JP2009216331A - Humidifier - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a constitution without hindering the sliding movement of a vessel by a member for constituting a carrying passage of a gas including active species, when slidingly moving the vessel to a body, in a humidifier constituted so as to purify storage water stored in the vessel for humidifying the inside of a space, by bubbling of the gas including the active species. <P>SOLUTION: The carrying passage 55 is separably constituted into: a vessel outside passage 55a positioned outside the vessel 41; and a vessel inside passage 55b positioned in the vessel 41. These passages 55a and 55b are constituted so as to be mutually connected when the vessel 41 is positioned in an installation position in a casing 11 by the sliding movement. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a humidity control apparatus including a container housed inside a casing and a humidifying mechanism that humidifies the space with stored water stored in the container, and belongs to the technical field of purification treatment of the stored water. It is.

  2. Description of the Related Art Conventionally, as a humidity control apparatus including a humidifying mechanism that humidifies the space, a device that vaporizes the stored water stored in a container and supplies the water to the space is generally known. In such a humidity control apparatus, if the stored water is stored in the container for a long time, mold, bacteria, or the like may be propagated and contaminated in the stored water. As described above, the water stored in the water storage section is purified with a photocatalyst or the like.

  As a method of purifying water, in addition to the method of using a photocatalyst as described above, for example, as disclosed in Patent Document 2, a method of generating active species such as ozone and purifying water with this active species It has been known.

Specifically, in the configuration disclosed in Patent Document 2, the water in the container is purified by bubbling the ozone gas generated by the ozoneizer with respect to the water stored in the container. I have to.
JP 2000-283512 A Japanese Patent Laid-Open No. 6-323566

  By the way, in general, in a humidifying device that requires moisture for humidification, a container in which water is stored is configured to be removable so that water can be replenished and cleaned in the container. Moreover, since the container is housed inside the casing of the apparatus, the container is often configured to be slidable relative to the casing.

  When the gas containing the active species is bubbled into the stored water in the container as in the latter conventional example, the humidifying device having such a configuration is configured such that the transport path through which the gas flows is stored in the stored water in the container. However, when the container is slid, there is a possibility that the members constituting the conveyance path interfere with each other and hinder the sliding movement.

  This invention is made | formed in view of such a point, The place made into the objective purifies the stored water stored in the container in order to humidify the space by bubbling of the gas containing an active species. In the humidity control apparatus configured as described above, when the container is slid with respect to the main body, a configuration is obtained in which members constituting the gas conveyance path containing the active species do not hinder the sliding movement of the container. There is.

  In order to achieve the above object, in the humidity control apparatus (10) according to the present invention, the transport path (55) through which the gas containing the active species flows is outside the container located outside the container (41) where the stored water is stored. The container (41) is configured to be separable into a passage (55a) and an in-container passage (55b) located inside the container (41). When the container (41) is housed in the casing (11), The passages (55a, 55b) were connected.

  Specifically, the first invention includes a container (41) housed inside the casing (11), and a humidifying mechanism (40) that humidifies the space with the stored water stored in the container (41). A humidity control apparatus equipped with

  And the active species generating means (51) for generating the active species, and a conveying path for conveying the gas containing the active species generated by the active species generating means (51) to the water of the stored water in the container (41) ( 55), and the container (41) is configured to be slidable out of the casing (11), and the transport path (55) is disposed outside the container (41). 55a) and a container passage (55b) located in the container (41) so as to be separable. These passages (55a, 55b) are formed in the casing by sliding the container (41). (11) It shall be comprised so that it may mutually connect when it is located in the attachment position in.

  With this configuration, the transport path (55) for transporting the gas containing the active species to the water in the stored water in the container (41) is separated inside and outside the container (41). Even when the casing (11) is slid with respect to the casing (11), it is possible to prevent the members constituting the transport path (55) from hindering the sliding movement of the container (41).

  In addition, when the container (41) is positioned at the mounting position in the casing (11), the container outer passage (55a) and the container inner passage (55b) constituting the conveyance path (55) are connected. Even if the conveyance path (55) is separated into two passages (55a, 55b), if the container (41) is positioned at the mounting position in the casing (11), the gas containing the active species can be conveyed. The conveyance path (55) can be reliably configured, and the gas containing the active species can be reliably supplied to the stored water in the container (41) via the conveyance path (55).

  In the above-described configuration, each of the outer container passage (55a) and the inner container passage (55b) may be provided so that the connection portion opens in a direction intersecting the sliding direction of the container (41) ( In the second aspect of the present invention, the container outer passage (55a) and the container inner passage (55b) may each be provided such that the connection portion opens in the sliding direction of the container (41) (third Invention). With these configurations, even when the transport path (55) is separated inside and outside the container (41), the transport path (55) can be configured by connecting the separated paths (55a, 55b). In particular, with the latter configuration, the container inner passage (55b) in the container (41) is connected to and separated from the outer container passage (55a) as the container (41) slides. I can. Therefore, with the latter configuration, it is possible to prevent the connecting portions of both the passages (55a, 55b) from being displaced due to the sliding position of the container (41), and to reliably connect both the passages (55a, 55b). it can.

  Moreover, it is preferable that the said container outer channel | path (55a) and the container inner channel | path (55b) are respectively comprised by the pipe member (71,72) (4th invention). Thereby, the conveyance path (55) for conveying the gas containing an active species to the stored water in a container (41) can be comprised easily.

  Further, the connecting portion (72a) of the pipe member (72) constituting either the passage (55b) of the outer passage (55a) or the inner passage (55b) constitutes the other passage (55a). It is preferable that the connecting member (71a) of the pipe member (71) to be fitted can be fitted outside (fifth invention). By doing so, in the connection portion of the outer container passage (55a) and the inner container passage (55b), the connection portion (72a) of the pipe member (72) constituting one passage (55b) is replaced with the other passage (55a). Therefore, the connecting portions (71a, 72a) can be reliably connected to each other.

  In addition, the connecting portion of at least one of the outer container path (55a) and the inner container path (55b) (55a) may be formed of an elastic member (sixth invention). As a result, when the container (41) is slid relative to the casing (11) and positioned at the mounting position, the elastic member forming the connecting portion (71a) of at least one of the passages is easily deformed, and the container outer passage (55a) and the passage in the container (55b) are easily connected. In addition, with the above-described configuration, the portion constituting the connecting portion of the container outer passage (55a) and the container inner passage (55b) comes into contact with other members or the like as the container (41) slides. Even in this case, since it easily deforms, it is possible to prevent this connecting portion from hindering the sliding movement of the container (41).

  Further, the container passage is not formed by a pipe member, but is formed in the container (91) such that an end opposite to the container outer passage side opens toward the inside of the container (91). You may comprise by the made hole (91b) (7th invention).

  By doing so, it is not necessary to separately provide a pipe member or the like in the container (41), so that it is possible to reduce the number of parts and to eliminate the need for attaching the pipe member or the like, thereby reducing the manufacturing cost. Therefore, the in-container passage can be easily formed in the container (41) at low cost.

  According to the first aspect of the present invention, the conveyance path (55) for supplying the gas containing the active species to the stored water in the container (41) is provided outside the container (41a). ) And an in-container passage (55b) positioned inside the container (41), and the container (41) configured to be slidable relative to the casing (11) is in the mounting position. Since the both passages (55a, 55b) are connected when positioned, the members constituting the transport path (55) in the configuration for bubbling the active species against the stored water in the container (41) The container (41) can be smoothly slid relative to the casing (11) without being obstructed by the above.

  Further, according to the second and third inventions, the connecting portions of the container outer passage (55a) and the container inner passage (55b) are in a direction intersecting or sliding with the sliding direction of the container (41). Since it is open, both the passages (55a, 55b) can be connected by sliding the container (41). In particular, the passages (55a, 55b) can be reliably connected to each other by opening in the sliding direction of the container (41) as in the third invention.

  According to the fourth aspect of the present invention, since the outer container passage (55a) and the inner container passage (55b) are constituted by the pipe members (71, 72), the conveyance path (55) is reliably and easily formed. can do.

  According to the fifth invention, the connecting portion (72a) of the pipe member (72) constituting at least one of the container outer passage (55a) and the container inner passage (55a) has the other passage. Since it is configured to be able to be externally fitted to the connecting portion (71a) of the constituting pipe member (71), both the passages (55a, 55b) can be reliably connected.

  According to the sixth aspect of the present invention, the connecting portion of at least one of the container outer passage (55a) and the container inner passage (55b) is formed by the elastic member, so that both the passages (55a, The connection of 55b) is facilitated, and it is possible to reliably prevent the connecting portion of the passages (55a, 55b) from inhibiting the sliding movement of the container (41).

  Further, according to the seventh invention, the container internal passage is formed in the container (91) such that an end opposite to the container external passage side opens toward the inside of the container (91). Since it is constituted by the hole (91b), the passage can be easily formed in the container (91) at low cost.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. It should be noted that the following description of the preferred embodiment is merely illustrative in nature and is not intended to limit the present invention, its application, or its use.

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

<Overall configuration of humidity control device>
As shown in FIGS. 1 and 2, the humidity control apparatus (10) is a resin casing (11) in which various components for performing a humidification operation and air purification are housed. The casing (11) is formed in a rectangular parallelepiped shape whose width dimension is larger than the dimension in the front-rear direction and whose height dimension is larger than the dimension in the width direction or the front-rear direction. The casing (11) is formed with a suction port (12) for introducing air into the casing (11) on at least one of the front and side surfaces thereof. Further, the casing (11) is formed with an outlet (13) for blowing out air in the casing (11) into the space at a portion near the upper rear side. An air passage (14) through which air flows from the suction port (12) toward the blowout port (13) is formed in the casing (11). In the humidity control apparatus (10) shown in FIG. 1, the front surface of the casing (11) is covered with a front panel (11a).

  As shown in FIG. 2, in the air passage (14), air purification means (20), humidification unit (40) (humidification mechanism), and centrifugal fan are arranged in order from the upstream side to the downstream side of the air flow. (15) is arranged. The humidity control apparatus (10) also includes an ozone supply unit (50) for supplying ozone into a water tank (41) (container) described later.

<Configuration of air purification means>
As shown in FIG. 2, the air purifying means (20) is for purifying the air flowing in the air passage (14). The air purifying means (20) is pre-sequentially from the upstream side to the downstream side of the air flow. It has a filter (21), an ionization part (22), and a pleated filter (23).

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

  The ionization part (22) constitutes a dust charging means for charging dust in the air. The ionization section (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 source, whereby 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).

<Composition of humidification unit>
Next, the configuration of the humidification unit (40) will be described below based on FIG. As shown in FIG. 2, the humidification unit (40) includes a water tank (41) for storing water (reserved water, humidified water), and a water turbine (for pumping up water in the water tank (41)). 42), a humidification rotor (43) constituting humidification means for imparting water pumped up by the water wheel (42) to the air, and a drive motor (44) for rotationally driving the humidification rotor (43) ). The humidification unit (40) also includes a heater (48) for heating the humidification rotor (43).

  As shown also in FIG. 1 etc., the said water tank (41) is comprised by the horizontally long box member (45) which an upper side opens, and the cover member (46) which covers the upper side of this box member (45). . The water tank (41) is installed in the space below the casing (11) so that the longitudinal direction of the water tank (41) is the width direction of the casing (11), and the side surface of the casing (11) It is configured to be able to be taken in and out (slidable) with respect to the outlet (11b) formed in (see FIG. 1). Thereby, in the state which pulled out the said water tank (41) from the casing (11), the water for humidification can be suitably replenished in this water tank (41).

  The water wheel (42) is formed in a substantially disc shape, and a rotation shaft (42a) is provided on the shaft center portion so as to protrude outward in the thickness direction from both surfaces. The rotating shaft (42a) is pivotally supported at the upper end of a bearing portion (not shown) erected on the bottom surface of the water tank (41), whereby the water turbine (42) is placed in the water tank (41). Is supported rotatably. Moreover, the said water turbine (42) is supported by the said bearing part so that the predetermined site | part containing the lower end part may become a height position immersed in the water in a water tank (41).

  In the water turbine (42), a plurality of recesses (42b) are formed on a side surface (side surface facing the humidification rotor (43)) located on the rear side of the casing. These concave portions (42b) constitute a humidifying concave portion for pumping humidified water to the humidifying rotor (43) side. The recesses (42b) are formed at equal intervals in the circumferential direction at the radially outer end of the water turbine (42). In addition, the concave portion (42b) is positioned at a position where the water tank (41) is immersed in the water or a position where the water tank (41) is pulled out of the water by the rotating operation of the water wheel (42), and is immersed in the water. The water that has entered the recess (42b) can be pumped up to the surface of the water.

  An intermediate gear (42d) is arranged coaxially with the water wheel (42) on the rear side surface of the water wheel (42), and a tooth on the outer peripheral surface of the intermediate gear (42d). The part (42c) is integrally formed. The tooth portion (42c) of the intermediate gear (42d) is configured to mesh with a driven gear (43a) of a humidifying rotor (43) described later.

  The humidification rotor (43) has an annular driven gear (43a) and a disk-like adsorption member (43b) that is fitted and held in the driven gear (43a). This adsorption member (43b) is comprised with the nonwoven fabric which has 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 said humidification rotor (43) is arrange | positioned so that the predetermined site | part containing the lower end may contact substantially with the said water turbine (42). That is, the humidification rotor (43) has a portion that overlaps the concave portion (42b) of the water turbine (42) in the axial direction (front-rear direction). Thereby, the water pumped up by the recessed part (42b) of a water wheel is absorbed by the adsorption member (43b) of the humidification rotor (43).

  The drive motor (44) is configured to rotationally drive the driven gear (43a) of the humidification rotor (43) via a pinion or the like. When the driven gear (43a) is rotated by the drive motor (44), the water wheel (42) meshing with the driven gear (43a) is rotated. Thereby, the humidification rotor (43) and the water wheel (42) can be rotated by the drive motor (44).

  The heater (48) is disposed so as to be close to the upper end of the upstream side surface of the humidification rotor (43). By providing this heater (48), the air flowing into the humidification rotor (43) can be heated, and the heat can vaporize the water in the humidification rotor (43) to humidify the air.

<Configuration of ozone supply unit>
The ozone supply unit (50) is for supplying ozone gas (gas containing active species) to water (reserved water, humidified water) in a water tank (41) supplied to the humidification rotor (43). . As shown in FIG. 3, the ozone supply unit (50) includes a discharge part (51) (active species generation means) as ozone generation means, and ozone gas generated by the discharge part (51) in the water tank ( 41) A transport duct (63) that constitutes a transport path (55) for guiding it into the interior, and a pressure pump (64) for pumping ozone gas into the water tank (41) via the transport duct (63) And. In FIG. 3, the lid member (46) covering the upper side of the water tank (41) is omitted.

  The discharge part (51) is disposed in the ozone gas generation chamber of the discharge part casing (62), and is configured to generate ozone gas by streamer discharge. Specifically, the discharge part (51) includes a rod-shaped electrode (52) and a plate electrode (53). The rod-like electrode (52) is supported on a substrate (52a) disposed in the ozone gas generation chamber via a support plate (52b). The flat plate electrode (53) is formed in a flat plate shape and is arranged so as to be parallel to the rod-shaped electrode (52).

  The rod-like electrode (52) is connected to the positive side of the power source (18), and the flat plate electrode (53) is connected to the negative side (or ground side) of the power source (18). When a potential difference is applied from the power source (18) to both electrodes (52, 53), streamer discharge occurs from the tip of the rod-like electrode (52) toward the flat plate electrode (53). As a result, the oxygen molecules flowing between the electrodes (52, 53) dissociate and recombine with other oxygen molecules to generate ozone gas. Note that a DC high voltage is preferably supplied from the power source (18) to the discharge unit (51), and so-called constant current control is preferably performed so that the discharge current is constant. .

  The discharge section casing (62) is connected to an introduction pipe (61) for introducing air into the ozone gas generation chamber inside the discharge section casing (62) and the transfer duct (63). As a result, ozone gas is generated between the electrodes (52, 53) using the air introduced from the introduction pipe (61), and this ozone gas is introduced into the water tank (41) via the transport duct (63). Can be supplied.

  The inlet pipe (61) has an inflow end opened to the air passage (14). That is, a part of the air flowing through the air passage (14) is branched and introduced into the introduction pipe (61). The transport duct (63) has its downstream end (63a) at the liquid level in the water tank (41) so that its downstream end (63a) is immersed in the water in the water tank (41). It is formed in such a length that it is located below (WL). As will be described in detail later, the transfer duct (63) is divided into an outer side and an inner side of the water tank (41) (FIG. 3 is a schematic diagram showing a schematic configuration of the ozone supply unit. The description of the structure is omitted).

  Thus, by supplying ozone gas with the downstream end (63a) of the transport duct (63) immersed in the stored water stored in the water tank (41), the water tank The stored water in (41) can be purified by ozone gas.

<Configuration of transfer duct>
FIG. 4 schematically shows the relationship between the water tank (41) in the casing (11) and the transfer duct (63). FIG. 5 is an enlarged view of a divided portion of the transport duct (63).

  As shown in FIGS. 4 and 5, the transfer duct (63) is configured to be separable outside and inside the water tank (41). That is, the transfer duct (63) is connected to the upper transfer duct (71) connected to the discharge casing (62) at the upper end and to the lower end of the upper transfer duct (71). A lower transfer duct (72) provided in the lid member (46) of the tank (41). The upper conveyance duct (71) constitutes the upper conveyance path (55a) of the conveyance path (55), and the lower conveyance duct (72) constitutes the lower conveyance path (55b) of the conveyance path (55). Has been.

  The upper transport duct (71) and the lower transport duct (72) are provided so as to open in a direction intersecting the sliding direction of the water tank (41) (a direction orthogonal to FIG. 4). That is, the upper transport duct (71) is disposed so as to open downward, while the lower transport duct (72) is disposed so as to open upward.

  Moreover, the lower end part (71a) of the said upper conveyance duct (71) and the upper end part (72a) of a lower conveyance duct (72) are formed, for example with elastic materials, such as rubber | gum. On the upper end surface (72a) of the lower transfer duct (72), an engagement recess (72b) that can be fitted to the lower end portion of the upper transfer duct (71) is formed on the upper end surface. . That is, the upper transport duct (71) and the lower transport duct (72) are configured such that the lower end of the lower end (71a) and the upper end of the upper end (72a) overlap in a side view.

  Further, the upper transfer duct (71) has a lower surface of the lower end portion (71a) that is a lid member of the water tank (41) so that the lower end portion (71a) does not hinder the sliding movement of the water tank (41). It is comprised so that it may be located above the upper surface of (46). On the other hand, the upper surface of the lower transfer duct (72) is such that the upper end portion (72a) is engageable with the lower end portion (71a) of the upper transfer duct (71). It is configured to be positioned above (46).

  Thus, when the water tank (41) is slid out of the casing (11) and pulled out, the transfer duct (63) is separated into the upper transfer duct (71) and the lower transfer duct (72). The transfer duct (63) can be prevented from obstructing the sliding movement of the water tank (41).

  When the water tank (41) is slid to the mounting position with respect to the casing (11) of the humidity control device (10) (FIG. 5A), the lower end of the upper transfer duct (71) ( 71a) and the upper end (72a) of the lower transfer duct (72) are each elastically deformed, and the lower end (71a) of the upper transfer duct (71) becomes the upper end (72a) of the lower transfer duct (72). ) Is engaged in the engagement recess (72b) formed in (). Therefore, the upper transfer duct (71) and the lower transfer duct (72) can be reliably connected as the water tank (41) slides. The mounting position of the water tank (41) means the position of the water tank (41) where both the ducts (71, 72) are connected.

  Furthermore, since the lower end portion (71a) and the upper end portion (72a) are each constituted by an elastic member, the connection portion of both can be sealed, and leakage of ozone gas from the connection portion can be prevented. it can.

  Although not particularly illustrated, at least one of the upper transport duct (71) and the lower transport duct (72) may be provided with a check valve, or a resistance member such as a porous body or a fiber member. Good. Thereby, the water in the water tank (41) can be prevented from rising in the upper transfer duct (71) and the lower transfer duct (72) and leaking out of the water tank (41).

-Driving action-
The humidity control apparatus (10) performs a humidifying operation for purifying indoor air and humidifying indoor air. Further, the humidity control apparatus (10) performs a water purification operation for purifying the stored water in the water tank (41) simultaneously with the humidification operation. The water purification operation may be performed not at the same time as the humidification operation but when the humidification operation is not performed.

<Humidification operation>
In the humidification operation, the centrifugal fan (15) is driven and the humidification rotor (43) is rotationally driven by the drive motor (44). In addition, a voltage is applied to the electrode of the ionization section (22) of the air purification means (20), and the heater (48) located on the air upstream side of the humidification rotor (43) is energized.

  When the centrifugal fan (15) is driven, indoor air is introduced from the suction port (12) into the air passage (14) in the casing (11), as indicated by a white arrow in FIG. The air introduced into the air passage (14) passes through the prefilter (21), and dust is captured by the prefilter (21), and then passes through the ionization section (22). In this ionization part (22), corona discharge is performed between the electrodes, and thereby dust in the air is charged. The air that has passed through the ionization section (22) passes through the pleated filter (23). In the pleated filter (23), the dust charged by the ionization part (22) is electrically attracted and captured. The air that has passed through the pleated filter (23) is heated by the heater (48) and then passes through the humidification rotor (43).

  In the humidification unit (40), the water wheel (42) rotates, and the humidified water in the water tank (41) is appropriately supplied to the adsorption member (43b) of the humidification rotor (43). Specifically, when the water wheel (42) rotates and the recess (42b) of the water wheel (42) is immersed in the humidified water in the water tank (41), the humidified water enters the recess (42b). , Held in the recess (42b). When the water turbine (42) further rotates, the concave portion (42b) holding the humidified water is pulled up from the humidified water and displaced upward. As described above, when the concave portion (42b) moves upward as the water turbine (42) rotates, the concave portion (42b) gradually approaches the humidification rotor (43) and the concave portion (42b) The humidified water held in the) gradually flows out of the recess (42b) by its own weight. Thereby, the humidified water in the said recessed part (42b) is adsorb | sucked by the adsorption | suction member (43b) of the said humidification rotor (43). By such an operation, humidification water is continuously supplied to the humidification rotor (43) in the humidification unit (40).

  In addition, the said recessed part (42b) is comprised so that the humidified water in this recessed part (42b) may flow out substantially all when it reaches | attains to the uppermost end position by rotation of the said water turbine (42).

  When the air flowing in the air passage (14) passes through the adsorption member (43b) of the humidification rotor (43) adsorbed with the humidified water as described above, the moisture adsorbed on the adsorption member (43b) is absorbed. Released into the air. As a result, air is humidified.

  The air purified and humidified as described above is supplied into the room from the air outlet (13). In this humidification operation, it is possible to perform an operation that does not actively purify air by stopping the supply of voltage from the power source to the ionization section (22).

<Purification of humidified water>
If humidified water is stored in the water tank (41) for a long time, the humidified water in the water tank (41) may be contaminated due to the growth of mold or bacteria in the water. is there. For example, if the air flowing in the air passage (14) contains a substance such as ammonia (toxic substance or odorous substance), this substance dissolves in water and the humidified water in the water tank (41) May be contaminated. If the contaminated humidified water is vaporized and supplied to the room, germs and harmful substances are also supplied to the room, which may impair the cleanliness of the room.

  In the humidity control apparatus (10) according to the present embodiment, the ozone gas supply unit (50) capable of generating ozone gas is used to supply ozone gas into the water tank (41), whereby the water tank (41) The water purification operation of purifying the humidified water is possible.

  Specifically, when the water purification operation starts, the pressure pump (64) is operated, and a voltage is applied from the power source (18) to the discharge unit (51). When the pressurizing pump (64) is operated, air is introduced into the ozone gas generation chamber in the discharge casing (62) through the introduction pipe (61) (see the white arrow in FIG. 3). When a voltage is applied to the discharge part (51), streamer discharge is generated in the discharge part (51). Ozone gas is generated in the discharge part casing (62) by this streamer discharge. The generated ozone gas is conveyed by the pressure pump (64) through the conveyance path (55) in the conveyance duct (63) toward the water tank (41), and the humidified water stored in the water tank (41). To be released.

  In this way, by releasing (bubble) ozone gas into the humidified water in the water tank (41), the germs and harmful substances contained in the humidified water are decomposed and removed by the ozone gas, and the water tank (41) The humidified water is purified.

-Desorption operation of water tank-
As described above, since the water stored in the water tank (41) is used for humidification, the stored water in the water tank (41) gradually decreases by performing the humidification operation. Therefore, it is necessary to appropriately replenish the water tank (41) with humidified water. For this reason, in the humidity control apparatus (10) according to this embodiment, the water tank (41) housed in the casing (11) Is configured to be slidable.

  However, in such a configuration, when the water tank (41) is slid, the ozone gas transfer duct (63) whose tip is immersed in the humidified water of the water tank (41) is provided in the water tank (41). May interfere with the sliding movement of the water tank (41).

  On the other hand, in the humidity control apparatus (10) according to the present embodiment, the ozone gas transport duct (63) whose tip is immersed in the water tank (41) is positioned outside the water tank (41). The upper transfer duct (71) and the lower transfer duct (72) located inside the water tank (41) are configured to slide the water tank (41) out of the water tank (41). Can be divided inside and outside.

  Specifically, when pulling out the water tank (41) from the casing (11), the lower transfer duct (72) located inside the water tank (41) is connected to the upper transfer duct (71). Separate in the sliding direction. On the other hand, when the water tank (41) is slid to the mounting position in the casing (11), the upper end (72a) of the lower transfer duct (72) provided on the water tank (41) side is the upper part. It approaches the lower end (71a) of the transfer dunk (71). And if the said water tank (41) is located in an attachment position, the lower end part (71a) of the said upper conveyance duct (71) and the upper end part (72a) of the said lower conveyance duct (72) will be connected. At this time, the upper end portion (71a) of the upper transfer duct (71) and the upper end portion (72a) of the lower transfer duct (72) are each constituted by an elastic member, thereby enabling smooth connection between the two. It becomes.

-Effect of the embodiment-
As described above, according to this embodiment, in order to purify the humidified water stored in the water tank (41), the transport duct (63) constituting the transport path (55) for transporting ozone gas to the humidified water is provided. ) Is divided between the outer side and the inner side of the water tank (41) so that when the water tank (41) is slid relative to the casing (11), the transfer duct (63) is connected to the water tank (41). Can be prevented from hindering the slide movement. That is, when pulling out the water tank (41) from the casing (11), the transfer duct (63) is connected to the upper transfer duct (71) outside the water tank (41) and the lower part in the water tank (41). Since it is separated from the transfer duct (72), the transfer duct (63) does not interfere with the water tank (41) to prevent the water tank (41) from sliding.

  Further, when the water tank (41) is positioned at the mounting position in the casing (11), the upper transport duct (71) and the lower transport duct (72) are connected, so that these ducts (71 , 72) can constitute a conveyance path (55) for conveying ozone gas, and the humidified water stored in the water tank (41) can be reliably purified by bubbling ozone gas.

  The lower end of the upper transfer duct (71) is positioned above the upper surface of the lid member (46) of the water tank (41) by positioning the lower surface of the lower end (71a) of the upper transfer duct (71). It is possible to reliably prevent the portion (71a) from interfering with the water tank (41) and hindering the sliding movement of the water tank (41).

  Further, the lower end portion (71a) of the upper transfer duct (71) and the upper end portion (72a) of the lower transfer duct (72) are each constituted by an elastic member so that both ducts (71, 72) are connected. In this case, the lower end (71a) and the upper end (72a) can be smoothly connected by elastic deformation, and the sealing performance of the connection portion can be improved.

-Modification 1 of embodiment-
As shown in FIGS. 6 and 7, the first modification differs from the above embodiment in that the transfer duct (85) can be separated near the side surface of the water tank (81).

  Specifically, the water tank (81) is configured to be slidable with respect to the casing (11), as in the above embodiment, and has a box member (82) opened upward and the box member (83). And a lid member (46) that covers the upper side. And the humidity control apparatus (10 ') which concerns on this modification 1 is the upper conveyance duct which comprises the said conveyance duct (85) by the side surface of the sliding direction back side in the box member (82) of the said water tank (81). (86) and the lower transfer duct (87) are connected to each other. Specifically, as shown in FIG. 6, the side surface of the water tank (81) on the back side in the sliding direction is configured such that the upper part is positioned inward of the water tank (81), as shown in FIG. The upper transfer duct (86) and the lower transfer duct (87) are connected at the upper part. The side surface on the far side in the sliding direction of the water tank (81) may be a flat surface.

  The upper transport duct (86) is connected to the discharge section casing (62) of the ozone supply unit (50) at the upper end portion and is formed to extend downward as in the above embodiment. And the lower end part (86a) of the said upper conveyance duct (86) is bent in the sliding direction (horizontal direction) of the said water tank (81).

  The lower transfer duct (87) is bent so that the upper part extends in the sliding direction of the water tank (81) and the lower part extends in the vertical direction, and the upper end part (87a) is formed in the upper transfer duct (86). On the other hand, the lower end is located below the liquid level (WL) of the humidified water in the water tank (81) and is immersed in the humidified water.

  The upper end portion (87a) of the lower transfer duct (87) is formed in a substantially bottomed cylindrical shape, and is configured to be externally fitted to the lower end portion (86a) of the upper transfer duct (86).

  With the above configuration, when the water tank (81) is slid in the pulling direction with respect to the casing (11), the upper transfer duct (86) located outside the water tank (81) and the water tank ( 81) The lower transfer duct (87) located inside is separated. On the other hand, when the water tank (81) is slid in the insertion direction with respect to the casing (11), the lower transfer duct (87) is moved relative to the lower end (86a) of the upper transfer duct (86). When the upper end portion (87a) approaches and the water tank (81) is positioned at the mounting position, the upper end portion (87a) of the lower transfer duct (87) is brought into contact with the lower end portion (86a) of the upper transfer duct (86). It is fitted outside.

  At this time, the water tank (81) slides along the axial centers of the upper end portion (87a) of the lower transfer duct (87) and the lower end portion (86a) of the upper transfer duct (86). The upper transfer duct (86) and the lower transfer duct (87) can be reliably connected without accurately positioning the water tank (81) at the mounting position.

  In addition, as described above, the lower end portion (86a) of the upper transfer duct (86) and the upper end portion (87a) of the lower transfer duct (87) move along the axial center and are thus fitted. As in the configuration of the embodiment, the lower end (86a) and the upper end (87a) can be easily connected without elastic deformation.

-Modification 2 of embodiment-
As shown in FIG. 8, this modification 2 is different from the above embodiment in that a conveyance path (55) for supplying ozone gas into the water tank (91) is integrally formed in the water tank (91). Different.

  Specifically, a bulging portion (91a) that bulges inward is integrally formed inside the box member (92) constituting the water tank (91). The bulging portion (91a) swells inside a corner of the substantially rectangular parallelepiped box member (92) that opens upward, over a predetermined range below the opening end of the box member (92). It is formed to come out. That is, the bulging portion (91a) is formed so that the lower end thereof is spaced upward from the bottom surface of the water tank (91).

  A through hole (91b) penetrating in the vertical direction is formed in the bulging portion (91a). The through hole (91b) constitutes a part of the transport path (55), and a transport path (not shown) is connected to the upper end of the through hole (91b). In addition, this conveyance path comprises a part of said conveyance path (55), and is comprised so that ozone gas may circulate through the inside.

  In this way, the bulging portion (91a) integrally formed inside the water tank (91) is provided with a through-hole (91b) that constitutes a part of the ozone gas transport path (55), whereby the transport The portion on the water tank (91) side of the passage (55) can be formed integrally with the water tank (91), and the work of assembling a duct or the like becomes unnecessary. As a result, the number of parts can be reduced and the assembling work can be omitted, and the cost can be reduced.

  When the upper side of the box member (92) is covered with a lid member (not shown), if the hole corresponding to the through hole (91b) is provided in the lid member, the through hole (91b) Ozone gas can be supplied inside.

  In the second modification, the bulging portion (91a) is integrally formed inside the water tank (91), and the through hole (91b) is formed in the bulging portion (91a). Instead, the through hole (91b) may be formed in the side wall of the water tank (91) without providing the bulging portion (91a).

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

  In the above embodiment, ozone gas is generated and supplied into the water tank (41). However, the present invention is not limited to this, and any kind of gas can be used as long as it is an active species. Good.

  Moreover, in the said embodiment, although ozone gas is generated by the streamer discharge in the ozone supply unit (50), it is not restricted to this, What kind of structure may be sufficient if it is the structure which can generate | occur | produce ozone gas.

  Furthermore, in the said embodiment, although the humidity control apparatus (10) is comprised so that a humidification operation may be performed, not only this but it may be comprised so that a dehumidification operation may be performed. When performing the dehumidifying operation in this way, the amount and frequency of replenishing the humidified water in the water tank (41) can be reduced by storing the water collected by dehumidification in the water tank (41). be able to.

  In the above embodiment, the water tank (41) is covered with the lid member (46) on the upper side of the box member (45). However, the present invention is not limited to this, and the box member (45) is covered with the lid member (46). The structure which does not cover an upper side may be sufficient.

  As described above, the present invention is particularly useful for a humidity control apparatus that includes a water tank for storing water and is configured to adjust the humidity in the space using the water tank. .

FIG. 1 is a perspective view showing a configuration of a humidity control apparatus according to an embodiment of the present invention (a state in which a water tank and a humidification rotor are pulled out). FIG. 2 is a cross-sectional view of the schematic configuration inside the humidity control apparatus as viewed from the side. FIG. 3 is a diagram schematically showing how ozone gas is supplied into the water tank by the ozone supply unit. FIG. 4 is a diagram illustrating the relationship between the water tank and the transport duct in the humidity control apparatus. FIG. 5 is a diagram illustrating a schematic structure of a connection portion between the upper conveyance duct and the lower conveyance duct. FIG. 6 is a view corresponding to FIG. 4 of the humidity control apparatus according to the first modification. FIG. 7 is a view corresponding to FIG. 5 of the humidity control apparatus according to the first modification. FIG. 8 is a perspective view showing a box member of the water tank of the humidity control apparatus according to the second modification.

Explanation of symbols

10,10 'humidity control device
11 Casing
40 Humidification unit (humidification mechanism)
41,81 Water tank (container)
51 Discharge section (active species generation means)
55 Transport path
55a Upper transfer path (passage outside the container)
55b Lower transfer path (passage in container)
71 Upper transfer duct (pipe member)
71a Lower end (connection part)
72 Lower transfer duct (pipe member)
72a Upper end (connection part)
91 Water tank (container)
91a bulge
91b Through hole

Claims (7)

A humidity control apparatus comprising a container (41) housed inside a casing (11), and a humidifying mechanism (40) for humidifying the interior of the space with stored water stored in the container (41),
Active species generating means (51) for generating active species;
A transport path (55) for transporting the gas containing the active species generated by the active species generating means (51) to the water of the stored water in the container (41),
The container (41) is configured to be slidable out of the casing (11),
The conveyance path (55) is configured to be separable into an outer container path (55a) located outside the container (41) and an inner container path (55b) located inside the container (41). These passages (55a, 55b) are configured to be connected to each other when the container (41) is positioned at the mounting position in the casing (11) by sliding movement. Wet equipment. In claim 1,
The humidity control apparatus characterized in that the container outer passage (55a) and the container inner passage (55b) are provided so that connection portions open in a direction intersecting the sliding direction of the container (41), respectively. . In claim 1,
The humidity control apparatus, wherein the container outer passage (55a) and the container inner passage (55b) are provided so that connection portions open in a sliding direction of the container (41), respectively. In any one of Claim 1 to 3,
The humidity control apparatus, wherein the container outer passage (55a) and the container inner passage (55b) are configured by pipe members (71, 72), respectively. In claim 4,
The connecting portion (72a) of the pipe member (72) constituting either one of the above-mentioned container outer passage (55a) or the container inner passage (55b) is a tube constituting the other passage (55a). A humidity control device configured to be externally fitted to a connection portion (71a) of a member (71). In any one of Claims 1 to 5,
A humidity control apparatus, wherein a connecting portion of at least one of the outer passage (55a) and the inner passage (55b) is formed by an elastic member. In any one of Claim 1 to 3,
The container internal passage is configured by a hole (91b) formed in the container (91) so that an end opposite to the container external passage side opens toward the inside of the container (91). A humidity control device characterized by that.

Images