JP2007196199A - Discharge device, air cleaning apparatus and air-flow generating device equipped with the discharge device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air cleaning apparatus equipped with a discharge device which has simple structure without increasing the number of parts and has air blowing efficiency free from degradation. <P>SOLUTION: The discharge device 20 is provided in the air cleaning apparatus 10 cleaning air to be treated, and has a discharge circuit 50 performing streamer discharging between a discharge electrode 30 and a counter electrode 40. Discharge current between the discharge electrode 30 and counter electrode 40 is set to 80μA, larger than a current value corresponding to the maximum value of ozone generation characteristics which lowers after an increase in the amount of ozone generation due to an increase in the discharge current. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

    The present invention relates to a discharge device, and an air purification device and a wind generating device including the discharge device, and particularly relates to measures against ozone.

    Conventionally, discharge devices have been applied to electrostatic precipitators, air purifiers, wind generators, and the like. For example, in the invention according to Patent Document 1, a discharge electrode and a counter electrode are arranged in a duct, and a corona discharge is generated between the discharge electrode and the counter electrode to generate an ionic wind, and the fine particles in the air are generated. It is charged and collected in the dust collector.

    Further, the invention according to Patent Document 2 generates corona discharge between a discharge line and a dust collecting electrode plate in a duct, and air attracted by ionic wind flows in the duct to pre-filter relatively large dust. At the same time, small dust is collected by the dust electrode plate.

    In the invention according to Patent Document 3, corona discharge is generated between the discharge electrode and the perforated flat plate electrode to generate an ion wind so that the air flows along the cylindrical electrode.

On the other hand, in the above discharge device, ozone is generated by the discharge. Therefore, in the invention according to Patent Document 1, the discharge electrode is heated by a heating element to thermally decompose ozone. In the invention according to Patent Document 2, ozone is decomposed by ultraviolet light emitted from an ultraviolet lamp. In the invention according to Patent Document 3, ozone is decomposed or adsorbed by a catalyst or activated carbon applied to a cylindrical electrode.
JP-A-7-63650 JP-A-8-238441 JP-A-10-199653

    However, in each conventional discharge device, since ozone is generated, a heating element, a catalyst, an ultraviolet lamp, and the like are provided, which causes a problem that the number of parts is large, the structure is complicated, and the cost is increased. there were. In addition, when a catalyst or the like is provided, there is a problem that ventilation resistance increases and blowing efficiency decreases.

    The present invention has been made in view of the above points, and has a discharge device that does not increase the number of parts, simplifies the structure, and does not lower the blowing efficiency, and an air purification device including the discharge device. And it aims at providing a wind-up device.

    The first invention includes a discharge circuit (50) that discharges between the discharge electrode (30) and the counter electrode (40). The discharge current between the discharge electrode (30) and the counter electrode (40) is a current value corresponding to the maximum value of the ozone generation characteristic that decreases after the amount of ozone generation increases as the discharge current increases. Is set larger than.

    In the first invention, the amount of ozone generation is reduced or eliminated by controlling the discharge current.

    That is, conventionally, it has been considered that the amount of ozone generated increases as the discharge current increases. As a result of intensive studies over many years on the relationship between the discharge current and the amount of ozone generated, the inventors of the present application have shown that, as shown in FIG. 2, the ozone generation amount increases as the discharge current increases. It has been found that when the discharge current increases from the current value, the amount of ozone generated decreases, and when the discharge current further increases, ozone is not generated.

    Therefore, in the present invention, the discharge current is made larger than the current value corresponding to the maximum value of the ozone generation characteristic C that decreases after the ozone generation amount increases with the increase of the discharge current.

    According to a second invention, in the first invention, the discharge current is 30 μA or more per discharge electrode (30), and in a third invention, the discharge current is one discharge in the first invention. It is 80 μA or more for the electrode (30).

    In the second aspect of the invention, the amount of generated ozone is reduced, and in the third aspect of the invention, there is no amount of generated ozone.

    In a fourth aspect based on the first aspect, the discharge circuit (50) is provided with a resistor (52) for limiting a current.

    In the fourth aspect of the invention, an electrical short circuit between the discharge electrode (30) and the counter electrode (40) is prevented, and a stable discharge is generated.

    The fifth invention is directed to an air purification device that includes the discharge device of the first invention and purifies the air to be treated. The discharge circuit (50) is configured to perform streamer discharge between the discharge electrode (30) and the counter electrode (40). The discharge electrode (30) and the counter electrode (40) The air to be treated is configured to flow between the discharge electrode (30) and the counter electrode (40).

    In the fifth aspect of the invention, the amount of generated ozone is reduced or eliminated, so that extremely safe air purification is performed.

    The sixth invention is directed to a wind-up device that includes the discharge device of the first invention and generates an ionic wind. The discharge electrode (30) and the counter electrode (40) are configured to generate an ion wind by discharge between the discharge electrode (30) and the counter electrode (40).

    In the sixth aspect of the invention, since the amount of ozone generation is reduced or eliminated, extremely safe ventilation is performed.

    According to the present invention, the amount of ozone generation can be reduced by controlling the discharge current, and the amount of ozone generation can be eliminated.

    In addition, it is not necessary to provide a heating element, a catalyst, an ultraviolet lamp, etc., compared to the conventional case where after-the-fact measures were taken after ozone is generated, and at the same time the number of parts can be reduced, The structure can be simplified. As a result, cost reduction can be achieved.

    Moreover, since it is not necessary to provide a catalyst etc., ventilation resistance can be reduced significantly, so that the blowing efficiency can be improved.

    According to the second aspect of the invention, the amount of ozone generation can be reliably reduced, and according to the third aspect of the invention, the amount of ozone generation can be eliminated.

    According to the fourth aspect of the invention, since the resistor (52) is provided, an electrical short circuit between the discharge electrode (30) and the counter electrode (40) can be surely prevented, so that it can be stably performed. A discharge can be generated.

    According to the fifth aspect of the invention, the amount of generated ozone is reduced or eliminated, so that extremely safe air purification can be performed.

    According to the sixth aspect of the present invention, the amount of ozone generation is reduced or eliminated, so that extremely safe ventilation can be performed.

    Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

<Embodiment 1 of the Invention>
In the present embodiment, as shown in FIG. 1, the air purifier (10) is provided with a discharge device (20). In particular, the discharge device (20) generates a streamer discharge B.

    The discharge device (20) includes a discharge circuit (50) having a plurality of discharge electrodes (30) and a plurality of counter electrodes (40). The counter electrode (40) faces the discharge electrode (30).

    The discharge electrode (30) serves as a base point of the streamer discharge B, and is constituted by a rod-like or linear discharge needle. The discharge electrode (30) is attached to the discharge side support member (31). The discharge-side support member (31) includes a flat plate member (32) and a plurality of projecting members (33) held by the flat plate member (32) at a predetermined interval. The discharge electrode (30) is provided on both end faces of the protruding member (33).

    The counter electrode (40) is formed in a flat plate shape and is attached to the counter-side support member (41). The discharge electrode (30) is disposed so as to face the discharge electrode (30) and substantially parallel to the front surface of the counter electrode (40). Specifically, the interval A between the discharge electrode (30) and the discharge electrode (30) is set to 4 mm.

    On the other hand, the air F to be treated such as room air flows in parallel with the counter electrode (40) and flows between the discharge electrode (30) and the counter electrode (40). The discharge circuit (50) is configured to generate a streamer discharge B between the discharge electrode (30) and the counter electrode (40), and low temperature plasma is generated by the streamer discharge B. And although not shown in figure, since the said air purification apparatus (10) is equipped with the catalyst filter, the highly reactive substance in the low temperature plasma by discharge is further activated, and the harmful component and odor component in to-be-processed air are removed. Decompose.

    The discharge electrode (30) and the counter electrode (40) are connected to a power source (51) through a discharge-side support member (31) to constitute the discharge circuit (50). The power source (51) is a DC power source. Furthermore, the discharge circuit (50) is provided with a limiting resistor (52) for limiting the current. The limiting resistor (52) is provided between the counter electrode (40) and the power source (51).

    As a feature of the present invention, the discharge device (20) is characterized in that the discharge current between the discharge electrode (30) and the counter electrode (40) decreases after the ozone generation amount increases with the increase of the discharge current. It is set larger than the current value corresponding to the maximum value of the ozone generation characteristic.

    For example, the power source (51) is configured with a DC power source of 5 KV to 7 KV, and the limiting resistor (52) is configured with 10 MΩ.

    Therefore, a technical principle for controlling the discharge current will be described.

    FIG. 2 shows an ozone generation characteristic C indicating the change in the amount of ozone generated per electrode with respect to the discharge current per electrode. When the discharge current starts to flow, the ozone generation characteristic C reaches a maximum value after increasing as the discharge current increases. Thereafter, when the discharge current further increases, the ozone generation amount decreases with this increase, and the ozone generation amount becomes zero (zero).

    The discharge current corresponding to the maximum value of the ozone generation amount is, for example, 30 μA, and the discharge current corresponding to the value at which the ozone generation amount is none (zero) is, for example, 80 μA.

    Therefore, in the discharge device (20) in the air purification device (10) of the present embodiment, for example, the discharge current of one discharge electrode (30) is set to 80 μA.

-Driving action-
Next, the operation of the air purification devices (10) and (10) of this embodiment will be described.

    During the operation of the air purification device (10), for example, a fan is driven and indoor air circulates in the casing. In this state, a voltage is applied to the discharge device (20).

    Since streamer discharge B is performed between the discharge electrode (30) and the counter electrode (40) of the discharge device (20), low temperature plasma is generated from the discharge electrode (30) toward the counter electrode (40). To do. This low temperature plasma generates highly reactive active species (electrons, ions, ozone, radicals, etc.). When these active species reach the catalyst filter (not shown), they are further activated to decompose and remove harmful components and odor components in the air. Clean indoor air from which harmful components and odor components are also removed is blown into the room.

    In particular, the discharge device (20) is set so that, for example, the discharge current of one discharge electrode (30) is 80 μA, so that ozone is not generated as shown in FIG.

    The discharge circuit (50) suppresses the occurrence of sparks by the limiting resistor (52). That is, if dust adheres to the surface of the discharge electrode (30) or an error occurs in the distance between the discharge electrode (30) and the counter electrode (40), the discharge characteristics vary. In addition, since the discharge current is set large for streamer discharge, sparks may occur. Therefore, the limiting resistor (52) suppresses the occurrence of sparks.

-Effect of Embodiment 1-
As described above, according to the first embodiment, it is possible to eliminate the amount of ozone generation by controlling the discharge current.

    In addition, it is not necessary to provide a heating element, a catalyst, an ultraviolet lamp, etc., as compared with the conventional case where after-the-fact measures are taken after ozone is generated, and at the same time, the number of parts can be reduced, The structure can be simplified. As a result, cost reduction can be achieved.

    Moreover, since it is not necessary to provide a catalyst etc., ventilation resistance can be reduced significantly, so that the blowing efficiency can be improved.

    Further, since the limiting resistor (52) is provided, an electrical short circuit between the discharge electrode (30) and the counter electrode (40) can be surely prevented, so that the streamer discharge B can be stably generated. Can be generated.

    In addition, since the amount of ozone generation is completely eliminated, extremely safe air purification can be performed.

<Embodiment 2 of the invention>
As shown in FIG. 3, in the present embodiment, the counter electrode (40) is configured by one common electrode instead of the first embodiment including a plurality of counter electrodes (40).

    The counter electrode (40) is composed of one flat plate electrode, is opposed to the discharge electrode (30), and is arranged so that the discharge electrode (30) is substantially parallel. In the discharge circuit (50), the limiting resistor (52) is provided between the power source (51) and the discharge electrode (30). Other configurations, operations, and effects are the same as those of the first embodiment, and in particular, the discharge current is set to be larger than the current value corresponding to the maximum value of the ozone generation amount, and, for example, the ozone generation amount is zero (zero). 80 μA corresponding to the value.

Embodiment 3 of the Invention
In this embodiment, as shown in FIGS. 4 and 5, the discharge device (20) is applied to the wind-up device instead of the air purification device (10) in the first embodiment.

    The wind generating device generates a streamer discharge B to generate an ion wind F, and a plurality of discharge electrodes (30) and a plurality of counter electrodes (40) are arranged inside the ventilation path. ing.

    The counter electrode (40) is formed in a flat plate shape, and a plurality of counter electrodes (40) are arranged in parallel at predetermined intervals.

    On the other hand, the discharge electrode (30) is constituted by a protruding member protruding in a triangular shape from the flat substrate (34), and is disposed between the counter electrodes (40). The said discharge electrode (30) is arrange | positioned in parallel with a counter electrode (40), and is comprised so that it may discharge toward the counter electrode (40) of both sides from a discharge electrode (30).

    Therefore, when the streamer discharge B is generated from the discharge electrode (30) toward the counter electrode (40), an ion wind F is generated by this discharge, and the air is discharged along the ventilation path to the discharge electrode (30) and the counter electrode. It will flow in parallel with (40).

    Other configurations, operations, and effects are the same as those of the first embodiment, and in particular, the discharge current is set to be larger than the current value corresponding to the maximum value of the ozone generation amount, and, for example, the ozone generation amount is zero (zero). 80 μA corresponding to the value. As a result, according to the present embodiment, the amount of ozone generation is reduced or eliminated, and therefore extremely safe ventilation can be performed.

<Embodiment 4 of the Invention>
In the present embodiment, as shown in FIG. 6, the ion wind F flows in parallel to the counter electrode (40) in the third embodiment, but the ion wind F is orthogonal to the counter electrode (40). It was made to flow through.

    Specifically, the counter electrode (40) is configured in a single flat plate as in the second embodiment, and a plurality of openings (42) are formed in the counter electrode (40). The opening (42) is formed at a position corresponding to the tip of the discharge electrode (30).

    The discharge electrode (30) is disposed so as to face the counter electrode (40) and to be substantially parallel to the counter electrode (40), as in the second embodiment.

    Therefore, when the streamer discharge B is generated from the discharge electrode (30) toward the counter electrode (40), an ion wind F is generated by the discharge, and the air passes through the opening (42) of the counter electrode (40). It flows in the direction orthogonal to the counter electrode (40).

    Other configurations, operations, and effects are the same as those of the third embodiment. In particular, the discharge current is set to be larger than the current value corresponding to the maximum value of the ozone generation amount, and, for example, the ozone generation amount is zero (zero). 80 μA corresponding to the value.

<Embodiment 5 of the Invention>
As shown in FIGS. 7 and 8, the present embodiment is different from the embodiment 3 in that the discharge is performed from one discharge electrode (30) to two counter electrodes (40). 30) to one counter electrode (40).

    Specifically, the discharge electrode (30) is constituted by a protruding member protruding in a triangular shape from the flat substrate (34), and is disposed between the counter electrodes (40). The discharge electrode (30) is bent from the substrate (34) toward the counter electrode (40), and alternately faces the counter electrode (40) on both sides, and from the discharge electrode (30) to one counter electrode (40). It is comprised so that it may discharge toward.

    Other configurations, operations, and effects are the same as those of the third embodiment. In particular, the discharge current is set to be larger than the current value corresponding to the maximum value of the ozone generation amount, and, for example, the ozone generation amount is zero (zero). 80 μA corresponding to the value.

<Other embodiments>
The present invention may be configured as follows with respect to the first embodiment.

    In the discharge devices (20) of the first to fifth embodiments, the discharge current is set to 80 μA, but may be set to 30 μA, which is larger than the current value corresponding to the maximum value of the ozone generation amount. Thereby, the amount of ozone generation can be reduced.

    Moreover, although the discharge apparatus (20) of the said Embodiment 1- Embodiment 5 was applied to the air purification apparatus (10) or a wind-up apparatus, the discharge apparatus (20) of this invention is not restricted to these, Discharge apparatus (20) It can be used alone or applied to various devices.

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful for a discharge device including a discharge electrode and a counter electrode, and an air purification device and a wind generating device including the discharge device.

It is a schematic block diagram explaining the outline of the air purification apparatus of Embodiment 1. FIG. It is a characteristic view which shows the ozone generation characteristic of the discharge device of Embodiment 1. It is a schematic block diagram explaining the outline of the air purification apparatus of Embodiment 2. FIG. It is a schematic block diagram explaining the outline of the air purification apparatus of Embodiment 3. It is a schematic perspective view of the discharge electrode and counter electrode of Embodiment 3. It is a schematic block diagram explaining the outline of the air purification apparatus of Embodiment 4. It is a schematic front view explaining the outline of the air purification apparatus of Embodiment 5. It is a schematic side view explaining the outline of the air purification apparatus of Embodiment 3.

Explanation of symbols

10 Air purifier
20 Discharge device
30 Discharge electrode
40 Counter electrode
50 Discharge circuit
51 Power supply
52 Limiting resistor
60 Winding device

Claims (6)

It has a discharge circuit (50) that discharges between the discharge electrode (30) and the counter electrode (40),
The discharge current between the discharge electrode (30) and the counter electrode (40) is larger than the current value corresponding to the maximum value of the ozone generation characteristic that decreases after the ozone generation amount increases with the increase of the discharge current. A discharge device characterized by being set large. In claim 1,
The discharge device, wherein the discharge current is 30 μA or more for one discharge electrode (30). In claim 1,
The discharge device, wherein the discharge current is 80 μA or more for one discharge electrode (30). In claim 1,
A discharge device characterized in that the discharge circuit (50) is provided with a resistor (52) for limiting current. An air purification device comprising the discharge device according to claim 1 for purifying air to be treated,
The discharge circuit (50) is configured to perform a streamer discharge between the discharge electrode (30) and the counter electrode (40),
The discharge electrode (30) and the counter electrode (40) are configured such that the air to be treated flows between the discharge electrode (30) and the counter electrode (40). apparatus. A wind-up device comprising the discharge device according to claim 1 and generating an ion wind,
The discharge electrode (30) and the counter electrode (40) are configured to generate an ion wind by discharge between the discharge electrode (30) and the counter electrode (40). Wind device.

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