JP4737330B2 - Discharge unit for liquid treatment, humidity control device, and water heater - Google Patents

Description

  The present invention relates to a liquid treatment discharge unit that purifies liquid by discharging in a liquid, and a humidity control apparatus and a water heater provided with the liquid treatment discharge unit.

  Conventionally, liquid purification techniques for purifying liquid by decomposing harmful substances in the liquid have been widely known. As this type of liquid purification technique, Patent Document 1 discloses a liquid processing apparatus including a discharge unit that purifies liquid by discharging.

  Specifically, the liquid processing apparatus disclosed in Patent Document 1 includes an electrode pair immersed in water and a power supply unit for applying a voltage to the electrode pair. This power supply unit is composed of a high-voltage pulse power supply. When a voltage is applied to the electrode pair from the power supply unit, a discharge is performed between the electrodes. At this time, in the vicinity of the electrode, the liquid is vaporized by Joule heat accompanying the discharge. Thereby, bubbles are generated in the liquid during discharge. In this liquid treatment device, high-voltage dielectric breakdown discharge occurs in such bubbles, thereby generating active species such as ions in the bubbles. ) Is disassembled and sterilized.

JP 2007-207540 A

  As in the liquid processing apparatus disclosed in Patent Document 1, in order to continuously discharge within bubbles, it is necessary to stably generate bubbles in the liquid. However, in the liquid processing apparatus disclosed in Patent Document 1, discharge is performed by applying a high voltage pulse of, for example, ± 50 kV to the electrode pair, so that a relatively large shock wave is generated in the liquid due to such a pulse voltage. Will occur. As a result, the bubbles generated in the liquid are destroyed due to the influence of such shock waves, and there is a possibility that the discharge in the bubbles cannot be continuously performed.

  The present invention has been made in view of such points, and an object of the present invention is to provide a liquid processing discharge unit capable of performing stable discharge in bubbles generated in the liquid, and the liquid processing discharge. It is to propose a humidity control device and a water heater provided with a unit.

1st invention applies a voltage to this electrode pair (52,53) so that discharge may be performed between this electrode pair (52,53) and this electrode pair (52,53) provided in a liquid A liquid treatment comprising a power supply unit (61), and in a current path between the electrode pair (52, 53), liquid is vaporized by Joule heat accompanying discharge to generate bubbles, and discharge is performed in the bubbles Targeted for electric discharge units. Then, the liquid treatment discharge unit, the power supply unit is formed by a high DC power source (61) comprises a constant-power control unit for controlling the discharge power of the electrode pair (52, 53) to be constant, the A current density concentrating portion (70) for increasing the current density of the current path between the electrode pair (52, 53), the current density concentrating portion (70) of the electrode pair (52, 53); An insulating cover member (71) covering a part of at least one of the electrodes (52), the cover member (71) being formed in a cylindrical shape having at least one end opened in the axial direction, the cylindrical cover The electrode (52) covered with the member (71) is formed in a rod shape that fits inside the cylindrical cover member (71), and the rod-shaped electrode (52) has a tip at the cylindrical cover member. (71) It is arrange | positioned so that it may dent inward rather than the opening surface (72a) of the one end side .

  In the first aspect of the invention, a voltage is applied from the power supply unit (61) to the electrode pair (52, 53), whereby discharge is performed between the electrode pair (52, 53). At this time, Joule heat is generated in the current path between the electrode pair (52, 53) due to current flowing. Between the electrode pair (52, 53), liquid is vaporized by this Joule heat, and bubbles are generated. When a voltage is applied to the electrode pair (52, 53), discharge occurs in the bubbles, and active species such as OH radicals are generated in the bubbles. Substances to be treated (toxic substances, bacteria, etc.) contained in the liquid are oxidized / decomposed by this active species.

In the present invention, a high-voltage DC power supply (61) is used as the power supply section (61) for applying a voltage to the electrode pair (52, 53). That is, in the conventional discharge unit, a high voltage pulse is applied from the high voltage pulse power source to the electrode pair, whereas in the discharge unit of the present invention, the electrode pair (52, 53) is supplied from the high voltage DC power source (61). DC voltage is applied to For this reason, in this invention, since it is suppressed that a shock wave generate | occur | produces in a liquid with discharge, the bubble generated in the liquid can be stabilized .

In the present invention, the current density of the current path between the electrode pair (52, 53) is increased by the current density concentration portion (70). In this way, when the current in the current path is locally concentrated, the Joule heat at this part increases, and as a result, bubbles tend to be generated at this part. Therefore, it is possible to reliably generate bubbles between the electrode pairs (52, 53) .

The liquid treatment discharge unit of the present invention is provided with an insulating cover member (71) as the current density concentration portion (70). The cover member (71) is disposed so as to cover a part of one or both of the electrode pairs (52, 53). Thereby, the dispersion | distribution of the electric current to the site | part covered with the cover member (71) among the electrodes (52) is suppressed. As a result, it is possible to increase the current density of the current path between the electrode pair (52, 53) and promote the generation of bubbles .

In the present invention, the rod-shaped electrode (52) is fitted inside the cylindrical cover member (71). Thereby, the current density on the tip side of the electrode (52) can be increased while avoiding the dispersion of the current to the outer peripheral side of the electrode (52). As a result, the generation of bubbles can be promoted in the vicinity of the tip side of the electrode (52).

In the present invention, the tip of the rod-shaped electrode (52) is located at a position recessed inward from the opening surface (72a) of the cylindrical cover member (71). As a result, an aperture space for reducing the cross-sectional area of the current path is formed inside the opening surface (72a) of the cover member (71). As a result, the current density can be further increased at the tip of the rod-like electrode (52). As a result, the generation of bubbles can be promoted near the opening of the cover member (71).

The second invention is characterized in that, in the first invention, the cover member (71) is arranged such that an opening on one end side thereof faces downward.

In the second invention, the opening on one end side of the cover member (71) faces downward. Thus, when bubbles are generated in the vicinity of the opening of the cover member (71), the bubbles accumulate between the tip of the electrode (52) and the opening surface (72a) of the cover member (71). As a result, air bubbles can be stably held under the cover member (71) .

The third invention is characterized in that in the first invention, there is provided a bubble holding part (75) for holding bubbles generated by discharge.

In the third invention, the bubbles generated with the discharge are held by the bubble holding part (75). This prevents bubbles in the liquid from escaping upward .

4th invention applies a voltage to this electrode pair (52,53) so that discharge may be performed between this electrode pair (52,53) and this electrode pair (52,53) provided in a liquid A liquid source is provided between the electrode pair (52, 53), and liquid is vaporized by Joule heat accompanying discharge to generate bubbles, and discharge is also performed in the bubbles. Targeting a discharge unit, the power supply section is composed of a high-voltage DC power supply (61), and a current density concentrating section (70) for increasing the current density of the current path between the electrode pair (52, 53). The current density concentrating portion (70) includes a cylindrical insulating cover member (71) having at least one end opened in the axial direction, and one of the electrode pairs (52, 53) is the cylindrical shape. The rod-shaped electrode (52) that fits inside the cover member (71) of the
The rod-shaped electrode (52) is disposed so that the tip thereof is recessed inwardly from the opening surface (72a) of the opening (72) on one end side of the cylindrical cover member (71), and the cover member (71) The opening (71b) is directed horizontally or upward.

A fifth invention is characterized in that, in the fourth invention, a heat insulating member (80) is provided so as to surround a current path between the electrode pair (52, 53).

In the fifth invention, the current path between the electrode pair (52, 53) is surrounded by the heat insulating member (80). Thereby, in the electric current path inside a heat insulation member (80), the temperature rise in the liquid by Joule heat is accelerated | stimulated. As a result, the vaporization of the liquid is promoted, and consequently the generation of bubbles is promoted.

The sixth invention is to purify the water in the storage part (41) for storing water, the humidifying part (43) for applying the water in the storage part (41) to the air, and the water in the storage part (41). A humidity control apparatus provided with a liquid processing discharge unit (50). The humidity control apparatus is characterized in that the liquid treatment discharge unit (50) includes any one of first to fifth liquid treatment discharge units.

In the humidity control apparatus of the sixth aspect of the invention, the water stored in the storage section (41) is given to the air by the humidification section (43), and humidification of the indoor space or the like is performed. When the discharge is performed in the liquid treatment discharge unit (50), the water in the reservoir (41) is purified by the active species generated by the discharge. Here, in the liquid processing discharge unit (50) of the present invention, a high-voltage DC power supply (61) is used as a power supply unit. For this reason, since it is suppressed that a shock wave generate | occur | produces in a liquid with discharge, the bubble generated in the liquid can be stabilized.

The seventh invention includes a dehumidifying unit (31) that captures moisture in the air and dehumidifies the air, a storage unit (41) in which water captured by the dehumidifying unit (31) is recovered, and the storage unit ( 41) A humidity control apparatus equipped with a liquid treatment discharge unit (50) for purifying water. The humidity control apparatus is characterized in that the liquid treatment discharge unit (50) includes the liquid treatment discharge unit according to any one of the first to fifth inventions.

In the seventh invention, the air is dehumidified by capturing moisture of the air by the dehumidifying section (31). The water captured by the dehumidifying part (31) is collected in the storage part (41). When the discharge is performed in the liquid treatment discharge unit (50), the water in the reservoir (41) is purified by the active species generated by the discharge. Here, in the liquid processing discharge unit (50) of the present invention, a high-voltage DC power supply (61) is used as a power supply unit. For this reason, since it is suppressed that a shock wave generate | occur | produces in a liquid with discharge, the bubble generated in the liquid can be stabilized.

An eighth invention is a water heater comprising a water supply tank (91) in which heated water is stored, and a liquid treatment discharge unit (50) for purifying the water in the water supply tank (91). It is targeted. In this hot water heater, the liquid treatment discharge unit (50) is constituted by the liquid treatment discharge unit according to any one of the first to fifth inventions.

In the eighth invention, heated water (hot water) is stored in the water supply tank (91). When the discharge is performed in the liquid treatment discharge unit (50), the water in the reservoir (41) is purified by the active species generated by the discharge. Here, in the liquid processing discharge unit (50) of the present invention, a high-voltage DC power supply (61) is used as a power supply unit. For this reason, since it is suppressed that a shock wave generate | occur | produces in a liquid with discharge, the bubble generated in the liquid can be stabilized.

  In the present invention, a DC voltage is applied from the high-voltage DC power source (61) to the electrode pair (52, 53) to discharge within the bubble. For this reason, in the case of a pulse power supply, a shock wave is generated in water and the bubble is easily broken, whereas in the present invention, such a shock wave is hardly generated, so that the bubble is stabilized. Therefore, stable discharge can be performed in the bubbles.

  Further, by using the DC power supply (61), the cost of the power supply unit can be reduced as compared with the pulse power supply. Further, by using the DC power supply (61), noise during discharge can be reduced as compared with the pulse power supply.

In the present invention, the current density of the current path is increased by the current density concentration portion (70). Thereby, the Joule heat in the current path can be increased to promote the vaporization of the liquid, and the generation of bubbles can be promoted accordingly. As a result, air bubbles can be reliably generated in the liquid, so that the discharge in the air bubbles can be further stabilized.

In the present invention, since a part of the electrode pair (52, 53) is covered by the insulating cover member (71), the diffusion of discharge in the liquid can be reliably prevented. As a result, it is possible to effectively increase the current density in the current path and promote the generation of bubbles.

In the present invention, the rod-shaped electrode (52) is fitted inside the cylindrical cover member (71). Thereby, in the vicinity of the opening of the cover member (71), it is possible to increase the current density of the current path and promote the generation of bubbles. Further, by covering the periphery of the electrode (52) with the cover member (71), the contact between the outer peripheral surface of the electrode (52) and the liquid can be suppressed. For this reason, since the leakage current from the electrode (52) into the liquid can be prevented, the power supply voltage of the DC power supply (61) can be reduced. As a result, the cost of the DC power supply (61) can be further reduced.

In the present invention, the front end surface (52a) of the electrode (52) is recessed inward from the opening surface (72a) on one end side of the cylindrical cover member (71). Thereby, an aperture space for reducing the cross-sectional area of the current path can be formed between the opening surface (72a) of the cover member (71) and the tip surface (52a) of the electrode (52). Therefore, the current density in this space can be significantly increased, and the generation of bubbles can be promoted.

In the second invention, the opening surface (72a) on one end side of the fitting groove (72) of the cover member (71) faces downward. For this reason, bubbles generated in the vicinity of the opening surface (72a) can be held below the tip of the electrode (52). As a result, the bubbles generated in the liquid can be prevented from escaping upward, so that the discharge in the bubbles can be performed more stably .

In the third invention, since the bubble holding part (75) for holding the generated bubbles is provided, it is possible to avoid the bubbles generated in the liquid from escaping upward. Therefore, the discharge in the bubbles can be performed more stably.

In the fifth invention, since the current path between the electrode pair (52, 53) is surrounded by the heat insulating member (80), the temperature rise of the liquid in the current path is further promoted to promote the generation of bubbles. Can do. As a result, the discharge in the bubbles can be performed stably.

In the sixth aspect of the invention, in the humidity control apparatus that performs at least humidification of air, discharge in the bubbles can be reliably and stably performed in water. In the seventh aspect of the invention, in the humidity control apparatus that performs at least dehumidification of air, the discharge in the bubbles can be reliably and stably performed in water. In the eighth invention, in the water heater that supplies hot water, the discharge in the bubbles can be reliably and stably performed in water.

FIG. 1 is a perspective view illustrating the overall configuration of the humidity control apparatus according to the first embodiment. FIG. 2 is a schematic configuration diagram illustrating the internal structure of the humidity control apparatus according to the first embodiment. FIG. 3 is a schematic configuration diagram of the discharge unit according to the first embodiment. FIG. 4 is an enlarged configuration diagram of the vicinity of the bubble generation region of the discharge unit according to the first embodiment. FIG. 5 is a schematic configuration diagram of the discharge unit according to the first embodiment . FIG. 6 is a schematic configuration diagram of the discharge unit of the first modification. FIG. 7 is a schematic configuration diagram of the discharge unit of the second modification. FIG. 8 is a schematic configuration diagram of the discharge unit according to the second embodiment . FIG. 9 is a schematic configuration diagram of the discharge unit of Reference Embodiment 3 . FIG. 10 is a schematic configuration diagram of the discharge unit according to the fourth embodiment . FIG. 11 is a schematic configuration diagram of a discharge unit of Modification 3 . FIG. 12 is a schematic configuration diagram of a discharge unit of Modification 4 . FIG. 13 is a schematic configuration diagram illustrating an internal structure of the humidity control apparatus according to the second embodiment. FIG. 14 is a schematic configuration diagram of a water heater according to the third embodiment.

  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.

Embodiment 1 of the Invention
The humidity control apparatus (10) according to Embodiment 1 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.

  As shown in FIGS. 1 and 2, the humidity control apparatus (10) is a resin casing (11) in which various components for humidifying and purifying air 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 the air in the casing (11) into the room at a position closer to the upper rear side. An air passage (14) through which air flows is formed in the casing (11) from the inlet (12) to the outlet (13). In addition, in the humidity control apparatus (10) shown in FIG. 1, the front surface of the said casing (11) is covered with the front panel (11a).

  As shown in FIG. 2, in the air passage (14), the air purification means (20), the humidification unit (40) (humidification mechanism), and the centrifugal fan (in order from the upstream side to the downstream side of the air flow) 15) is provided.

<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), and in order from the upstream side to the downstream side of the air flow, 21), an ionization part (22), a pleated filter (23), and a deodorizing filter (24).

  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).

  The deodorizing filter (24) is configured such that a deodorizing agent for deodorizing air is carried on the surface of a honeycomb structure base material. 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.

<Composition of humidification unit>
As shown in FIG. 2, the humidification unit (40) includes a water tank (41) as a storage unit that stores humidified water as a liquid, and a water wheel (42) for pumping up water in the water tank (41). A humidifying rotor (43) as a humidifying unit for applying water pumped up by the water wheel (42) to the air, and a drive motor (44) for rotationally driving the humidifying rotor (43) I have. The humidification unit (40) also includes a heater (48) for heating the humidification rotor (43).

  As shown in FIG. 1, the water tank (41) includes a horizontally long box member (45) whose upper side is open and a lid member (46) covering the upper side of the 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 so as to be able to be taken in and out (slidable) with respect to the outlet (11b) formed in the above. That is, the water tank (41) is detachably accommodated in the casing (11). Thereby, in the state which pulled out the 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 disk shape, and a rotation shaft (42a) is provided on the axial 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 including 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 casing rear side. 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). Moreover, the said recessed part (42b) displaces alternately between the position immersed in the water of a water tank (41), and the position pulled out from water by rotation operation of a water wheel (42). Thereby, in the water wheel (42), it is possible to pump the water that has entered the recess (42b) at the position to be immersed in water to the upper side of the liquid level.

  An intermediate gear (42d) is disposed coaxially with the water wheel (42) on the rear side surface of the water wheel (42), and a tooth portion is formed on the outer peripheral surface of the intermediate gear (42d). (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-shaped adsorbing member (43b) 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 discharge unit for liquid treatment>
As shown in FIG.2 and FIG.3, the humidity control apparatus (10) is provided with the discharge unit (50) as a liquid treatment discharge unit for purifying the water stored in the water tank (41). . The discharge unit (50) has a discharge part (51) where discharge for purifying water is performed, and a power supply unit (60) constituting a power supply circuit of the discharge part (51).

  The discharge part (51) is disposed near the bottom surface of the water tank (41) inside the water tank (41). The discharge part (51) has an electrode pair (52, 53) composed of two electrodes (52, 53). The electrode pair (52, 53) includes a discharge electrode (52) and a counter electrode (53).

  The discharge electrode (52) is provided so as to be immersed in water in the water tank (41). The discharge electrode (52) is made of metal and has a rod shape or a line shape extending toward the counter electrode (53). The discharge electrode (52) has a circular cross section perpendicular to the axis, but the cross section perpendicular to the axis may have another shape such as a triangle, a quadrangle, or an ellipse.

  The counter electrode (53) is provided so as to be immersed in water in the water tank (41). The counter electrode (53) is disposed at a predetermined distance from the discharge electrode (52) so as to face the axial end (upper end) of the discharge electrode (52). The counter electrode (53) is made of metal, and its outer shape is flat. One surface of the counter electrode (53) faces the tip of the discharge electrode (52).

  The discharge unit (50) includes a cover member (71) that covers a part of the discharge electrode (52). The cover member (71) constitutes a current density concentration portion (70) for increasing the current density of the current path between the electrode pair (52, 53). In the present embodiment, the cover member (71) is made of an insulating ceramic material.

  The cover member (71) is formed in a bottomed cylindrical shape whose upper end is open and whose lower end is closed. A fitting groove (72) extending in the axial direction extends from the upper end surface of the cover member (71) to a portion slightly above the lower end surface of the cover member (71) at the center of the cover member (71). Is formed. The fitting groove (72) has a cross section perpendicular to the axis of a circular shape. A rod-shaped discharge electrode (52) is fitted into the fitting groove (72). That is, the cover member (71) covers the outer peripheral surface and the lower end surface of the discharge electrode (52), while exposing the upper end surface (tip surface (52a)) of the discharge electrode (52) to the counter electrode (53). .

  In this embodiment, the inner wall of the fitting groove (72) of the cover member (71) and the discharge electrode (52) are substantially in contact with each other, and the contact area between the discharge electrode (52) and water is reduced. It is planned. However, a gap may be formed between the inner wall of the fitting groove (72) of the cover member (71) and the discharge electrode (52).

  In this embodiment, the front end surface (52a) of the discharge electrode (52) fitted in the fitting groove (72) is the opening surface (72a) of the opening on one end side (upper end side) of the fitting groove (72). It is recessed inward (downward). Thereby, in the fitting groove (72), a constricted space (73) is formed between the opening surface (72a) and the tip surface (52a) of the discharge electrode (52). The constricted space (73) is a space for concentrating current by constricting the current path from the discharge electrode (52) to the counter electrode (53) (reducing the cross-sectional area of the current path). As a result, when the discharge unit (50) is discharged, bubbles are generated with the throttle space (73) as a base point (see FIG. 4, details will be described later). That is, the throttle space (73) of the present embodiment constitutes a part of the bubble generation region (B) where bubbles are generated.

  The power supply unit (60) of this embodiment has a high-voltage DC power supply (61). A discharge electrode (52) is connected to the positive electrode of the DC power supply (61). On the other hand, the counter electrode (53) is connected to the negative electrode of the DC power supply (61). That is, the DC power supply (61) constitutes a power supply unit that applies a DC voltage to the electrode pair (52, 53). The voltage applied to the electrode pair (52, 53) is set to about 10 kV, for example. The discharge current of the electrode pair (52, 53) is set to be, for example, about 10 mA. Furthermore, the power supply unit (60) is provided with a control unit (not shown) for performing constant power control so that the discharge power of the electrode pair (52, 53) is constant.

-Driving action-
Next, the operation of the humidity controller (10) will be described. The humidity control apparatus (10) performs a humidifying operation for humidifying the room air while purifying the room air. In addition, the humidity control apparatus (10) performs a water purification operation for purifying water in the water tank (41) during the humidifying operation or when stopped (details will be described later).

<Humidification operation>
In the humidification operation, the centrifugal fan (15) is operated, 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), and the heater (48) is energized.

  When the centrifugal fan (15) is operated, room air (open arrows in FIGS. 1 and 2) is introduced from the suction port (12) into the air passage (14) in the casing (11). 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 the ionization section (22), corona discharge is performed between the pair of electrodes, and dust in the air is charged by the corona discharge. 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) flows through the deodorizing filter (24). In the deodorizing filter (24), components to be treated (odorous substances and harmful substances) contained in the air are removed. The air that has passed through the deodorizing filter (24) is heated by the heater (48) and then passes through the humidification rotor (43).

  In the humidification unit (40), water (humidified water) in the water tank (41) is appropriately supplied to the adsorption member (43b) of the humidification rotor (43) by rotating the water wheel (42).

  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 humidifying rotor (43) and the concave portion (42b) The humidified water held in the water gradually flows out of the recess (42b) by its own weight. Thereby, the humidified water in the recessed part (42b) is adsorbed by the adsorbing member (43b) of the humidifying rotor (43). By such an operation, humidification water is continuously supplied to the humidification rotor (43) in the humidification unit (40).

  The concave portion (42b) is configured such that when the water turbine (42) reaches the uppermost end position, the humidified water in the concave portion (42b) is almost entirely discharged.

  When air passes through the humidification rotor (43) to which the humidified water is adsorbed as described above, the moisture adsorbed on the adsorption member (43b) of the humidification rotor (43) is released into the air. Thereby, humidified water is given in the air and the 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, by stopping the supply of voltage from the power source to the ionization unit (22), it is possible to perform an operation of humidifying the room while stopping the purification of air by the ionization unit (22).

<Water purification operation>
When the humidified water is stored in the water tank (41) for a long period of time, the humidified water in the water tank (41) may be contaminated due to the growth of fungi or germs in the water. In addition, for example, if the air flowing in the air passage (14) contains a substance such as ammonia (hazardous substance or odorous substance), this substance dissolves in the water and the humidified water in the water tank (41) It can be contaminated. Accordingly, when the humidified water contaminated in this way is supplied into the room as described above, bacteria and harmful substances are added to the room, which may impair the cleanliness of the room. Therefore, in the humidity control apparatus (10), a water purification operation for purifying water in the water tank (41) is performed by the discharge unit (50).

  During the water purification operation, a predetermined DC voltage is applied from the DC power supply (61) of the power supply unit (60) to the electrode pair (52, 53) of the discharge unit (51). Thereby, in the discharge part (51), discharge is performed toward the counter electrode (53) from the discharge electrode (52). In the discharge part (51) of the present embodiment, so-called positive discharge is performed in which the discharge electrode (52) has a positive potential and the counter electrode (53) has a negative potential. When discharge is performed as described above, active species such as OH radicals are generated in water with discharge.

  In addition, when a discharge is performed between the discharge electrode (52) and the counter electrode (53), the temperature of water is remarkably increased in the current path between the pair of electrodes (52, 53) due to Joule heat accompanying the discharge. To rise. In particular, in the present embodiment, an aperture space (73) is formed on the distal end side of the discharge electrode (52) by the cover member (71), so that the cross-sectional area of the current path is reduced. For this reason, the current density is also significantly increased in the aperture space (73). Thereby, Joule heat generated in the throttle space (73) is increased, and vaporization of water in the throttle space (73) is promoted. As a result, the generation of bubbles in the vicinity of the throttle space (73) is promoted, and the bubbles can be reliably generated in the bubble generation region (B) (see FIG. 4). In this bubble generation region (B), the generation of bubbles due to the vaporization of water and the liquefaction of bubbles due to cooling by the surrounding water proceed at the same speed. For this reason, the bubbles in the bubble generation region (B) remain in the same shape.

  Furthermore, in this embodiment, a DC voltage is applied to the electrode pair (52, 53) by the high-voltage DC power source (61). For this reason, for example, compared with the case where a high voltage pulse is applied to an electrode pair, the shock wave accompanying discharge is hardly generated in water. Therefore, in the present embodiment, the bubbles are not broken due to such a shock wave, so that the bubbles can be stably generated in the bubble generation region (B).

  As described above, when bubbles are generated in the bubble generation region (B), discharge is performed in the bubbles along with the dielectric breakdown of the gas. Thereby, in the discharge part (51) of the present embodiment, active species such as OH radicals are generated not only in the liquid but also in the bubbles. As described above, the active species generated in the water tank (41) are used for cleaning the substances to be treated (hazardous substances, bacteria, etc.). That is, in the water tank (41), harmful substances are oxidatively decomposed by active species and sterilized by active species. As a result, since the water in the water tank (41) is purified, clean water can be supplied indoors in the subsequent humidification operation.

-Effect of Embodiment 1-
According to the above-described embodiment, bubbles are generated using Joule heat accompanying discharge, and discharge is also performed in the bubbles. Here, in the power supply unit (60) of the present embodiment, a high-voltage DC power supply (61) is used as a power supply unit that applies a voltage to the electrode pair (52, 53). For this reason, for example, when discharging by applying a high voltage pulse from a pulse power supply, a relatively large shock wave is generated in water, whereas in this embodiment, such a shock wave is almost generated in water. Absent. Therefore, bubbles can be stably generated in the bubble generation region (B). As a result, discharge in the bubbles can be performed reliably.

  Moreover, the noise resulting from discharge can also be reduced by using a high-voltage DC power supply (61). Further, as compared with a pulse power supply, the power supply unit can be simplified and the cost can be reduced.

  In the above embodiment, the current density of the current path is increased by covering a part of the discharge electrode (52) with the insulating cover member (71). In particular, in the cover member (71), since the throttle space (73) is formed on the distal end side of the discharge electrode (52), the sectional area of the current path can be significantly reduced by the throttle space (73). As a result, the generation of bubbles can be promoted by increasing the Joule heat in the throttle space (73).

  Moreover, in the said embodiment, the contact area of a discharge electrode (52) and water is made small by making a part of discharge electrode (52) and a cover member (71) contact. For this reason, since the leakage current flowing into the water from the discharge electrode (52) can be reduced, the power supply voltage of the DC power supply (61) can be reduced. Therefore, the DC power supply (61) can be reduced in size and cost. In addition, power consumption required for the water purification operation can be reduced.

-Modification of Embodiment 1-
About the discharge unit (50) of the said embodiment, it is good also as a structure of each following modifications.

< Reference form 1>
As shown in FIG. 5, in the discharge unit (50) of Reference Embodiment 1, the tip surface (52a) of the discharge electrode (52) and the opening surface (72a) of the fitting groove (72) of the cover member (71) Are located on the same plane. That is, in Modification 1, the depth of the fitting groove (72) and the length of the discharge electrode (52) are substantially equal. Further, the inner wall of the fitting groove (72) of the cover member (71) and the discharge electrode (52) are substantially in contact with each other.

In the reference form 1, the current density is increased in the vicinity of the tip surface (52a) of the discharge electrode (52). For this reason, in the vicinity of the front end surface (52a) of the discharge electrode (52), water is vaporized due to an increase in Joule heat, and a bubble generation region (B) is formed. Therefore, discharge can be performed in the bubbles in the bubble generation region (B). At this time, in the discharge unit (50), since a direct current voltage is applied to the electrode pair (52, 53), bubbles can be stably formed.

<Modification 1 >
As shown in FIG. 6, in the discharge unit (50) of Modification 1 , the discharge electrode (52) extends in the horizontal direction. On the other hand, the counter electrode (53) is held in water in a vertical posture so as to face the tip of the discharge electrode (52). Further, in the cover member (71), a fitting groove (72) extending in the horizontal direction is formed, and an opening on one end side (right side in FIG. 6) faces the counter electrode (53). As in the first embodiment, the fitting groove (72) has a discharge electrode (52a) that is recessed from the opening surface (72a) of the cover member (71). 52) is provided. Thereby, an aperture space (73) is formed between the opening surface (72a) of the fitting groove (72) and the tip surface (52a) of the discharge electrode (52).

In Modification Example 1, the diaphragm space (73), the current density is high. For this reason, in the vicinity of the front end surface (52a) of the discharge electrode (52), water is vaporized due to an increase in Joule heat, and a bubble generation region (B) is formed. Therefore, discharge can be performed in the bubbles in the bubble generation region (B). At this time, in the discharge unit (50), since a direct current voltage is applied to the electrode pair (52, 53), bubbles can be stably formed.

<Modification 2 >
As shown in FIG. 7, in the discharge unit (50) of the second modification, relative positions of the discharge electrode (52) and the cover member (71) and the counter electrode (53) with respect to the first embodiment. The relationship is flipped up and down.

In the second modification, the bubble generation region (B) is formed in the narrowed space (73) below the front end surface (52a) of the discharge electrode (52). Here, in the modified example 2 , since the fitting groove (72) and the discharge electrode (52) are formed on the upper side of the bubble generation region (B), the generated bubbles are surely placed inside the fitting groove (72). Can be held. Accordingly, it is possible to further stabilize the bubbles generated in the water.

< Reference form 2 >
As shown in FIG. 8, in the discharge unit (50) of Reference Embodiment 2 , the cover member (71) is constituted by two members (71a, 71b). Specifically, the cover member (71) has a box part (71a) whose upper part is opened, and a lid part (71b) which closes the open part above the box part (71a). The box part (71a) and the lid part (71b) are each made of an insulating material such as ceramics.

In Reference Form 2 , a plate-like discharge electrode (52) is laid on the bottom of the box (71a). In addition, a through hole (74) is formed in the lid (71b) so as to allow discharge from the discharge electrode (52) to the counter electrode (53). In other words, the cover (71b) of the cover member (71) is disposed so as to partition the electrode pair (52, 53) and has a through hole (for forming a current path of the electrode pair (52, 53)). 74) is formed as an insulating shielding member. And the cover part (71b) of the cover member (71) forms a current density concentration part (70) for increasing the current density of the current path between the electrode pair (52, 53).

In Reference Mode 2 , the cross-sectional area of the current path is reduced in the through hole (74) of the lid (71b), and the current density is increased. For this reason, in the vicinity of the through hole (74), Joule heat increases and a bubble generation region (B) is formed. As a result, also in this reference embodiment 2 , the generation of bubbles can be promoted, and the discharge within the bubbles can be performed stably.

< Reference form 3 >
As shown in FIG. 9, in the discharge unit (50) of the reference form 3 , as in the reference form 2 , the cover member (71) has a box part (71a) and a lid part (71b). The box portion (71a) of the modified example 5 is configured to be flatter than that of the modified example 4, while the lid portion (71b) of the modified example 5 is thicker in the vertical direction than the reference form 2 . The discharge electrode (52) is accommodated inside the box part (71a) so as to contact the bottom surface of the box part (71a) and the lower surface of the lid part (71b).

The lid portion (71b) of the reference form 3 is formed with a tapered through hole (74). That is, the through hole (74) of the reference form 3 has a trapezoidal conical shape in which the cross-sectional area perpendicular to the axis gradually decreases from the lower side near the discharge electrode (52) toward the upper side near the counter electrode (53). Is formed. Thereby, inside the through hole (74), the cross-sectional area of the current path gradually decreases as it goes upward.

In Reference Mode 3 , since the current density increases particularly in the vicinity of the upper end portion of the through hole (74), the bubble generation region (B) is formed in the vicinity of this portion. As a result, also in this reference form 3 , the generation of bubbles can be promoted, and discharge within the bubbles can be performed stably.

< Reference form 4 >
As shown in FIG. 10, in the discharge unit (50) of Reference Embodiment 4 , the plate-like discharge electrode (52) and the plate-like counter electrode (53) are disposed so as to face each other in the horizontal direction. . A shielding plate (77) as a shielding member is provided between these electrode pairs (52, 53). The shielding plate (77) is made of an insulating material such as ceramics. The shielding plate (77) has a through-hole (74) extending in the horizontal direction at a portion interposed between the discharge electrode (52) and the counter electrode (53). The through hole (74) constitutes a part of a current path between the electrode pair (52, 53). And the shielding board (77) comprises the current density concentration part (70) for raising the current density of the current pathway between electrode pairs (52,53).

In Reference Mode 4 , since the current density increases inside the through hole (74), a bubble generation region (B) is formed in the vicinity of the inside of the through hole (74). In the example shown in FIG. 10, bubble generation regions (B) are formed in the vicinity of the openings at both ends in the axial direction of the through hole (74). As a result, in this reference embodiment 4 , the generation of bubbles can be promoted, and discharge within the bubbles can be performed stably.

<Modification 3 >
As shown in FIG. 11, in the discharge unit (50) of the third modification, a bubble holding plate (75) as a bubble holding unit is further added to the first embodiment. The bubble holding plate (75) is provided above the fitting groove (72) of the cover member (71) of the first embodiment (that is, above the bubble generation region (B)). The bubble holding plate (75) is made of an insulating material such as ceramics or insulating resin. Further, the bubble holding plate (75) is preferably plate-shaped so as to cover the bubbles from the upper side, for example, a disk shape, a quadrangular shape, a bowl shape opening to the lower side, a semi-resting shape opening to the lower side, etc. It has become.

In the modification 3 , the bubble generated in the bubble generation region (B) can be held below the bubble holding plate (75). For this reason, since it is possible to avoid the bubbles generated in the bubble generation region (B) from escaping upward from the liquid, the bubbles in the liquid can be stabilized. As a result, the discharge in the bubbles can be performed stably.

<Modification 4 >
As shown in FIG. 12, in the discharge unit (50) of Modification 4 , a heat insulating member (80) is further added to the first embodiment. The heat insulating member (80) is formed in a hollow rectangular box shape, and accommodates the discharge electrode (52), the counter electrode (53), and the cover member (71) therein.

  The heat insulating member (80) is made of an insulating ceramic material, and has a plurality of opening holes (81, 81) on the side. By the opening holes (81, 81), inflow of water from the outside to the inside of the heat insulating member (80) and outflow of water from the inside of the heat insulating member (80) are allowed. The cover member (71) is installed at the bottom of the heat insulating member (80). Further, the counter electrode (53) is disposed on the upper side of the heat insulating member (80) so as to face the discharge electrode (52) fitted in the fitting groove (72) of the cover member (71). As described above, the heat insulating member (80) is disposed so as to surround the current path of the electrode pair (52, 53).

In the modified example 4 , by surrounding the current path with the heat insulating member (80), the temperature of the water in the current path is hardly lowered due to the influence of the outside air. That is, in the modification 4 , since the temperature rise of the water accompanying a discharge is accelerated | stimulated, vaporization of the water in an electric current path | route is also accelerated | stimulated. As a result, in the fourth modification, bubbles can be generated more reliably, and discharge within the bubbles can be performed stably.

  Needless to say, the discharge unit (50) according to the combination of the first embodiment described above and each modification may be employed.

<< Embodiment 2 of the Invention >>
The humidity control apparatus (10) according to the second embodiment is the same as the humidity control apparatus according to the first embodiment, except that an air dehumidifying function is provided. That is, the humidity control apparatus (10) of the second embodiment shown in FIG. 13 is provided with a dehumidification unit (30) in addition to the air purification means (20) and the humidification unit (40) of the first embodiment. .

  The dehumidifying unit (30) is provided on the upstream side of the humidifying unit (40) in the air passage (14). The dehumidifying unit (30) includes a dehumidifying rotor (31), a rotor case (32), a circulation fan (33), and a dehumidifying heater (34).

  The dehumidifying rotor (31) constitutes a dehumidifying unit that captures moisture in the air and dehumidifies the air. The dehumidifying rotor (31) of Embodiment 2 is a so-called rotary adsorption rotor. In other words, the dehumidification rotor (31) is configured such that an adsorbent (zeolite or the like) is supported on the surface of a honeycomb structure base material through which air can flow. The dehumidifying rotor (31) is rotatable together with a rotating shaft driven by a driving mechanism such as a motor.

  The rotor case (32) has a circular opening (not shown) near the top. The rotor case (32) holds the dehumidification rotor (31) rotatably inside the circular opening. Thereby, the air flowing through the air passage (14) passes through the dehumidification rotor (31) through the circular opening. The rotor case (32) is formed with a circulation passage (35) through which air for regenerating the adsorbent of the dehumidifying rotor (31) flows. The circulation passage (35) is formed around the dehumidification rotor (31), and a circulation fan (33) and a dehumidification heater (34) are provided so as to straddle the circulation passage (35). That is, the air conveyed in the circulation passage (35) by the circulation fan (33) is heated by the dehumidification heater (34) and then passes through the regeneration unit of the dehumidification rotor (31). Thereby, the water | moisture content of the adsorption agent of a dehumidification rotor (31) desorbs, and this adsorption agent is reproduced | regenerated. The air deprived of moisture from the adsorbent of the dehumidifying rotor (31) flows under the rotor case (32). At this time, the air flowing through the circulation passage (35) is cooled by the air flowing through the air passage (14). Thereby, the water vapor contained in the air in the circulation passage (35) is condensed to generate condensed water. This condensed water is sent to the water tank (41) through a condensed water passage (not shown).

  As described above, in the humidity control apparatus (10) of the second embodiment, the water captured by the dehumidification rotor (31) is collected in the water tank (41). That is, the humidity control apparatus (10) of Embodiment 2 is configured so that water collected by the dehumidification rotor (31) can be used as humidified water. The air after the condensed water is generated in the circulation passage (35) is heated again by the dehumidifying heater (34) and used for regeneration of the adsorbent of the dehumidifying rotor (31).

  Also in the humidity control apparatus (10) of the second embodiment, a discharge unit (50) similar to that of the first embodiment is provided (see FIG. 3). That is, the discharge unit (50) of the second embodiment includes the same discharge unit (51) and power supply unit (60) as those of the first embodiment. The power supply unit (60) is provided with a DC power supply (61) for applying a DC voltage to the electrode pair (52, 53) to discharge in the bubbles.

-Driving action-
The humidity control apparatus (10) of Embodiment 2 is configured to be able to perform a dehumidifying operation while purifying air and a humidifying operation while purifying air. The humidifying operation of the humidity control apparatus (10) of the second embodiment is substantially the same as that of the first embodiment. Therefore, hereinafter, the dehumidifying operation of the humidity control apparatus (10) of the second embodiment will be described.

<Dehumidifying operation>
In the dehumidifying operation, the dehumidifying rotor (31) rotates and the dehumidifying 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. Further, when the centrifugal fan (15) is operated, indoor air is introduced into the air passage (14) through the suction port (12). At the same time, regeneration air circulates in the circulation passage (35) by operating the circulation fan (33). A voltage is applied to the electrode of the ionization section (22).

  When the centrifugal fan (15) is operated, room air is introduced from the suction port (12) into the air passage (14) in the casing (11). 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 the ionization section (22), corona discharge is performed between the pair of electrodes, and dust in the air is charged by the corona discharge. 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) flows through the deodorizing filter (24). In the deodorizing filter (24), components to be treated (odorous substances and harmful substances) contained in the air are removed. The air that has passed through the deodorizing filter (24) passes through the dehumidification rotor (31) through the circular opening of the rotor case (32).

  The part of the dehumidification rotor (31) through which the air passage (14) flows is in a state regenerated by the regeneration air flowing through the circulation passage (35). For this reason, the moisture contained in the air flowing through the air passage (14) is adsorbed by the adsorbent of the dehumidifying rotor (31). As a result, the air passing through the dehumidification rotor (31) is dehumidified. The air purified and dehumidified as described above is supplied into the room through the air outlet (13).

<Water purification operation>
In the dehumidifying operation as described above, the water imparted to the air circulating through the circulation passage (35) is collected in the water tank (41). And the water collect | recovered by this water tank (41) is utilized also as subsequent humidification water. For this reason, also in the second embodiment, the same water purification operation as in the first embodiment is performed in order to purify the water in the water tank (41).

  That is, as shown in FIGS. 3 and 4, in the water purification operation, a voltage is applied from the DC power source (61) to the electrode pair (52, 53), so that the discharge electrode (52) and the counter electrode (53) are applied. Discharge occurs between At this time, since the current density is high in the throttle space (73) of the cover member (71), a bubble generation region (B) is formed in the vicinity of the throttle space (73). For this reason, it is possible to generate active species for purifying water by reliably performing discharge in the bubbles generated in the bubble generation region (B). At this time, since a DC voltage is applied to the electrode pair (52, 53), a shock wave is hardly generated in the liquid. Accordingly, the bubbles in the liquid are prevented from being broken, and the discharge can be stably performed in the bubbles.

  In addition, of course, about the humidity control apparatus (10) of Embodiment 2, you may employ | adopt the discharge unit (50) which concerns on each modification mentioned above and those combination.

<< Embodiment 3 of the Invention >>
In Embodiment 3, the discharge unit (50) according to Embodiment 1 described above is applied to a water heater (90). The water heater (90) is for supplying hot water to a water supply or a bath. As shown in FIG. 14, the water heater (90) includes a water supply tank (91) in which water (hot water) is stored, and a sub tank (92) for purifying water. An inflow water channel (93), an outflow water channel (94), and a circulation water channel (95) are connected to the water supply tank (91).

  The outflow end of the inflow water channel (93) is connected to the top of the water supply tank (91). A heating means (not shown) is provided on the inflow side of the inflow water channel (93). That is, the inflow water channel (93) is a channel for supplying water (hot water) heated by the heating means to the water supply tank (91). In the present embodiment, a radiator of a heat pump device that performs a refrigeration cycle using carbon dioxide as a refrigerant is used as the heating means.

  The outflow water channel (94) is connected to the bottom of the water supply tank (91). The outflow water channel (94) is a flow channel for supplying hot water stored in the water supply tank (91) to a predetermined supply source (bath, faucet, etc.).

  The circulating water channel (95) has an inflow end connected to a lower portion of the water supply tank (91) and an outflow end connected to an intermediate portion of the water supply tank (91). A circulation pump (96) and a sub tank (92) are connected to the circulation water channel (95). The circulation pump (96) is for sending the water in the water supply tank (91) to the sub tank (92) and sending the water in the sub tank (92) to the water supply tank (91) again. The sub tank (92) is configured to temporarily store water circulating in the circulation channel (95) and to purify the stored water.

  The water heater (90) of Embodiment 3 has the same liquid treatment discharge unit (50) as in Embodiments 1 and 2. The sub tank (92) is provided with a discharge part (51) similar to those of the first and second embodiments (see, for example, FIG. 3). Further, the water heater (90) is provided with a DC power source (61) for applying a high-voltage DC voltage to the electrode pair (52, 53) of the discharge section (51).

  In the third embodiment, when a high DC voltage is applied from the DC power source (61) to the electrode pair (52, 53), bubbles are generated in the liquid and discharge is also performed in the bubbles. As a result, active species are generated in the bubbles and in the liquid, and the water in the sub tank (92) is purified by the active species. At this time, since a high DC voltage is applied to the electrode pair (52, 53), a shock wave is hardly generated in the liquid. For this reason, it is suppressed that the bubble which generate | occur | produced in water breaks, and it can discharge stably within a bubble. The water purified in the above manner in the sub tank (92) is sent to the water supply tank (91). As a result, in the water heater (90) of this embodiment, the cleanliness of the water in the water supply tank (91) is maintained.

  In addition, of course, about the water heater (90) of Embodiment 3, you may employ | adopt the discharge unit (50) which concerns on each modification mentioned above and those combination.

<< Other Embodiments >>
About the said embodiment (each modification is also included), it is good also as following structures.

  The cover member (71) according to the above embodiment may not necessarily be in contact with the discharge electrode (52) as long as it covers a part of the discharge electrode (52). Also in this case, the current density in the current path can be increased by covering a part of the discharge electrode (52).

  Further, the cover member (71) according to the above embodiment covers a part of the discharge electrode (52) corresponding to the discharge electrode (52). However, the cover member (71) may be provided so as to correspond to the counter electrode (53) and cover a part of the counter electrode (53). That is, covering the vicinity of the counter electrode (53) with the cover member (71) can also increase the current density of the current path and promote the generation of bubbles. Further, both the discharge electrode (52) and the counter electrode (53) may be covered with a cover member (71).

  The cover member (71) according to the above embodiment covers the discharge electrode (52) so that a part of the discharge electrode (52) faces the counter electrode (53). However, as long as a current path between the discharge electrode (52) and the counter electrode (53) can be secured, a part of the discharge electrode (52) does not necessarily have to face the counter electrode (53).

  In the discharge unit (50) according to the above embodiment, the discharge electrode (52) is set to a positive potential and the counter electrode (53) is set to a negative potential, so that the discharge electrode (52) is directed to the counter electrode (53). Positive discharge is performed. However, negative discharge may be performed from the discharge electrode (52) toward the counter electrode (53) by setting the discharge electrode (52) to a negative potential and the counter electrode (53) to a positive potential.

  Further, in the discharge unit (50) according to the above embodiment, only one discharge electrode (52) is provided, but a plurality of discharge electrodes (52) may be provided in the discharge unit (50). Further, although the outer shape of the counter electrode (53) is formed in a substantially plate shape, for example, the counter electrode (53) may be linear or rod-shaped, and the counter electrode (53) may be dot-shaped. Similarly, the discharge electrode (52) may be formed in a dot shape or a plate shape.

  As described above, the present invention is useful for a liquid treatment discharge unit that discharges in liquid and purifies the liquid, and a humidity control apparatus and a water heater provided with the liquid treatment discharge unit.

10 Humidity control device
31 Dehumidification rotor (dehumidification part)
41 Water tank (reservoir)
43 Humidification rotor (humidification section)
50 Discharge unit (Discharge unit for liquid treatment)
52 Discharge electrodes (electrode pairs)
53 Counter electrode (electrode pair)
61 Electrode (DC power supply)
70 Current density concentration part
71 Cover member (current density concentration part)
71a Lid (shielding member)
72 Mating groove
72a Open face
74 Through hole
75 Bubble holding plate (bubble holding part)
77 Shield plate (shield member)
80 Thermal insulation
90 Water heater
91 Water supply tank
B Bubble generation area

Claims (8)

An electrode pair (52, 53) provided in the liquid, and a power supply unit (61) for applying a voltage to the electrode pair (52, 53) so that a discharge is performed between the electrode pair (52, 53). A liquid treatment discharge unit between the electrode pair (52, 53), in which liquid is vaporized by Joule heat accompanying discharge to generate bubbles, and discharge is also performed in the bubbles,
The power supply unit is composed of a high-voltage DC power supply (61),
A constant power control unit for controlling the discharge power of the electrode pair (52, 53) to be constant ;
A current density concentrating part (70) for increasing the current density of the current path between the electrode pair (52, 53);
The current density concentration part (70) is an insulating cover member (71) that covers a part of at least one electrode (52) of the electrode pair (52, 53),
The cover member (71) is formed in a cylindrical shape having at least one end opened in the axial direction,
The electrode (52) covered with the cylindrical cover member (71) is formed in a rod shape that fits inside the cylindrical cover member (71),
The rod-shaped electrode (52) is disposed so that a tip thereof is recessed inwardly from an opening surface (72a) on one end side of the cylindrical cover member (71) . Discharge unit. In claim 1 ,
The liquid treatment discharge unit, wherein the cover member (71) is disposed such that an opening on one end side thereof faces downward. In claim 1 ,
A liquid processing discharge unit comprising a bubble holding part (75) for holding bubbles generated with discharge. An electrode pair (52, 53) provided in the liquid, and a power supply unit (61) for applying a voltage to the electrode pair (52, 53) so that a discharge is performed between the electrode pair (52, 53). A liquid treatment discharge unit between the electrode pair (52, 53), in which liquid is vaporized by Joule heat accompanying discharge to generate bubbles, and discharge is also performed in the bubbles,
The power supply unit is composed of a high-voltage DC power supply (61),
A current density concentrating part (70) for increasing the current density of the current path between the electrode pair (52, 53);
The current density concentration portion (70) is constituted by a cylindrical insulating cover member (71) that is open at least at one end in the axial direction.
One of the electrode pair (52, 53) is composed of a rod-shaped electrode (52) that fits inside the cylindrical cover member (71),
The rod-like electrode (52) is disposed so that the tip is recessed inwardly from the opening surface (72a) of the opening (72) on one end side of the cylindrical cover member (71),
The liquid processing discharge unit, wherein the opening (71b) of the cover member (71) faces in the horizontal direction or upward. In claim 4,
A liquid processing discharge unit comprising a heat insulating member (80) disposed so as to surround a current path between the electrode pair (52, 53). A storage unit (41) for storing water, a humidifying unit (43) for applying water in the storage unit (41) to the air, and a liquid processing discharge unit for purifying the water in the storage unit (41) (50) a humidity control device comprising:
The liquid treatment discharge unit (50), humidity control, characterized in that it is constituted by any one of the liquid treatment discharge unit of claims 1 to 5 device. A dehumidifying part (31) that captures moisture in the air and dehumidifies the air, a storage part (41) that collects water captured by the dehumidifying part (31), and purifies the water in the storing part (41) A humidity control apparatus comprising a liquid treatment discharge unit (50) for
The liquid treatment discharge unit (50), humidity control, characterized in that it is constituted by any one of the liquid treatment discharge unit of claims 1 to 5 device. A water heater provided with a water supply tank (91) for storing heated water, and a liquid treatment discharge unit (50) for purifying water in the water supply tank (91),
The hot water heater according to any one of claims 1 to 5 , wherein the liquid processing discharge unit (50) is constituted by any one of the liquid processing discharge units.

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