaner body (22).

  According to the structure of the said Example, when the cleaner main body (22) is in cleaning operation, the deodorizing apparatus used as an air resistance body in a garbage suction air path (23) like the said 1st Example Since (1) does not exist, the vacuum cleaner can ensure a strong suction force and maintain the cleaning function. When the cleaning operation is not performed, that is, when the hand switch is turned off, the deodorizing device (1) In the dust suction air passage (23), the deodorizing function is activated, so that the cleaning and the deodorizing function can be effectively activated. The deodorizing device (1) can be arranged without providing a large bypass air passage (2 '), and the vacuum cleaner main body can be made compact without increasing the outer shape.

  In each of the above embodiments, the energization control of the high-voltage discharge means in the deodorizing device (1) is performed by a hand switch for cleaning from the time when the power plug of the cleaner body (12) (22) is inserted into the outlet. This is done when the cleaning function is not activated until it is turned on, and when the function of the vacuum cleaner main body (12) (22) is changed from the running state to the stopped state. However, the deodorizing operation may be performed only after the power plug is inserted into the outlet until the hand switch is turned on.

  Further, the deodorizing operation may be performed only when the vacuum cleaner main body function is changed from the operating state to the stopped state. Further, the high-voltage discharging means may be energized for several seconds after receiving the operation signal for the cleaner main body function, and then controlled so as to drive the main body function such as performing a cleaning operation.

  If the power source for driving the deodorizing function in the deodorizing device (1) is a battery, the deodorizing function can be activated even if the power plugs of the cleaner main bodies (12) and (22) are removed from the outlet.

  Further, in each of the above embodiments, the deodorizing device is described as an example attached to the main body of the vacuum cleaner. However, the target product of the present invention is not limited to this, and an air conditioner, a humidifier, a dehumidifier, or a range is used. The present invention can be applied to an electric device having a blower mechanism in a product main body such as a hood.

It is a schematic basic block diagram of a photocatalyst deodorizing apparatus. It is the schematic which shows the deodorizing apparatus arrange | positioned in the air path of the product of one Embodiment of this invention. It is the schematic which shows the air path state at the time of a deodorizing driving | operation with respect to FIG. It is the schematic of the product air path which provided the deodorizing apparatus which shows the other Example of this invention. It is the schematic which shows the air path state at the time of a deodorizing driving | operation with respect to FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Deodorizing device 2 Air path 2 'bypass air path 3 Photocatalyst module 4 Ozone decomposition catalyst 6 Discharge electrode 7 Counter electrode
10 High voltage generator
11, 11 ′ fans
12, 22 Vacuum cleaner body
13, 23 Garbage suction air passage
15 Air inlet
16 Air outlet
17, 18 damper
19 Dust collector
25 Recess

Claims (7)

  Means for generating ozone and ultraviolet rays by high voltage discharge in the air flow path of the product body equipped with the air blowing mechanism, and odor components contained in the air by photocatalysis by the ultraviolet rays generated by the high voltage discharge means A deodorizing device provided with a photocatalyst module for decomposing toxic substances and the like and an ozone decomposing unit for decomposing ozone generated by the high voltage discharging unit is disposed, and the activation of the high voltage discharging unit is controlled by the product main body function A deodorizing device characterized in that the deodorizing device is used when the vehicle is not driven.   2. The deodorizing apparatus according to claim 1, wherein the energizing of the high voltage discharging means is performed when the product main body function is changed from the operating state to the stopped state.   2. The deodorizing apparatus according to claim 1, wherein the high voltage discharging means is energized for a predetermined time from the time when the product main body function receives the operation signal, and then the product main body function is driven.   2. The deodorizing apparatus according to claim 1, wherein the high voltage discharging means is energized from the time when the power plug of the product is inserted into the outlet until the drive switch of the product main body is turned on.   The deodorizing apparatus according to claim 1, wherein the deodorizing apparatus main body is disposed in a bypass air passage provided in a ventilation path of the product main body.   2. The deodorizing apparatus according to claim 1, wherein when the deodorizing function is not driven, the deodorizing apparatus main body is detached from the inside of the bypass air passage of the air blowing path of the product main body and stored in the accommodating portion outside the bypass air passage.   The deodorizing apparatus according to claim 1, wherein a power source for driving the deodorizing function is a battery.

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