JP2010063947A - Air cleaner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air cleaner which is installed near a ceiling and exhibits sufficient performance even with reduced frequency of maintenance. <P>SOLUTION: The air cleaner includes a casing (11) installed near the ceiling, and air clarifying means (21, 30, 60) that are arranged in an air passage (20) inside the casing (11) and clarify air to be treated. The air clarifying means (21, 30, 60) includes an electric dust collecting unit (30) comprising a charging part (31) for electrifying dust in the air to be treated and a dust collecting part (40) for electrically collecting dust electrified by the charging part (31). <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an air cleaner that purifies air to be treated.

  2. Description of the Related Art Conventionally, air purifiers that purify air to be treated are known. For example, Patent Document 1 discloses this type of air cleaner.

This air purifier is configured as a floor-standing type installed on a floor surface such as a room. The air purifier includes flat casings at the front and rear, and an air passage through which air to be treated flows is formed inside the casing. A filter, a discharge device, and the like are disposed in the air passage. In the filter, dust in the air to be treated is physically captured. In the discharge device, streamer discharge is performed between the electrodes, and active species are generated along with this discharge. Odor components are decomposed / removed by contacting the odor components in the air to be treated with the active species.
Japanese Patent Laid-Open No. 2005-262085

  By the way, it is conceivable to install the air cleaner as described above behind the ceiling, embed it in the ceiling, or install it on the wall near the ceiling. That is, by installing the air cleaner near the ceiling, it is possible to secure a wide effective space in a room such as a house.

  On the other hand, when the air purifier is installed in the vicinity of the ceiling in this way, maintenance of the air purifier becomes complicated. Specifically, for example, in a case where dust in the air to be treated is captured by a filter, it is necessary to periodically clean or replace the filter. However, if the air purifier is installed near the ceiling, it is difficult to remove or attach the filter, and the frequency of maintenance by the user or the like is reduced. As a result, the amount of dust trapped by the filter becomes excessive, and the original dust collecting function may be impaired. Moreover, pressure loss increases due to clogging of the filter, and the power of the blower may become excessive.

  The present invention has been made in view of the above points, and an object of the present invention is to make it possible to sufficiently exhibit performance even if the frequency of maintenance is low in an air cleaner installed near the ceiling. .

  According to a first aspect of the present invention, there is provided a casing (11) installed in the vicinity of a ceiling, and an air purification means (21, 30, 60) disposed in an air passage (20) in the casing (11) to purify the air to be treated. The air purifying means (21, 30, 60) is charged by the charging unit (31) for charging the dust in the air to be treated and the charging unit (31). And an electric dust collection unit (30) having a dust collection part (40) for electrically collecting the generated dust.

  In the air cleaner of the first invention, the casing (11) is installed in the vicinity of the ceiling. That is, the casing (11) of the air purifier is installed on, for example, the back of the ceiling, the ceiling surface, and the wall surface near the ceiling. In the present invention, an electric dust collection unit (30) is provided as an air purification means for purifying the air to be treated. In the electric dust collection unit (30), first, dust in the air to be treated is charged to a positive or negative charge in the charging unit (31). The dust charged by the charging unit (31) is attracted to the dust collection unit (40) and is electrically captured. Thereby, the dust in to-be-processed air is removed.

  Such an electric dust collection unit (30) is less likely to deteriorate in performance even when operated for a long period of time, for example, as compared with a filter that physically captures dust. In addition, since the electric dust collection unit (30) is not clogged like a filter, pressure loss is unlikely to increase even if it is operated for a long time.

  In a second aspect based on the first aspect, the dust collecting portion (40) is a lattice-shaped base portion (42, 52) in which a large number of vent holes (47, 57) are formed along the air flow. And first and second electrodes (41, 51) having a plurality of protrusions (43, 53) extending in parallel with the axial direction of the vent (47, 57) from the base (42, 52) The protrusion (43) of the first electrode (41) extends into the vent (57) of the second electrode (51), and the protrusion (53) of the second electrode (51) is the first electrode. (41) It is comprised so that it may extend inside the vent hole (57).

  In the second invention, the first electrode (41) and the second electrode (51) are provided in the dust collecting part (40). These electrodes (41, 51) each have a base (42, 52) and a protrusion (43, 53). The protrusion (53) of the second electrode (51) is inserted into the vent (47) of the base (42) of the first electrode (41), and the base (52) of the second electrode (51) is inserted. ) Is inserted into the projection (43) of the first electrode (41). As a result, an electric field is formed between the inner peripheral wall of the vent (47) of the base portion (42) of the first electrode (41) and the protrusion (53) of the second electrode (51). Further, an electric field is also formed between the inner peripheral wall of the vent hole (57) of the base portion (52) of the second electrode (51) and the protrusion (43) of the first electrode (41). The air to be treated flows through the vents (47, 57) of the base parts (42, 52) of the first and second electrodes (41, 51). As a result, the dust charged by the charging portion (31) is attracted to and adhered to the inner peripheral wall of the vent hole (47, 57) or the outer periphery of the protruding portion (43, 53). Thereby, the dust in to-be-processed air is removed.

  In the first and second electrodes (41, 51) configured as described above, the dust collection area for capturing dust is relatively large, so that the performance is unlikely to deteriorate even after long-term operation. Further, since the vent holes (47, 57) are formed along the air flow, the pressure loss is unlikely to increase even if the operation is performed for a long time.

  According to a third invention, in the first or second invention, the charging unit (31) includes a needle electrode (33b) and a counter electrode (32), and the needle electrode (33b) is a counter electrode (32 ), And an electric field is formed between both electrodes (33b, 32).

  In the charging part (31) of the third invention, an electric field is formed between the needle electrode (33b) and the counter electrode (32). The needle electrode (33b) has a lower potential than the counter electrode (32). For this reason, in the charging part (31), electrons move from the needle electrode (33b) on the low potential side toward the counter electrode (32) on the high potential side. That is, in the charging part (31), so-called negative discharge is performed in which electrons collide with the counter electrode (32). Here, if discharge is performed from the counter electrode to the needle electrode, for example, the electrons collide with the needle electrode, so that the needle electrode is worn / degraded in a relatively short period of time. Will have to be replaced. On the other hand, in the present invention, since electrons collide not with the needle electrode (33b) but with the counter electrode (32), wear / deterioration of the needle electrode (33b) can be prevented.

  According to a fourth invention, in any one of the first to third inventions, the air purification means (21, 30, 60) includes a deodorization unit (62) for capturing odor components in the air to be treated, It includes a deodorizing unit (60) having a discharge unit (61) that generates active species that decompose the odor components captured by the deodorizing unit (62).

  In 4th invention, a deodorizing unit (60) is provided as a purification | cleaning means for purifying to-be-processed air. In the deodorization unit (60), odor components in the air to be treated are captured in the deodorization section (62). In the discharge part (61), active species (electrons, ions, ozone, radicals, etc.) are generated along with the discharge. The odor component captured by the deodorization part (62) is decomposed / removed by the active species. As a result, the ability to purify odorous components in the deodorizing section (62) is restored.

  According to a fifth aspect of the present invention, in any one of the first to fourth aspects, the air purification means (21, 30, 60) is a filter member (21 arranged upstream of the electric dust collection unit (30). ), And further includes a filter cleaning mechanism (22) having a scraping portion (25) for scraping dust captured by the filter member (21).

  In the fifth invention, the filter member (21) is provided as a purification means for purifying the air to be treated. The filter member (21) captures dust in the air to be treated. The dust trapped by the filter member (21) is scraped by the scraping part (25) of the filter cleaning mechanism (22). Thereby, the dust collection performance in the filter member (21) can be recovered. Moreover, the clogging of dust in the filter member (21) can be eliminated.

  According to a sixth invention, in any one of the first to fifth inventions, in the air passage (20), an air conditioning means (65, 65) for adjusting one or both of temperature and humidity of the air to be treated is provided in the air passage (20). 75, 80).

  In the sixth invention, the air to be treated is purified by the air purification means (21, 30, 60), and the temperature and humidity of the air to be treated are adjusted by the air conditioning means (65, 75, 80). That is, the air cleaner of the present invention is given a function of harmonizing air.

  In a seventh aspect based on any one of the first to sixth aspects, the casing (11) is formed with an outdoor air inlet (12) for introducing outdoor air into the air passage (20). It is characterized by.

  In the seventh invention, outdoor air is introduced from the outside air inlet (12) into the air passage (20), and the outdoor air is purified by the air purifying means (21, 30, 60) and then supplied to the room. That is, in this invention, indoor ventilation is performed by supplying outdoor air indoors. Here, outdoor air contains more dust and the like than indoor air. However, in the present invention, the dust is removed by the electric dust collection unit (30), so that it is possible to avoid a decrease in dust collection performance and an increase in pressure loss.

  In an eighth invention according to any one of the first to seventh inventions, the casing (11) includes an outdoor air inlet (12) for introducing outdoor air into the air passage (20), An inside air suction port (17) for introducing air into the air passage (20) is formed.

  In the eighth invention, outdoor air is introduced from the outside air inlet (12) into the air passage (20). Further, room air is introduced from the room air inlet (17) into the air passage (20). That is, in the present invention, both indoor air and outdoor air are purified by the air purifying means (21, 30, 60) and supplied to the room. Thereby, the cleanliness of the room can be improved while the room is ventilated.

  The ninth invention is characterized in that, in the seventh or eighth invention, exhaust means (70, 74) for exhausting indoor air to the outside is further provided.

  In the ninth aspect of the invention, outdoor air is supplied into the room through the air passage (20), and the indoor air is discharged out of the room by the exhaust means (70, 74). This increases the ventilation efficiency of the room and avoids the room from becoming positive pressure.

  According to the present invention, since the casing (11) of the air cleaner is installed in the vicinity of the ceiling, it is possible to sufficiently secure an effective space in the room. In addition, since the electric dust collection unit (30) is used as the air purification means, it is possible to prevent a decrease in dust collection performance associated with long-term operation compared to, for example, a filter, and pressure loss due to clogging or the like. Can also be prevented. Therefore, in an air cleaner that is installed near the ceiling and is relatively complicated to maintain, sufficient performance can be achieved while reducing the frequency of maintenance of the air purification means (21, 30, 60). .

  In particular, in the second invention, from the lattice-shaped base (42,52) and the protrusion (43,53) extending into the vent (47,57) of the base (42,52). The first and second electrodes (41, 51) are combined to constitute the dust collecting part (40). For this reason, since the dust collection area for collecting dust can be increased, the fall of the dust collection performance accompanying a long-term driving | operation can be prevented. Further, since the vent holes (47, 57) are formed along the air flow, the pressure loss can be reduced. As a result, the maintenance frequency can be further reduced.

  According to the third aspect of the invention, since negative discharge is performed from the low potential side needle electrode (33b) toward the counter electrode (32), wear / deterioration of the needle electrode (33b) is avoided. be able to. As a result, the maintenance frequency of the needle electrode (33b) can also be reduced.

  According to 4th invention, the cleanliness of to-be-processed air can be improved by making the deodorizing part (62) capture the odor component in to-be-processed air. Here, the odor component captured by the deodorization part (62) can be decomposed by the active species generated in the discharge part (61). Thereby, since the capture | acquisition capability of the odor component in a deodorizing part (62) can be recovered, maintenance, such as replacement | exchange of a deodorizing part (62), becomes unnecessary.

  According to the fifth aspect, dust in the air to be treated can be captured by the filter member (21). Moreover, since the dust trapped by the filter member (21) can be removed by the scraping part (25) of the filter cleaning mechanism (22), maintenance such as replacement of the filter member (21) becomes unnecessary.

  According to the sixth aspect of the invention, it is possible to provide an air purifier that simultaneously performs indoor cleaning and indoor air conditioning (temperature adjustment and humidity adjustment). Moreover, according to the 7th and 8th invention, the air cleaner which performs indoor cleaning and indoor ventilation simultaneously can be provided. In particular, according to the ninth aspect, ventilation efficiency can be improved by discharging the indoor air to the outside while supplying the outdoor air to the room. Further, it is possible to avoid such a problem that the room has a positive pressure and condensation occurs on the wall surface.

  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.

Embodiment 1 of the Invention
The air cleaner (10) of this embodiment purifies the air to be treated. As shown in FIG. 1, the air cleaner (10) of Embodiment 1 is provided with the casing (11) installed in the vicinity of a ceiling (C). The casing (11) is formed in a hollow rectangular parallelepiped shape that is flat up and down. The casing (11) is installed on the back surface (upper surface) of the ceiling (C). That is, the air cleaner (10) of Embodiment 1 is configured as a so-called ceiling-back type.

  An outside air inlet (12) is formed on one side surface of the casing (11) of the first embodiment. One end of an outside air duct (13) is connected to the outside air inlet (12). The other end of the outside air duct (13) extends outside the room through the wall (W) of the building. The other end of the outside air duct (13) has an inner diameter enlarged and faces the outside. An air supply port (14) is formed on the other side surface of the casing (11). One end of an air supply duct (15) is connected to the air supply port (14). The other end of the air supply duct (15) is bent downward and extends through the ceiling (C) into the room. The other end of the air supply duct (15) has a larger inner diameter and faces the room.

  Inside the casing (11), an air passage (20) through which air to be treated flows is formed from the outside air inlet (12) side toward the air inlet (14) side. In the air passage (20), a pre-filter (21), an electrostatic dust collection unit (30), and a deodorizing unit (60) are arranged from the upstream side to the downstream side as air purification means for purifying the air to be treated. Are arranged in order. An air supply fan (16) for supplying air into the room is installed on the downstream side of these air purification means.

  The prefilter (21) constitutes a filter member and physically captures relatively large dust in the air to be treated. The prefilter (21) is formed in a long band shape or sheet shape. The prefilter (21) is joined at both ends in the longitudinal direction so as to have a closed loop shape.

  The air cleaner (10) includes a filter cleaning mechanism (22) for cleaning the prefilter (21). The filter cleaning mechanism (22) includes two roller portions (23, 24) and a brush mechanism (25).

  The two roller portions (23, 24) are arranged in parallel on the upper side and the lower side of the air passage (20). A prefilter (21) is wound around the outside of the two roller portions (23, 24). The roller portions (23, 24) are rotationally driven by a motor (not shown). The brush mechanism (25) constitutes a scraping part for scraping off the dust trapped by the prefilter (21), and is disposed below the lower roller part (24). The prefilter (21) is sandwiched between the brush tip of the brush mechanism (25) and the roller portion (24). When the roller portions (23, 24) are driven to rotate, the prefilter (21) turns outside the roller portions (23, 24) so that the surface facing the air to be treated is displaced. When the pre-filter (21) turns, the brush tip of the brush mechanism (25) is in sliding contact with the collection surface of the pre-filter (21). Thereby, the dust collected on the pre-filter (21) is scraped off by the brush mechanism (25). The dust thus scraped off is collected in a dust box (not shown). The collected dust is collected, for example, from a room by a nozzle of a vacuum cleaner or the like, or discharged outside the room by air transportation or the like.

 The electric dust collection unit (30) electrically collects relatively small dust in the air to be treated. The electric dust collection unit (30) includes an ionization unit (31) and a dust collection unit (40).

  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).

  The dust collection part (40) is for electrically attracting and capturing the dust charged by the ionization part (31). As shown in FIGS. 3-5, the dust collection part (40) is provided with the electrode (41) for dust collection and the electrode (51) for electric field formation. One of the dust collection electrode (41) and the electric field forming electrode (51) constitutes a first electrode, and the other constitutes a second electrode. The dust collection electrode (41) is connected to the plus side of a DC high-voltage power supply (not shown), and the electric field forming electrode (51) is connected to the minus side of the DC high-voltage power supply. Further, the positive side of the DC high-voltage power supply is grounded, the dust collection electrode (41) is at zero potential, and the electric field forming electrode (51) is at negative potential.

The dust collecting electrode (41) and the electric field forming electrode (51) are made of an integrally molded conductive resin. Both the dust collecting electrode (41) and the electric field forming electrode (51) are preferably a slightly conductive resin, and the volume resistivity of the resin is 10 ⁸ Ωcm or more and less than 10 ¹³ Ωcm. It is preferable.

  The dust collecting electrode (41) and the electric field forming electrode (51) are composed of one base (42,52) and a number of protrusions (43,53) protruding from the base (42,52). ) And each. The base (42,52) includes a frame (44,54), a plurality of vertical partition members (45,55) and horizontal partition members (46,56) provided inside the frame (44,54). ) Are integrally formed.

  The frame (44, 54) is formed in a rectangular shape. The frame (44) of the electrode for collecting dust (41) and the frame (54) of the electrode for forming electric field (51) are arranged in such a way that the base parts (42, 52) face each other. The four corners of the body (44, 54) are fixed to each other. In addition, each base part (42, 52) has a posture perpendicular to the air flow in the air passage (20), and the base part (42) of the dust collecting electrode (41) is closer to the upstream side, The base part (52) of the electric field forming electrode (51) is located closer to the downstream side.

  In the dust collecting electrode (41) and the electric field forming electrode (51), the vertical partition members (45, 55) extend vertically, the horizontal partition members (46, 56) extend horizontally, and the vertical partition members (45, 55). ) And the horizontal partition members (46, 56) are arranged so as to intersect vertically and horizontally. The base portion (42,52) has a number of vent holes (47,57) surrounded by the frame (44,54), the vertical partition members (45,55), and the horizontal partition members (46,56). ) Is formed. That is, the base part (42, 52) has a square lattice structure in which a large number of ventilation holes (47, 57) along the air flow are formed.

  The vertical partition members (45, 55) of the dust collecting electrode (41) and the electric field forming electrode (51) are positioned on the same plane while being separated from each other in the assembled state in which both electrodes (41, 51) are fixed. Is configured to do. On the other hand, the horizontal partition members (46, 56) of the dust collecting electrode (41) and the electric field forming electrode (51) are arranged in a staggered manner in the vertical direction in the assembled state of both electrodes (41, 51). (See FIGS. 4 and 5).

  In the dust collection electrode (41) and the electric field forming electrode (51), the protrusions (43, 53) protrude in the axial direction from the horizontal partition members (46, 56). The protrusion (43, 53) is composed of a flat plate-like protruding piece having the same thickness as the horizontal partition member (46, 56), and into the vent (47, 57) of the opposing electrode (41, 51). It extends. And the horizontal partition member (46,56) of the electrode (41,51) which opposes is located in the gap of the horizontal direction of an adjacent projection part (43,53). Further, the protrusion (43, 53) is located at the center of the inside of the opposing base (42, 52). Thereby, air flows through the vents (47, 57) above and below the protrusions (43, 53). The distance between the protrusion (43) of the dust collecting electrode (41) and the protrusion (53) of the electric field forming electrode (51) is preferably 1.0 mm to 2.0 mm. .6 mm is preferable.

  The protrusion (43) of the dust collection electrode (41) is surrounded by the vertical partition member (55) and the horizontal partition member (56) of the electric field forming electrode (51). The distances between the projections (43) of the dust collection electrode (41) and the partition members (55, 56) are substantially equal. A radial electric field is formed in the cross section of the vent (57) between the projection (43) of the dust collection electrode (41) and each partition member (55, 56). Similarly, the protrusion (53) of the electric field forming electrode (51) is surrounded by the vertical partition member (45) and the horizontal partition member (46) of the dust collection electrode (41). The distance between the protrusion (53) of the electric field forming electrode (51) and each partition member (45, 46) is substantially equal. A radial electric field is formed in the cross section of the vent (47) between the protrusion (53) of the electric field forming electrode (51) and each partition member (45, 46).

  As shown in FIG. 1, the deodorizing unit (60) removes odorous components (including odorless harmful components) in the air to be treated. The deodorizing unit (60) includes a discharge part (61) and a catalyst filter (62) disposed on the downstream side of the discharge part (61). The discharge part (61) has a pair of electrodes to which a high-voltage DC voltage is applied. For example, in the discharge part (61), linear or rod-shaped discharge electrodes are arranged so as to be substantially parallel to the flat counter electrode. In the discharge part (61), 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 (61), active species (electrons, ions, ozone, radicals, etc.) highly reactive with the odor component are generated.

  The catalyst filter (62) 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 (62) constitutes a deodorizing part that captures odor components. That is, in the catalyst filter (62), the odor component in the air to be treated is adsorbed / decomposed and removed. The odor component adsorbed on the catalyst filter (62) is gradually decomposed by the active species generated in the discharge part (61).

-Driving action-
Next, the operation of the air cleaner (10) will be described. As shown in FIG. 1, when the air supply fan (16) is driven, outdoor air is sucked into the outside air duct (13). The outdoor air that has flowed out of the outside air duct (13) is introduced from the outside air suction port (12) into the air passage (20) in the casing (11).

  The to-be-processed air flowing through the air passage (20) first passes through the prefilter (21). In the prefilter (21), relatively large dust contained in the air to be treated is collected. The air to be treated that has passed through the prefilter (21) circulates in the vicinity of the electric dust collection unit (30).

  First, 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.

  Air to be treated containing negatively charged dust flows through the dust collecting section (40). In the dust collection section (40), a DC voltage is applied between the dust collection electrode (41) and the electric field forming electrode (51). When the air to be treated flows through the vent (47) of the base (42) of the dust collecting electrode (41), the negatively charged dust is attracted to the inner peripheral wall of the vent (47). Adhere to. Thereafter, when the air to be treated flows through the vent hole (57) of the base portion (52) of the electric field forming electrode (51), the negatively charged dust adheres to the outer peripheral surface of the protruding portion (43). As described above, in the dust collection section (40), dust adheres to the surface of the dust collection electrode (41) and is captured.

  The air that has passed through the electric dust collection unit (30) flows in the vicinity of the deodorization unit (60). In the discharge part (61) of the deodorizing unit (60), 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 (62), the odor component in the air to be treated is adsorbed and removed by the catalyst filter (62). The odor component adsorbed on the catalyst filter (62) is gradually decomposed by the active species generated in the discharge part (61). Thereby, the capture capability (adsorption capability) of the odor component in the catalyst filter (62) is recovered.

  The air from which the odor component has been removed by the deodorizing unit (60) flows from the air passage (20) into the air supply duct (15) through the air supply port (14), and then is supplied indoors. As a result, the room is cleaned, and outdoor air is supplied to the room for ventilation.

-Effect of Embodiment 1-
According to the first embodiment, the air cleaner (10) is installed behind the ceiling. For this reason, compared with the case where it installs, for example in the floor surface of the room | chamber interior of an air cleaner (10), the indoor living space can fully be ensured. On the other hand, if the air cleaner (10) is installed in the back of the ceiling in this way, maintenance work for various functional parts of the air cleaner (10) becomes very complicated. Therefore, in the air cleaner (10), it is preferable to minimize the frequency of maintenance. Therefore, in the first embodiment, the frequency of maintenance is reduced as follows.

  First, the electric dust collection unit (30) is used as means for collecting dust in the air to be treated. Compared to a filter that physically collects dust in the air to be treated, the electric dust collection unit (30) is less likely to have a reduced dust collection performance even when operated for a long period of time. Further, in the electric dust collection unit (30), dust is not clogged like a filter. For this reason, the electric dust collection unit (30) can sufficiently remove dust without performing maintenance for a long period of time.

  In addition, in the dust collection part (40), by combining the base part (42,52) and the projection part (43,53) having a lattice structure, a dust collection area for collecting dust is relatively wide. be able to. Accordingly, the dust collection performance of the dust collection electrode (41) can be guaranteed over a long period of time, and the frequency of maintenance can be reduced. Moreover, since the vent hole (57) of the base part (42, 52) is formed along the air flow, the pressure loss can be reduced. Therefore, the power of the air supply fan (16) can be reduced.

  Further, in the ionization section (31), the potential of the needle electrode (33b) is lower than the potential of the rod electrode (32) so that electrons move from the needle electrode (33b) toward the rod electrode (32). is doing. Thereby, the frequency of maintenance of the needle electrode (33b) can be reduced. That is, if electrons or the like move from the rod-shaped electrode (32) toward the needle-shaped electrode (33b), the tip of the needle-shaped electrode (33b) with which the electrons or the like collide is easily worn / deteriorated, The replacement frequency of the electrode (33b) increases. On the other hand, in this embodiment, since electrons collide with the rod-like electrode (32) side, the durability of the needle-like electrode (33b) can be guaranteed and the frequency of maintenance can be reduced.

  Moreover, in the said embodiment, since the filter cleaning mechanism (22) for collecting the dust collected by the prefilter (21) is used, the clogging of the dust in the prefilter (21) can be avoided, The frequency of maintenance such as replacement of the prefilter (21) can also be reduced.

  In the above embodiment, after the odor component is adsorbed on the catalyst filter (62), the odor component is decomposed and removed by the active species generated by the streamer discharge. For this reason, it is possible to prevent a decrease in the adsorption performance of the catalyst filter (62) and to reduce the frequency of maintenance such as replacement of the catalyst filter (62).

  Furthermore, in the said embodiment, since outdoor air is taken in and supplied indoors, indoor ventilation can be performed with indoor cleansing.

<Modification 1 of Embodiment 1>
In the air cleaner (10) of Modification 1 shown in FIG. 6, the inside air inlet (17) is further formed in the casing (11) of Embodiment 1 described above. One end of the inside air duct (18) is connected to the inside air suction port (17). The other end of the inside air duct (18) is bent downward and extends through the ceiling (C) into the room. The other end of the inside air duct (18) has a larger inner diameter and faces the room.

  As described above, in the casing (11) of the air cleaner (10) of the first modification, the outdoor air inlet (12) for introducing outdoor air into the air passage (20) and the indoor air through the air passage (20 ) Is formed in a parallel relationship with the inside air inlet (17) for introduction into the interior. Therefore, when the air supply fan (16) is driven, both indoor air and outdoor air are introduced into the air passage (20) and mixed. This air is purified by various air purification means and supplied to the room as in the first embodiment.

  In the air cleaner (10) of the first modification, the room can be cleaned relatively quickly as compared with the case where only the outdoor air is sucked and supplied to the room. Moreover, compared with the case where only outdoor air is sucked and supplied to the room, the indoor heat can be used effectively, and the indoor air conditioning load can be reduced. Furthermore, indoor air can be ventilated by taking in outdoor air.

<Modification 2 of Embodiment 1>
The air cleaner (10) of Modification 2 shown in FIG. 7 introduces room air into the air passage (20) through the inside air duct (18) and the inside air inlet (17), and purifies the air before entering the room. To supply. That is, the air cleaner (10) of Modification 2 is obtained by deleting the outside air inlet (12) and the outside air duct (13) in the configuration of Modification 1. In the air cleaner (10) of the second modified example, the indoor air can be swiftly cleaned, and the indoor air conditioning load can be effectively reduced.

<Modification 3 of Embodiment 1>
The air cleaner (10) of Modification 3 shown in FIG. 8 is provided with a heat exchanger (65) in the air passage (20) in the casing (11) of the air cleaner (10) of Modification 2. Is. The heat exchanger (65) is connected to a refrigerant circuit (not shown) in which, for example, a vapor compression refrigeration cycle is performed, and functions as an evaporator or a condenser. In the heat exchanger (65), the refrigerant flowing through the refrigerant circuit and the air to be treated exchange heat. That is, the heat exchanger (65) constitutes an air conditioning means for adjusting the temperature of the air to be treated. In this example, the heat exchanger (65) is disposed downstream of the catalyst filter (62). Therefore, after the air flowing through the air passage (20) is purified by various air purification means, it is heated or cooled by the heat exchanger (65) and supplied into the room. As described above, in the air cleaner (10) of the third modification, the room can be cooled and heated at the same time as the room is cleaned.

<Modification 4 of Embodiment 1>
In the air cleaner (10) of Modification 4 shown in FIG. 9, the exhaust passage (70) is formed in the casing (11). One end of the exhaust passage (70) communicates with the room through the room introduction port (71). The other end of the exhaust passage (70) communicates with the outside through the exhaust port (72) and the exhaust duct (73). Further, an exhaust fan (74) is installed in the exhaust passage (70). As described above, in the fourth modification, the exhaust passage (70) and the exhaust fan (74) constitute exhaust means for exhausting room air to the outside.

  In Modification 4, the total heat exchanger (75) is provided so as to straddle the air passage (20) and the exhaust passage (70). Specifically, the total heat exchanger (75) takes in the air to be treated (outdoor air) taken into the air passage (20) from the outside and the air passage (70) from the inside to the exhaust passage (70). A vent hole through which indoor air can flow is partitioned. In the total heat exchanger (75), both sensible heat and latent heat of the air to be treated and room air exchange heat. That is, the total heat exchanger (75) constitutes air conditioning means for adjusting both the temperature and humidity of the air to be treated.

  When the air cleaner (10) is operated, the air supply fan (16) and the exhaust fan (74) are driven. Thereby, outdoor air is taken into the air passage (20) as air to be treated, and indoor air is taken into the exhaust passage (70). The air to be treated is purified by various air purification means and then passes through the total heat exchanger (75). For example, in summer, the air to be treated flowing through the total heat exchanger (75) is cooled by the indoor air on the exhaust passage (70) side. Further, moisture in the air to be treated is given to room air on the exhaust passage (70) side. As a result, relatively low temperature and low humidity air to be processed can be supplied into the room. Further, for example, in winter, the air to be processed flowing through the total heat exchanger (75) is heated by the room air on the exhaust passage (70) side. Further, moisture in the indoor air on the exhaust passage (70) side is imparted to the air to be treated. As a result, relatively high temperature and high humidity air can be supplied into the room.

  As described above, in Modification 4, the indoor temperature and humidity can be adjusted simultaneously with the indoor cleaning. In the fourth modification, outdoor air is supplied to the room and at the same time the room air is discharged to the outside. For this reason, indoor ventilation efficiency becomes high and it can keep indoor environment favorable. Moreover, since it can avoid that a room becomes a positive pressure by doing in this way, the malfunction that dew condensation will arise on the wall surface etc. of a room | chamber interior can also be avoided. In addition, the use of the total heat exchanger (75) can reduce indoor latent heat load and sensible heat load.

  In the example shown in FIG. 9, in the air passage (20), the total heat exchanger (75) is arranged downstream of various air purification means. However, this total heat exchanger (75) may be arranged upstream of various air purification means (here, prefilter (21)) as shown in FIG. 10, for example. In the configuration shown in FIG. 10, for example, in the summer, high-humidity air can be dehumidified by the total heat exchanger (75). As a result, it is possible to avoid moisture in the air to be treated from adhering to various air purification means, thereby preventing the function of air purification by the air purification means from being impaired.

<Modification 5 of Embodiment 1>
The air cleaner (10) of Modification 5 shown in FIG. 11 uses a desiccant rotor (80) instead of the total heat exchanger (75) of Modification 4. Specifically, in the casing (11) of the modified example 5, the exhaust passage (70) in which the exhaust fan (74) is installed is formed in the same manner as in the modified example 4.

  The desiccant rotor (80) of the modified example 5 has an adsorbent supported on the surface of a disk-shaped substrate and constitutes an air conditioning means for adjusting the humidity of the air to be treated. The desiccant rotor (80) is rotatably supported while straddling the air passage (20) and the exhaust passage (70). Thus, in the desiccant rotor (80), an adsorption region (81) facing the air passage (20) and a regeneration region (82) facing the exhaust passage (70) are formed. Further, a heater (83) is installed in the exhaust passage (70) on the upstream side of the regeneration region (82) of the desiccant rotor (80). The heater (83) constitutes a heating means for heating the room air introduced into the exhaust passage (70).

  In the air passage (20) of the air cleaner (10) of Modification 5, the air to be treated after passing through the prefilter (21) flows through the adsorption region (81) of the desiccant rotor (80). As a result, moisture in the air to be treated is adsorbed to the adsorption region (81), and the air to be treated is dehumidified. The dehumidified air passes through the electric dust collection unit (30) and the deodorization unit (60) and is purified as described above.

  On the other hand, the room air introduced into the exhaust passage (70) is heated by the heater (83) and then passes through the regeneration region (82) of the desiccant rotor (80). In the regeneration region (82), the adsorbent to which moisture has been adsorbed is heated by air, and moisture is desorbed (desorbed) from the adsorbent. As a result, the adsorbent is regenerated. The regenerated adsorbent is displaced toward the adsorption region (81) and used for dehumidification of the air to be treated.

  As described above, in Modification 5, the indoor humidity can be adjusted simultaneously with the indoor cleaning. Also, in the fifth modification, as in the fourth modification, the outdoor air can be supplied to the room and at the same time the indoor air can be discharged to the outside to increase the ventilation efficiency. Further, by dehumidifying the air to be treated with the desiccant rotor (80), it is possible to avoid the performance from being deteriorated due to moisture adhering to the electric dust collection unit (30) and the deodorizing unit (60).

<< Embodiment 2 of the Invention >>
As shown in FIG. 12, the air cleaner (10) according to Embodiment 2 includes a casing (11) installed in the vicinity of the ceiling (C). The casing (11) is fitted into the opening of the ceiling (C) and is disposed so that the lower surface thereof faces the room. That is, the air cleaner (10) of Embodiment 2 is configured as a so-called ceiling-embedded type.

  An inside air suction port (17) and an air supply port (14) are formed on the lower surface of the casing (11) of the second embodiment. The inside air suction port (17) is formed at the center of the lower surface of the casing (11). The air supply port (14) is formed on the outer peripheral side of the internal air suction port (17) on the lower surface of the casing (11). An air passage (20) through which air to be treated flows is formed in the casing (11) from the inside air inlet (17) to the air inlet (14).

  The air passage (20) is provided with the same electrostatic dust collection unit (30) as in the first embodiment. An air supply fan (16) for supplying air into the room is provided on the downstream side of the electric dust collection unit (30). The air supply fan (16) of the second embodiment is a centrifugal fan (turbo fan).

  When the air supply fan (16) is driven, room air is introduced into the air passage (20) from the room air inlet (17). In the ionization part (31), dust in the air to be treated is charged. The charged dust is collected by the dust collecting electrode (41) of the dust collecting section (40). The air to be treated from which dust has been removed as described above is sent to the outer peripheral side of the air passage (20), and is supplied into the room from the air supply port (14).

  Also in the air cleaner (10) of Embodiment 2, since it is a ceiling embedded type, maintenance of functional parts, such as an air purifying means, will become complicated. However, also in Embodiment 2, since the electric dust collection unit (30) is used as the air purification means, the frequency of maintenance can be reduced.

<Modification 1 of Embodiment 2>
The air cleaner (10) of Modification 1 shown in FIG. 13 is obtained by adding a prefilter (21), a filter cleaning mechanism (22), and a deodorizing unit (60) to the configuration of the second embodiment. That is, in the air cleaner (10) of the first modification, as in the first embodiment, the prefilter (21) and the electric dust collection unit (30) are sequentially arranged from the upstream side to the downstream side of the air passage (20). ), And deodorizing uni and (60) are arranged in order.

  Also in this example, the dust collected by the prefilter (21) can be automatically cleaned by the filter cleaning mechanism (22). Moreover, the odor component adsorbed by the catalyst filter (62) can be removed by the active species generated in the discharge part (61). Therefore, the maintenance frequency of the prefilter (21) and the catalyst filter (62) can be reduced.

<Modification 2 of Embodiment 2>
The air cleaner (10) of Modification 2 shown in FIG. 14 uses a heat exchanger (65) instead of the deodorizing unit (60) in the configuration of Modification 1 shown in FIG. The heat exchanger (65) constitutes air conditioning means for adjusting the temperature of the air to be treated, as in the example of FIG. 8 described above. In this example, indoor cleaning and indoor cooling and heating can be performed simultaneously.

<< Embodiment 3 of the Invention >>
As shown in FIG. 15, the air cleaner (10) according to Embodiment 3 includes a casing (11) installed in the vicinity of the ceiling (C). The casing (11) is attached to the indoor wall surface (W) in the vicinity of the lower side of the ceiling (C). That is, the air cleaner (10) of Embodiment 3 is configured as a so-called wall-hanging type.

  In the casing (11), an inside air suction port (17) is formed from the front side to the upper side. The casing (11) has an air supply port (14) formed on the lower side thereof. An air passage (20) through which air to be treated flows is formed in the casing (11) from the inside air inlet (17) to the air inlet (14). In the air passage (20), a pre-filter (21), an electric dust collection unit (30), and a heat exchanger (65) are arranged in order from the upstream side to the downstream side. The air passage (20) is provided with a filter cleaning mechanism (22) for cleaning the dust collected by the prefilter (21). Furthermore, an air supply fan (16) is provided in the air passage (20) on the downstream side of the heat exchanger (65).

  When the air supply fan (16) is operated, room air is introduced into the air passage (20) from the room air inlet (17). When the air to be treated passes through the prefilter (21), dust in the air to be treated is collected by the prefilter (21). Next, relatively small dust in the air to be treated is collected by the electric dust collection unit (30). The temperature of the air to be treated from which dust has been removed is adjusted by exchanging heat with the refrigerant in the heat exchanger (65). The air to be treated, which has been purified as described above and whose temperature has been adjusted, is supplied to the room through the air supply port (14).

  Also in the air cleaner (10) of Embodiment 3, since it is attached to the wall surface near the ceiling, maintenance of functional parts such as air purifying means becomes complicated. However, also in Embodiment 3, since the electric dust collection unit (30) is used as the air purification means, the frequency of maintenance can be reduced.

<Modification of Embodiment 3>
The air cleaner (10) of the modification shown in FIG. 16 is provided with a deodorizing unit (60) instead of the heat exchanger (65) in the configuration of the third embodiment. Moreover, in Embodiment 3, the inside air inlet (17) is formed in the upper part of the casing (11), and the air inlet (14) is formed in the lower part. An air passage (20) is formed in the casing (11) in the vertical direction from the inside air suction port (17) to the air supply port (14). Also in this example, the frequency of maintenance of the electric dust collection unit (30), the pre-filter (21), etc. can be reduced.

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

  In each embodiment mentioned above, in the dust collection part (40), although the two electrodes (41, 51) which consist of conductive resin are used, any one or both is good also as a metal.

  Further, the ionization section (31) may be configured as shown in FIGS. In FIGS. 17A to 17C, the sawtooth electrode (33) is arranged along the air flow. That is, in the sawtooth electrode (33) shown in FIG. 17, the needle-like electrode (33b) formed on one side end surface protrudes toward the downstream side of the air flow, and the needle-like electrode formed on the other side end surface. The electrode (33b) protrudes toward the upstream side of the air flow.

  In the example of FIG. 17 (A), two pairs of rod-shaped electrodes (32, 32) disposed on both sides of the needle-shaped electrode (33b) are provided. The pair of rod-like electrodes (32, 32) are arranged so as to substantially coincide with the tip of the corresponding needle-like electrode (33b) in the direction orthogonal to the air flow. Thereby, electrons moving from the needle-like electrode (33b) toward the rod-like electrode (32) easily reach (collision) the rod-like electrode (32), and so-called collision charging can be promoted.

  In the example of FIG. 17B, a pair of rod-like electrodes (32, 32) is provided on both sides of the substrate portion (33a) of the sawtooth electrode (33). Thereby, a pair of rod-shaped electrode (32, 32) has shifted | deviated from the front-end | tip part of the acicular electrode (33b) in the direction orthogonal to an air flow. Thereby, the distance between the tip of the needle-like electrode (33b) and the rod-like electrode (32) becomes larger than the example of FIG. For this reason, electrons moving from the needle-like electrode (33b) to the rod-like electrode (32) do not easily reach the rod-like electrode (32), and so-called diffusion charge can be promoted.

  Furthermore, in the example of FIG. 17C, on the downstream side of the air flow, the needle-like electrode (33b) and the pair of rod-like electrodes (32, 32) are aligned in the direction orthogonal to the air flow, and on the upstream side, The needle electrode (33b) and the pair of rod electrodes (32, 32) are shifted in a direction perpendicular to the air flow. Thereby, in the upstream rod-like electrodes (32, 32), electrons easily reach and the collision charge is promoted. In addition, in the rod-shaped electrodes (32, 32) on the downstream side, it is difficult for electrons to reach and diffusion charge is promoted.

  In addition, it goes without saying that the air introduction method and the purification method of the air to be treated in each of the above embodiments may be combined with each other.

  As described above, the present invention is useful for an air purifier that purifies the air to be treated.

FIG. 1 is a schematic configuration diagram illustrating an overall configuration of the air cleaner according to the first embodiment. FIG. 2 is a schematic configuration diagram of the ionization unit. FIG. 3 is a perspective view showing the overall configuration of the electric dust collection unit. FIG. 4 is an enlarged perspective view of a main part of the electric dust collection unit. FIG. 5 is an enlarged longitudinal sectional view of a main part of the electric dust collection unit. FIG. 6 is a schematic configuration diagram illustrating an overall configuration of an air cleaner according to the first modification of the first embodiment. FIG. 7 is a schematic configuration diagram illustrating an overall configuration of an air cleaner according to a second modification of the first embodiment. FIG. 8 is a schematic configuration diagram illustrating an overall configuration of an air cleaner according to the third modification of the first embodiment. FIG. 9 is a schematic configuration diagram illustrating an overall configuration of an air cleaner according to a fourth modification of the first embodiment. FIG. 10 is a schematic configuration diagram illustrating an overall configuration of an air purifier according to another example of the fourth modification of the first embodiment. FIG. 11 is a schematic configuration diagram illustrating an overall configuration of an air purifier according to a fifth modification of the first embodiment. FIG. 12 is a schematic configuration diagram illustrating an overall configuration of the air cleaner according to the second embodiment. FIG. 13 is a schematic configuration diagram illustrating an overall configuration of an air purifier according to Modification 1 of Embodiment 2. FIG. 14 is a schematic configuration diagram illustrating an overall configuration of an air cleaner according to a second modification of the second embodiment. FIG. 15 is a schematic configuration diagram illustrating the overall configuration of the air cleaner according to the third embodiment. FIG. 16 is a schematic configuration diagram illustrating an overall configuration of an air purifier according to a modification of the third embodiment. FIG. 17 is a schematic configuration diagram of an ionization unit according to another embodiment.

Explanation of symbols

11 Casing
12 Outside air inlet
17 Inside air inlet
20 Air passage
21 Pre-filter (filter member, air purification means)
22 Filter cleaning mechanism
25 Brush mechanism (scraping part)
30 Electric dust collection unit (air purification means)
31 Ionization part (charge part)
32 Rod electrode (counter electrode)
33b needle electrode
40 Dust collector
41 Dust collection electrode (first electrode, second electrode)
42 Base
43 Projection
52 Base
53 Projection
51 Electric field forming electrode (second electrode, first electrode)
60 Deodorizing unit
61 Discharge section
62 Catalyst filter (deodorization part)
65 Heat exchanger (air conditioning means)
70 Exhaust passage (exhaust means)
74 Exhaust fan (exhaust means)
75 Total heat exchanger (air conditioning means)
80 Desiccant rotor (air conditioning means)

Claims (9)

Air provided with a casing (11) installed in the vicinity of the ceiling and air purification means (21, 30, 60) disposed in the air passage (20) in the casing (11) to purify the air to be treated A purifier,
The air purification means (21, 30, 60) includes a charging unit (31) for charging dust in the air to be treated, and a dust collector for electrically collecting the dust charged by the charging unit (31). And an electric dust collecting unit (30) having a portion (40). In claim 1,
The dust collection part (40) includes a grid-like base part (42,52) in which a large number of vents (47,57) along the air flow are formed, and the base part (42,52). 1st and 2nd electrode (41,51) which has many protrusion parts (43,53) extended in parallel with the axial direction of a vent hole (47,57), and protrusion of this 1st electrode (41) The portion (43) extends into the vent (57) of the second electrode (51), and the protrusion (53) of the second electrode (51) extends into the vent (47) of the first electrode (41). It is comprised so that it may extend, The air cleaner characterized by the above-mentioned. In claim 1 or 2,
The charging unit (31) includes a needle electrode (33b) and a counter electrode (32), and the needle electrode (33b) has a lower potential than the counter electrode (32), and both electrodes (33b, 32) It is comprised so that an electric field may be formed between, The air cleaner characterized by the above-mentioned. In any one of Claims 1 thru | or 3,
The air purification means (21, 30, 60) generates a deodorizing part (62) that captures odor components in the air to be treated and an active species that decomposes the odor components captured by the deodorizing part (62). An air cleaner comprising a deodorizing unit (60) having a discharge part (61). In any one of Claims 1 thru | or 4,
The air purification means (21, 30, 60) includes a filter member (21) disposed on the upstream side of the electric dust collection unit (30),
An air cleaner, further comprising a filter cleaning mechanism (22) having a scraping part (25) for scraping dust trapped by the filter member (21). In any one of Claims 1 thru | or 5,
An air cleaner characterized in that the air passage (20) is provided with air conditioning means (65, 75, 80) for adjusting one or both of temperature and humidity of the air to be treated. In any one of Claims 1 thru | or 6,
An air cleaner, wherein the casing (11) is formed with an outdoor air inlet (12) for introducing outdoor air into the air passage (20). In any one of Claims 1 thru | or 7,
The casing (11) has an outside air inlet (12) for introducing outdoor air into the air passage (20), and an inside air inlet (17) for introducing indoor air into the air passage (20). And an air cleaner characterized by being formed. In claim 7 or 8,
An air cleaner characterized by further comprising exhaust means (70, 74) for discharging indoor air to the outside.

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