JP3709449B1 - Gas processing equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the size of a gas processing apparatus that performs electrostatic dust collection and decomposition of odor or the like by plasma.
In a casing (20) of an air purification device (10), a plasma generator (40) is integrally incorporated in an ionization section (32). The ionization part (32) includes an ionization line (35), and a columnar portion having a U-shaped cross section in the negative electrode member (37) forms the counter electrode (36). The plasma generator (40) includes a discharge electrode (41) and shares the counter electrode (36) with the ionization line (35). During operation of the air purification device (10), relatively small dust in the indoor air is charged by the discharge between the ionization line (35) and the counter electrode (36) and collected by the electrostatic filter (33). . Low temperature plasma is generated by the streamer discharge between the discharge electrode (41) and the counter electrode (36), and harmful substances and odorous substances in the indoor air are decomposed by the active species contained therein.
[Selection] Figure 1

Description

  The present invention relates to a gas processing apparatus that performs discharge to remove dust, odors, and the like in the air.

  Conventionally, as a kind of gas processing apparatus, as disclosed in Patent Document 1, an air cleaner that discharges and removes dust, odor, and the like in the air is known. This air cleaner is provided with a dust collection filter and a plasma generator. The plasma generating device is provided with a plasma generating electrode plate and a counter electrode plate, and by applying a discharge voltage to both electrode plates, a streamer discharge is caused to generate plasma.

In the air cleaner, dust in the air is collected by the dust collection filter. In the plasma generator, malodorous components in the air are decomposed and removed by a highly reactive substance (active species) contained in the plasma generated by the streamer discharge. Then, the clean air from which dust and malodorous components have been removed is discharged to the outside of the air cleaner as supply air.
JP 2001-218828 A

  As described above, in the air cleaner disclosed in Patent Document 1, dust is removed by filtration using a dust collection filter. On the other hand, so-called electrostatic dust collection is also known as means for removing dust in the air. That is, there is generally known a dust collection method in which dust in the air is charged by corona discharge and the charged dust is collected by an electrostatic filter (electric dust collecting member). If this electric dust collection is adopted, it is possible to remove even finer dust than when the air is simply filtered by a dust collection filter. It is also conceivable to apply electric dust collection to the air cleaner of Patent Document 1 to improve the dust collection capacity.

  However, if electric dust collection is employed in a gas processing apparatus that uses the plasma as described above for deodorization or the like, the apparatus becomes large. This point will be described. When electric dust collection is adopted, in addition to the discharge electrode and counter electrode for streamer discharge that generate plasma, the discharge electrode and counter electrode for corona discharge that charge dust must be installed in the air passage. That is, it is necessary to provide two sets of discharge electrodes and counter electrodes. For this reason, a space for installing the discharge electrode and the counter electrode for charging the dust is required, and the gas processing apparatus is enlarged accordingly.

  This invention is made | formed in view of this point, The place made into the objective is to aim at the compactization regarding the gas processing apparatus which performs what is called electrostatic dust collection and decomposition | disassembly of the odor etc. by plasma.

A first invention is directed to a gas processing apparatus that collects dust in a gas to be processed and decomposes a component to be processed in the gas to be processed. Then, a plurality of first discharge electrodes (35) that cause discharge between the counter electrode (36) and the counter electrode (36) so that dust in the gas to be processed is charged, and the charged electrode A plurality of electrical dust collecting members (33) that collect dust in the processing gas and a plurality of electrodes that cause discharge between the counter electrode (36) so as to generate plasma for decomposing the components to be processed. and a second discharge electrode (41), the first discharge electrode (35) and the second discharge electrode (41), are arranged on the same plane a the plane perpendicular to the flow of the gas to be treated It is what.

The second invention is directed to a gas processing apparatus that collects dust in a gas to be processed and decomposes a component to be processed in the gas to be processed. And the 1st discharge electrode (35) which raise | generates discharge between a counter electrode (36) and the said counter electrode (36) so that the dust in the said process gas may be charged, and the said to-be-processed gas charged A second discharge electrode for causing discharge between the electric dust collecting member (33) for collecting the dust therein and the counter electrode (36) so as to generate plasma for decomposing the component to be treated (41), so that the discharge between the second discharge electrode (41) and the counter electrode (36) is performed from the downstream side to the upstream side of the flow of the gas to be processed. 36) is positioned on the upstream side of the flow of the gas to be treated, Ru der which the second discharge electrode (41) is positioned downstream of the flow of the gas to be treated.

A third invention is directed to a gas processing apparatus that collects dust in a gas to be processed and decomposes a component to be processed in the gas to be processed. And the 1st discharge electrode (35) which raise | generates discharge between a counter electrode (36) and the said counter electrode (36) so that the dust in the said process gas may be charged, and the said to-be-processed gas charged A second discharge electrode for causing discharge between the electric dust collecting member (33) for collecting the dust therein and the counter electrode (36) so as to generate plasma for decomposing the component to be treated (41), the counter electrode (36) is formed in a columnar shape with a U-shaped cross section, and at least the second discharge electrode (41) is disposed inside the counter electrode (36). Is.

The fourth invention is directed to a gas processing apparatus that collects dust in a gas to be processed and decomposes a component to be processed in the gas to be processed. Then, a discharge is caused between the electrode member (37) formed in a corrugated plate and constituting the counter electrode (36) and the electrode member (37) so that dust in the gas to be treated is charged. A first discharge electrode (35); an electric dust collecting member (33) for collecting dust in the charged gas to be treated; and the electrode member so as to generate plasma for decomposing the component to be treated. (37) and a second discharge electrode (41) for causing discharge between the first discharge electrode (35) on one surface side of the electrode member (37) and a second discharge electrode on the other surface side. A discharge electrode (41) is provided, and each of the first discharge electrode (35) and the second discharge electrode (41) is disposed inside a concave portion of the corrugated electrode member (37). is there.

According to a fifth invention, in any one of the first to fourth inventions, the electric dust collecting member (33) is constituted by an electrostatic filter.

According to a sixth invention, in any one of the first to fourth inventions, the plasma is activated by the plasma generated by the discharge between the second discharge electrode (41) and the counter electrode (36) to be processed. A plasma catalyst that promotes decomposition of components is provided. Here, the plasma catalyst preferably has an adsorption performance for the component to be treated in the gas to be treated, and more preferably one that can adsorb and decompose active species such as ozone generated by the generation of plasma.

According to a seventh invention, in any one of the first to fourth inventions, the first discharge electrode (35) is formed in a linear shape extending along the counter electrode (36), and the second discharge electrode (41) is electrically connected in the middle of the first discharge electrode (35), and the distance from the counter electrode (36) is greater than the distance between the counter electrode (36) and the first discharge electrode (35). Are also arranged to be shorter.

According to an eighth invention, in the invention according to any one of the first to fourth inventions, the plasma is activated by the plasma generated by the discharge between the second discharge electrode (41) and the counter electrode (36) to be processed. An optical semiconductor catalyst that promotes decomposition of components is provided.

In a ninth aspect based on the eighth aspect , the photosemiconductor catalyst is supported on the electric dust collecting member (33).

According to a tenth aspect , in the sixth aspect , the plasma catalyst is disposed on the downstream side of the second discharge electrode (41) and the counter electrode (36), and the second discharge electrode is disposed on the electric dust collecting member (33). The photo-semiconductor catalyst activated by the plasma generated by the discharge between the electrode (41) and the counter electrode (36) and promoting the decomposition of the component to be treated is supported, and the electric dust collecting member (33) It is arranged between the second discharge electrode (41) and the counter electrode (36) and the plasma catalyst.

-Action-
In the first to fifth inventions, the counter electrode (36) is used in combination with the first discharge electrode (35) and the second discharge electrode (41). When a voltage is applied between the first discharge electrode (35) and the counter electrode (36), a discharge is performed between them. This discharge charges the dust in the gas to be treated. The charged dust is collected by an electrical dust collecting member (electrostatic filter) (33).

  On the other hand, when a voltage is applied between the second discharge electrode (41) and the counter electrode (36), a discharge occurs between the two, and plasma is generated by this discharge. In the gas processing apparatus, harmful substances and odorous substances, which are components to be processed in the gas to be processed, are decomposed using the generated plasma.

  In this way, different types of discharge are generated between the first discharge electrode (35) and the counter electrode (36), and between the second discharge electrode (41) and the counter electrode (36). Dust and components to be processed are removed respectively.

In particular, in the third aspect of the invention, at least the second discharge electrode (41) is arranged inside the counter electrode (36) formed in a columnar shape having a U-shaped cross section. Discharge is performed between the second discharge electrode (41) and the inner surface of the counter electrode (36). In addition to the second discharge electrode (41), the first discharge electrode (35) may be disposed inside the counter electrode (36).

In the fourth aspect of the invention, the electrode member (37) is provided in the gas processing apparatus. The electrode member (37) is formed in a corrugated plate shape in which “mountains” and “valleys” are alternately repeated. The waveform of the electrode member (37) may be any waveform such as a sine wave, a rectangular wave, or a triangular wave.

  In the electrode member (37), the first discharge electrode (35) is provided on one surface side, and the second discharge electrode (41) is provided on the other surface side facing the one surface. The first discharge electrode (35) is arranged in a “valley” portion as viewed from one surface side of the electrode member (37), that is, inside the recess. On the other hand, the second discharge electrode (41) is disposed in a “valley” portion as viewed from the other surface side of the electrode member (37), that is, inside the recess. Then, discharge is performed between the first discharge electrode (35) and the electrode member (37) and between the second discharge electrode (41) and the electrode member (37).

In the sixth aspect , the plasma catalyst is provided in the gas processing apparatus. This plasma catalyst is activated by the plasma generated by the discharge performed between the second discharge electrode (41) and the counter electrode (36). The activated plasma catalyst promotes decomposition of the component to be processed in the gas to be processed.

In the seventh invention, the second discharge electrode (41) is electrically connected to the middle of the first discharge electrode (35) formed in a linear shape. That is, the first discharge electrode (35) and the second discharge electrode (41) are conductive, and the potentials of both are equal when a voltage is applied.

  In the present invention, the distance between the second discharge electrode (41) and the counter electrode (36) is shorter than the distance between the first discharge electrode (35) and the counter electrode (36). Therefore, although the potentials of the first discharge electrode (35) and the second discharge electrode (41) are equal, the second discharge electrode (41) is larger than the electric field strength between the first discharge electrode (35) and the counter electrode (36). ) And the counter electrode (36). Therefore, a stronger discharge is performed between the second discharge electrode (41) and the counter electrode (36) than between the first discharge electrode (35) and the counter electrode (36).

In the eighth aspect of the invention, the photo semiconductor catalyst is provided in the gas processing apparatus. This photo-semiconductor catalyst is generally used as a “photo-catalyst” that is activated by irradiating light, but in the present invention, the second discharge electrode (41) and the counter electrode even in a state where the light source is not irradiated. It is activated by the plasma generated by the discharge performed between (36). The activated photo-semiconductor catalyst promotes decomposition of the component to be processed in the gas to be processed.

  Here, since the photosemiconductor catalyst has a characteristic that dirt is difficult to adhere, it is possible to suppress dust and the like in the gas to be treated from adhering to the surface of the photosemiconductor catalyst and reducing the activity of the photosemiconductor catalyst. .

In the ninth aspect of the invention, the photosemiconductor catalyst is supported on the electric dust collecting member (33). And this photo-semiconductor catalyst is activated by the plasma which generate | occur | produces by the discharge performed between a 2nd discharge electrode (41) and a counter electrode (36). The activated photo-semiconductor catalyst promotes decomposition of the component to be processed in the gas to be processed.

  Moreover, the to-be-processed component (for example, tobacco spear and allergen) adhering to the electrical dust collecting member (33) can be decomposed | disassembled with an optical semiconductor catalyst. Furthermore, the growth of fungi in the electrical dust collecting member (33) can be suppressed by the photo semiconductor catalyst.

In the tenth aspect of the invention, the electrical dust collecting member (33) carrying the photosemiconductor catalyst is disposed downstream of the second discharge electrode (41) and the counter electrode (36). Further, a plasma catalyst is disposed on the downstream side of the electrical dust collecting member (33). For this reason, both the photosemiconductor catalyst of the electrical dust collection member (33) and the plasma catalyst are activated by the plasma generated by the discharge performed between the second discharge electrode (41) and the counter electrode (36). It becomes. And decomposition | disassembly of the to-be-processed component in to-be-processed gas is effectively accelerated | stimulated by the activated optical semiconductor catalyst and plasma catalyst.

  Here, when the said optical semiconductor catalyst and a plasma catalyst have different active characteristics, the to-be-processed component containing the composite odor component can be decomposed | disassembled effectively.

  In addition, when the plasma catalyst has an adsorption performance for the component to be treated in the gas to be treated, the component to be treated that has not been decomposed by the activation of the optical semiconductor catalyst and the plasma catalyst can be adsorbed and removed by the plasma catalyst.

  Furthermore, when the plasma catalyst has an adsorption decomposition performance with respect to the active species such as ozone generated during the plasma discharge, the active species such as ozone can be removed by adsorption decomposition using the plasma catalyst.

  In the present invention, the counter electrode (36) is used in combination with the first discharge electrode (35) and the second discharge electrode (41) to remove dust and components to be processed. That is, the first discharge electrode (35) and the second discharge electrode (41) do not discharge between the individual counter electrodes, but discharge between the common counter electrode (36). . Therefore, according to the present invention, by sharing the counter electrode (36) of the first discharge electrode (35) and the second discharge electrode (41), the installation space can be reduced and the gas processing apparatus can be made compact. Can be achieved.

In the fourth invention, the corrugated electrode member (37) has a first discharge electrode (35) inside the concave portion on one surface side and a second discharge electrode (41) inside the concave portion on the other surface side. Is provided. Therefore, both the first discharge electrode (35) and the second discharge electrode (41) can be disposed within the thickness range of the corrugated electrode member (37). Therefore, according to this invention, the installation space of a 1st discharge electrode (35) and a 2nd discharge electrode (41) can be reduced further, and the further compactization of a gas processing apparatus can be achieved.

According to the sixth aspect of the invention, the component to be treated in the gas to be treated is decomposed by the plasma generated by the discharge performed between the second discharge electrode (41) and the counter electrode (36), while the plasma catalyst catalyzes the treatment. The decomposition of the component to be processed in the processing gas can be promoted. Therefore, according to the present invention, the processing performance of the gas processing apparatus can be improved.

In the seventh invention, the second discharge electrode (41) is electrically connected in the middle of the first discharge electrode (35), and both the first discharge electrode (35) and the second discharge electrode (41) are connected. There is no need to individually apply a voltage to each other. For this reason, a voltage can be applied to both the 1st discharge electrode (35) and the 2nd discharge electrode (41) only by connecting the 1st discharge electrode (35) to a power supply, for example. Therefore, according to the present invention, the configuration for applying a voltage can be simplified.

According to the eighth aspect of the invention, the activation of the photo semiconductor catalyst promotes the decomposition of the component to be processed by plasma discharge, thereby improving the processing performance of the gas processing apparatus.

  In addition, since the photosemiconductor catalyst has a characteristic that dirt is difficult to adhere, it is possible to prevent dirt in the gas to be treated from adhering to the surface of the photosemiconductor catalyst and reducing the active action of the photosemiconductor catalyst. Accordingly, it is possible to stabilize the processing performance of the gas processing apparatus.

According to the ninth aspect of the invention, by supporting the photosemiconductor catalyst on the electrical dust collecting member (33), it is possible to impart the above-described active action of the photosemiconductor catalyst to the electrical dust collecting member (33). . Therefore, in a compact configuration, it is possible to obtain the dust collection effect by the electrical dust collection member (33) and the decomposition promotion effect by the photo semiconductor catalyst.

  In addition, by supporting the photo-semiconductor catalyst on the electric dust collecting member (33), the decomposition effect of the odor component adsorbed on the electric dust collecting member (33) or the sterilization in the electric dust collecting member (33) An effect can be obtained. Therefore, the life of the electrical dust collecting member (33) can be extended.

According to the tenth aspect of the invention, the electrical dust collecting member (33) carrying the photo-semiconductor catalyst and the plasma catalyst are disposed on the downstream side of the second discharge electrode (41) and the counter electrode (36). By activating both the semiconductor catalyst and the plasma catalyst, the decomposition action of the component to be treated can be promoted. Accordingly, it is possible to effectively improve the processing performance of the gas processing apparatus.

  Here, when the photo-semiconductor catalyst and the plasma catalyst have different active characteristics, it is possible to effectively decompose the component to be treated containing the composite odor component. Accordingly, it is possible to improve the processing performance of the gas processing apparatus for the gas to be processed containing the composite odor.

  Further, when the plasma catalyst has an adsorption performance for the component to be treated, the component to be treated that could not be decomposed and removed by the plasma discharge can be adsorbed and removed by the plasma catalyst. Therefore, it is possible to obtain processing performance that follows fluctuations in the concentration load of the odor component, and to improve the reliability of the gas processing apparatus.

  Further, when the plasma catalyst has an adsorption decomposition performance for active species such as ozone generated by plasma discharge, the active species such as ozone can be decomposed and removed by the plasma catalyst. Therefore, it is possible to suppress the release of active species (by-products) generated in the apparatus due to plasma discharge to the outside of the apparatus, and it is possible to further improve the reliability of the gas processing apparatus.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The gas treatment device according to the present embodiment is an air purification device (10) used in general households, small stores, and the like.

Embodiment 1 of the Invention
As shown in FIG. 1, the air purification device (10) of this embodiment is a casing comprising a box-shaped casing body (21) with one end opened and a front plate (22) attached to the open end surface. (20). Air suction ports (23) are formed on both side surfaces of the casing (20) on the front plate (22) side. The casing body (21) is formed with an air outlet (24) near the back plate of the top plate.

  In the casing (20), there is formed an air passage (25) through which indoor air, which is a gas to be treated, flows from the air inlet (23) to the air outlet (24). In this air passage (25), in order from the upstream side of the air flow, various functional parts (30) for purifying the air, and a centrifugal blower (26) for circulating indoor air in the air passage (25), Is arranged.

  The functional component (30) includes, in order from the front plate (22) side, a prefilter (31), an ionization section (32), an electrostatic filter (electrical dust collecting member) (33), and a catalyst filter (34). Is provided. A plasma generator (40) for generating low-temperature plasma is integrally incorporated in the ionization section (32).

  The pre-filter (31) is a filter that collects relatively large dust contained in room air.

  The ionization section (32) charges relatively small dust contained in the room air that has passed through the prefilter (31), and the electrostatic filter is disposed on the downstream side of the ionization section (32). For collecting according to (33).

  The ionization part (32) is provided with a negative electrode member (37) as an electrode member. The negative electrode member (37) is formed by pressing a metal plate into a corrugated plate shape, and is erected in the casing (20). Specifically, the negative electrode member (37) is formed in a corrugated plate shape having a rectangular waveform. In other words, in the negative electrode member (37), a columnar portion having a U-shaped cross section and extending vertically and a plurality of vertically elongated rectangular plate portions are alternately formed in the horizontal direction. The negative electrode member (37) is installed in such a posture that the opening side of the columnar portion having a U-shaped cross section faces the electrostatic filter (33), that is, the opening side faces the downstream side of the air flow. Yes.

  In the negative electrode member (37), the columnar portion having a U-shaped cross section constitutes the counter electrode (36). In this columnar portion, the portion orthogonal to the opening side constitutes a pair of side surface portions (37b), and the portion orthogonal to the side surface portion (37b) and located on the prefilter (31) side is the front surface portion (37a). It is composed. On the other hand, the rectangular portion sandwiched between the columnar portions constitutes the back surface portion (37c). As shown in FIG. 2, a large number of air holes (50) are opened in the back surface portion (37c). In addition, a large number of air holes (50) are also opened at positions near the back surface portion (37c) in the side surface portion (37b).

  The ionization part (32) is provided with a plurality of ionization lines (35) as first discharge electrodes. This ionization line (35) is surrounded on three sides by the inner side of the recess when the negative electrode member (37) is viewed from the prefilter (31) side, that is, the pair of side surface portions (37b) and the back surface portion (37c). It is provided inside the part. Further, the ionization line is stretched from the upper end to the lower end of the ionization section (32), and is provided so as to straddle the counter electrode (36) at the lower end. Each ionization line (35) is located at equal intervals on one virtual plane parallel to the electrostatic filter (33).

  The plasma generator (40) includes a discharge electrode (41) as a second discharge electrode, and shares the counter electrode (36) with an ionization line (35).

  As shown in FIG. 2, the discharge electrode (41) has a negative electrode member (37) as viewed from the electrostatic filter (33) side. It is provided inside the part surrounded by three sides. That is, the discharge electrode (41) is disposed inside the “U” -shaped counter electrode (36). Specifically, a columnar electrode holding member (43) having a square cross section and extending vertically is provided inside the counter electrode (36). Among the side surfaces of the electrode holding member (43), a plurality of fixing members (44) are attached at equal intervals in the vertical direction on the surface on the front surface portion (37a) side. Each fixing member (44) is provided with a discharge electrode (41). That is, the discharge electrode (41) is held by the electrode holding member (43) via the fixing member (44). The discharge electrode (41) is a linear or rod-like electrode, and is disposed so that a portion protruding from the fixing member (44) is substantially parallel to the front surface portion (37a).

  The electrode holding member (43) and the fixing member (44) are made of the same metal as the discharge electrode (41). The discharge electrode (41) and the electrode holding member (43) are conducted through the fixing member (44).

  The ionization section (32) is provided with a high-voltage DC power supply (45) for applying a voltage between the ionization line (35) and the counter electrode (36). The DC power supply (45) also serves as a power supply for the plasma generator (40). When a voltage is applied to the ionization line (35) and the discharge electrode (41) by the DC power supply (45), ions are generated around the ionization line (35), and from the tip of the discharge electrode (41) to the counter electrode (36) A streamer discharge is generated toward A high voltage (for example, 5 kV) of the same potential is applied to the ionization line (35) and the discharge electrode (41). The distance between the ionization line (35) and the counter electrode (36) is, for example, 10 mm, and the discharge electrode (41 ) And the counter electrode (36), for example, by 5 mm, the electric field strength is differentiated so that the ion generation action in the ionization section (32) and the streamer discharge action in the plasma generator (40) occur simultaneously. ing.

  The electrostatic filter (33) is disposed on the downstream side of the plasma generator (40) constituted by the discharge electrode (41) and the counter electrode (36). The electrostatic filter (33) collects relatively small dust charged by the ionization part (32) described above on the upstream surface, while the optical semiconductor catalyst is supported on the downstream surface to support the optical semiconductor. A catalyst layer (38) is formed. The photo-semiconductor catalyst of the photo-semiconductor catalyst layer (38) consists of highly reactive substances (electrons, ions, ozone, radicals, etc.) in the low-temperature plasma generated by the discharge at the discharge electrode (41) and the counter electrode (36). It is further activated by the active species) and promotes the decomposition of harmful substances and odorous substances that are components to be treated in the indoor air. For example, titanium dioxide, zinc oxide, tungsten oxide, cadmium sulfide, or the like is used as the optical semiconductor catalyst.

  The catalyst filter (34) is disposed on the downstream side of the electrostatic filter (33). The catalyst filter (34) is, for example, a plasma catalyst supported on the surface of a substrate having a honeycomb structure. This plasma catalyst, like the above-mentioned photo-semiconductor catalyst, is a highly reactive substance (electron, ion, ozone, radical, etc.) in the low temperature plasma generated by the discharge at the discharge electrode (41) and the counter electrode (36). (Active species) is further activated to promote decomposition of harmful substances and odorous substances, which are components to be treated, in the indoor air. As the plasma catalyst, a manganese-based catalyst or a noble metal-based catalyst, and those obtained by adding an adsorbent such as activated carbon to these catalysts are used.

-Driving action-
Next, the operation of the air purification device (10) will be described.

  During the operation of the air purification device (10), the centrifugal blower (26) is activated, and the indoor air that is the gas to be treated flows through the air passage (25) in the casing (20). In this state, a high voltage is applied from the DC power source (45) to the ionization unit (32) and the plasma generator (40).

  When indoor air is introduced into the casing (20), relatively large dust is first removed in the prefilter (31). The room air that has passed through the prefilter (31) flows to the ionization section (32). In the ionization part (32), relatively small dust in the indoor air is charged by the discharge between the ionization line (35) and the counter electrode (36). The room air containing the charged dust passes through the air holes (50) provided in the side surface portion (37b) and the back surface portion (37c) and flows into the electrostatic filter (33). The electrostatic filter (33) collects charged dust.

  In the plasma generator (40) integrated into the ionization part (32), low temperature plasma is generated by streamer discharge between the discharge electrode (41) and the counter electrode (36). On the other hand, during discharge, as shown by a broken line in FIG. 2, an ion wind is generated that is reflected by the front surface portion (37a) and travels downstream of the air flow. The generated low temperature plasma rides on this ion wind, passes through the ionization section (32), and flows downstream along with the room air.

  The low-temperature plasma contains a highly reactive substance (active species). The highly reactive substance comes into contact with room air flowing through the air passage (25) and decomposes harmful substances and odorous substances in the room air. When the active species reach the electrostatic filter (33), the active species are further activated by the photo-semiconductor catalyst carried on the photo-semiconductor catalyst layer (38) of the electrostatic filter (33), and harmful substances in indoor air and Odor components are further decomposed. When the active species reach the catalyst filter (34), these substances are further activated, and harmful substances and odorous substances in the indoor air are further decomposed.

  The clean indoor air from which dust is removed and harmful substances and odorous substances are removed as described above is taken into the centrifugal blower (26) and blown into the room from the air outlet (24).

-Effect of Embodiment 1-
In this embodiment, the ionization part (32) and the plasma generator (40) share the counter electrode (36). That is, the ionization line (35) and the discharge electrode (41) are not discharged between the individual counter electrodes, but are discharged between the common counter electrode (36). Therefore, according to the present embodiment, by sharing the counter electrode (36) of the ionization line (35) and the discharge electrode (41), the installation space can be reduced, and the air purification device (10) can be made compact. Can be achieved.

  According to the present embodiment, harmful substances and odorous substances in the indoor air are decomposed by plasma generated by the discharge performed between the discharge electrode (41) and the counter electrode (36), while the plasma catalyst causes The decomposition of harmful substances and odorous substances can be promoted. Therefore, according to this embodiment, the processing performance of the air purification device (10) can be improved.

  Further, in the present embodiment, the discharge electrode (41) is provided inside the counter electrode (36) having a U-shaped cross section, and the ion wind generated by the discharge is exposed to the outside of the counter electrode (36). It flows toward the downstream side of the air flow without diffusing. For this reason, the plasma generated by the discharge performed between the discharge electrode (41) and the counter electrode (36) is reliably supplied to the catalyst filter (34) together with the ion wind. Therefore, according to this embodiment, decomposition | disassembly of the harmful | toxic substance and odor substance in indoor air can be accelerated | stimulated further, and the processing performance of an air purification apparatus (10) can be improved further.

  In addition, according to the present embodiment, since the discharge electrode (41) is disposed on the downstream side of the counter electrode (36), the amount of dust and the like in the indoor air adhering to the discharge electrode (41) is greatly reduced. it can. Therefore, stable streamer discharge can be continued between the discharge electrode (41) and the counter electrode (36), and the processing performance of the air purification device (10) can be maintained.

  Furthermore, in this embodiment, the ionization line (35) is provided inside the concave portion on one surface side of the corrugated negative electrode member (37), and the discharge electrode (41) is provided inside the concave portion on the other surface side. . For this reason, both the ionization line (35) and the discharge electrode (41) can be disposed within the thickness range of the corrugated negative electrode member (37). Therefore, according to this embodiment, the installation space of the ionization line (35) and the discharge electrode (41) can be further reduced, and the air purification device (10) can be further downsized.

  Furthermore, according to this embodiment, since the photosemiconductor catalyst is supported on the electrostatic filter (33), it is possible to promote the decomposition of harmful substances and odorous substances in the indoor air by plasma. Therefore, the processing performance of the air purification device (10) can be improved. Further, by integrating the photosemiconductor catalyst into the electrostatic filter (33), the air purification device (10) can be made thinner and more compact.

  Furthermore, by supporting the photo semiconductor catalyst on the electrostatic filter (33), it is possible to obtain an effect of decomposing odor components adsorbed on the electrostatic filter (33) or a sterilizing effect on the electrostatic filter (33). . Therefore, the lifetime of the electrostatic filter (33) can be extended.

-Modification of Embodiment 1-
About the air purification apparatus (10) of the said Embodiment 1, you may change the structure of the plasma generator (40) in an ionization part (32).

  First, as shown in FIG. 3, in the first modification, the discharge electrode (41) is attached to the electrode holding member (43) of the plasma generator (40). The discharge electrode (41) is a triangular plate-shaped piece, and is erected on the side surface of the electrode holding member (43) on the front surface portion (37a) side. When a voltage is applied, streamer discharge is generated from the tip of the discharge electrode (41) toward the counter electrode (36).

  Next, as shown in FIG. 4, in the second modified example, the electrode holding member (43) of the plasma generator (40) has a portion that becomes the discharge electrode (41) in a part thereof. That is, the discharge electrode (41) is not held by the electrode holding member (43), but a plurality of portions of the electrode holding member (43) are the discharge electrodes (41) protruding at equal intervals.

  Specifically, the electrode holding member (43) is formed in a vertically long and narrow flat plate shape, and is provided in parallel with the side surface portion (37b). A plurality of triangular protrusions are provided at regular intervals on the side surface of the electrode holding member (43) on the front surface portion (37a) side. This protruding portion is a discharge electrode (41). When a voltage is applied, streamer discharge is generated from the tip of the discharge electrode (41) toward the counter electrode (36).

<< Embodiment 2 of the Invention >>
In the second embodiment of the present invention, the configuration of the ionization section (32) in the first embodiment is changed. Here, the difference between the present embodiment and the first embodiment will be described.

  As shown in FIG. 5, in the air purification device (10) of the present embodiment, a plurality of circular ventilation holes (51) are provided in the front surface portion (37a) of the ionization section (32). This ventilation hole (51) is located in the middle of each fixing member (44) provided in an electrode holding member (43). A portion of the room air that has passed through the prefilter (31) flows into the ionization section (32) through the ventilation hole (51) as shown by a solid line in FIG.

  On the other hand, in the plasma generator (40), low temperature plasma is generated by streamer discharge between the discharge electrode (41) and the counter electrode (36). The active species contained in the low temperature plasma rides on the room air that has passed through the vent hole (51) and flows to the catalyst filter (34) while diffusing throughout the air passage (25). In the catalyst filter (34), the plasma catalyst is further activated, and the decomposition of harmful substances and odorous substances in the indoor air is further promoted. Therefore, according to the present embodiment, harmful substances and odorous substances in the indoor air flowing through the air passage (25) can be reliably decomposed, and the processing performance of the air purification device (10) can be improved.

<< Embodiment 3 of the Invention >>
In the third embodiment of the present invention, the configuration of the ionization section (32) in the first embodiment is changed. Here, the difference between the present embodiment and the first embodiment will be described with reference to FIG. 6A is a plan view, and FIG. 6B is a view seen from the upstream side of the air flow. This also applies to FIG.

  In the air purification device (10) of the present embodiment, a plurality of insulators (60) are attached to the back surface portion (37c) of the ionization section (32). The insulator (60) is for insulating electrical conduction, and is provided at equal intervals in the vertical direction of the negative electrode member (37). A current-carrying member (61) is attached to the pre-filter (31) side of each insulator (60). The energizing member (61) is for conducting electricity.

  The discharge electrode (41) is attached to the surface on the side surface portion (37b) side among the side surfaces of the energization member (61) via the fixing member (44). In addition, an ionization line (35) is provided on the prefilter (31) side of the energization member (61), and the ionization line (35) is supported by the energization member (61). That is, the ionization line (35) and the discharge electrode (41) are electrically connected via the energization member (61).

  When a discharge voltage is applied to either the ionization line (35) or the discharge electrode (41), the ionization line (35) and the discharge electrode (41) have the same potential. Discharge occurs between the ionization line (35) and the counter electrode (36) of the side surface portion (37b), and between the discharge electrode (41) and the counter electrode (36) of the side surface portion (37b). Is called.

  Here, the distance between the discharge electrode (41) and the counter electrode (36) is sufficiently shorter than the distance between the ionization line (35) and the counter electrode (36), and there is a difference in the electric field strength between the two. For this reason, streamer discharge is performed between the discharge electrode (41) and the counter electrode (36), thereby generating plasma and decomposing and removing harmful substances and odorous substances in the indoor air. Moreover, the dust in room air is charged by the discharge between an ionization line (35) and a counter electrode (36).

-Modification of Embodiment 3-
In the air purification device (10) of the third embodiment, the configuration of the ionization unit (32) may be changed. Here, this modification will be described with respect to differences from the third embodiment.

  As shown in FIG. 7, in the air purification apparatus (10) of this modification, a plurality of discharge electrodes (41) are provided at equal intervals in the middle of the ionization line (35). That is, the ionization line (35) and the discharge electrode (41) are electrically connected. The discharge electrode (41) has a diamond-shaped cross section viewed from the upstream side of the air flow, and is provided so as to be symmetric with respect to the ionization line (35). Discharge occurs between the ionization line (35) and the counter electrode (36) of the side surface portion (37b), and between the discharge electrode (41) and the counter electrode (36) of the side surface portion (37b). Is called.

  In this modification, the discharge electrode (41) is electrically connected in the middle of the ionization line (35), so that it is not necessary to individually apply a voltage to both the ionization line (35) and the discharge electrode (41). . For this reason, for example, a voltage can be applied to both the ionization line (35) and the discharge electrode (41) only by connecting the ionization line (35) to a power supply. Therefore, according to this modification, the configuration for applying the voltage can be simplified.

<< Other Embodiments >>
-First modification-
In the air purification device (10) of the first and second embodiments, the configuration of the ionization unit (32) may be changed.

  As shown in FIG. 8, in the air purification device (10) of this modification, the air hole (50) provided in the negative electrode member (37) of the ionization section (32) exists only in the side surface portion (37b). Yes. That is, the air hole (50) does not exist in the back surface portion (37c). All of the room air that has flowed into the ionization section (32) passes through the air holes (50) in the side surface portion (37b), and is downstream from the opening side of the counter electrode (36) provided in the “U” shape. It flows to.

  On the other hand, in the plasma generator (40), low temperature plasma is generated by streamer discharge between the discharge electrode (41) and the counter electrode (36). The active species contained in the low-temperature plasma ride on the room air that has passed through the air holes (50), and flow into the catalyst filter (34) while diffusing throughout the air passage (25). In the catalyst filter (34), the plasma catalyst is further activated, and the decomposition of harmful substances and odorous substances in the indoor air is further promoted. Therefore, according to the present modification, harmful substances and odorous substances in the indoor air flowing through the air passage (25) can be reliably decomposed, and the processing performance of the air purification device (10) can be improved.

  In this modification, the portion constituting the rear portion (37c) and the portion constituting the front portion (37a) and the side portion (37b) are formed of separate members so that each member can have a gap. You may arrange. In this case, since the member constituting the back surface portion (37c) acts as a baffle plate, the room air that has flowed into the ionization portion (32) It flows to the downstream side through a gap provided between the members constituting (37c).

-Second modification-
In the air purification devices (10) of the first to third embodiments, the configuration of the ionization unit (32) may be changed. In the ionization part (32) of this modification, the shape of the waveform in the negative electrode member (37) is not limited to a rectangular waveform, and may be any waveform such as a sine waveform or a triangular waveform. In the negative electrode member (37), an ionization line (35) is provided on the surface on the prefilter (31) side, and a discharge electrode (41) is provided on the surface on the catalyst filter (34) side facing the surface. The ionization line (35) is disposed in a “valley” portion of the negative electrode member (37) viewed from the prefilter (31) side, that is, inside the recess. On the other hand, the discharge electrode (41) is disposed in a “valley” portion of the negative electrode member (37) viewed from the electrostatic filter (33) side, that is, inside the recess.

-Third modification-
In the above embodiment, the electrostatic filter (33) is used as the electric dust collecting member, but a dust collecting plate (electrode plate) may be used as the electric dust collecting member instead of the electrostatic filter.

-Fourth modification-
Further, in the above embodiment, the catalyst filter (34) in which a plasma catalyst such as a manganese catalyst or a noble metal catalyst is supported on a base material is provided on the downstream side of the plasma generator (40). However, instead of the catalyst filter (34), an adsorption processing member in which an adsorbent such as activated carbon or zeolite is supported on a base material may be provided on the downstream side of the plasma generator (40).

  As described above, the present invention is useful for a gas processing apparatus that performs discharge to remove dust, odor, and the like in the air.

1 is an exploded perspective view of an air purification device according to Embodiment 1. FIG. It is a principal part expansion perspective view of the ionization part in the air purification apparatus which concerns on Embodiment 1. FIG. It is a principal part expansion perspective view of the ionization part in the air purification apparatus which concerns on Embodiment 1. FIG. It is a principal part expansion perspective view of the ionization part in the air purification apparatus which concerns on Embodiment 1. FIG. It is a principal part expansion perspective view of the ionization part in the air purification apparatus which concerns on Embodiment 2. FIG. It is the schematic which shows the structure of the ionization part in the air purification apparatus which concerns on Embodiment 3. FIG. It is the schematic which shows the structure of the ionization part in the air purification apparatus which concerns on Embodiment 3. FIG. It is a principal part expansion perspective view of the ionization part in the air purification apparatus which concerns on other embodiment.

Explanation of symbols

(33) Electric dust collector (electrostatic filter)
(35) First discharge electrode (ionization line)
(36) Counter electrode (37) Electrode member (negative electrode member)
(41) Second discharge electrode (discharge electrode)

Claims (10)

A gas processing apparatus that collects dust in the gas to be processed and decomposes components to be processed in the gas to be processed,
A counter electrode (36);
A plurality of first discharge electrodes (35) for causing discharge with the counter electrode (36) so that dust in the gas to be treated is charged;
An electrical dust collecting member (33) for collecting dust in the charged gas to be treated;
A plurality of second discharge electrodes (41) for causing discharge with the counter electrode (36) so as to generate plasma for decomposing the component to be treated;
The first discharge electrode (35) and the second discharge electrode (41), a gas processing device which is arranged on the same plane a the plane perpendicular to the flow of the gas to be treated. A gas processing apparatus that collects dust in the gas to be processed and decomposes components to be processed in the gas to be processed,
A counter electrode (36);
A first discharge electrode (35) for causing discharge with the counter electrode (36) so that dust in the gas to be treated is charged;
An electrical dust collecting member (33) for collecting dust in the charged gas to be treated;
A second discharge electrode (41) for causing discharge with the counter electrode (36) so as to generate plasma for decomposing the component to be treated;
The counter electrode (36) is formed of the gas to be processed so that the discharge between the second discharge electrode (41) and the counter electrode (36) is performed from the downstream side to the upstream side of the flow of the gas to be processed. A gas processing apparatus located on the upstream side of the flow, wherein the second discharge electrode (41) is located on the downstream side of the flow of the gas to be processed. A gas processing apparatus that collects dust in the gas to be processed and decomposes components to be processed in the gas to be processed,
A counter electrode (36);
A first discharge electrode (35) for causing discharge with the counter electrode (36) so that dust in the gas to be treated is charged;
An electrical dust collecting member (33) for collecting dust in the charged gas to be treated;
A second discharge electrode (41) for causing discharge with the counter electrode (36) so as to generate plasma for decomposing the component to be treated;
The counter electrode (36) is formed in a columnar shape having a U-shaped cross section, and at least the second discharge electrode (41) is disposed inside the counter electrode (36). A gas processing apparatus that collects dust in the gas to be processed and decomposes components to be processed in the gas to be processed,
An electrode member (37) formed in a corrugated plate and constituting a counter electrode (36);
A first discharge electrode (35) for causing discharge with the electrode member (37) so that dust in the gas to be treated is charged;
An electrical dust collecting member (33) for collecting dust in the charged gas to be treated;
A second discharge electrode (41) for causing discharge with the electrode member (37) so as to generate plasma for decomposing the component to be treated;
A first discharge electrode (35) is provided on one surface side of the electrode member (37), and a second discharge electrode (41) is provided on the other surface side, respectively.
The gas treatment device, wherein the first discharge electrode (35) and the second discharge electrode (41) are disposed inside the concave portion of the corrugated electrode member (37). The gas treatment device according to any one of claims 1 to 4 ,
A gas treatment apparatus in which the electric dust collecting member (33) is constituted by an electrostatic filter. The gas treatment device according to any one of claims 1 to 4 ,
A gas processing apparatus comprising a plasma catalyst that is activated by plasma generated by discharge between the second discharge electrode (41) and the counter electrode (36) and promotes decomposition of a component to be processed. The gas treatment device according to any one of claims 1 to 4 ,
The first discharge electrode (35) is formed in a linear shape extending along the counter electrode (36),
The second discharge electrode (41) is electrically connected in the middle of the first discharge electrode (35), and the distance from the counter electrode (36) is the same as that of the counter electrode (36) and the first discharge electrode (35). ) Is a gas processing device arranged to be shorter than the distance. The gas treatment device according to any one of claims 1 to 4 ,
A gas processing apparatus comprising a photosemiconductor catalyst that is activated by plasma generated by a discharge between the second discharge electrode (41) and the counter electrode (36) and promotes decomposition of a component to be processed. The gas treatment device according to claim 8 , wherein
The photo-semiconductor catalyst is a gas processing device carried on an electrical dust collecting member (33). The gas treatment device according to claim 6 , wherein
The plasma catalyst is disposed downstream of the second discharge electrode (41) and the counter electrode (36),
The electrical dust collecting member (33) is provided with a photosemiconductor catalyst that is activated by the plasma generated by the discharge between the second discharge electrode (41) and the counter electrode (36) to promote decomposition of the component to be treated. Carried,
The gas processing apparatus, wherein the electrical dust collecting member (33) is disposed between the second discharge electrode (41) and the counter electrode (36) and the plasma catalyst.

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