JP2010188280A - Dust collector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dust collector maintaining the dust collecting performance of a dust collecting part over a long period of time. <P>SOLUTION: A plurality of electrode parts (71, 81) of a first electrode (41) comprises a first electrode part (81) and a first projection electrode part (71) whose projection length to the upstream side of air flow is formed larger than the first electrode part (81). A plurality of electrode parts (72, 82) of a second electrode (51) comprises a second electrode part (82) and a second projection electrode part (72) whose projection length to the upstream side of the air flow is formed larger than the second electrode part (82). The respective electrode parts (71, 72, 81, 82) of the first electrode (41) and the second electrode (51) are arrayed such that the upstream parts of the first projection electrode part (71) and the second projection electrode part (72) face each other and at least one set of the first electrode part (81) and the second electrode part (82) is provided between the downstream parts of the projection electrode parts (71, 72) of both electrodes. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a dust collector including a charging unit that charges dust in air to be treated and a dust collecting unit that collects dust charged by the charging unit, and particularly relates to measures for improving dust collection efficiency. is there.

  2. Description of the Related Art Conventionally, dust collectors that remove dust in air to be treated are known, and are used in air purifiers that purify indoor air.

  Patent Document 1 discloses this type of dust collector. In this dust collector, a charging part and a dust collecting part are sequentially arranged in an air passage through which air to be treated flows. The charging unit includes an ionization line and a counter electrode facing the ionization line, and is configured to discharge between the ionization line and the counter electrode. The dust collection unit includes a pair of grid-like electrodes facing each other. Further, these electrodes are made of a conductive resin material. When a voltage is applied to these electrodes, one electrode constitutes a dust collecting electrode (so-called dust collecting electrode) that electrically collects dust, and the other electrode faces the dust collecting electrode. A non-dust collecting electrode (so-called electric field forming electrode) is formed.

When the air to be treated flows through the ionization unit during the operation of the dust collector, the dust in the air to be treated is charged negatively, for example. The negatively charged dust flows through the dust collecting portion and passes between the grid-like electrodes. At this time, the negatively charged dust is attracted to, for example, a positively charged dust collecting electrode, and is collected by adhering to the surface of the dust collecting electrode. As described above, in this dust collector, the dust charged by the charging unit is electrically collected by the dust collecting electrode of the dust collecting unit, thereby purifying the air to be treated.
JP 2008-18425 A

  When the operation of the dust collector as described above is continued, dust gradually accumulates on the surface of the electrode of the dust collector. In particular, the air flowing near the upstream end of each electrode contains dust having a relatively large particle size. Therefore, dust having a relatively large diameter is attracted and attached to the upstream end portion of the dust collecting electrode, and therefore the dust tends to be enlarged.

  As described above, when dust accumulates at the upstream end of each electrode, a leakage current easily flows between the dust collection electrode and the electric field forming electrode. In particular, when the atmosphere of the dust collecting part is in a high humidity state, this leakage current is increased. Here, when at least one of the electrodes of the dust collecting portion is made of a conductive resin material having a relatively large resistance as disclosed in Patent Document 1, a voltage drop in the resin material due to the leakage current increases, The surface potential also decreases. As a result, there is a problem that the potential difference between the two electrodes is lowered, and the dust collection efficiency of the dust collection unit is lowered.

  This invention is made | formed in view of this point, The objective is to propose the dust collector which can maintain the dust collection performance of a dust collection part over a long period of time.

  The first invention includes a charging unit (31) for charging dust in the air to be treated, a first electrode (41), and a second electrode (51), and the first electrode (41) and the second electrode A dust collecting part (40) for forming an electric field for collecting dust charged by the charging part (31) between the electrode (51) and the first electrode (41) and the second electrode (51 ) Has a plurality of electrode portions (71, 72, 81, 82) arranged alternately, and at least one of the first electrode (41) and the second electrode (51) is conductive. Targets dust collectors made of resin. In the dust collector, the plurality of electrode portions (71, 81) of the first electrode (41) are arranged upstream of the first electrode portion (81) and the air flow from the first electrode portion (81). And a plurality of electrode portions (72, 82) of the second electrode (51) are connected to the second electrode portion (82). And a second protruding electrode part (72) having a protruding length upstream of the second electrode part (82) to the upstream side of the air flow, the first electrode (41) and the second electrode ( 51) In each of the electrode portions (71, 72, 81, 82), the upstream portions of the first protruding electrode portion (71) and the second protruding electrode portion (72) face each other, and the protruding electrode portions of the both The first electrode portion (81) and the second electrode portion (82) are arranged so as to be provided at least one set between the downstream portions of (71, 72).

  In the dust collector of the first invention, first, the air to be treated passes through the charging portion (31). In the charging unit (31), dust in the air to be treated is charged. The air to be treated containing charged dust flows in the vicinity of the dust collecting section (40).

  On the upstream side of the dust collection part (40), an electric field is formed between the upstream part of the first protruding electrode part (71) and the upstream part of the second protruding electrode part (72). Here, the distance between the two protruding electrode portions (71, 72) is the distance between the first electrode portion (81) and the second electrode portion (82) located on the downstream side of the dust collecting portion (40). It becomes wider than the distance. For this reason, the electric field strength between the upstream portions of both protruding electrode portions (71, 72) is relatively weak. Therefore, a large amount of dust having a relatively large diameter is suppressed from being captured on the surface of the upstream portion of both protruding electrode portions (71, 72).

  On the downstream side of the dust collection part (40), the plurality of electrode parts (81, 82) of the first electrode (41) and the second electrode (51) are alternately arranged. That is, for example, when a pair of the first electrode portion (81) and the second electrode portion (82) are provided between the first protruding electrode portion (71) and the second protruding electrode portion (72). The first projecting electrode part (71), the second electrode part (82), the first electrode part (81), and the second projecting electrode part (72) are in order of the respective electrode parts (71, 72, 81, 82). It is arranged. As a result, on the downstream side of the dust collection part (40), the distance between the electrode parts (71, 72, 81, 82) is such that the upstream part of the first protruding electrode part (71) and the second protruding electrode part ( 72) shorter than the distance to the upstream part. For this reason, the electric field strength is relatively large on the downstream side of the dust collecting section (40). Therefore, on the downstream side of the dust collection part (40), even a relatively small diameter dust is sufficiently captured on the surface of each electrode part (71, 72, 81, 82).

  According to a second aspect of the present invention, in the first aspect, the electrode portions (71, 72, 81, 82) of the first electrode (41) and the second electrode (51) 72), the first electrode portion (81) and the second electrode portion (82) are arranged so that only one set is provided between the downstream portions.

  In the second invention, only one set of the first and second electrode portions (81, 82) is provided between the downstream portions of the protruding electrode portions (71, 72). Thereby, for example, compared with the case where two or more sets of the first electrode portion (81) and the second electrode portion (82) are arranged between the downstream portions of both protruding electrode portions (71, 72), The distance between the first projecting electrode part (71) and the second projecting electrode part (72) is reduced. Therefore, it is possible to prevent the distance between the first projecting electrode part (71) and the second projecting electrode part (72) from becoming too large, and thereby the electric field strength between the two projecting electrode parts (71, 72). Can be prevented from becoming too weak.

  According to a third invention, in the first or second invention, the first electrode (41) is formed in a lattice shape in which a plurality of air holes (46) through which air flows is formed, and the first electrode ( 41) a base part (42) on which a plurality of electrode parts (71, 81) are supported, and the second electrode (51) is a lattice in which a plurality of air holes (56) through which air flows are formed. And a base portion (52) on which the plurality of electrode portions (72, 82) of the second electrode (51) are supported, and the dust collecting portion (40) includes the first electrode The plurality of electrode portions (72, 82) of the second electrode (51) are inserted into the vent hole (46) of the base portion (42) of (41), and the base portion of the second electrode (51) ( The plurality of electrode portions (71, 81) of the first electrode (41) are inserted into the vent hole (56) of 52).

  In the third invention, the first electrode (41) and the second electrode (51) are each provided with a lattice-like base (42, 52). And the electrode part (71, 81) of the first electrode (41) is inserted into the vent hole (56) of the base part (52) of the second electrode (51), and the electrode part ( 72, 82) are inserted into the vent hole (46) of the base part (42) of the first electrode (41). Thereby, a radial electric field can be formed between the electrode part (71, 81) of the first electrode (41) and the inner wall of the vent hole (56) of the second electrode (51). Similarly, a radial electric field can be formed between the electrode portions (72, 82) of the second electrode (51) and the inner wall of the vent hole (46) of the first electrode (41). As a result, the dust collection part (40) can efficiently collect dust in the air to be treated.

  According to a fourth invention, in any one of the first to third inventions, in the first electrode (41), an air flow between the first electrode portion (81) and the first protruding electrode portion (71). The lengths in the direction are equal, and the first protruding electrode part (71) is arranged closer to the upstream side of the air flow than the first electrode part (81).

  In the fourth invention, on the first electrode (41) side, the lengths in the air flow direction of the first electrode portion (81) and the first protruding electrode portion (71) are equal. Thereby, a 1st electrode part (81) and a 1st protrusion electrode part (71) can be manufactured by the same manufacturing method. The first protruding electrode part (71) is disposed closer to the upstream side of the air flow than the first electrode part (81). As a result, the protruding length of the first protruding electrode portion (71) on the upstream side of the air flow is larger than that of the first electrode portion (81).

  In the dust collection part (40) of this invention, the 1st protrusion electrode part (71) and the 2nd protrusion electrode part (72) which protrusion length becomes large in the upstream of an air flow are provided, and the 1st protrusion electrode part (71 ) And the second projecting electrode portion (72), the first electrode portion (81) and the second electrode portion (82) are provided between the downstream portions. Thereby, a relatively weak electric field can be formed between the upstream portion of the first protruding electrode portion (71) and the upstream portion of the second protruding electrode portion (72), and the first protruding electrode portion (71) A relatively strong electric field can be formed between the downstream portion and the downstream portion of the second protruding electrode portion (72). For this reason, it is possible to prevent a large amount of dust from adhering to the electrode surface on the upstream side of the dust collecting section (40), so that the dust adhering to this portion is prevented from enlarging. it can. As a result, since the leakage current between both electrodes (41, 51) can be suppressed, the dust collection performance of the dust collection part (40) can be maintained over a long period of time. In addition, on the downstream side of the dust collection part (40), dust of a relatively small diameter can be actively captured on the surface of the electrode (41, 51), so that the performance of the dust collection part (40) can be fully exhibited. it can.

  According to the second aspect of the invention, the first electrode portion (81) and the second electrode portion (82) are 1 between the first protruding electrode portion (71) and the second protruding electrode portion (72). Since only the sets are arranged, it is possible to prevent the distance between the upstream portion of the first protruding electrode portion (71) and the upstream portion of the second protruding electrode portion (72) from becoming too large. Thereby, it can avoid that dust collection performance falls too much in the upstream of a dust collection part (40).

  In the dust collecting part (40) of the third invention, between the inner wall of the vent hole (46, 56) of the lattice-like base part (42, 52) and the electrode part (71, 72, 81, 82). Since the radial electric field is formed, dust in the air to be treated can be efficiently captured on the surface of the electrode (41, 51).

  In the fourth invention, since the length of the first projecting electrode portion (71) and the first electrode portion (81) in the air flow direction is the same, these electrodes (71, 81) are made of the same mold or the like. Manufacturing cost can be reduced.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In addition, embodiment described below is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  The dust collector (30) of the embodiment is mounted on an indoor air cleaner (10) installed on the floor of the room. The air cleaner (10) purifies indoor air and supplies the purified air to the room.

  As shown in FIG. 1, the air cleaner (10) includes a casing (11) installed indoors. The casing (11) is formed in a hollow rectangular parallelepiped shape that is flat in the front-rear direction. A suction port (12) is formed on one side surface of the casing (11) so as to face the indoor space. An air supply port (13) is formed on the other side surface of the casing (11) so as to face the indoor space.

  An air passage (20) through which air to be processed flows from the suction port (12) toward the air supply port (13) is formed in the casing (11). The air passage (20) includes a prefilter (21), an ionization part (31), a dust collection part (40), a discharge part (22), and a catalyst filter part (as a means for purifying the air to be treated. 23) are arranged in order from the upstream side to the downstream side. An air supply fan (24) for supplying air into the room is installed on the downstream side of these air purification means. The ionization section (31) and the dust collection section (40) constitute a dust collection unit (dust collection apparatus (30)) for removing dust.

  The prefilter (21) constitutes a pretreatment filter member that physically collects relatively large dust in the air to be treated.

  The ionization part (31) comprises the charge part which charges the dust in to-be-processed air. As shown in FIGS. 2A and 2B, the ionization section (31) has a rod-shaped electrode (32), a sawtooth electrode (33), and a power source (34). The power source (34) is a DC high-voltage power source. The rod-shaped electrode (32) is connected to the positive side of the power source (34), and the sawtooth electrode (33) is connected to the negative side of the power source (34). The positive side of the power source (34) is grounded. As a result, the rod-shaped electrode (32) has a zero potential, and the sawtooth electrode (33) has a negative potential. That is, in the ionization part (31), the electric potential of the sawtooth electrode (33) is lower than the electric potential of the rod electrode (32).

  In the air passage (20), the plurality of rod-like electrodes (32) are arranged in parallel to each other. The rod-shaped electrode (32) extends horizontally so as to be orthogonal to the air flow. Although the cross section of the rod-shaped electrode (32) of this embodiment is substantially circular, it is not limited to this and may be, for example, substantially rectangular. Further, at least one rod-like electrode (32) may be provided, but two or more rod-like electrodes are preferable. Further, the rod-like electrodes (32) extending in the vertical direction may be arranged in the left-right direction (horizontal direction).

  The sawtooth electrode (33) includes a substrate portion (33a) and a needle electrode (33b). The substrate portion (33a) is disposed at an intermediate position between the plurality of rod-shaped electrodes (32), and extends so as to be parallel to the rod-shaped electrodes (32). That is, the substrate portion (33a) extends horizontally so as to be orthogonal to the air flow. Moreover, the board | substrate part (33a) of this embodiment is formed in flat form, and becomes the attitude | position which the thickness direction substantially corresponds with the direction of an air flow. The plurality of needle-like electrodes (33b) are formed at both ends in the width direction of the substrate portion (33a). The needle-like electrode (33b) of the present embodiment is formed into a sharp needle-like shape or a protrusion shape, and protrudes toward each rod-like electrode (32). Thereby, the said rod-shaped electrode (32) comprises the counter electrode which opposes the needle-shaped electrode (33b).

As shown in FIG. 3, the dust collection part (40) includes a dust collection electrode (41), a high voltage electrode (51), and a power source (S) for applying a voltage to these electrodes (41, 51). Yes. One of the dust collection electrode (41) and the high voltage electrode (51) constitutes the first electrode, and the other constitutes the second electrode. In the present embodiment, the dust collection electrode (41) is made of a metal material such as stainless steel, and the high voltage electrode (51) is made of a conductive resin material. The high voltage electrode (51) is preferably a slightly conductive resin, and the volume resistivity of the resin is preferably 10 ⁵ Ωcm or more and less than 10 ¹⁰ Ωcm.

  The power source (S) constitutes a high-voltage DC power source. The positive side of the power supply (S) is connected to earth and grounded. The dust collecting electrode (41) is connected to the positive side (that is, the ground side) of the power source (S), and the high voltage electrode (51) is connected to the negative side of the power source (S). When a voltage is applied from the power source (S) to both electrodes (41, 51), an electric field is formed between both electrodes (41, 51). Thereby, in this embodiment, the dust collection surface for collecting the negatively charged dust is formed on the surface of the dust collection electrode (41). That is, the dust collection electrode (41) constitutes a dust collection electrode for electrically attracting dust. On the other hand, the high voltage electrode (51) is an electric field forming electrode for forming an electric field between both electrodes (41, 51), and constitutes a non-dust collecting side electrode from which dust is not attracted electrically. Yes.

  As shown in FIG. 3 to FIG. 7, the dust collection electrode (41) includes a grid-like base (42) and a protruding plate (43) protruding downstream from the end of the base (42). And have. The base part (42) of the dust collecting electrode (41) is formed with a plurality of vertical wall parts (44) and a plurality of horizontal wall parts (45) that are orthogonal (intersect) with each other. The plurality of vertical wall portions (44) are arranged in the horizontal direction at equal intervals while being parallel to each other.

  The plurality of horizontal wall portions (45) are arranged in the vertical direction at equal intervals while being parallel to each other. The plurality of lateral wall portions (45) are composed of a plurality of first lateral wall portions (45a) and a plurality of second lateral wall portions (45b). The first horizontal wall portion (45a) is substantially equal in length in the air flow direction to the vertical wall portion (44). In contrast, the second horizontal wall portion (45b) is shorter in the air flow direction than the vertical wall portion (44), and is formed in a portion closer to the downstream side of the base portion (42). . And in the base part (42) of a dust collection electrode (41), two 2nd horizontal wall parts (45b, 45b) intervene between two adjacent 1st horizontal wall parts (45a, 45a). The horizontal wall portions (45) are arranged in each other.

  The plurality of protruding plates (43) are connected to the downstream end of each lateral wall (45). That is, the protruding plate (43) is connected to both the first horizontal wall portion (45a) and the second horizontal wall portion (45b). In the base part (42), a vent hole (46) through which air to be treated can flow is formed between the vertical wall part (44) and the horizontal wall part (45). Specifically, on the upstream side of the base part (42) of the dust collecting electrode (41), the upstream side air hole (46a) is provided between the vertical wall part (44) and the second horizontal wall part (45b). Is formed (see FIG. 5). A downstream vent (46b) is formed between the vertical wall (44), the first horizontal wall (45a), and the second horizontal wall (45b) near the downstream side of the base (42). (See FIG. 6). The vertical opening height of the upstream side vent hole (46a) is larger than the vertical opening height of the downstream side vent hole (46b).

  The high-voltage electrode (51) includes a grid-like base portion (52) and a protruding plate (53) that protrudes upstream from the end portion of the base portion (52). A plurality of vertical wall portions (54) and a plurality of horizontal wall portions (55) orthogonal to each other are formed on the base portion (52) of the high-voltage electrode (51). The plurality of vertical wall portions (54) are arranged in the horizontal direction at equal intervals while being parallel to each other. The plurality of horizontal wall portions (55) are arranged in the vertical direction at equal intervals while being parallel to each other. A vent hole (56) is formed between the vertical wall portion (54) and the horizontal wall portion (55) in the base portion (52) of the high-voltage electrode (51).

  The plurality of protruding plates (53) are connected to the upstream end of each lateral wall (55). The plurality of projecting plates (53) of the high-voltage electrode (51) includes a first projecting plate (53a) and a second projecting plate (53b). The first protruding plate (53a) is longer in the air flow direction than the second protruding plate (53b). In the high-voltage electrode (51), each projection plate (53) is arranged such that two second projection plates (53b) are interposed between two adjacent first projection plates (53a). .

  In the dust collecting part (40), each projection plate (43) of the dust collecting electrode (41) is inserted into each vent hole (56) of the base part (52) of the high voltage electrode (51), and the dust collecting part. Both electrodes (41, 51) are combined so that the protruding plate (53) of the high voltage electrode (51) is inserted into each vent hole (46) of the base portion (42) of the electrode (41) ( (See FIG. 4).

  In the combined state of the dust collection electrode (41) and the high voltage electrode (51), the first projection plate (53a) of the high voltage electrode (51) is inserted into the upstream side vent hole (46a) (see FIG. 5). ). Thereby, in the site | part near the upstream of the base part (42) of a dust collection electrode (41), between the outer peripheral surface of a 1st projection board (53a), and the inner peripheral surface of an upstream vent hole (46a). An electric field for collecting dust is formed. In the combined state of the dust collection electrode (41) and the high voltage electrode (51), the first projection plate (53a) and the second projection plate (53b) of the high voltage electrode (51) are connected to the downstream side vent hole (46b). (See FIG. 6). Thereby, in the site | part near the downstream of the base part (42) of a dust collection electrode (41), the outer peripheral surface of a 1st projection plate (53a), the outer peripheral surface of a 2nd projection plate (53b), and a downstream vent hole An electric field for collecting dust is formed between the inner peripheral surface of (46b). Furthermore, in the combined state of the dust collection electrode (41) and the high voltage electrode (51), the projection plate (43) of the dust collection electrode (41) is inserted into the vent hole (56) (see FIG. 7). . Thereby, in the base part (52) of the high-voltage electrode (51), an electric field for collecting dust is formed between the outer peripheral surface of the projection plate (43) and the inner peripheral surface of the vent hole (56). The

  In the dust collecting electrode (41) configured as described above, the plurality of first lateral wall portions (45a) and the protruding plate (43) constitute a plurality of first protruding electrode portions (71), The two lateral wall portions (45b) and the protruding plate (43) constitute a plurality of first electrode portions (81). That is, the first protruding electrode part (71) is formed to have a longer protruding length upstream of the air flow than the first electrode part (81). In the high-voltage electrode (51), the plurality of first projecting plates (53a) and the lateral wall portion (55) constitute a plurality of second projecting electrode portions (72), and the plurality of second projecting plates (53b) ) And the lateral wall portion (55) constitute a plurality of second electrode portions (82). That is, the projecting length of the second projecting electrode part (72) to the upstream side of the air flow is larger than that of the second electrode part (82).

  And in the dust collection part (40) of this embodiment, the upstream part of the 1st protrusion electrode part (71) and the upstream part of the 2nd protrusion electrode part (72) mutually oppose, and both protrusion electrode part ( 71, 72), each electrode part (71, 72, 81, 82) is arranged so that only one set of the first electrode part (81) and the second electrode part (82) is provided between the downstream parts. ing.

  The discharge section (22) is configured to generate low-temperature plasma by generating streamer discharge. The discharge part (22) has a pair of electrodes to which a high-voltage DC voltage is applied. For example, in the discharge part (22), linear or rod-like discharge electrodes are arranged so as to be substantially parallel to the flat counter electrode. In the discharge part (22), streamer discharge progresses from the tip of the discharge electrode toward the counter electrode, and low-temperature plasma is generated. Thereby, in the discharge part (22), active species (electrons, ions, ozone, radicals, etc.) highly reactive with the odor component are generated.

  The catalyst filter portion (23) is configured such that a functional material such as a catalyst or an adsorbent is supported on the surface of a mesh-like, honeycomb-like, or lattice-like substrate in which a plurality of air holes are formed. As the catalyst, a manganese-based catalyst, a noble metal-based catalyst, or the like is used, and as the adsorbent, zeolite, activated carbon, or the like is used. The catalyst filter part (23) constitutes a deodorizing part for capturing odor components. That is, in the catalyst filter part (23), the odor component in the air to be treated is adsorbed / decomposed and removed. The odor component adsorbed on the catalyst filter part (23) is gradually decomposed by the active species generated in the discharge part (22).

-Driving action-
Next, the operation of the air cleaner (10) will be described. When the air supply fan (24) is operated, room air is introduced into the air passage (20) in the casing (11) through the suction port (12) as shown in FIG.

  The air to be treated that flows through the air passage (20) passes through the prefilter (21). In the prefilter (21), relatively large dust in the air to be treated is physically captured. Next, the air to be treated flows through the ionization section (31). Here, in the ionization section (31), a DC voltage is applied between the rod-shaped electrode (32) and the sawtooth electrode (33). Thereby, in the ionization part (31), an electric field is formed between these electrodes (33b, 32) while the needle-like electrode (33b) has a lower potential than the rod-like electrode (32). As a result, electrons, negative ions, and the like move from the tip of the needle electrode (33b) toward the rod electrode (32), and these electrons collide with the rod electrode (32). When the air to be treated flows between these electrodes (33b, 32), the dust in the air to be treated is negatively charged.

  In the dust collector (40), a voltage is applied to both electrodes (41, 51) from the power source (S), and an electric field is formed between both electrodes (41, 51). As shown in FIG. 3, in the dust collecting section (40), first, the air to be treated flows through the upstream vent hole (46a). In the upstream side vent hole (46a), an electric field is formed between the first projection plate (53a) and the inner wall (the first horizontal wall portion (45a) or the vertical wall portion (44)) of the upstream side vent hole (46a). Has been. Here, since the distance between the first projection plate (53a) and the first lateral wall portion (45a) is relatively large in the upstream side vent hole (46a), the first projection plate (53a) and the first lateral wall portion are arranged. The electric field strength formed between (45a) is relatively weak. Therefore, in the upstream vent hole (46a), a large amount of dust contained in the air to be treated is prevented from adhering to the first lateral wall portion (45a).

  The air to be treated that has passed through the upstream side vent hole (46a) then flows through the downstream side vent hole (46b) of the base part (42). At the downstream side vent hole (46b), between the first projection plate (53a) and the inner wall (second horizontal wall part (45b) or vertical wall part (44)) of the downstream side vent hole (46b), the second projection An electric field is formed between the plate (53b) and the inner wall of the downstream vent hole (46b). Here, in the downstream side vent hole (46b), for example, the distance between the second projection plate (53b) and the second lateral wall portion (45b), the first projection plate (53a), and the second lateral wall portion (45b). Is narrower than the distance between the first projection plate (53a) and the first lateral wall (45a) (approximately 1/3 of the distance). Therefore, the electrolytic strength formed between the first projection plate (53a) and the second lateral wall portion (45b) or between the second projection plate (53b) and the second lateral wall portion (45b) is compared. Become stronger. Therefore, in the downstream side vent hole (46b), relatively small dust in the air to be treated is efficiently removed as compared with the upstream side vent hole (46a). That is, in the downstream side vent hole (46b), dust having a relatively small diameter actively adheres to the surfaces of the first horizontal wall portion (45a) and the second horizontal wall portion (45b).

  The air to be treated that has passed through the downstream side vent hole (46b) flows through the vent hole (56) of the base part (52) of the high-voltage electrode (51). In the vent hole (56), an electric field is formed between the protruding plate (43) and the inner wall (the vertical wall portion (54) and the horizontal wall portion (55)) of the vent hole (56). In the vent hole (56), the distance between the projection plate (43) and the lateral wall portion (55) is smaller than the distance between the first projection plate (53a) and the first lateral wall portion (45a). (The distance is about 1/3). For this reason, the electric field strength formed between the protruding plate (43) and the lateral wall portion (55) becomes relatively strong. Therefore, in the vent hole (56), relatively small dust in the air to be treated is efficiently removed as compared with the upstream vent hole (46a). That is, in the vent hole (56), dust having a relatively small diameter is positively attached to the surface of the projection plate (43).

  The air that has passed through the dust collection unit (30) flows in the vicinity of the discharge part (22). In the discharge part (22), streamer discharge is performed between the discharge electrode and the counter electrode, and active species are generated in the air. When this active species comes into contact with the odor component in the air to be treated, the odor component is oxidatively decomposed and removed. When the air to be treated passes through the catalyst filter part (23), the odor component in the air to be treated is adsorbed and removed by the catalyst filter part (23). The odor component adsorbed on the catalyst filter part (23) is gradually decomposed by the active species generated in the discharge part (22). Thereby, the capture | acquisition capability (adsorption capability) of the odor component in a catalyst filter part (23) will be recovered.

  As described above, the relatively large-diameter dust and the relatively small-diameter dust are removed, and the air to be treated from which the odor component is removed passes through the air supply port (13) to the room outside the casing (11). Supplied to. As a result, clean air is supplied into the room, so that the room is cleaned.

-Effect of the embodiment-
In the dust collection part (40) of the said embodiment, the 1st protrusion electrode part (71) and the 2nd protrusion electrode part (72) to which protrusion length becomes large are provided in the upstream of an air flow, and a 1st protrusion electrode part ( 71) and the second projecting electrode portion (72) are provided with a pair of the first electrode portion (81) and the second electrode portion (82) between the downstream portions. Thereby, a relatively weak electric field can be formed between the upstream portion of the first protruding electrode portion (71) and the upstream portion of the second protruding electrode portion (72), and the first protruding electrode portion (71) A relatively strong electric field can be formed between each of the electrode portions (71, 81, 82, 72) between the downstream portion and the downstream portion of the second protruding electrode portion (72). For this reason, it is possible to prevent a relatively large amount of dust from adhering to the electrode surface on the upstream side of the dust collecting part (40) (inside the upstream side vent hole (46a)). It is possible to avoid the adhering dust from becoming enlarged. As a result, since the leakage current between the dust collection electrode (41) and the high voltage electrode (51) can be suppressed, the dust collection performance of the dust collection section (40) can be maintained for a long time. In addition, since dust of a relatively small diameter can be actively captured on the electrode surface on the downstream side of the dust collecting part (40) (inside the downstream vent hole (46b) or the vent hole (56)), the dust collecting part ( The performance of 40) can be fully exhibited.

  Since only one set of the first electrode part (81) and the second electrode part (82) is arranged between the first protruding electrode part (71) and the second protruding electrode part (72), It is possible to prevent the distance between the upstream portion of the first protruding electrode portion (71) and the upstream portion of the second protruding electrode portion (72) from becoming too large. That is, for example, if two sets of first and second electrode portions (81, 82) are provided between the first protruding electrode portion (71) and the second protruding electrode portion (72), the first protruding electrode portion ( The interelectrode distance between 71) and the second protruding electrode portion (72) is about 6 times the interelectrode distance between the first and second electrode portions (81, 82). In that case, in the dust collection part (40), the dust collection performance in the upstream side vent hole (46a) becomes too low, and the dust collection performance as a whole of the dust collection unit (30) may be lowered. . On the other hand, in this embodiment, one set of the first electrode portion (81) and the second electrode portion (82) is provided between the first protruding electrode portion (71) and the second protruding electrode portion (72). Therefore, it is possible to avoid that the dust collection performance in the upstream side air hole (46a) becomes too low.

-Modification of the embodiment-
In the above embodiment, the following modifications may be made.

<Modification 1>
As shown in FIG. 8, the first protruding electrode portion (71) and the first electrode portion (81) have the same length in the air flow direction, and the second protruding electrode portion (72) and the second electrode portion (82). May be the same length in the air flow direction. In the first modification, the first protruding electrode portion (71) is arranged closer to the upstream side than the first electrode portion (81), so that the protruding length of the first protruding electrode portion (71) is on the upstream side. It is getting bigger. Similarly, the second protruding electrode portion (72) is arranged closer to the upstream side than the second electrode portion (82), so that the protruding length of the second protruding electrode portion (72) increases toward the upstream side. It has become.

  In the first modification, the downstream end portion of the first electrode portion (81) extends through the vent hole (56) to the downstream side of the base portion (52). Further, the downstream end portion of the second electrode portion (82) also extends to the downstream side of the base portion (52). An electric field for capturing dust is also formed in the extended portions (81a, 82a) of both the first electrode portion (81) and the second electrode portion (82).

  In the first modification, the first protruding electrode portion (71) and the first electrode portion (81) have substantially the same length in the longitudinal direction, and the second protruding electrode portion (72) and the second electrode portion (82) ) Are substantially the same length in the longitudinal direction. For this reason, manufacturing cost can be reduced by manufacturing these electrodes (71, 72, 81, 82) with the same metal mold.

  Moreover, in the modification 1, the dust in to-be-processed air can be capture | acquired between the extension parts (81a, 82a) used as a pair in the downstream of a high voltage electrode (51). For this reason, in the dust collection part (40) of the modification 1, dust with a comparatively small diameter can be reliably removed.

<Modification 2>
In the second modification shown in FIG. 9, in the first modification, the downstream end portion of the first protruding electrode portion (71) extends further to the downstream side than the base portion (52). Thereby, in the modification 2, the extension part (71a) of the 1st protrusion electrode part (71) has opposed the extension part (82a) of the 2nd electrode part (82). Therefore, in the second modification, an electric field for capturing dust can be formed even between these extending portions (71a, 82a), so that dust having a relatively small diameter can be more reliably removed. .

<< Other Embodiments >>
About the said embodiment, it is good also as the following structures.

  In each of the above embodiments, if the distance between the first projecting electrode portion (71) and the second projecting electrode portion (72) becomes too large as described above, the dust collection performance of the dust collection unit (30) is reduced. There is a risk of it. Therefore, for example, as shown in FIGS. 9 and 10, the distance between the first protruding electrode portion (71) and the second protruding electrode portion (72) may be narrowed.

  Specifically, in the example shown in FIG. 9, the enlarged portion (73) is formed at the upstream end portion of the first protruding electrode portion (71). The enlarged portion (73) has a substantially trapezoidal longitudinal section that increases the plate thickness of the first protruding electrode portion (71) as it goes upstream of the air flow. In the example of FIG. 9, by forming the enlarged portion (73) in this way, the distance between the first protruding electrode portion (71) and the second protruding electrode portion (72) is slightly narrowed. As a result, it can be avoided that the dust collection performance between the first protruding electrode portion (71) and the second protruding electrode portion (72) is excessively lowered. The enlarged portion (73) may be formed only on the second protruding electrode portion (72), or may be formed on both the first protruding electrode portion (71) and the second protruding electrode portion (72). Also good.

  Further, in the example shown in FIG. 10, a folded portion (74) is formed toward the downstream side at the upstream end portion of the first protruding electrode portion (71). The folded plate portion (74) increases the substantial thickness of the first protruding electrode portion (71), and the distance between the first protruding electrode portion (71) and the second protruding electrode portion (72) is slightly narrowed. Become. As a result, it can be avoided that the dust collection performance between the first protruding electrode portion (71) and the second protruding electrode portion (72) is excessively lowered. The folded portion (74) may be formed only on the second protruding electrode portion (72), or may be formed on both the first protruding electrode portion (71) and the second protruding electrode portion (72). Also good.

  In each of the above embodiments, the dust collection electrode (41) is connected to the ground to have a zero potential, and the high voltage electrode (51) is connected to the minus side, but this may be reversed, or either May be connected to the positive side. In short, it is sufficient that either one of the dust collection electrode (41) and the high voltage electrode (51) is on the high potential side and the other is on the low potential side. Further, either one or both of the dust collection electrode (41) and the high voltage electrode (51) may be a conductive resin material.

  Moreover, in the said embodiment, although the dust collection electrode (41) and the high voltage electrode (51) are comprised by what is called a grid-shaped dust collection cell, the dust collection electrode (41) and the high voltage electrode (51) are arranged alternately. You may comprise only the flat plate electrode (electrode part).

  In each embodiment, the dust collection unit (30) is applied to the indoor air cleaner (10). However, the ceiling-back air cleaner, the air conditioner for indoor air conditioning, etc. A dust collection unit (30) may be applied.

  As described above, the present invention is useful for a dust collecting apparatus including a dust collecting unit that collects dust charged by a charging unit.

Drawing 1 is a schematic structure figure showing the whole air cleaner composition concerning an embodiment. FIG. 2 is a schematic configuration diagram of the ionization unit. Drawing 3 is a schematic structure figure of a dust collection part concerning an embodiment. FIG. 4 is an enlarged perspective view of a main part of the dust collecting part. 5 is a cross-sectional view taken along line VV in FIG. 6 is a cross-sectional view taken along the line VI-VI in FIG. 7 is a cross-sectional view taken along the line VII-VII in FIG. FIG. 8 is a schematic configuration diagram of a dust collection unit according to the first modification. FIG. 9 is a schematic configuration diagram of a dust collection unit according to the second modification. FIG. 10 is a schematic configuration diagram of a dust collection unit according to a first example of other embodiments. FIG. 11: is a schematic block diagram of the dust collection part which concerns on the 2nd example of other embodiment.

10 Air purifier
30 Dust collection unit (dust collector)
31 Ionization part (charge part)
40 Dust collector
41 Dust collection electrode (first electrode, second electrode)
42 Base
44 Vertical wall (first wall, second wall)
45 Horizontal wall (second wall, first wall)
46 Vent
51 High voltage electrode (second electrode, first electrode)
52 Base
56 Vent
71 First protruding electrode part (electrode part)
72 Second protruding electrode part (electrode part)
81 1st electrode part (electrode part)
82 Second electrode part (electrode part)

Claims (4)

A charging portion (31) for charging dust in the air to be treated; a first electrode (41); and a second electrode (51), wherein the first electrode (41) and the second electrode (51) A dust collecting part (40) for forming an electric field for collecting dust charged by the charging part (31) between the first electrode (41) and the second electrode (51) Each has a plurality of electrode portions (71, 72, 81, 82) extending in the air flow direction and alternately arranged, and at least one of the first electrode (41) and the second electrode (51) Is a dust collector made of conductive resin,
The plurality of electrode portions (71, 81) of the first electrode (41) are formed with a first electrode portion (81) and a projecting length to the upstream side of the air flow larger than that of the first electrode portion (81). A first protruding electrode portion (71) to be formed,
The plurality of electrode portions (72, 82) of the second electrode (51) are formed with a second electrode portion (82) and a projecting length to the upstream side of the air flow larger than that of the second electrode portion (82). A second protruding electrode portion (72) to be formed,
The electrode portions (71, 72, 81, 82) of the first electrode (41) and the second electrode (51) are upstream portions of the first protruding electrode portion (71) and the second protruding electrode portion (72). Are arranged so that they face each other and at least one pair of the first electrode part (81) and the second electrode part (82) is provided between the downstream parts of the protruding electrode parts (71, 72). A dust collector characterized by that. In claim 1,
The electrode portions (71, 72, 81, 82) of the first electrode (41) and the second electrode (51) are disposed between the downstream portions of the two protruding electrode portions (71, 72). (81) and the 2nd electrode part (82) are arranged so that only one set may be provided, The dust collector characterized by the above-mentioned. In claim 1 or 2,
The first electrode (41) is formed in a lattice shape in which a plurality of air holes (46) through which air flows is formed, and a plurality of electrode portions (71, 81) of the first electrode (41) are supported. A base (42)
The second electrode (51) is formed in a lattice shape in which a plurality of air holes (56) through which air flows is formed, and a plurality of electrode portions (72, 82) of the second electrode (51) are supported. Has a base (52)
In the dust collection part (40), the plurality of electrode parts (72, 82) of the second electrode (51) are inserted into the vent hole (46) of the base part (42) of the first electrode (41), A plurality of electrode portions (71, 81) of the first electrode (41) are inserted into the vent holes (56) of the base portion (52) of the second electrode (51). . In any one of Claims 1 thru | or 3,
In the first electrode (41), the lengths in the air flow direction of the first electrode portion (81) and the first protruding electrode portion (71) are equal, and the first protruding electrode portion (71) Is disposed closer to the upstream side of the air flow than the first electrode part (81).

Images