JP5834912B2 - Underwater discharge device - Google Patents

Description

  The present invention relates to an underwater discharge device that discharges in water.

  2. Description of the Related Art Conventionally, underwater discharge devices that perform discharge in water are known and applied to various applications. For example, Patent Document 1 discloses this type of underwater discharge device. The underwater discharge device includes an electrode pair immersed in water and a pulse power source that applies a pulse high voltage to the electrode pair. When a pulse voltage is applied to the electrode pair from the pulse power source, underwater discharge is performed between the electrode pair. This discharge generates active species mainly composed of hydrogen peroxide in water. This active species decomposes and removes organic substances contained in the water.

  Such an underwater discharge device is used for purifying condensed water (drain water) collected in a drain pan, for example, in an air conditioner. Drain water contains various germs and odor components, and the drain water is purified by an underwater discharge device and then discharged to the outside.

JP 2010-58036 A

  By the way, in the said underwater discharge apparatus which produces | generates hydrogen peroxide by discharge, there exists a limit in the purification | cleaning capability of drain water. Therefore, the conventional underwater discharge device has a problem that drain water containing a relatively large amount of various germs and odor components cannot be sufficiently purified.

  This invention is made | formed in view of such a point, The objective is to provide the underwater discharge apparatus which can generate a reactive mass in large quantities.

  The first invention is an underwater discharge device, a container (19) for storing water, a power source (70, 70a, 70b, 70c, 70d), and the power source (70, 70a, 70b, 70c, 70d) To the electrode pair (64, 64a, 64b, 65, 65a, 65b, 170, 178) that generates a hydroxyl radical in the water in the container (19) An ultrasonic generator (94) that converts hydrogen peroxide in a liquid generated by changing generated hydroxyl radicals by irradiating water with ultrasonic waves into hydroxyl radicals. And the positive electrode of an electrode pair (21,22,64,64a, 64b, 65,65a, 65b, 170,178) is comprised with the metal containing copper or iron.

  In the underwater discharge device of the invention, discharge is performed by applying a voltage to the electrode pairs (64, 65, 64, 64a, 64b, 65, 65a, 65b, 170, 178). When discharge is performed, hydrogen peroxide which is an active species is generated in water. Moreover, in order to generate discharge in water, a high voltage is applied to the electrode pair (64, 65). Therefore, electrolysis occurs around each electrode (21, 22), oxygen gas is generated, and hydrogen ions are generated in the water.

  In the present invention, at least one of the electrode pair (64, 65) is made of a metal containing copper or iron. Therefore, by electrolysis, copper atoms or iron atoms in the electrode are eluted into water, and copper ions or iron ions are generated. When copper ions or iron ions are generated under conditions where hydrogen peroxide and hydrogen ions are present in water, the so-called Fenton reaction takes place, and copper ions and iron ions act catalytically, resulting in highly reactive activity. Hydroxyl radicals that are seeds are generated.

  Furthermore, hydrogen peroxide generated by discharge is decomposed by ultrasonic waves to generate hydroxyl radicals, whereby a large amount of highly reactive active species can be generated.

  According to a second invention, in the first invention, a first control unit (2) for controlling on / off of a voltage applied to the electrode pair (64, 64a, 64b, 65, 65a, 65b), and generation of ultrasonic waves A second control unit (5) for controlling the operation of the unit (94), wherein the first control unit (2) and the second control unit (5) are peroxidized in the liquid in the container (19). Control the on / off of the voltage applied to the electrode pair (64, 64a, 64b, 65, 65a, 65b) and the operation of the ultrasonic generator (94) so that the hydrogen concentration does not exceed the specified upper limit. It is characterized by doing.

  In the second invention, the concentration of hydrogen peroxide in the liquid supplied from the purification apparatus to the outside is suppressed to the upper limit value or less, so that the treatment for removing the hydrogen peroxide becomes easy.

  A third invention further includes a sensor (7) for monitoring the concentration of hydrogen peroxide contained in the liquid in the container (19) in the second invention, and the first control unit (2) includes the sensor (7 ) To control the on / off of the voltage applied to the electrode pair (64, 64a, 64b, 65, 65a, 65b) according to the monitoring result, and the second control unit (5) monitors the result of the sensor (7). The operation of the ultrasonic wave generation unit (94) is controlled according to the above.

  According to a fourth invention, in the third invention, when at least the concentration of hydrogen peroxide in the liquid exceeds the upper limit value, the first control unit (2) controls the electrode pair (64, 64a, 64b, 65). , 65a, 65b) to turn off the voltage applied to stop the discharge, and the second control unit (5) operates the ultrasonic wave generation unit (94).

  According to a fifth invention, in any one of the second to fourth inventions, the second control unit (5) is configured such that the concentration of hydrogen peroxide contained in the liquid in the container (19) is lower than the upper limit value. The ultrasonic wave generation unit (94) is turned on during a period exceeding the lower limit value.

  In the fifth invention, since the ultrasonic generator (94) is turned on when the concentration of hydrogen peroxide in the liquid is equal to or higher than the lower limit value, the hydrogen peroxide is efficiently and continuously removed from the hydrogen peroxide in the liquid. Can generate radicals.

  According to a sixth aspect of the present invention, in the first aspect, on / off control of the voltage applied to the electrode pair (64, 64a, 64b, 65, 65a, 65b) and control of the operation of the ultrasonic generator (94) And a control unit that performs the control so that the concentration of hydrogen peroxide contained in the liquid in the container (19) does not exceed a predetermined upper limit value (64, 64a, 64b, 65, 65a, 65b) is controlled to turn on or off the voltage to be applied, and to control the operation of the ultrasonic wave generator (94).

  In a sixth aspect based on the sixth aspect, the control unit, when the concentration of hydrogen peroxide contained in the liquid in the container (19) exceeds a predetermined upper limit value, sets the electrode pair (64, 64a, 64b, 65, 65a, 65b) is turned off to stop the discharge, and during the period when the concentration of hydrogen peroxide contained in the liquid exceeds a predetermined lower limit lower than the upper limit, the ultrasonic generator (94 ) Is turned on.

  According to an eighth invention, in any one of the first to seventh inventions, a discharge means (119) for discharging bubbles into the liquid in the container (19) and a sending means for sending gas to the discharge means (119) (99) and the electrode pair (64, 65) is plate-shaped and arranged to face each other, and the power source (70b) applies a pulse voltage to the electrode pair (64a, 65a). The discharge means (119) is disposed between the electrode pair (64, 65) and at the bottom of the container (19).

  According to a ninth invention, in any one of the first to eighth inventions, the power source (70, 70a, 70b, 70c, 70d) is a DC power source, and the electrode pair (21, 22, 64, 64a, 64b). , 65, 65a, 65b, 170, 178) is composed of a metal containing copper or iron, and the negative electrode is the positive electrode of the electrode pair (21, 22, 64, 64a, 64b, 65, 65a, 65b, 170, 178) It is comprised by the metal with a lower ionization tendency than copper or iron contained in.

  In the present invention, the positive electrode of the electrode pair (64, 65) is composed of a metal containing copper or iron, and the negative electrode is composed of a metal having a lower ionization tendency than copper or iron. The reaction in which iron ions take electrons from the metal atoms constituting the negative electrode to become copper atoms or iron atoms is less likely to occur.

  The tenth invention includes a cooling part (17) for cooling air, a drain pan (19) for recovering condensed water condensed in the air by the cooling part (17) cooling the air, and a drain pan (19) And an underwater discharge device that discharges in the water so that hydrogen peroxide is generated in the water, wherein the underwater discharge device is any one of the first to ninth inventions. It consists of an underwater discharge device, and the drain pan (19) is a container (19).

  In the present invention, the air conditioner is provided with an underwater discharge device. In this underwater discharge device, discharge is performed in water (drain water) collected in a drain pan (19), and hydrogen peroxide as an active species is generated in the drain water. Further, in the drain water, electrolysis occurs with discharge, and hydrogen ions and copper ions or iron ions are generated. When copper ions or iron ions are generated under conditions where hydrogen peroxide and hydrogen ions are present in water, the Fenton reaction takes place, and the copper ions and iron ions act catalytically, resulting in highly reactive active species. Hydroxyl radicals are generated. Highly reactive active species can be generated in large quantities by decomposing hydrogen peroxide with ultrasound to generate hydroxyl radicals. The generated hydroxyl radicals act on various germs and odor components contained in the drain water, and the various germs and odor components are decomposed and removed.

  According to the present invention, hydrogen peroxide is generated by discharging in water, and at least one of the electrodes of the electrode pair (64, 65) for discharging is formed of a metal containing copper or iron. I made it. Furthermore, an ultrasonic wave generator for irradiating ultrasonic waves in water was provided. Thereby, in water, in addition to hydrogen peroxide, highly reactive hydroxyl radicals can be generated in large quantities. With these active species, for example, water can be purified with a high purification capacity.

  In addition, hydroxyl radicals have a very short life and react immediately to change into hydrogen peroxide. Therefore, in the conventional underwater discharge device, even if hydroxyl radicals are generated in the water by discharge, most of the hydroxyl radicals are changed to hydrogen peroxide before acting on various germs. However, in the underwater discharge device of the present invention, even if the hydroxyl radical changes to hydrogen peroxide, the hydrogen peroxide can be changed again to the hydroxyl radical by the Fenton reaction. Moreover, hydrogen peroxide can be changed again into hydroxyl radicals by ultrasonic irradiation. Thus, in the present invention, hydroxyl radicals can be regenerated and high purification ability can be maintained without reducing the hydroxyl radical concentration in water.

  According to the second invention, since the concentration of hydrogen peroxide in the liquid supplied to the outside from the underwater discharge device is suppressed to the upper limit value or less, the treatment for removing hydrogen peroxide is facilitated.

  According to the third invention, the first control unit (2) and the second control unit (5) control the discharge and the ultrasonic irradiation according to the hydrogen peroxide concentration of the liquid in the container (19). Since each is performed, the purification treatment can be performed while controlling the concentration of hydrogen peroxide in the liquid to be within a desired range.

  According to the fourth invention, when the concentration of hydrogen peroxide in the liquid exceeds the upper limit value, the discharge is stopped and the generation of hydrogen peroxide is stopped. It is possible to facilitate the removal of hydrogen peroxide from the treated liquid.

  According to the fifth aspect of the invention, since the concentration of hydrogen peroxide in the liquid can be controlled to the lower limit value or more, it is possible to efficiently generate hydroxyl radicals when irradiated with ultrasonic waves.

  According to the sixth aspect of the invention, since the control unit controls the concentration of hydrogen peroxide in the liquid so as not to exceed the upper limit value, the processing for removing the hydrogen peroxide can be facilitated.

  According to the seventh aspect, since the concentration of hydrogen peroxide in the liquid can be controlled to the lower limit value or more, it is possible to efficiently generate hydroxyl radicals when irradiated with ultrasonic waves.

  According to the eighth aspect of the invention, since it is possible to generate a discharge even when a pulse voltage is applied to the electrode pair (64a, 65a), hydroxyl radicals are efficiently generated in water, and ultrasonic irradiation is performed. By combining with the Fenton effect, the concentration of hydroxyl radicals can be more efficiently maintained.

  According to the ninth aspect, the positive electrode of the electrode pair (64, 65) is made of a metal containing copper or iron, and the negative electrode is made of copper or iron contained in the positive electrode of the electrode pair (64, 65). Also, it was made of a metal having a low ionization tendency. Thereby, it can suppress that the copper ion or iron ion in water reacts and precipitates as a copper atom or an iron atom. Thus, if the precipitation reaction of copper or iron is suppressed, the concentration of copper ions or iron ions in water is not reduced, and the production efficiency of hydroxyl radicals by the Fenton effect can be maintained.

  In the present invention, since the DC power supply (70) is used for discharging, for example, the power supply unit can be simplified, reduced in cost, and reduced in size as compared with the pulse power supply. Moreover, when a pulse power supply is used, the shock wave and noise which generate | occur | produce in water with discharge will become large. On the other hand, when a DC power source (70) is used, such shock waves and noise can be reduced.

  According to the tenth invention, the discharge is performed in the drain water collected by the drain pan (19) of the air conditioner. Thereby, in drain water, in addition to hydrogen peroxide, a highly reactive hydroxyl radical can be produced | generated in large quantities, and the disinfection performance of drain water and the removal performance of an odor component can be improved.

  In addition, if the drain water is left without being sterilized for a long time, muddy matter (so-called slime) is generated due to germs and the like grown in the drain pan (19). However, in the tenth invention, the growth of bacteria can be reliably prevented by the highly reactive hydroxyl radical, and the generation of slime can be avoided in advance. Even when slime is generated, the slime can be decomposed and removed by highly reactive hydroxyl radicals. Therefore, when drain water is discharged, it is possible to prevent the slime from being caught in the drain path of the drain pan.

1 is a schematic configuration diagram of an indoor unit of an air-conditioning apparatus according to Embodiment 1. FIG. FIG. 2 is a schematic configuration diagram of the underwater discharge device according to the first embodiment, and shows a state before starting the discharge operation. FIG. 3 is a perspective view of the insulating casing according to the first embodiment. FIG. 4 is a schematic configuration diagram of the underwater discharge device according to the first embodiment, and shows a state in which bubbles are generated by starting the discharge operation. FIGS. 5A and 5B are enlarged cross-sectional views showing specific examples of the ultrasonic wave generator. FIG. 6 is a diagram illustrating a basic cycle of liquid treatment by the purification device according to the first embodiment. FIG. 7A is a time chart showing an example of operation control in the case of performing feedback control using the concentration of hydrogen peroxide in the liquid, and FIG. 7B is a measurement of the change in concentration of hydrogen peroxide. It is a time chart which shows an example of the operation control in the case of performing feedforward control using a value. FIG. 8 is a schematic configuration diagram of an underwater discharge device according to a modification of the first embodiment. FIG. 9 is a perspective view of an insulating casing according to a modification of the first embodiment. FIG. 10 is a schematic configuration diagram of the underwater discharge device according to the second embodiment, and shows a state before starting the discharge operation. FIG. 11 is a schematic configuration diagram of the underwater discharge device according to the second embodiment, and shows a state in which bubbles are generated by starting the discharge operation. FIG. 12 is a plan view of the lid portion of the insulating casing according to the modification of the second embodiment. FIG. 13 is a configuration diagram illustrating a purification device according to Embodiment 3 of the present invention. FIG. 14 is a configuration diagram illustrating a purification device according to Embodiment 4 of the present invention. FIG. 15 is a configuration diagram illustrating a purification device according to Embodiment 5 of the present invention.

  In various studies for solving the above-mentioned problems, the inventors of the present application have found that the concentration of hydrogen peroxide in the liquid is increased by discharge in water, and the concentration of hydrogen peroxide at that time is water. It was experimentally confirmed that it was about 100 times depending on the conditions compared with the case of electrolyzing. This is presumably because the hydroxyl radicals and oxygen radicals generated by the discharge eventually became hydrogen peroxide.

  On the other hand, when the liquid is irradiated with ultrasonic waves, hydroxyl radicals are not generated directly from water, but hydrogen peroxide is decomposed to generate hydroxyl radicals. The inventors of the present application consider these things, and by combining discharge and ultrasonic irradiation, the liquid can be effectively and continuously purified by hydroxyl radicals, and the concentration of hydrogen peroxide in the liquid is constant. I came up with a range that can be controlled.

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

Embodiment 1
The discharge unit (1) according to Embodiment 1 of the present invention is mounted on an indoor unit (11) of an air conditioner (10) that performs indoor air conditioning. The indoor unit (11) is a wall-mounted room air conditioner for general households.

  As shown in FIG. 1, the indoor unit (11) includes a horizontally long and substantially semi-cylindrical indoor casing (12). In the indoor casing (12), a suction port (13) is formed in the upper half of the front side (left side in FIG. 1), and a blowout port (14) is formed in the lower end thereof. The suction port (13) constitutes an air introduction port for taking indoor air into the indoor casing (12). The air outlet (14) constitutes an air supply port for supplying the air whose temperature is adjusted by the indoor unit (11) from the indoor casing (12) to the room.

  An air passage (15) through which air to be treated flows from the suction port (13) to the blower outlet (14) is formed inside the indoor casing (12). The air passage (15) is provided with a prefilter (16), an indoor heat exchanger (17), a fan (18), and a drain pan (19).

  The pre-filter (16) is provided in the vicinity of the inside of the suction port (13) along the suction port (13). The prefilter (16) is arranged over the entire area of the suction port (13). The prefilter (16) constitutes a dust collecting means for collecting dust in the air to be treated.

  The indoor heat exchanger (17) is connected to an outdoor unit (not shown) via a refrigerant pipe, and constitutes a part of a refrigerant circuit in which the refrigerant circulates and performs a refrigeration cycle. The indoor heat exchanger (17) constitutes a so-called fin-and-tube air heat exchanger. The indoor heat exchanger (17) functions as an evaporator or a condenser according to the refrigerant circulation direction in the refrigerant circuit. That is, the indoor heat exchanger (17) constitutes a cooling unit that cools indoor air and a heating unit that heats indoor air.

  The drain pan (19) is provided below the indoor heat exchanger (17). When the air to be treated is cooled by the indoor heat exchanger (17), the drain pan (19) has a condensate water recovery unit that collects the condensed water dripping from the heat exchanger (17) when water vapor in the air is condensed. It is composed.

  As shown in FIG. 2, the drain pan (19) is formed in a flat dish shape with its upper side open, and a bottom plate (55a) located at the bottom of the drain pan (19) and a peripheral wall (55b) surrounding the bottom plate (55a) And a drainage path (57) provided through the peripheral wall (55b). The drain pan (19) stores the collected water (drain water) (56). The drain pan (19) is provided with a discharge unit (1) and an ultrasonic generator (94) that irradiates the water in the drain pan (19) with ultrasonic waves.

  Moreover, the purification apparatus of this embodiment includes a discharge waveform generator (3) connected to the high voltage generator (70), and a controller that controls on or off of the voltage applied to the electrode pair (64, 65). (2), an ultrasonic waveform generator (8) for supplying an AC voltage of a predetermined frequency to the ultrasonic generator (94) via the amplifier (9), and an ultrasonic waveform generator (8) A control unit (5) for controlling the operation of the ultrasonic wave generation unit (94) and a sensor (7) for monitoring the hydrogen peroxide concentration of the liquid in the drain pan (19) are provided. Although not shown, a central processing unit (CPU) that controls the control units (2, 5) based on the monitoring result of the sensor (7) may be provided. A method of controlling the discharge unit (62) and the ultrasonic wave generation unit (94) by the control unit (2, 5) will be described later. In addition, when performing so-called feedforward control described later, the sensor (7) is not necessarily provided.

  The discharge unit (1) constitutes an underwater discharge device for discharging in drain water (56). The discharge unit (1) includes an electrode pair (64, 65) composed of an electrode A (64) and an electrode B (65), and a high voltage generator (applied to the electrode pair (64, 65)). 70) and an insulating casing (71) for accommodating the electrode A (64) therein. In the following example, the high voltage generator (70) applies a DC voltage.

  The electrode pair (64, 65) is for generating discharge in the drain water (56). The electrode A (64) is disposed inside the insulating casing (71). The electrode A (64) is formed in a plate shape that is flat vertically. The electrode A (64) is connected to the positive electrode side of the high voltage generator (70). The electrode A (64) is made of a copper material. On the other hand, the electrode B (65) is disposed outside the insulating casing (71). The electrode B (65) is provided above the electrode A (64). The electrode B (65) has a flat plate shape in the vertical direction, and is configured in a mesh shape or a punching metal shape having a plurality of through holes (23) in the vertical direction. The electrode B (65) is disposed substantially parallel to the electrode A (64). The electrode B (65) is connected to the negative electrode side of the high voltage generator (70). The electrode B (65) is made of a material (for example, platinum material) having a lower ionization tendency than copper contained in the positive electrode of the electrode pair (64, 65).

  The high voltage generation unit (70) may be constituted by, for example, a DC power source that applies a predetermined DC voltage to the electrode pair (64, 65). That is, the high voltage generator (70) is not a pulse power source that repeatedly applies a high voltage instantaneously to the electrode pair (64,65), but is always several kilovolts to the electrode pair (64,65). Apply the DC voltage. Of the high voltage generator (70), the negative electrode side to which the electrode B (65) is connected is grounded. The high voltage generator (70) is provided with a constant power controller (not shown) that controls the discharge power of the electrode pair (64, 65) to be constant.

  The insulating casing (71) is installed on the bottom plate (55a) of the drain pan (19). The insulating casing (71) is made of an insulating material such as ceramics. The insulating casing (71) has a container-like case body (72) whose one surface (upper surface) is open, and a plate-like lid (73) that closes the open portion above the case body (72). doing.

  The case body (72) has a square cylindrical side wall (72a) and a bottom (72b) that closes the bottom of the side wall (72a). The electrode A (64) is laid on the upper side of the bottom (72b). In the insulating casing (71), the vertical distance between the lid (73) and the bottom (72b) is longer than the thickness of the electrode A (64). That is, a predetermined interval is secured between the electrode A (64) and the lid portion (73). Thereby, inside the insulating casing (71), a space (S) is formed between the electrode A (64), the case main body (72), and the lid portion (73).

  As shown in FIGS. 2 and 3, the lid portion (73) of the insulating casing (71) is formed with one opening (44) penetrating the lid portion (73) in the thickness direction. The opening (44) allows formation of an electric field between the electrode A (64) and the electrode B (65). The inner diameter of the opening (44) of the lid part (73) is preferably 0.02 mm or more and 0.5 mm or less.

  As described above, the insulating casing (71) accommodates only one electrode (electrode A (64)) of the electrode pair (64, 65) inside, and between the electrode pair (64, 65). An insulating member having an opening (44) forming a current density concentration portion for increasing the current density of the current path is configured.

  In addition, in the opening (44) of the insulating casing (71), as shown in FIG. 4, the current density in the current path is concentrated, so that water is vaporized by Joule heat and bubbles (B) are formed. . That is, the opening (44) of the insulating casing (71) functions as a gas phase forming part that forms bubbles (B) forming a gas phase part in the opening (44).

  In the discharge unit (1) having such a configuration, when a voltage is applied from the high voltage generator (70) to the electrode pair (64, 65), the discharge is generated by the bubbles (B) formed in the opening (44). Occur. Thus, active species mainly composed of hydrogen peroxide are generated in the vicinity region (C) where discharge is performed.

  Further, along with the discharge, electrolysis occurs around the electrode A (64) and the electrode B (65). On the side of the electrode B (65) connected to the negative electrode of the high voltage generator (70), a reaction (reduction reaction) for receiving electrons from the electrode B (65) occurs. Around the electrode B (65), hydrogen gas is generated and hydroxide ions are generated in the drain water (56). On the other hand, on the side of the electrode A (64) connected to the positive electrode of the high voltage generator (70), a reaction (oxidation reaction) for transferring electrons to the electrode A (64) occurs. Around the electrode A (64), oxygen gas is generated and hydrogen ions are generated in the drain water (56). Moreover, the copper contained in the electrode A (64) also becomes copper ions by electrolysis and is eluted in water. As described above, the electrode A (64) connected to the positive electrode of the high voltage generator (70) constitutes an ion generator that generates metal ions such as copper ions in the drain water (56). Further, hydrogen ions and copper ions generated around the electrode A (64) are released to the region (C) side through the opening (44) by the convection of water brought about during discharge.

  In the region (C), hydrogen peroxide, hydrogen ions, and copper ions coexist. Under such conditions, the so-called Fenton reaction generates hydroxyl radicals, which are highly reactive active species.

  Next, in the example shown in FIG. 2, the ultrasonic generator (94) includes a plate-shaped piezoelectric ceramic (95) and a pair of metal plates (96a, 96) provided so as to sandwich the piezoelectric ceramic (95) therebetween. 96b). The case (97) enclosing the ultrasonic generator (94) is hermetically sealed and arranged at the bottom of the drain pan (19). The ultrasonic generator (94) is disposed at a position closer to the water supply port of the drain pan (19) than the electrode pair (64, 65) (in other words, a position far from the water injection port).

  The metal plate (96a, 96b) is supplied with the output signal (AC voltage) of the ultrasonic waveform generator (8) amplified by the amplifier (9). Thereby, an ultrasonic wave generation part (94) irradiates the liquid in a drain pan (19) with the ultrasonic wave of arbitrary frequencies. However, in order to decompose hydrogen peroxide and efficiently generate hydroxyl radicals, it is particularly preferable that the frequency of the ultrasonic wave is about 100 kHz or more.

  In addition, the ultrasonic wave generation part (94) may be installed in arbitrary positions in the range which can irradiate a liquid in a drain pan (19) with an ultrasonic wave. For example, as shown to Fig.5 (a), the ultrasonic wave generation part (94) may be installed in the bottom outer side of the drain pan (19), and an electrode pair (64,65) is inside the drain pan (19). It may be installed in a position closer to the water inlet. When the ultrasonic generator (94) is installed outside the bottom of the drain pan (19), the ultrasonic wave is transmitted to the liquid through the wall surface of the drain pan (19).

  Moreover, the structure of an ultrasonic wave generation part (94) is not restricted to the example shown in FIG. For example, as shown in FIG. 5B, a plate-shaped piezoelectric ceramic (95) is sandwiched between the upper part of a metal case (97a) and a metal plate (96), and an AC voltage is supplied between the two. May be.

-Driving action-
Next, the operation of the air conditioner (10) according to this embodiment will be described. Hereinafter, the cooling operation of the air conditioner (10) will be described as an example.

  As shown in FIG. 1, when the air conditioner (10) is in operation, the fan (18) is in an operating state. In addition, a low-pressure liquid refrigerant flows inside the indoor heat exchanger (17), and the indoor heat exchanger (17) functions as an evaporator.

  When indoor air is introduced into the indoor casing (12) from the suction port (13), the air passes through the prefilter (16). In the prefilter (16), dust in the air is collected. The air after passing through the prefilter (16) passes through the indoor heat exchanger (17). In the indoor heat exchanger (17), the refrigerant absorbs heat from the air to cool the air. The air cooled as described above is supplied into the room from the air outlet (14).

  During the cooling operation as described above, the condensed water condensed in the indoor heat exchanger (17) accumulates in the drain pan (19) as drain water (56). If the drain water (56) stays in the drain pan (19) for a long period of time, various germs grow in the drain water (56) and cause odor generation. Furthermore, when the growth of various germs proceeds, mud (so-called slime) is generated in the drain water (56). Therefore, in the air conditioner (10) of the present embodiment, the discharge unit (1) generates hydrogen peroxide and highly reactive hydroxyl radicals in the drain water (56), and the drainage is generated by these active species. Water (56) is regularly purified and the generated slime is decomposed and removed.

  At the start of the operation of the discharge unit (1), the space (S) in the insulating casing (71) is in a flooded state, as shown in FIG. When a predetermined voltage (for example, 1 kV) is applied from the high voltage generator (70) to the electrode pair (64, 65), an electric field is formed between the electrode pair (64, 65). At this time, the periphery of the electrode A (64) is covered with the insulating casing (71). For this reason, the leakage current between the electrode pair (64, 65) is suppressed, and the current density of the current path in the opening (44) is increased.

  As the current density in the opening (44) increases, the Joule heat in the opening (44) increases. As a result, in the insulating casing (71), the vaporization of water is promoted in the vicinity of the opening (44) to form bubbles (B). As shown in FIG. 4, the bubbles (B) cover almost the entire area of the opening (44), and are formed between the water on the negative electrode side conducting to the electrode B (65) and the electrode A (64) on the positive electrode side. Air bubbles (B) are interposed between them. Therefore, in this state, the bubble (B) functions as a resistance that prevents conduction between the electrode A (64) and the electrode B (65) via water. Thereby, the leakage current between the electrode A (64) and the electrode B (65) is suppressed, and a desired potential difference is maintained between the electrode pair (64, 65). Then, in the bubble (B), discharge is generated due to dielectric breakdown. As described above, when discharge is performed with the bubbles (B), active species mainly composed of hydrogen peroxide are generated in the region (C) near the discharge region.

  Further, along with the discharge, electrolysis occurs around the electrode A (64) and the electrode B (65). The electrode B (65) is connected to the negative electrode of the high voltage generator (70). Therefore, on the electrode B (65) side, a reaction (reduction reaction) for receiving electrons from the electrode B (65) occurs. As shown in the reaction formula (1), on the electrode B (65) side, water reacts to generate hydrogen gas, and hydroxide ions are generated in the drain water (56).

4H ₂ O + 4e ⁻ → 2H ₂ + 4OH ⁻ (1)
On the other hand, the electrode A (64) side is connected to the positive electrode of the high voltage generator (70). Therefore, on the electrode A (64) side, a reaction (oxidation reaction) for passing electrons to the electrode A (64) occurs. As shown in the reaction formula (2), on the electrode A (64) side, water reacts to generate oxygen gas, and hydrogen ions are generated in the drain water (56). Further, as shown in the reaction formula (3), the copper contained in the electrode A (64) is also converted into copper ions by electrolysis and is eluted in the drain water (56). And the hydrogen ion and copper ion which were produced | generated around the electrode A (64) are discharge | released to the area | region (C) side through the opening (44) by the convection of the water brought about by discharge.

2H ₂ O → O ₂ + 4H ⁺ + 4e ⁻ (2)
Cu → Cu ⁺ + e ⁻ (3)
In the region (C), hydrogen peroxide, hydrogen ions, and copper ions coexist. Under such conditions, a so-called Fenton reaction shown in the reaction formula (4) occurs, and copper ions act catalytically to generate hydroxyl radicals.

H ₂ O ₂ + H ⁺ + Cu ⁺ → OH + H ₂ O + Cu ²⁺ (4)
Thus, when hydrogen peroxide and hydroxyl radicals, which are active species, are generated in the drain water (56), the drain water (56) is purified. That is, germs and odor components in the drain water (56) are decomposed and removed. Hydroxyl radicals are more reactive than hydrogen peroxide. For this reason, purification with the generated hydrogen peroxide and hydroxyl radicals has a higher purification capacity than purification with hydrogen peroxide alone.

  In addition, hydroxyl radicals have a very short life and react immediately to change into hydrogen peroxide. Therefore, in the conventional discharge unit, even if hydroxyl radicals are generated in the drain water (56) by the discharge, most of the hydroxyl radicals are changed to hydrogen peroxide before acting on various bacteria. However, in the discharge unit (1) of this embodiment, even if the hydroxyl radical changes to hydrogen peroxide, the hydrogen peroxide can be changed again to the hydroxyl radical by the Fenton reaction. That is, hydroxyl radicals can be regenerated and a strong purification ability can be maintained without reducing the hydroxyl radical concentration.

  In addition, the convection caused by the heat generated by the discharge promotes the diffusion of hydrogen peroxide and hydroxyl radicals generated in the region (C). Moreover, when discharge is performed in the bubbles (B), ion wind is generated in the bubbles (B). And the diffusion effect of hydrogen peroxide and hydroxyl radical is further improved by this ion wind.

  Moreover, the platinum which comprises the electrode B (65) which is a negative electrode has a lower ionization tendency than copper. Therefore, copper precipitation reaction in which copper ions in water take electrons from platinum to become copper atoms is unlikely to occur. When the copper precipitation reaction is suppressed in this way, the concentration of copper ions in water does not decrease, and the production efficiency of hydroxyl radicals by the Fenton effect can be maintained.

  Furthermore, in the air conditioning apparatus (10) of the present embodiment, the amount of hydroxyl radicals can be maintained by combining ultrasonic treatment with discharge. This will be described below.

  FIG. 6 is a diagram showing a basic cycle of liquid treatment by the purification apparatus of the present embodiment. As shown in the figure, the liquid such as water stored in the drain pan (19) is first purified by the discharge generated between the electrode pair (64, 65). At this time, active species such as hydroxyl radicals are generated in the liquid by the discharge, and decomposition or sterilization of organic substances or the like is performed (steps St1 and St2 in FIG. 3). Hydroxyl radicals change to hydrogen peroxide in a short time (step St3).

  Next, an ultrasonic wave is propagated from the ultrasonic wave generation unit (94) to the liquid, hydrogen peroxide in the liquid is decomposed, and converted into hydroxyl radicals (step St4). Hydroxyl radicals generated by ultrasonic irradiation are changed to hydrogen peroxide again. However, since hydroxyl radicals used in liquid purification reactions such as sterilization change to water, the concentration of hydrogen peroxide decreases when the discharge is stopped and only ultrasonic irradiation is performed. It will be.

  In addition, you may perform said liquid purification by what is called batch processing which replaces | exchanges all the liquids in the drain pan (19) for every time. Alternatively, the purification may be performed by continuous treatment in which water is poured from the inflow path (201) to the drain pan (19) and liquid is continuously discharged from the drain pan (19) to the drain path (57).

  Next, a specific example of operation control of the purification device combining discharge and ultrasonic treatment will be described. FIG. 7A is a time chart showing an example of operation control when feedback control is performed using the concentration of hydrogen peroxide in the liquid. In the following method, hydrogen peroxide in the liquid is detected by the sensor (7).

  In this method, first, the operation is started in a state where liquid is accumulated in the drain pan (19). The control unit (2) applies a predetermined voltage between the electrode pair (64, 65) to cause discharge. At this time, the ultrasonic wave generator (94) is turned off. As a result, the liquid is purified and the concentration of hydrogen peroxide in the liquid increases.

  Next, when the hydrogen peroxide concentration in the liquid exceeds a preset lower limit value, the control unit (2) continues to supply voltage to the electrode pair (64, 65), and the control unit (5) The generator (94) is turned on to irradiate the liquid with ultrasonic waves. As a result, the liquid is purified by the hydroxyl radicals generated by the discharge and the hydroxyl radicals generated from the hydrogen peroxide. Since the amount of hydrogen peroxide generated by the discharge is larger than the amount of hydrogen peroxide decomposed by the ultrasonic wave, the concentration of hydrogen peroxide in the liquid increases during this period.

  Next, when the hydrogen peroxide concentration of the liquid exceeds a preset upper limit value, the control unit (2) stops the voltage supply to the electrode pair (64, 65) and stops the discharge. The controller (5) continues to turn on the ultrasonic generator (94) to irradiate the liquid with ultrasonic waves. Thereby, the liquid is purified by hydroxyl radicals generated from hydrogen peroxide. During this period, since the hydrogen peroxide is decomposed by the ultrasonic wave, the concentration of hydrogen peroxide in the liquid decreases.

  Next, when the concentration of hydrogen peroxide in the liquid falls below the lower limit, the control unit (2) resumes the voltage supply to the electrode pair (64, 65). Thereby, the concentration of hydrogen peroxide in the liquid rises again. Thereafter, by repeating the period of performing only the ultrasonic irradiation and the period of combining the ultrasonic irradiation and the discharge in the same manner, while controlling the hydrogen peroxide concentration of the liquid within the range of the lower limit value and the upper limit value, Purify the liquid.

-Effect of Embodiment 1-
In the first embodiment, the discharge unit (1) is used for purifying the drain water (56) of the air conditioner (40). When discharge is performed in the discharge unit (1), hydrogen peroxide and highly reactive hydroxyl radicals are generated in the drain water (56). Therefore, the drain water (56) can always be kept in a clean state with the high purification ability brought about by these active species, and the growth of miscellaneous bacteria and the generation of malodor can be avoided in advance.

  Moreover, even if the growth of various bacteria progresses and slime is generated in the drain water (56), the highly reactive hydroxyl radical acts on the slime, so that the slime can be decomposed and removed. Therefore, when drain water (56) is discharged, it is possible to prevent the slime from being caught in the drain path (57) of the drain pan.

  In addition, since the discharge unit (1) has a very high purification capacity and can be designed compactly, even if the discharge unit (1) is mounted on the air conditioner (10), the size of the air conditioner may be increased. Absent.

  Furthermore, in the above method, the control unit (2) can purify the liquid by generating discharge and generating hydroxyl radicals until the hydrogen peroxide concentration of the liquid reaches the upper limit after the operation is started. Further, the control unit (5) turns on the ultrasonic wave generation unit (94) during a period in which the liquid hydrogen peroxide concentration exceeds the predetermined lower limit value, in other words, the hydrogen peroxide concentration is set to the predetermined lower limit value. The ultrasonic wave generation unit (94) is turned off during the period less than. That is, when sufficient hydrogen peroxide is present in the liquid, the hydroxyl radicals are generated by ultrasonic waves, so that the liquid can be effectively purified. Furthermore, by continuously irradiating with ultrasonic waves in the presence of a sufficient concentration of hydrogen peroxide, hydroxyl radicals can be continuously generated, so that a strong purification ability can be maintained for a predetermined period. it can.

  Furthermore, according to the above-described method, the concentration of hydrogen peroxide in the liquid supplied from the drain pan (19) to the drainage channel (57) can be suppressed to the upper limit value or less. This process can be facilitated.

  In addition, in the case of continuously treating a liquid, as shown in FIG. 2, by arranging the ultrasonic generator (94) closer to the water supply port than the electrode pair (64, 65), peroxidation caused by discharge Hydroxyl radicals can be effectively generated from hydrogen by ultrasonic irradiation.

  In FIG. 2, a control unit (2) for controlling on / off of a voltage applied to the electrode pair (64, 65) and a control unit (5) for controlling the operation of the ultrasonic wave generation unit (94) Although provided separately, it is also possible to control the on / off of the voltage applied to the electrode pair (64, 65) and the operation of the ultrasonic wave generator (94) by one control unit.

  In addition, in the purification apparatus of this embodiment, the bacteria etc. which propagate in the drain pan (19) can be effectively sterilized simultaneously with the liquid purification process by the hydroxyl radical generated by the discharge and the ultrasonic irradiation.

  In the above description, the electrode A (64) is made of a copper material, and the electrode B (65) is made of a material having a lower ionization tendency than copper. However, the electrode B (65) is not particularly limited as long as it can be used as an electrode. Moreover, both the electrode A (64) and the electrode B (65) may be made of the same material.

<Modification 1 of Embodiment 1>
In the first embodiment, one opening (74) is formed in the lid (73) of the insulating casing (71). However, for example, as shown in FIGS. 8 and 9, a plurality of openings (74) may be formed in the lid portion (73) of the insulating casing (71). In the first modification, the lid portion (73) of the insulating casing (71) is formed in a substantially square plate shape, and a plurality of openings (74) are arranged in a grid pattern at equal intervals in the lid portion (73). It is arranged. On the other hand, the electrode A (64) and the electrode B (65) are formed in a square plate shape over all the openings (74).

  Also in this modification 1, each opening (74) functions as an electric field density concentration part and a vapor phase formation part. As a result, when a voltage is applied from the high voltage generator (70) to the electrode pair (64, 65), the current density of each opening (74) increases, and bubbles (B) are formed in each opening (74). Is done. As a result, discharge occurs in each bubble (B), and hydrogen peroxide is generated in the region (C) near the discharge region. In addition, around the electrode A (21), hydrogen ions and copper ions are generated by electrolysis, and these ions are released to the region (C) side by convection of water caused by discharge. In the region (C), hydrogen peroxide, hydrogen ions, and copper ions coexist. Under such conditions, the Fenton reaction occurs and hydroxyl radicals are generated. Also, hydroxyl radicals are generated from hydrogen peroxide by ultrasonic irradiation. The drain water (56) is purified by hydrogen peroxide and highly reactive hydroxyl radicals.

<Modification 2 of Embodiment 1>
Hereinafter, Modification Example 2 of the operation of the purification device in the present embodiment will be described.

  FIG. 7B is a time chart showing an example of operation control when feedforward control is performed using a measured value of the change in the concentration of hydrogen peroxide.

  The purification device used here is not necessarily provided with the sensor (7). However, when only the discharge is performed, the time T1 required for the hydrogen peroxide concentration of the liquid in the drain pan (19) to reach the lower limit value from 0, and the liquid peroxidation when the discharge and the ultrasonic irradiation are performed simultaneously. The time T2 required for the hydrogen concentration to reach the upper limit value from the lower limit value, and the time T3 required to reach the lower limit value from the upper limit value when only ultrasonic irradiation is performed are measured in advance, and the measurement data Is stored in a memory (not shown) provided inside or outside the control unit (2, 5). The control unit (2, 5) performs the following control based on the measurement data. A timer for counting time is provided inside or outside the control unit (2, 5).

  In the method according to this modification, first, the control unit (2) applies a predetermined voltage between the electrode pair (64, 65) to cause discharge. At this time, the ultrasonic wave generator (94) is turned off. As a result, the liquid is purified and the concentration of hydrogen peroxide in the liquid increases.

  Next, when time T1 has elapsed from the start of operation, the control unit (2) continues to supply voltage to the electrode pair (64, 65), and the control unit (5) turns on the ultrasonic wave generation unit (94). The liquid is irradiated with ultrasonic waves. As a result, the liquid is purified by the hydroxyl radicals generated by the discharge and the hydroxyl radicals generated from the hydrogen peroxide. Even during this period, the concentration of hydrogen peroxide in the liquid increases.

  Next, when the time T2 has elapsed, the control unit (2) stops the voltage supply to the electrode pair (64, 65) and stops the discharge. The controller (5) continues to turn on the ultrasonic generator (94) to irradiate the liquid with ultrasonic waves. Thereby, the liquid is purified by hydroxyl radicals generated from hydrogen peroxide. During this period, the concentration of hydrogen peroxide in the liquid decreases.

  Next, when the time T3 further elapses, the control unit (2) resumes the voltage supply to the electrode pair (64, 65) and continues this state for the time T2. Thereby, the concentration of hydrogen peroxide in the liquid rises again. Thereafter, similarly, by repeating a period in which only ultrasonic irradiation is performed (time T3) and a period in which ultrasonic irradiation and discharge are combined (time T2), the hydrogen peroxide concentration of the liquid is not less than the lower limit and not more than the upper limit. The liquid is purified while being controlled within the range.

  Also by the above method, it is possible to purify the liquid while controlling the concentration of hydrogen peroxide in the liquid within the range of the lower limit value and the upper limit value. This is a modification of the driving operation, and the liquid can be purified by other methods.

<< Embodiment 2 >>
Next, a second embodiment of the present invention will be described in detail based on the drawings. This embodiment is different from the discharge unit (1) of the first embodiment in configuration. Hereinafter, differences from the first embodiment will be mainly described.

  As shown in FIG. 10, the discharge unit (1) of the second embodiment is configured as a so-called flange unit type that is inserted and fixed from the outside to the inside of the drain pan (19). In the discharge unit (1) of the second embodiment, the electrode A (21), the electrode B (22), and the insulating casing (41) are integrally assembled.

  The insulating casing (41) of Embodiment 2 has a substantially outer shape that is cylindrical. The insulating casing (41) has a case body (42) and a lid (43).

  The case body (42) of Embodiment 2 is made of an insulating material made of glass or resin. The case body (42) includes a cylindrical base portion (46), a cylindrical wall portion (47) projecting from the base portion (46) toward the drain pan (19), and the cylindrical wall portion (47). An annular convex portion (48) projecting further toward the drain pan (19) side from the outer edge portion is provided. The case body (42) is integrally formed with a distal end cylindrical portion (49) on the distal end side of the annular convex portion (48). A cylindrical insertion opening (46a) extends in the axial direction in the axial center portion of the base portion (46). A cylindrical space (S) that is coaxial with the insertion port (46a) and has a larger diameter than the insertion port (46a) is formed inside the cylindrical wall portion (47).

  The cover part (43) of Embodiment 2 is formed in a substantially disc shape, and is fitted inside the annular convex part (48). The lid (43) is made of a ceramic material. As in the first embodiment, one circular opening (44) penetrating the lid (43) up and down is formed at the axis of the lid (43).

  The electrode A (21) is a vertically long rod-shaped electrode having a circular cross section perpendicular to the axis. The electrode A (21) is fitted in the insertion opening (46a) of the base (46). Thereby, the electrode A (21) is accommodated inside the insulating casing (41). In the second embodiment, the end of the electrode A (21) opposite to the drain pan (19) is exposed to the outside of the drain pan (19). For this reason, the high voltage generation part (70) arrange | positioned outside the drain pan (19) and the electrode A (21) can be easily connected by electrical wiring.

  The end (21a) on the drain pan (19) side of the electrode A (21) faces the space (S) inside the insulating casing (41). In the example shown in FIG. 10, the end (21a) of the electrode A (21) protrudes above the opening surface of the insertion port (46a) (on the drain pan (19) side). The tip end surface of 21a) may be substantially flush with the opening surface of the insertion port (46a), or the end (21a) may be recessed below the opening surface of the insertion port (46a). In addition, the electrode A (21) has a predetermined gap between the electrode A (21) and the lid (43) having the opening (44), as in the first embodiment.

  The electrode B (22) includes a cylindrical electrode body (22a) and a flange portion (22b) projecting radially outward from the electrode body (22a). The electrode body (22a) is externally fitted to the case body (42) of the insulating casing (41). The flange portion (22b) constitutes a fixed portion that is fixed to the wall portion of the drain pan (19) and holds the discharge unit (1). In a state where the discharge unit (1) is fixed to the drain pan (19), a part of the electrode body (22a) of the electrode B (22) is submerged.

  The electrode B (22) includes an inner cylindrical portion (22c) having a smaller diameter than the electrode main body (22a), and a connecting portion (22d) formed between the inner cylindrical portion (22c) and the electrode main body (22a). ). The inner cylinder part (22c) and the connecting part (22d) are immersed in the water in the drain pan (19). The inner cylinder portion (22c) forms a cylindrical space (24) therein. One end of the inner cylindrical portion (22c) in the axial direction constitutes a holding portion that contacts the lid portion (43) and holds the lid portion (43). Further, the tip cylinder part (49) of the case body (42) is fitted between the electrode body (22a), the inner cylinder part (22c), and the connecting part (22d). On the other end side in the axial direction of the inner cylindrical portion (22c), a mesh-shaped leakage preventing material (25) is provided so as to cover the cylindrical space (24). The leakage preventive material (25) is substantially grounded by being in contact with the electrode B (22). Thereby, the leakage preventive material (25) prevents leakage from the inside to the outside of the cylindrical space (24) in the space (underwater) inside the drain pan (19).

  The electrode B (22) is in a state where a part of the electrode body (22a) is exposed to the outside of the drain pan (19). For this reason, the high voltage generation part (70) and the electrode B (22) can be easily connected by electric wiring.

  Although not shown in FIG. 10 (and FIG. 11), in the air conditioner of Embodiment 2, the same high voltage generator (70) and discharge waveform generator (70) as shown in FIG. 3), control unit (2,5), amplifier (9), ultrasonic waveform generation unit (8), sensor (7), etc. are provided.

  At the start of operation of the discharge unit (1), as shown in FIG. 10, the space (S) in the insulating casing (41) is in a flooded state. When a predetermined voltage (for example, 1 kV) is applied from the high voltage generator (70) to the electrode pair (21, 22), the current density inside the opening (44) increases.

  From the state shown in FIG. 7, when voltage is continuously applied to the electrode pair (21, 22), water in the opening (44) is vaporized to form bubbles (B) (see FIG. 11). ). In this state, the bubble (B) covers almost the entire area of the opening (44), and the resistance of the bubble (B) is between the negative electrode side water in the cylindrical space (24) and the electrode A (21). Is granted. As a result, the potential difference between the electrode A (21) and the electrode B (22) is maintained, and discharge occurs in the bubbles (B). As a result, hydrogen peroxide is generated in the region (C) near the discharge region. In addition, around the electrode A (21), hydrogen ions and copper ions are generated by electrolysis, and these ions are released to the region (C) side by convection of water caused by discharge. In the region (C), hydrogen peroxide, hydrogen ions, and copper ions coexist. Under such conditions, the Fenton reaction occurs and hydroxyl radicals are generated.

  Similarly to the first embodiment, hydroxyl radicals are also generated from hydrogen peroxide by ultrasonic waves irradiated into water by the ultrasonic generator (94).

  The drain water (56) is purified by hydrogen peroxide and highly reactive hydroxyl radicals.

<Modification of Embodiment 2>
In the second embodiment, one opening (44) is formed in the axial center of the disc-shaped lid (43), but a plurality of openings (44) may be formed in the lid (43). Good. In the example shown in FIG. 12, five openings (44) are arranged at equal intervals on a virtual pitch circle centered on the axis of the lid (43). Thus, by forming a plurality of openings (44) in the lid part (43), it is possible to generate a discharge in the vicinity of each opening (44).

<< Embodiment 3 >>
FIG. 13 is a configuration diagram illustrating a purification device according to Embodiment 3 of the present invention. In the same figure, the same code | symbol as FIG. 2 is attached | subjected about the structure similar to the purification apparatus which concerns on Embodiment 1. FIG. Also, the drainage path (57), discharge waveform generator (3), controller (2,5), amplifier (9) and sensor (7) are not shown in FIG. It is provided in the form purification device. Hereinafter, differences from the underwater discharge device according to the first embodiment will be mainly described.

  The underwater discharge device of the present embodiment includes a drain pan (19), an electrode pair (64a, 65a) disposed in the drain pan (19), and a high voltage generator (power source) connected to the electrode pair (64a, 65a). Part) (70a) and an ultrasonic wave generation part (94) installed at the bottom of the drain pan (19).

  The electrode (64a) is housed inside the insulating casing (71a), and the electrode (65a) is housed inside the insulating casing (71b). The electrode (64a) and the electrode (65a) are each formed in a flat plate shape. At least one of the electrode (64a) and the electrode (65a) is made of a copper material. The high voltage generator (70a) supplies a voltage of about several kilovolts to the electrode pair (64a, 65a).

  The insulating casings (71a, 71b) are made of, for example, an insulating material such as ceramics, and have the same configuration as the insulating casing (71) shown in FIG.

  That is, the insulating casing (71a) includes a container-like case body (180a) whose one surface (the right-hand surface in FIG. 13) is opened, and a plate-like lid portion that closes the open portion of the case body (180a). (73a). The insulating casing (71b) includes a container-like case main body (180b) whose one side (left side in FIG. 13) is open, and a plate-like lid that closes the open part of the case main body (180b). (73b).

  One opening (74a) that penetrates the lid (73a) in the thickness direction is formed in the lid (73a) of the insulating casing (71a). One opening (74b) penetrating the lid (73b) in the thickness direction is also formed in the lid (73b) of the insulating casing (71b). These openings (74a, 74b) allow formation of an electric field between the electrode (64a) and the electrode (65a). The inner diameter of the openings (74a, 74b) is preferably 0.02 mm or more and 0.5 mm or less. The openings (74a, 74b) as described above constitute a current density concentration portion that increases the current density of the current path between the electrode pair (64a, 65a).

  The insulating casings (71a, 71b) are installed on the side surfaces facing each other in the drain pan (19) so that the lid portions (73a, 73b) face each other. In other words, the electrode (64a) and the electrode (65a) are arranged to face each other.

  In the openings (74a, 74b) of the insulating casing (71a, 71b), the current density in the current path increases, so that the liquid is vaporized by Joule heat and bubbles are formed. That is, the opening (74a, 74b) of the insulating casing (71a, 71b) functions as a gas phase forming part that forms bubbles as a gas phase part in the opening (74a, 74b). With this configuration, when a voltage is supplied to the electrode pair (64a, 65a), a discharge can be generated in the bubbles between the electrode pair (64a, 65a).

  The specific configuration of the ultrasonic generator (94) is the same as that of the purification device according to the first embodiment.

  By adopting the above configuration, even when a voltage is supplied to the electrode pair (64a, 65a), a discharge can be generated between the electrode pair (64a, 65a), and a high purification ability can be exhibited.

  Further, since at least one of the electrode (64a) and the electrode (65a) is made of a copper material, the Fenton effect can be obtained in the same manner as described in the first embodiment, and this also increases the amount of hydroxyl radicals. Can be maintained. Of the electrode (64a) and the electrode (65a), the electrode that is not composed of a copper material may be composed of a platinum material that has a lower tendency to be ions than copper. Further, both the electrode (64a) and the electrode (65a) may be made of a copper material.

  By operating the purification apparatus of the present embodiment by the method shown in FIGS. 7A and 7B, the concentration of hydrogen peroxide in the liquid is maintained within a predetermined range, while the drain pan (19) The liquid can be effectively purified.

<< Embodiment 4 >>
FIG. 14 is a configuration diagram illustrating a purification device according to Embodiment 4 of the present invention. In the same figure, the same code | symbol as FIG. 2 is attached | subjected about the structure similar to the purification apparatus which concerns on Embodiment 1. FIG. Further, the drainage path (57), the discharge waveform generation unit (3), the control unit (2,5), the amplifier (9), and the sensor (7) are omitted in FIG. It is provided in the form purification device. Below, a different point from the purification apparatus mainly concerning Embodiment 1 is demonstrated.

  The purification device of the present embodiment includes a drain pan (19), an electrode pair (64, 65) disposed in the drain pan (19), and a high voltage generator (power supply unit) connected to the electrode pair (64, 65). ) (70b) and an ultrasonic generator (94) installed at the bottom of the drain pan (19).

  In the purification apparatus of the present embodiment, the electrode A (64) and the electrode B (65) are respectively connected to the positive electrode side and the negative electrode side of the high voltage generator (70b), and the electrode pair from the high voltage generator (70b). A high pulse voltage is supplied to (64, 65). The positive electrode A (64) is made of a copper material. The electrode B (65) which is a negative electrode may be made of a material having a lower ionization tendency than copper contained in the positive electrode, for example, a platinum material.

  Further, the insulating casing (71) surrounding the electrode A (64) is not provided. The electrode A (64) and the electrode B (65) are both plate-shaped and are installed on the side surfaces in the drain pan (19) so as to face each other.

  Further, the purification device includes, for example, a nozzle (discharging means) provided at least between the electrode pair (64, 65) and lower than the electrode pair (64, 65), such as the bottom of the drain pan (19). (119) and an air pump (sending means) (99) for sending a gas such as air to the nozzle (119) are provided. The gas in the drain pan (19) is circulated through the nozzle (119) by the air pump (99). However, gas may be supplied from the outside into the drain pan (19) by the air pump (99).

  The configuration of the ultrasonic generator (94) is the same as that of the purification device according to the first embodiment, and may be installed at the bottom of the drain pan (19), but the liquid in the drain pan (19) can be irradiated with ultrasonic waves. As long as it can be installed at any position.

  Bubbles are discharged from the nozzle (119) into the liquid at least during the period during which the discharge treatment is performed. By supplying a pulse voltage to the electrode pair (64, 65) in a state where bubbles are present in the liquid, a discharge is generated inside the bubbles and hydroxyl radicals are generated.

  Further, since at least one of the electrode (64a) and the electrode (65a) is made of a copper material, the Fenton effect can be obtained in the same manner as described in the first embodiment, and this also increases the amount of hydroxyl radicals. Can be maintained. Of the electrode (64a) and the electrode (65a), the electrode that is not composed of a copper material may be composed of a platinum material that has a lower tendency to be ions than copper. Further, both the electrode (64a) and the electrode (65a) may be made of a copper material.

  In the purification apparatus according to the present embodiment, liquid purification that combines discharge and ultrasonic irradiation is performed by basically the same method as the purification apparatus according to the first embodiment, that is, the method shown in FIGS. Is called. However, during the discharge process shown in FIGS. 7A and 7B, a pulse voltage is intermittently supplied from the high voltage generator (70b) to the electrode pair (64, 65), and the electrode pair (64 , 65), intermittent discharge occurs.

  According to the above configuration and method, even when pulse discharge is generated between the electrode pair (64, 65), by combining with ultrasonic irradiation, high purification ability is exhibited while suppressing an increase in hydrogen peroxide concentration. be able to.

<< Embodiment 5 >>
FIG. 15 is a configuration diagram illustrating a purification device according to Embodiment 5 of the present invention. In the same figure, the same code | symbol as FIG.1 and FIG.13 is attached | subjected about the structure similar to the purification apparatus concerning Embodiment 1 and Embodiment 3. FIG. Also, the drainage path (57), the discharge waveform generator (3), the controller (2,5), the amplifier (9) and the sensor (7) are omitted in FIG. It is provided in the form purification device. Below, a different point from the purification apparatus mainly concerning Embodiment 2 is demonstrated.

  The purification device of the present embodiment includes a drain pan (19), an electrode pair (64b, 65b) disposed in the drain pan (19), and a high voltage generator (power supply unit) connected to the electrode pair (64b, 65b). ) (70c) and an ultrasonic generator (94) installed at the bottom of the drain pan (19).

  The electrode (64b) and the electrode (65b) are respectively installed on the side surfaces in the drain pan (19) so as to face each other. At least one of the electrode (64a) and the electrode (65a) is made of a copper material.

  The electrode (64b) has at least one conductive part (164) and an insulating part (165) surrounding the conductive part (164).

The electrode (65b) has at least one conductive portion (166) and an insulating portion (167) surrounding the conductive portion (166). As described above, the conductive portion (164) of the electrode (64b) Since the area of the exposed surface and the exposed surface of the conductive portion (166) in the electrode (65b) is small, current density is concentrated on the surface of the conductive portion (164,166) when voltage is supplied to the electrode pair (64b, 65b). Part is formed. Therefore, on the surface of the conductive portion (164, 166), the liquid is vaporized by Joule heat to form bubbles. By continuing the voltage supply from the high voltage generator (70c) in a state where the exposed surfaces of the conductive parts (164, 166) are covered with the bubbles, a discharge is generated inside the bubbles.

  The specific configuration of the ultrasonic generator (94) is the same as that of the purification device according to the first and third embodiments.

  By operating the purification apparatus of the present embodiment by the method shown in FIGS. 7A and 7B, the concentration of hydrogen peroxide in the liquid is maintained within a predetermined range, while the drain pan (19) The liquid can be effectively purified.

  Further, since at least one of the electrode (64a) and the electrode (65a) is made of a copper material, the Fenton effect can be obtained in the same manner as described in the first embodiment, and this also increases the amount of hydroxyl radicals. Can be maintained. Of the electrode (64a) and the electrode (65a), the electrode that is not composed of a copper material may be composed of a platinum material that has a lower tendency to be ions than copper. Further, both the electrode (64a) and the electrode (65a) may be made of a copper material.

  Even with the above configuration, by combining discharge between the electrode pair (64b, 65b) and ultrasonic irradiation, high purification ability can be exhibited while suppressing an increase in the hydrogen peroxide concentration.

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

<Discharge unit configuration>
In each embodiment mentioned above, electrode A (21, 64, 64a) is comprised with the copper material. However, the electrode A (21, 64, 64a) may be made of a material containing copper. Furthermore, the electrode A (21, 64, 64a) may be made of an iron material. When the electrode A (21) is composed of an iron material, hydroxyl radicals can be generated by the Fenton reaction shown in the reaction formula (6). The electrode A (21) may be made of a metal containing iron.

Fe → Fe ²⁺ + 2e ⁻ (5)
^{_{H 2 O 2 + H + +}} Fe 2+ → · OH + H 2 O + Fe 3+ (6)
Moreover, in each embodiment mentioned above, the electrode B (22) is comprised with the platinum material. However, the electrode B (22) as the negative electrode may be made of a metal having a lower ionization tendency than copper or iron contained in the positive electrode of the electrode pair (21, 22), and may be, for example, silver or gold. .

<Applications of underwater discharge devices>
The above-described underwater discharge device is applied to a purpose of purifying drain water collected in a drain pan (19) of an air conditioner (10). However, it can be applied to other uses as long as it purifies water. Examples of these uses include purification of tank water in a water heater or humidifier, purification of water supplemented by a dehumidifier, and the like. The underwater discharge device can also be applied to use for cleaning the object to be cleaned by supplying or spraying water obtained by discharge and electrolysis to a predetermined object to be cleaned.

  As described above, the present invention is also useful as an apparatus for purifying various liquids by combining discharge using a copper electrode and ultrasonic irradiation.

1 Discharge unit (underwater discharge device)
17 Indoor heat exchanger (cooling section)
19 Drainpan
21 Electrode A (electrode pair)
22 Electrode B (electrode pair)
30 Power supply (power supply)
94 Ultrasonic generator

Claims (10)

A container (19) for storing water;
A power source (70, 70a, 70b, 70c, 70d), connected to the power source (70, 70a, 70b, 70c, 70d), causing discharge in the water, and water in the container (19) An electrode pair (64, 64a, 64b, 65, 65a, 65b, 170, 178) for generating acid radicals;
An ultrasonic generator (94) that converts hydrogen peroxide in the liquid generated by changing the generated hydroxyl radicals into hydroxyl radicals by irradiating the water in the container (19) with ultrasonic waves. And
At least one of said electrode pair (21,22,64,64a, 64b, 65,65a, 65b, 170,178) is comprised with the metal containing copper or iron, The underwater discharge apparatus characterized by the above-mentioned. In claim 1,
A first controller (2) for controlling on or off of a voltage applied to the electrode pair (64, 64a, 64b, 65, 65a, 65b);
A second controller (5) for controlling the operation of the ultrasonic generator (94),
The first control unit (2) and the second control unit (5) are arranged so that the concentration of hydrogen peroxide contained in the water in the container (19) does not exceed a predetermined upper limit value. (64, 64a, 64b, 65, 65a, 65b) An underwater discharge apparatus that controls on / off of a voltage applied to (64, 64a, 64b, 65, 65a, 65b) and the operation of the ultrasonic generator (94). In claim 2,
A sensor (7) for monitoring the concentration of hydrogen peroxide contained in the water in the container (19);
The first control unit (2) controls on or off of a voltage applied to the electrode pair (64, 64a, 64b, 65, 65a, 65b) according to a monitoring result by the sensor (7),
The underwater discharge device, wherein the second control unit (5) controls the operation of the ultrasonic wave generation unit (94) according to a monitoring result by the sensor (7). In claim 3,
The voltage applied to the electrode pair (64, 64a, 64b, 65, 65a, 65b) by the first controller (2) when at least the concentration of hydrogen peroxide in the water exceeds the upper limit value. Is turned off to stop the discharge, and the second control unit (5) operates the ultrasonic wave generation unit (94). In any one of Claims 2 thru | or 4,
The second control unit (5) includes the ultrasonic generation unit (94) during a period in which the concentration of hydrogen peroxide contained in the water in the container (19) exceeds a predetermined lower limit value lower than the upper limit value. An underwater discharge device characterized by turning on the underwater discharge device. In claim 1,
A control unit for controlling on / off of a voltage applied to the electrode pair (64, 64a, 64b, 65, 65a, 65b) and controlling the operation of the ultrasonic wave generation unit (94);
The control unit applies the electrode pair (64, 64a, 64b, 65, 65a, 65b) so that the concentration of hydrogen peroxide contained in the water in the container (19) does not exceed a predetermined upper limit value. An underwater discharge device that controls on / off of a voltage to be applied and operation of the ultrasonic wave generator (94). In claim 6,
When the concentration of hydrogen peroxide contained in the water in the container (19) exceeds a predetermined upper limit value, the control unit is configured to use the electrode pair (64, 64a, 64b, 65, 65a, 65b) The ultrasonic generator (94) is turned on during the period when the concentration of hydrogen peroxide contained in the water exceeds a predetermined lower limit value lower than the upper limit value by turning off the voltage applied to An underwater discharge device characterized by that. In any one of Claims 1 thru | or 7,
Discharge means (119) for discharging bubbles into the water in the container (19);
A delivery means (99) for sending gas to the discharge means (119);
The electrode pair (64, 65) has a plate shape and is arranged to face each other,
The power source (70b) applies a pulse voltage to the electrode pair (64a, 65a),
The underwater discharge device, wherein the discharge means (119) is disposed between the electrode pair (64, 65) and at the bottom of the container (19). In any one of claims 1 to 8,
The power source (70, 70a, 70b, 70c, 70d) is a DC power source,
The positive electrode of the electrode pair (21, 22, 64, 64a, 64b, 65, 65a, 65b, 170, 178) is made of a metal containing copper or iron, and the negative electrode is formed of the electrode pair (21, 22, 64, 64a, 64b, 65, 65a, 65b, 170, 178), an underwater discharge apparatus comprising a metal having a lower ionization tendency than copper or iron contained in the positive electrode. A cooling section (17) for cooling the air;
A drain pan (19) for recovering condensed water condensed in the air by cooling the air (17);
An air conditioner comprising an underwater discharge device that discharges in water so that hydrogen peroxide is generated in the water in the drain pan (19),
The underwater discharge device includes the underwater discharge device according to any one of claims 1 to 9,
The air conditioner characterized in that the drain pan (19) is the container (19).

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