JP4985353B2 - Humidity control device - Google Patents

Description

  The present invention relates to a humidity control apparatus including a humidifying unit that applies water in a water container to the air, and particularly relates to measures for purifying water in the water container.

  Conventionally, humidity control devices for adjusting the humidity of air in a room or the like are widely known. Patent Document 1 discloses this type of humidity control apparatus.

  The humidity control device of Patent Document 1 constitutes a humidifier that humidifies air. The humidity control apparatus includes a water container that stores water, and a disk-shaped humidification rotor that is disposed so as to straddle the air passage. The lower part of the humidification rotor is immersed in the water in the water container.

During the operation of the humidity control device, the humidification rotor rotates continuously. In the humidifying filter, a portion containing moisture in the water container is displaced to the air passage. When air passes through this part, moisture in the humidification rotor is imparted to the air. The air humidified as described above flows out of the air passage and is supplied to the room or the like.
JP 2007-139251 A

  By the way, in the humidity control apparatus as described above, since water is stored in the water container, bacteria may grow in this water and the water may be contaminated. Further, for example, when a substance such as ammonia (a harmful substance or an odorous substance) is contained in the air flowing through the air passage, the substance may be dissolved in water to contaminate the water in the water container. Therefore, when such contaminated water is supplied indoors as humidified water, the cleanliness of the room is impaired. Moreover, when draining such contaminated water suitably, the water pollution load of a drainage system (for example, a sewer) will become large.

  Therefore, in order to purify the water in the water container, it is conceivable to discharge toward the water surface in the water container. Specifically, a discharge electrode is disposed at a predetermined position higher than the water surface of the water container, and a potential difference is applied between the discharge electrode and the water in the water container, so that the discharge electrode discharges toward the water surface. Can occur. By generating active species such as radicals in the air or water with the occurrence of this discharge, sterilization in water can be performed with the active species, or harmful substances dissolved in water can be removed by oxidative decomposition.

  However, the above discharge means has a problem that the distance between the discharge electrode and the water surface (that is, the distance between the electrodes) cannot be kept constant, and a desired discharge cannot be performed. Specifically, the water stored in the water container greatly fluctuates with the consumption of the humidified water accompanying the humidifying operation and the replenishment of the humidified water into the water container. Therefore, in this discharge means, the distance between the discharge electrode and the water surface cannot be kept constant, the distance between the electrodes becomes too short and abnormal discharge such as spark occurs, or the distance between the electrodes becomes too long. There arises a problem that the amount of active species produced decreases.

  This invention is made | formed in view of this point, The objective is to enable it to purify | clean the water in a water container stably.

1st invention presupposes the humidity control apparatus provided with the water container (41) and the humidification means (43) which provides the water in this water container (41) to the air, and humidifies air. Then, the humidity control apparatus includes a discharge processing unit (51) in which discharge is performed so as to generate active species for purifying water, and water in the water container (41) to the discharge processing unit (51). Transfer means (60) for transferring to the discharge treatment section (51), and a return flow path for sending water transferred to the discharge treatment section (51) to the water container (41), wherein the transfer means (60) It is immersed in the container (41), and is composed of a rotating member (42) having a recess (61) for pumping up the water in the water container (41), and the discharge treatment part (51) A first electrode (53) having a flowing water surface (53a) in which water flowing out from the recess (61) of the member (42) flows in a film form, and the flowing water surface (53a) and the first electrode (53) a second electrode (54) disposed to face is configured to discharge from the second electrode (54) towards the surface of the first electrode (53) is carried out And said that you are.

  In the first invention, the water in the water container (41) is humidified by being applied to the air by the humidifying means (43). Here, the transfer means (60) of the present invention transfers the water in the water container (41) to the discharge treatment section (51). In the discharge processing section (51), discharge is performed toward the transferred water, and active species (radicals, ozone, fast electrons, excited molecules, etc.) are generated along with the discharge. Therefore, harmful substances contained in water are decomposed and removed into active species, and at the same time, sterilization in water is performed. As a result, water is purified in the discharge processing section (51).

  As described above, in the present invention, the discharge is not performed toward the water surface of the water container (41), but is performed toward the water transferred by the transfer means (60). Therefore, the discharge can be stably performed toward the transferred water without being affected by the fluctuation of the water level of the water container (41). As a result, in the discharge processing unit (51), the active species are stably generated, and the water is reliably purified.

In the first invention, the water containing the active species transferred from the water container (41) to the discharge treatment section (51) is sent back to the water container (41) again through a predetermined return flow path. Therefore, purification of water by active species is performed not only in the discharge processing section (51) but also in the water container (41).

In the discharge processing section (51) of the first invention, the first electrode (53, 56, 57) and the second electrode (54) are arranged to face each other. The water transferred by the transfer means (60) adheres to the first electrode (53, 56, 57) and forms a water film on the surface thereof. When discharge is performed from the second electrode (54) toward the first electrode (53, 56, 57), discharge is also performed toward the water film. As a result, the active species generated with the discharge efficiently contacts / reacts with the water film, thereby improving the water purification ability.

In the first invention, the water transferred by the transfer means (60) flows in the form of a film on the surface of the first electrode (53) (that is, the flowing water surface (53a)). That is, the first electrode (53) also serves as a flow path for circulating water. On the other hand, since the 2nd electrode (54) is arrange | positioned facing the flowing water surface (53a) of the 1st electrode (53), the flowing water surface (53a) of the 1st electrode (53) from the 2nd electrode (54). Discharge is performed toward. That is, the discharge is performed from the second electrode (54) toward the water film flowing through the first electrode (53). As a result, the active species generated with the discharge efficiently contacts / reacts with the water film, thereby improving the water purification ability.

The second invention is the humidity control apparatus of the first aspect of the invention, the first electrode (53) is arranged so that its running water surface (53a) is vertical or inclined obliquely downward, the water container On the upper side of (41), an opening is formed so as to face the lower end of the first electrode (53).

In the second invention, the water transferred by the transfer means (60) flows downward along the flowing water surface (53a) of the first electrode (53). This water passes through the lower end of the first electrode (53) and drops downward while being purified by the active species. The dropped water is collected in the water container (41). As described above, in the present invention, the water transferred to the first electrode (53) can be sent into the water container (41) by its own weight.

According to a third aspect of the present invention, in the humidity control apparatus of the first or second aspect , the rotating member (42) includes a plurality of water for pumping water in the water container (41) toward the humidifying means (43). A humidifying recess (42b) is formed around the axis.

In the third invention, a humidifying recess (42b) is formed around the axis of the rotating member (42). That is, when the rotating member (42) rotates, the water in the water container (41) also enters the humidifying recess (42b), and the water is pumped upward and sent to the humidifying means (43) side. It is done. That is, the rotating member (42) of the present invention supplies transfer means for transferring water in the water container (41) to the discharge treatment section (51) and supplies water in the water container (41) to the humidification means (43). It also serves as both the transfer means.

  In the present invention, the water in the water container (41) is transferred to the discharge treatment part (51) by the transfer means (60) and discharged by the discharge treatment part (51), thereby purifying the water by the active species. Like to do. Therefore, according to the present invention, even if the water level of the water container (41) fluctuates with the consumption or replenishment of the humidified water, the discharge treatment unit (51) is stable without being affected by the fluctuation of the water level. Electric discharge can be performed, and water can be reliably purified by the active species generated in the discharge treatment section (51). As a result, for example, even if this water is discharged out of the system (sewer), the water pollution load outside the system can be surely reduced.

In the first invention, the water that has been transferred to the discharge treatment section (51) and purified is returned to the water container (41) through the return flow path. Therefore, the active species generated in the discharge processing section (51) can be sent together with water to the water container (41), and the water in the water container (41) can be purified more efficiently. Moreover, the cleanliness of the water provided in the air can be maintained by sending the purified water to the humidifying means (43). Therefore, for example, it can be avoided that contaminated water is supplied indoors and the cleanliness of the room is impaired, and the reliability of the humidity control apparatus can be ensured.

In the first invention, a water film is formed on the surface of the first electrode (53, 56, 57), and discharge is performed from the second electrode (54) to the surface of the first electrode (53, 56, 57). ing. Therefore, according to the present invention, it is possible to increase the contact efficiency between the active species generated by the discharge and the water, and the water purification efficiency.

According to the second invention, since the water transferred to the first electrode (53, 57) is dropped and collected in the water container (41) by its own weight, a transport means such as a pump can be omitted, Simplification of the device structure and reduction of power can be achieved.

According to the first invention, the water in the water container (41) is pumped up by the concave portion (61) of the rotating member (42), so that the water in the water container (41) can be drawn into the first electrode (53, 57).

Furthermore, according to the third invention, since the rotating member (42) is used as a means for transferring water to the humidifying means (43), the number of parts of the humidity control device can be reduced and the structure of the device can be simplified. Can be planned.

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

  The humidity control apparatus (10) according to the present embodiment is configured to be capable of a humidifying operation for humidifying air and a dehumidifying operation for dehumidifying air. Moreover, the humidity control apparatus (10) has various air purification means for purifying air.

<Overall configuration of humidity control device>
As shown in FIG.1 and FIG.2, the humidity control apparatus (10) has a casing (11). The casing (11) is formed in a rectangular shape that is flat in the front-rear direction. A front panel (11a) is formed on the front side (near the left side in FIG. 1) of the casing (11). A suction port (12) for introducing air into the casing (11) is formed in the front panel (11a) (see FIG. 2). The suction port (12) is formed on the left and right sides of the front panel (11a), for example. Moreover, the blower outlet (13) for blowing off the air in a casing (11) is formed in the casing (11) in the site | part near the upper back. An air passage (14) through which air flows from the suction port (12) to the outlet (13) is formed in the casing (11).

  As shown in FIG. 2, in the air passage (14), a prefilter (21), an ionization unit (22), a pleat filter (23), a deodorizing member (in order from the upstream side to the downstream side of the air flow) 24) A dehumidifying unit (30), a humidifying unit (40), and a centrifugal fan (20) are provided.

  An inflow end of the return passage (15) is opened above the centrifugal fan (20) and below the outlet (13). That is, a part of the air flowing out from the air passage (14) to the blowout port (13) is divided into the return passage (15). The return passage (15) constitutes a space extending forward and backward so as to be partitioned from the air passage (14). The outflow end of the return passage (15) is connected to the upstream side of the prefilter (21). In addition, an air purification discharge section (25) is formed in the vicinity of the outflow end of the return passage (15).

  As shown in FIG. 3, a guide passage (16) communicating with the return passage (15) is formed on the front side of the prefilter (21). The guide passage (16) is defined by a partition member formed on the back side of the front panel (11a), for example. The guide passage (16) guides the air that has flowed out of the return passage (15) to the intermediate portion in the width direction of the prefilter (21), and flows this air to the left and right sides to send it to the prefilter (21) side. (See the arrow in FIG. 3). As described above, in the humidity control apparatus (10) of the present embodiment, part of the air on the outflow side of the air passage (14) is transferred to the inflow side of the air passage (14) through the air purification discharge section (25). Is configured to return.

<Configuration of air purification means>
As shown in FIG. 2, the humidity control apparatus (10) includes the above-described prefilter (21), ionization unit (22), pleated filter (23), deodorizing member (24) as air purification means for purifying air. ) And an air purifying discharge part (25).

  The pre-filter (21) constitutes a dust collection filter that physically captures relatively large dust contained in the air.

  The ionization part (22) comprises dust charging means for charging dust in the air. The ionization part (22) is provided with, for example, a linear electrode and a plate-like electrode facing the linear electrode. In the ionization part (22), a voltage is applied to both electrodes from a power supply (18), and corona discharge is performed between both electrodes. By this corona discharge, dust in the air is charged to a predetermined charge (positive or negative charge).

  The pleated filter (23) constitutes a corrugated electrostatic filter. That is, in the pleated filter (23), the dust charged by the ionization part (22) is electrically attracted and captured. Note that a deodorizing material such as a photocatalyst may be supported on the pleated filter (23).

  The deodorizing member (24) is configured such that a deodorizing agent for deodorizing air is carried on the surface of a substrate having a honeycomb structure. As the deodorizer, an adsorbent that adsorbs components to be treated (odorous substances and harmful substances) in the air, a catalyst for oxidizing and decomposing the components to be treated, and the like are used.

  In the air purifying discharge section (25), streamer discharge is performed to purify the air. The air purifying discharge section (25) is provided with a rod-shaped or linear electrode (26) and a plate-shaped electrode (27). Both electrodes (26, 27) are arranged in parallel to each other. When voltage is applied from the power source (18) to both electrodes (26, 27), streamer discharge is generated from the tip of the rod-shaped electrode (26) toward the plate-shaped electrode (27). By this streamer discharge, active species (radicals, ozone, fast electrons, excited molecules, etc.) are generated in the air. When this active species reacts with the component to be treated in the air, the component to be treated is oxidized and decomposed and removed.

<Configuration of dehumidifying unit>
As shown in FIG. 4, the dehumidifying unit (30) includes a dehumidifying rotor (31), a cover member (32), a circulation fan (33), and a heater (34).

  The dehumidifying rotor (31) is a dehumidifying means for dehumidifying air by adsorbing moisture in the air, and constitutes a so-called rotary adsorption rotor. That is, the dehumidification rotor (31) is formed in a disk shape through which air can flow in the front and rear, and the rotation shaft (31a) of the shaft center is rotated by a predetermined drive source (not shown), thereby rotating. The shaft (31a) is configured to be rotatable. Further, the dehumidifying rotor (31) is configured such that an adsorbent is supported on the surface of a substrate having a honeycomb structure. As the adsorbent, a material excellent in moisture adsorption performance such as granular zeolite is used. As the binder for supporting the adsorbent on the substrate, thermoplastic resins such as modified polyphenylene ether, polystyrene, and ABS resin (acrylonitrile-butadiene-styrene copolymer synthetic resin) are used.

  The cover member (32) holds the dehumidification rotor (31) therein. Specifically, the cover member (32) is formed in a substantially rectangular shape that is flat in the front-rear direction, and a circular opening (32a) is formed near the upper portion thereof. The circular opening (32a) penetrates the cover member (32) back and forth, and the dehumidifying rotor (31) is rotatably held therein. Thereby, the air which flows through an air path (14) passes a dehumidification rotor (31) through a circular opening (32a).

  The cover member (32) is formed with a circulation passage (35) through which air for regenerating the adsorbent of the dehumidifying rotor (31) (regeneration air) flows. Specifically, the circulation passage (35) is formed in the cover member (32) around the dehumidification rotor (31), and the circulation fan (33) and the heater are straddling the circulation passage (35). (34) is provided. More specifically, in the cover member (32), the first to fourth cover passage portions (35a, 35b, 35c, 35d) and the circulation fan (33) are connected in a closed loop shape, so that the circulation passage is formed. (35) is configured.

  The circulation fan (33) and the first cover passage portion (35a) are formed on the rear side of the upper end portion of the cover member (32). The inflow end of the first cover passage portion (35a) communicates with the outlet side of the circulation fan (33). The heater (34) is housed in the outflow end of the first cover passage (35a). That is, the heater (34) is provided on the rear side of the dehumidification rotor (31) (see FIG. 2). The heater (34) constitutes heating means for heating the air upstream of the dehumidification rotor (31) in the circulation passage (35).

  The second cover passage portion (35b) is provided at a portion substantially opposite to the first cover passage portion (35a) with the dehumidification rotor (31) interposed therebetween. The first cover passage portion (35a) and the second cover passage portion (35b) communicate with each other via the dehumidification rotor (31). The second cover passage portion (35b) is formed in a fan shape in its outer shape, and covers about one-sixth of the side surface of the dehumidification rotor (31).

  The third cover passage portion (35c) is formed so as to surround the lower half of the dehumidification rotor (31) in the cover member (32). The inflow end of the third cover passage portion (35c) is connected to the lower end portion of the second cover passage portion (35b). The outflow end of the third cover passage portion (35c) is connected to the suction side of the circulation fan (33) through the fourth cover passage portion (35d).

  The third cover passage portion (35c) is formed with a plurality of communication hole portions (37) penetrating in the front-rear direction. Each communication hole portion (37) is formed so that the cross section of the passage is vertically long and approximately elliptical, and the air flowing through the air passage (14) (the air to be treated) can flow therethrough. The plurality of communication holes (37) are arranged so as to surround the radially outer side of the dehumidification rotor (31).

  In the third cover passage portion (35c), the regeneration air and the air to be treated exchange heat to condense moisture in the regeneration air (details will be described later). The water condensed in the third cover passage part (35c) is collected into a water tank (41) described later through a flow path (not shown).

<Composition of humidification unit>
As shown in FIG. 5, the humidification unit (40) was pumped up by a water tank (41) for storing water, a water wheel (42) for pumping water from the water tank (41), and a water wheel (42). A humidification rotor (43) constituting a humidification means for imparting water to the air, and a drive motor (44) for rotationally driving the humidification rotor (43) are provided.

  The water tank (41) constitutes a horizontally long water container whose upper side is open. The water tank (41) is installed in a lower space in the casing (11), and is configured to be freely taken in and out through an outlet (11b) of the casing (11) (see FIG. 1). Thereby, the user etc. can replenish the water tank (41) with the water for humidification suitably. Further, as described above, the water captured by the dehumidification rotor (31) is collected in the water tank (41). Therefore, the frequency of replenishment of humidified water to the water tank (41) can be reduced. Further, a bearing member (41a) for rotatably holding the water wheel (42) is erected on the bottom surface of the water tank (41).

  The water turbine (42) is formed in a substantially disk shape that is flat in the front-rear direction, and a rotating shaft (42a) projects from the axial center. The rotating shaft (42a) is pivotally supported at the upper end of the bearing member (41a). The water wheel (42) is rotatably provided so that a part (predetermined part including the lower end portion) of the water tank (41) is immersed in the humidified water, and constitutes a rotating member.

  In the water turbine (42), a plurality of rear recesses (42b) are formed around the axis of the rear side surface (side surface facing the humidification rotor (43)). The rear concave portion (42b) constitutes a humidifying concave portion for pumping humidified water to the humidifying rotor (43) side. The plurality of rear recesses (42b) have a substantially trapezoidal opening whose width is increased toward the radially outer side. The circumferential width of the opening of the rear recess (42b) is narrower than the circumferential width of the internal space of the rear recess (42b). Furthermore, the inner wall on the radially inner side of the rear concave portion (42b) is inclined so as to gradually approach the axial center side toward the opening end. The rear recesses (42b) are arranged at equal intervals in the circumferential direction at the radially outer end of the water turbine (42). In the water wheel (42) during the rotating operation, the position where the rear concave portion (42b) is immersed in the water of the water tank (41) and the position where the water tank (41) is drawn out are alternately displaced.

  Further, a gear (42c) is integrally formed on the rear side surface of the water turbine (42) at a portion near the axial center. The gear (42c) is configured to mesh with a driven gear (43a) of a humidifying rotor (43) described later. Furthermore, a plurality of front side recesses (61) are formed on the front side surface of the water turbine (42) (details will be described later).

  The humidification rotor (43) has an annular driven gear (43a) and a disk-shaped moisture absorbing member (43b) that is fitted and held in the driven gear (43a). The hygroscopic member (43b) is made of a non-woven fabric having water absorption. The humidification rotor (43) is rotatably held via a rotating shaft at a position higher than the water level when the water tank (41) is full. Moreover, the humidification rotor (43) is arrange | positioned so that the predetermined site | part including the lower end may contact the said water turbine (42) substantially. That is, the humidification rotor (43) has a portion that coincides with the rear recess (42b) of the water turbine (42) in the axial direction. Thereby, the humidification rotor (43) is configured such that the humidifying water (43b) can absorb the humidified water pumped up by the rear concave portion (42b) of the water wheel (42).

  The drive motor (44) has a drive gear (44a). The drive gear (44a) meshes with the driven gear (43a) of the humidification rotor (43) via the pinion (45). That is, when the drive motor (44) rotationally drives the drive gear (44a), the pinion (45) and the driven gear (43a) rotate, and the water wheel (42) that meshes with the driven gear (43a) rotates. .

<Configuration of water purification unit>
The humidity control apparatus (10) further includes a water purification unit (50) for purifying the humidified water. The water purification unit (50) includes a water purification discharge section (51) as a discharge treatment section, and a transfer means (60) for transferring water in the water tank (41) to the water purification discharge section (51). Have.

  As shown in FIGS. 6 (A) and 6 (B), the water turbine (42) is also used as the transfer means (60) of the present embodiment. Specifically, the front recesses (61) described above are formed on the front side of the water turbine (42), and are configured in the same manner as the rear recesses (42b) described above. That is, the front concave portion (61) is formed around the axis of the water wheel (42) and is immersed from the humidified water in the water tank (41) (first position) and from the humidified water in the water tank (41). It is comprised so that it may displace alternately with the position (2nd position) pulled up. The humidified water is pumped upward by the front concave portion (61), so that the humidified water can be supplied to the water purification discharge section (51).

  The water purifying discharge part (51) of the present embodiment is provided in the vicinity of the upper part of the front side surface of the water turbine (42). The water purification discharge section (51) includes a flat plate electrode (53) constituting the first electrode and a rod-like electrode (54) constituting the second electrode. The flat plate electrode (53) is formed in a long flat plate shape extending along the front side surface of the water wheel (42). The plate electrode (53) is disposed at a position lower than the front concave portion (61) located at the uppermost portion. Therefore, when the humidified water flows out from the front side concave portion (61) closer to the upper side, the humidified water is supplied to the upper surface (53a) of the flat plate electrode (53).

  The flat plate electrode (53) is inclined obliquely so that both ends in the longitudinal direction have different heights. More specifically, the flat plate electrode (53) is slightly inclined in the same rotational direction as the water turbine (42) with respect to a horizontal posture. The humidified water supplied to the upper surface (53a) of the flat plate electrode (53) flows downward along the upper surface (53a) of the flat plate electrode (53) by its own weight. That is, the upper surface (53a) of the flat plate electrode (53) constitutes a flowing water surface in which water transferred by the water wheel (42) flows in a film shape.

  Furthermore, the flat plate electrode (53) is disposed on the upper side of the water tank (41), and the lower end of the flat plate electrode (53) faces the inside of the water tank (41). Thus, the humidified water that has flowed out of the flat electrode (53) is dropped into the water tank (41) and collected. That is, the space from the outflow end of the flat plate electrode (53) to the inside of the water tank (41) is a return flow for sending the water transferred to the water purification discharge section (51) to the water tank (41). Constitutes the road. In addition, you may use the water piping arrange | positioned so that water may flow down as this return flow path.

  The rod-like electrode (54) is supported on the substrate (54a) via a support plate (54b). The rod-like electrode (54) is formed in an elongated line shape and has a substantially circular longitudinal section. The rod-shaped electrode (54) is disposed to face the rod-shaped electrode (54) while being in a posture parallel to the flat plate electrode (53).

  A voltage is also applied from the power source (18) between the rod-shaped electrode (54) and the plate electrode (53). When a potential difference is applied to both electrodes (53, 54), streamer discharge is performed from the tip of the rod-shaped electrode (54) toward the flat plate electrode (53) and the water film. That is, the water purifying discharge section (51) constitutes a discharge processing section in which discharging is performed so as to generate active species for purifying the humidified water.

  In the water purifying discharge part (51), the rod-shaped electrode (54) is on the positive electrode side, and the plate electrode (53) is on the negative electrode (or ground electrode) side. In addition, it is preferable that a DC high voltage is supplied from the power source (18) to the water purification discharge section (51), and further, the discharge current of the water purification discharge section (51) is constant. It is preferable to perform so-called constant current control.

-Driving action-
The humidity control apparatus (10) according to the present embodiment switches between a dehumidifying operation for dehumidifying the room and a humidifying operation for humidifying the room. Further, in the dehumidifying operation and the humidifying operation, air purification is simultaneously performed by the various air purification means described above.

<Dehumidifying operation>
In the dehumidifying operation, the dehumidifying rotor (31) rotates and the heater (34) is energized. On the other hand, the humidification rotor (43) is not rotationally driven, and the water turbine (42) rotating in conjunction with the humidification rotor (43) is also stopped. Also, when the centrifugal fan (20) is operated, indoor air is introduced into the air passage (14) through the suction port (12), and when the circulation fan (33) is operated, the circulation passage (35) Regeneration air circulates inside. Further, a high voltage is applied from the power source (18) to the electrodes (26, 27) of the air purification discharge section (25). Further, a voltage is applied from the power source (18) to the electrode of the ionization section (22).

  As shown in FIG. 2, the air flowing into the air passage (14) passes through the prefilter (21), captures dust, and then passes through the ionization section (22). In the ionization part (22), corona discharge is performed between the electrodes, and dust in the air is charged. The air that has flowed out of the ionization section (22) passes through the pleated filter (23). In the pleated filter (23), the charged dust is electrically attracted and captured. The air that has flowed out of the pleated filter (23) passes through the deodorizing member (24). In the deodorizing member (24), the component to be treated contained in the air is adsorbed by the adsorbent or is oxidized and decomposed by the catalyst.

  By the way, at the outflow end of the air passage (14), part of the air on the outlet side (positive pressure side) of the centrifugal fan (20) flows into the return passage (15). The air flowing through the return passage (15) is sent forward and flows through the air purification discharge section (25). In the air purifying discharge section (25), streamer discharge is performed between the electrodes (26, 27) facing each other. As a result, in the air purifying discharge section (25), the above-mentioned active species are generated along with the streamer discharge. The air containing the active species merges with the air flowing upstream of the prefilter (21) through the return passage (15) and the guide passage (16). Therefore, in the air passage (14), the active species flow from the inflow end to the outflow end, so that the reaction time between the component to be treated and the active species in the air is secured and the deodorization performance is improved.

  During the dehumidifying operation, the air that has passed through the deodorizing member (24) passes through the dehumidifying rotor (31). In the dehumidification rotor (31), moisture contained in the air is adsorbed by the adsorbent, and the air is dehumidified. The air purified and dehumidified as described above is supplied into the room through the air outlet (13).

  On the other hand, in the dehumidifying rotor (31) that rotates sequentially, the portion where moisture of air is adsorbed (moisture absorbing portion) is displaced to a position where it faces the circulation passage (35). Here, in the circulation passage (35), the air blown from the circulation fan (33) flows out of the first cover passage portion (35a) and is heated by the heater (34). And the air after a heating passes the said moisture absorption site | part of a dehumidification rotor (31). As a result, the adsorbent at the hygroscopic site is heated, and moisture is desorbed (desorbed) from the adsorbent. The air that has been used for regeneration of the adsorbent of the dehumidifying rotor (31) and becomes highly humid flows into the third cover passage portion (35c) through the second cover passage portion (35b).

  In the third cover passage portion (35c), air on the air passage (14) side circulates through each communication hole portion (37). Therefore, the regeneration air on the circulation passage (35) side exchanges heat with the air to be treated on the air passage (14) side through the side wall of the communication hole (37). Here, the air for regeneration is higher in temperature than the air to be treated and contains moisture close to saturation. As a result, in the third cover passage portion (35c), the regeneration air is cooled and water vapor contained in the air is condensed. The water condensed in the third cover passage portion (35c) flows down a predetermined flow path by its own weight and is collected in the water tank (41).

  The low-humidity air in the third cover passage portion (35c) is sucked into the circulation fan (33) through the fourth cover passage portion (35d) and sent again to the first cover passage portion (35a) for dehumidification. Used to regenerate the adsorbent of the rotor (31).

<Humidification operation>
In the humidification operation, the humidification rotor (43) and the water wheel (42) are rotationally driven by the drive motor (44). On the other hand, the dehumidification rotor (31) is not rotationally driven, and the heater (34) and the circulation fan (33) are stopped. In addition, when the centrifugal fan (20) is operated, indoor air is introduced into the air passage (14) through the suction port (12), and the air purification discharge unit (25) is supplied from the power source (18). And a voltage is applied to each electrode of an ionization part (22).

  As shown in FIG. 2, the air that has flowed into the air passage (14) is purified by various air purification means, as in the humidification operation. The purified air passes through the dehumidifying rotor (31) that does not substantially perform the dehumidifying operation, and then flows into the humidifying rotor (43).

  Here, in the humidification unit (40), the water turbine (42) rotates, so that the humidified water in the water tank (41) is appropriately supplied to the moisture absorbing member (43b) of the humidification rotor (43). Specifically, in the water wheel (42), the rear concave portion (42b) is immersed in the humidified water stored in the water tank (41). Thereby, in humidified water, humidified water penetrate | invades and is hold | maintained in a back side recessed part (42b). The rear side recess (42b) in a state where the humidified water is retained is pulled up from the humidified water and further displaced upward. When the rear recess (42b) gradually approaches the humidification rotor (43), the humidified water retained in the rear recess (42b) gradually flows out of the rear recess (42b) by its own weight. . When the rear concave portion (42b) is displaced to the uppermost position, substantially all of the humidified water in the rear concave portion (42b) flows out.

  The humidified water flowing out from the rear concave portion (42b) comes into contact with the humidifying rotor (43) adjacent to the rear concave portion (42b) and is absorbed by the moisture absorbing member (43b). With such an operation, in the humidification unit (40), humidified water is continuously supplied to the humidification rotor (43).

  In the humidification rotor (43), air circulates through the portion replenished with moisture. As a result, the humidified water contained in the moisture absorbing member (43b) is released into the air, whereby the air is humidified. The air purified and humidified as described above is supplied into the room through the air outlet (13).

<Other driving operations>
In the humidification operation and dehumidification operation, the supply of voltage from the power source (18) to the ionization unit (22) and the air purification discharge unit (25) is stopped to perform an operation that does not actively purify air. It is also possible. In addition, the dehumidifying operation of the dehumidifying unit (30) and the humidifying operation of the humidifying unit (40) are substantially stopped, while performing the above discharge in the ionization unit (22) and the air purifying discharge unit (25), It is also possible to perform an air cleaning operation that purifies air without adjusting the humidity of the air.

<Purification of humidified water>
Moreover, the humidity control apparatus (10) can perform a water purification operation for purifying the humidified water stored in the water tank (41). In the humidity control apparatus (10) of the present embodiment, a water purification operation is performed in conjunction with the humidification operation.

  Specifically, as shown in FIG. 6A, when the water wheel (42) rotates during the humidification operation, the front recess (61) of the water wheel (42) is sequentially immersed in the humidified water of the water tank (41). The humidified water enters and is held in the front recess (61). When the front concave portion (61) holding the humidified water is pulled up from the water and further displaced upward, the humidified water gradually flows out from the front concave portion (61). When this effluent water drops on the upper surface (53a) of the plate electrode (53), a water film (55) is formed on the upper surface (53a) of the plate electrode (53) (see FIG. 6C).

  On the other hand, during the water purification operation, a voltage is supplied from the power source (18) to the water purification discharge section (51). As a result, streamer discharge is performed from the rod-shaped electrode (54) toward the plate electrode (53) and the water film (55), thereby generating the active species. This active species is used for sterilization of humidified water by removing toxic substances contained in water by oxidative decomposition.

  The water purified as described above is dropped downward from the lower end of the plate electrode (53) and is collected in the water tank (41). Since active species still remain in the water collected in the water tank (41), removal of harmful substances in the humidified water and sterilization are continuously performed in the water tank (41).

-Effect of the embodiment-
In the above embodiment, the water in the water tank (41) is transferred to the water purification discharge section (51) by the water wheel (42) and purified by the active species generated in the water purification discharge section (51). ing. Thereby, the water in a water tank (41) can be purified reliably, without being influenced by the fluctuation | variation of the water level in a water tank (41).

  More specifically, if the rod-shaped electrode (54) is disposed above the water surface in the water tank (41) and a potential difference is applied between the rod-shaped electrode (54) and the humidified water, for example, humidified water. The distance between the rod-shaped electrode (54) and the water surface (humidified water) cannot be kept constant due to fluctuations in the level of the humidified water accompanying use or replenishment. As a result, with the change in the so-called interelectrode distance, there arises a problem that spark discharge (spark) occurs or the desired streamer discharge cannot be continued, resulting in a reduction in water purification efficiency.

  On the other hand, in the above embodiment, the water in the water tank (41) is transferred to the water purification discharge part (51) outside the water tank (41) and discharged at this site. Such discharge can be stably performed without being affected by the fluctuation of the water level in the water tank (41), and the humidified water can be reliably purified.

  In the above embodiment, the contact efficiency between the active species and water is increased by forming a water film (55) on the upper side of the plate electrode (53) and discharging toward the water film (55). Water purification action can be enhanced. Further, by inclining the flat plate electrode (53), the water on the upper surface (53a) of the flat plate electrode (53) can be easily collected into the water tank (41) by its own weight. Therefore, it is not necessary to separately provide a water transport means such as a pump for sending the water transferred to the water purification discharge section (51) to the water tank (41), piping, etc., and the structure of the apparatus can be simplified. it can. In addition to inclining the water surface of the plate electrode (53) obliquely, the plate electrode (53) is arranged in a vertical posture so that the water surface is vertical, and the transferred water is transmitted along the water surface. In this way, it may be allowed to flow downward.

  Further, by collecting the water containing the active species in the water tank (41), the water in the water tank (41) can be further purified by the active species. Therefore, the cleanliness of water given to the air during the humidification operation can be further increased. Therefore, for example, it can be avoided that harmful substances (such as ammonia) and bacteria in humidified water are supplied indoors and the cleanliness of the room is impaired.

-Modification of the embodiment-
In the above embodiment, the configuration of the water purification unit (50) may be the configuration of each of the following modifications.

<Modification 1>
As shown in FIG. 7, the flat plate electrode (53) may be formed in an arc shape such that the cross-sectional view in the longitudinal direction bulges downward. In this case, water flowing through the upper surface (53a) of the flat plate electrode (53) can be prevented from flowing out in the width direction, and this water can be reliably sent to the lower end side. Further, when the rod-shaped electrode (54) is arranged so as to coincide with the axis of the plate electrode (53), the distance from the rod-shaped electrode (54) to the plate electrode (53) can be made uniform in the circumferential direction, Discharge can be further stabilized.

< Reference form 1 >
As shown in FIGS. 8A to 8C, a rotating electrode (56) as a first electrode may be formed on the radially outer surface of the water turbine (42). The rotating electrode (56) has an annular shape or a cylindrical shape that is fitted on the outer peripheral surface of the water turbine (42), and is formed in a mesh shape having a plurality of holes. As a result, when the rotating electrode (56) is immersed in the water of the water tank (41) and then pulled up from the water, moisture adheres to the surface of the rotating electrode (56) and a water film is formed.

  On the other hand, the rod-shaped electrode (54) is disposed in the vicinity of the upper portion of the water wheel (42) so as to face the portion of the rotating electrode (56) pulled up from the water. The rod-shaped electrode (54) extends in the axial direction of the water wheel (42) and is disposed substantially parallel to the rotating electrode (56). Further, the tip of the rod-shaped electrode (54) is located immediately above the intermediate portion in the axial direction of the rotating electrode (56).

In the reference mode 1 , for example, during the humidifying operation, the position where the rotating electrode (56) is immersed in water and the position where the rotating electrode (56) is pulled up from the water are alternately displaced as the water wheel (42) rotates. In the rotating electrode (56), when the part where the water film (55) is formed by being pulled up from the water is substantially opposite to the rod-like electrode (54), the water film (55) (mesh) of this part from the rod-like electrode (54) Streamer discharge is performed toward the electrode. As a result, this water is purified by the active species. In addition, the water containing the active species is immersed in the water in the water tank (41) as the water wheel (42) rotates, and is also used for purification of the water.

< Reference form 2 >
As shown in FIGS. 9A to 9C, a rotating electrode (56) as a first electrode may be formed on the side surface of the water wheel (42). The rotating electrode (56) is formed in the whole area of the side surface on the front surface side of the water turbine (42) and has a disk shape and a mesh shape having a plurality of holes. As a result, when the rotating electrode (56) is immersed in the water of the water tank (41) and then pulled up from the water, moisture adheres to the surface of the rotating electrode (56) and a water film is formed.

  On the other hand, the rod-like electrode (54) is disposed in the vicinity of the front side of the water wheel (42) so as to face a portion of the rotating electrode (56) pulled up from the water. The rod-shaped electrode (54) extends in the vertical direction and is disposed substantially parallel to the rotating electrode (56).

In the reference mode 2 , for example, during the humidifying operation, the position where the rotating electrode (56) is immersed in water and the position where the rotating electrode (56) is pulled up from the water are alternately displaced as the water wheel (42) rotates. In the rotating electrode (56), when the part where the water film (55) is formed by being pulled up from the water is substantially opposite to the rod-like electrode (54), the water film (55) (mesh) of this part from the rod-like electrode (54) Streamer discharge is performed toward the electrode. As a result, this water is purified by the active species. In addition, the water containing the active species is immersed in the water in the water tank (41) as the water wheel (42) rotates, and is also used for purification of the water.

< Reference form 3 >
As shown in FIGS. 10A to 10B, a transfer pipe (64) and a water pump (65) as transfer means (60) may be used. In this example, the inflow end of the transfer pipe (64) opens into the water in the water tank (41), and the outflow end of the transfer pipe (64) faces the gas phase space above the water tank (41). Yes. Further, the water pump (65) for pumping up the water in the water tank (41) is connected to the transfer pipe (64).

  The outflow end of the transfer pipe (64) is opened so as to face downward, and a mesh plate electrode (57) as a first electrode is disposed in the vicinity of the lower side. The mesh plate electrode (57) is a flat plate having a horizontal posture, and is formed in a mesh shape having a plurality of holes penetrating vertically. On the other hand, the rod-shaped electrode (54) is disposed in the vicinity of the lower surface of the mesh plate electrode (57). The rod-shaped electrode (54) is disposed substantially parallel to the lower surface of the mesh plate electrode (57).

In the reference form 3 , the water in the water tank (41) is pumped upward through the transfer pipe (64) by operating the water pump (65). This water flows out from the outflow end of the transfer pipe (64) toward the mesh plate electrode (57). In the mesh plate electrode (57), the water that has flowed out forms a water film on the surface. Then, streamer discharge is performed from the rod-shaped electrode (54) toward the mesh plate electrode (57) in such a state. As a result, this water is purified by the active species. Thus, the water containing the active species is collected in the water tank (41) through the plurality of holes of the mesh plate electrode (57), and is also used for purifying the water in the water tank (41). In Reference Mode 3 , the mesh plate electrode (57) may be disposed so as to be inclined obliquely downward (see FIG. 11). Further, the mesh plate electrode (57) may be arranged vertically.

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

  In the embodiment and the modification, the water purification unit (50) according to the present invention is applied to the humidity control apparatus (10) having a dehumidifying function, an air purification function, and a humidifying function. However, you may apply this water purification unit (50) to the humidity control apparatus which has only a humidification function (namely, humidification means).

  Specifically, the humidity control apparatus in FIG. 12 constitutes a humidifier (70) that only humidifies air. The humidifier (70) is provided with a water tank (41), a water wheel (42), and a humidification rotor (43) similar to those in the above embodiment in the air passage in the casing. In the humidifier (70), a humidifying heater (71) is provided in a part of the humidifying rotor (43). Water in the water tank (41) is supplied to the humidification rotor (43) via the water wheel (42). On the other hand, the air flowing in the casing is heated by the humidifying heater (71) and then passes through the humidifying rotor (43). As a result, the moisture of the humidification rotor (43) is imparted to the air. The air humidified as described above is discharged to the outside of the casing and used for humidification in a room or the like.

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

  As described above, the present invention is useful for a humidity control apparatus including a humidifying unit that applies water in a water container to the air.

FIG. 1 is a perspective view showing the overall configuration of the humidity control apparatus according to the embodiment, and shows a state in which a water tank is pulled out from a casing. FIG. 2 is a schematic longitudinal sectional view showing the inside of the humidity control apparatus. FIG. 3 is a schematic vertical cross-sectional view showing the inside of the humidity control apparatus near the front side. FIG. 4 is a perspective view of the dehumidifying unit. FIG. 5 is a perspective view of the humidifying unit. FIG. 6 is a diagram schematically illustrating a schematic configuration of the water purification unit. FIG. 7 is a perspective view schematically showing a schematic configuration of the water purification unit of the first modification. FIG. 8 is a diagram schematically illustrating a schematic configuration of the water purification unit according to the first embodiment . FIG. 9 is a diagram schematically illustrating a schematic configuration of the water purification unit according to the second embodiment . FIG. 10 is a diagram schematically illustrating a schematic configuration of the water purification unit according to the third embodiment . FIG. 11 is a diagram schematically showing a schematic configuration of a water purification unit of another example of Reference Embodiment 3 . It is a perspective view which shows the whole structure of the humidifier which concerns on other embodiment.

41 Water tank (water container)
42 Water wheel (rotating member, transfer means)
42b Rear recess (humidification recess)
43 Humidification rotor (humidification means)
51 Discharge treatment part (discharge part for water purification)
53 Flat electrode (first electrode)
53a Top surface (flowing water surface)
54 Rod electrode (second electrode)
60 Means of transport
61 Front recess (recess)

Claims (3)

A humidity control device comprising: a water container (41); and a humidifying means (43) for humidifying the air by applying water in the water container (41) to the air,
A discharge treatment section (51) in which discharge is performed so as to generate active species for purifying water;
Transfer means (60) for transferring water in the water container (41) to the discharge treatment section (51);
A return flow path for sending water transferred to the discharge treatment section (51) to the water container (41);
The transfer means (60) is composed of a rotating member (42) that has a recess (61) that is immersed in the water container (41) and pumps up the water in the water container (41).
The discharge treatment section (51) includes a first electrode (53) on which a flowing water surface (53a) through which water flowing out from the concave portion (61) of the rotating member (42) flows in a film form, and the flowing water surface ( 53a) and a second electrode (54) disposed so as to face the first electrode (53), and the discharge from the second electrode (54) toward the surface of the first electrode (53) A humidity control apparatus characterized by being configured to be performed . In claim 1 ,
The first electrode (53) is disposed such that its water surface (53a) is inclined downward or becomes vertical,
The humidity control apparatus, wherein the water container (41) is opened such that an upper side thereof faces a lower end portion of the first electrode (53). In claim 1 or 2 ,
The rotating member (42) is characterized in that a plurality of humidifying recesses (42b) for pumping the water in the water container (41) to the humidifying means (43) side are formed around the axis. Humidity control device.

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