JP5870828B2 - Purification device - Google Patents

Description

  The present invention relates to a purification device that decomposes organic substances contained in a gas to be purified by hydroxy radicals.

  As a prior art, there is an air cleaner disclosed in Patent Document 1 below. In this air purifier, water is sprayed from a humidifying nozzle to supply water to the surface of the honeycomb structure while air is circulated through the honeycomb structure carrying polyaniline as a hydroxy radical generating member. As a result, ponyaniline oxidizes water to generate hydroxy radicals, and decomposes odorous substances adhering to the surface of the honeycomb structure.

Japanese Patent No. 4120299

  However, in the above-described prior art air purifier, although the organic matter in the air that contacts the surface of the honeycomb structure is decomposed, the organic matter in the air that passes through a position away from the surface of the honeycomb structure can be decomposed. Have difficulty. Therefore, there is a problem that it is difficult to reliably purify the air flowing in the air purifier, and it is difficult to obtain sufficient purification performance.

  This invention is made | formed in view of the said point, and it aims at providing the purification apparatus which can improve the performance which purify | cleans purification object gas.

In order to achieve the above object, in one of the disclosed inventions ,
A water tank (10) for storing the stored water (11) therein;
Bubble forming means (20) for forming fine bubbles (12) of the gas to be purified containing organic matter in the stored water;
Radical generating means (50) for generating hydroxy radicals in the stored water,
Decomposes organic substances in the bubbles by hydroxy radicals generated around the bubbles .
A blowout port (61) for blowing out the gas to be purified that has departed from the stored water into the room (9);
Cooling means (70) for cooling the gas in the room;
Condensed water introducing means (71) for introducing condensed water generated when the cooling means cools the indoor gas into the water storage tank .
In another disclosed invention,
A water tank (10) for storing the stored water (11) therein;
Bubble forming means (20) for forming fine bubbles (12) of the gas to be purified containing organic matter in the stored water;
Radical generating means (50) for generating hydroxy radicals in the stored water,
Decomposes organic substances in the bubbles by hydroxy radicals generated around the bubbles.
The stored water contains organic matter,
Organic substances in the stored water are also decomposed by the hydroxy radicals generated by the radical generating means,
An aquarium water introduction means (126) for introducing the water in the water tank (101) for containing the aquatic organism (102) into the water tank;
A stored water deriving means (226) for deriving the stored water into the storage tank,
The water in the storage tank is introduced into the water tank by the water tank water introduction means, so that the stored water contains organic matter,
The stored water deriving means is characterized in that the stored water in which the organic matter contained by the hydroxy radicals is decomposed is derived into the stored water tank.

According to any of these, the gas to be purified is taken into the stored water as fine bubbles, and the organic matter in the bubbles can be decomposed by the hydroxy radicals generated around the bubbles by the radical generating means. Therefore, the organic substance can be decomposed by hydroxy radicals from the entire gas-liquid interface surrounding the fine bubbles of the purification target gas, and the purification target gas can be reliably purified. In this way, the performance of purifying the gas to be purified can be improved.

  In addition, a further feature of the present invention is that the radical generating means is an ultrasonic irradiation means for irradiating the stored water with ultrasonic waves.

  According to this, cavitation in which the fine bubbles become cavitation species is generated by the ultrasonic wave irradiated to the stored water by the ultrasonic wave irradiation means. When the fine bubbles are crushed by this cavitation, hydroxy radicals can be easily generated around the fine bubbles. Therefore, it is possible to easily improve the performance of purifying the purification target gas.

  In addition, the code | symbol in the parenthesis attached | subjected to each said means is an example which shows a corresponding relationship with the specific means as described in embodiment mentioned later.

It is a schematic diagram which shows schematic structure of the purification apparatus in 1st Embodiment to which this invention is applied. It is sectional drawing which shows schematic structure of an aspirator. It is a figure for demonstrating the crushing phenomenon of the bubble by ultrasonic irradiation. It is a schematic diagram which shows schematic structure of the purification apparatus in 2nd Embodiment. It is a schematic diagram which shows schematic structure of the purification apparatus in 3rd Embodiment.

  A plurality of modes for carrying out the present invention will be described below with reference to the drawings. In each embodiment, parts corresponding to the matters described in the preceding embodiment may be denoted by the same reference numerals, and redundant description may be omitted. In the case where only a part of the configuration is described in each embodiment, the other parts of the configuration are the same as those described previously. In addition to the combination of parts specifically described in each embodiment, the embodiments may be partially combined as long as the combination is not particularly troublesome.

(First embodiment)
A first embodiment to which the present invention is applied will be described with reference to FIGS.

  The purification apparatus 1 of this embodiment is for purifying the air in the room 9 of the container 8, for example. As shown in FIG. 1, the purification apparatus 1 includes a water tank 10, a bubble generator 20, a vibrator 50, a blower duct 60, a control device 100, and the like.

  The water tank 10 is made of metal, for example, and is a container body that is open at the top. The water tank 10 stores the stored water 11 therein, and corresponds to the water storage tank in the present embodiment. The bubble generator 20 is disposed near the bottom in the water tank 10. The bubble generator 20 includes, for example, a metal aspirator 21 and a water pump 28. The water pump 28 discharges the sucked stored water 11 to the aspirator 21 through the water conduit 26.

  As illustrated in FIG. 2, the aspirator 21 has a nozzle portion 22 that restricts the flow path of water. The aforementioned introduction pipe 26 is connected to the introduction port 23 at the right end of the nozzle portion 22 in the figure. The water introduced from the introduction port 23 passes through the tip opening of the nozzle portion 22 and is ejected into the water tank 10 from the jet outlet 24 at the left end in the figure.

  A suction port 25 at the upper end of the figure communicates with a space in the aspirator 21 where the tip opening of the nozzle portion 22 faces. The downstream end of the intake pipe 27 shown in FIG. 1 is connected to the intake port 25. The upstream end of the intake pipe 27 communicates with the room 9, and the air in the room 9 can flow into the intake pipe 27. A filter 30 is disposed at the upstream end of the intake pipe 27 so as to remove relatively large foreign substances from the air sucked into the intake pipe 27. The intake pipe 27 is provided with an air supply pump 29.

  As shown in FIG. 2, in the aspirator 21, when a water flow from the introduction port 23 toward the jet port 24 is formed inside, the flow velocity of water increases at the tip of the nozzle portion 22 with a narrowed inner diameter. Along with this, the pressure of water decreases due to the venturi effect. Air sucked from the suction port 25 is caught in the water flow whose pressure has been reduced. And the water spouted from the spout 24 contains many fine bubbles 12. The bubble generator 20 corresponds to a bubble forming unit that forms fine bubbles in the stored water 11. The bubbles 12 are so-called microbubbles having a diameter of 100 μm or less, for example.

  As shown in FIG. 1, a vibrator 50 is disposed in the water tank 10 along the side wall surface of the water tank 10. The vibrator 50 oscillates an ultrasonic wave by vibrating. The vibrator 50 corresponds to an ultrasonic irradiation unit that irradiates the stored water 11 with ultrasonic waves. The vibrator 50 is not limited to the one installed on the side wall surface of the water tank 10, and may be arranged at the bottom of the water tank 10, for example. Further, the number of vibrators 50 is not limited to one, and a plurality of vibrators 50 may be provided. The vibrator 50 is not limited to one that oscillates ultrasonic waves of one frequency, and may oscillate ultrasonic waves of a plurality of frequencies at the same time.

  Above the water tank 10, for example, an air duct 60 made of metal or resin is disposed. The upstream end of the air duct 60 is connected to the upper opening of the water tank 10. A downstream end of the air duct 60 is connected to and opened to a side wall portion of the container 8, for example. The opening at the downstream end of the air duct 60 serves as an air outlet 61 that blows air into the room 9. A blower fan 62 for supplying air from the upstream end to the downstream end is disposed in the blower duct 60.

  The room 9 is provided with an air conditioner 70 for air-conditioning the room 9. Although detailed illustration is omitted, the air conditioner 70 includes, for example, a cooling heat exchanger capable of cooling the air in the room 9. The air conditioner 70 corresponds to a cooling unit that cools the air in the room 9. When the air conditioner 70 cools the air in the room 9, the water vapor contained in the air is condensed to generate condensed water. The air conditioner 70 has a drain pipe 71 for discharging the generated condensed water to the outside. The downstream end of the drain pipe 71 communicates with the water tank 10.

  In the room 9, an environmental sensor 80 for detecting the environmental state of the room 9 is disposed. The environmental sensor 80 constitutes detection means for detecting the temperature, humidity, dust, bacteria, and organic substance concentration such as ethylene gas in the room 9, for example. The ethylene gas is a so-called aging gas that produces fruits and vegetables when the cargo stored in the room 9 is fruits and vegetables, for example.

  The control device 100 as control means inputs the environmental state information detected by the environmental sensor 80, and based on this input information and preset setting conditions, the water pump 28, the pump 29, the vibrator 50, and the blower fan. 62 and the air conditioner 70 are controlled to operate.

  Next, the action | operation of the purification apparatus 1 is demonstrated based on the said structure.

  When the temperature of the room 9 is out of the set temperature range, the control device 100 drives the air conditioner 70 to adjust the temperature of the room 9 to be within the set temperature range. Condensed water generated when the air conditioner 70 cools the air in the room 9 is introduced into the water tank 10 via the drain pipe 71. The drain pipe 71 corresponds to condensed water introduction means for introducing condensed water into the storage tank.

  When the humidity in the room 9 is lower than the set humidity, the control device 100 performs so-called ultrasonic humidification by vibrating the vibrator 50 in the humidification mode, for example. Here, the humidification mode is to oscillate ultrasonic waves having a frequency of 1 MHz to 5 MHz, for example. At this time, for example, the blower fan 62 is operated to blow humidified air into the room 9.

  The humidification of the room 9 can be performed, for example, by driving the water pump 28. When the water pump 28 is driven, a large number of fine bubbles 12 can be formed in the stored water 11 by the action of the aspirator 21 described above. At this time, water vapor is taken into the bubbles 12 having a large specific surface area relatively quickly. Therefore, a large amount of water vapor is contained in the air rising from the surface of the stored water 11. The air in the room 9 can also be humidified by blowing this air into the room 9. At this time, the blower fan 62 may be driven to assist the blowing. The pump 29 may also be driven so as to assist in the intake of air in the room 9.

  When the amount of organic matter contained in the air in the room 9 is larger than the set value, the control device 100 drives the water pump 28 and vibrates the vibrator 50 in the cavitation mode. Here, the cavitation mode is to oscillate ultrasonic waves having a frequency of, for example, several kHz to 3 MHz, preferably 20 kHz to 1 MHz.

  By driving the water pump 28, a large number of fine bubbles 12 are generated in the stored water 11 by the action of the aspirator 21 described above. In addition, by irradiating the stored water 11 with ultrasonic waves by the vibrator 50, cavitation is generated in the fine bubbles 12 in the stored water 11. When the bubbles 12 are crushed by cavitation, the organic matter in the bubbles 12 is decomposed and the air in the bubbles 12 is purified.

  Specifically, when ultrasonic waves are applied to the stored water 11 by the vibrator 50, the pressure in the stored water 11 varies with time as illustrated in the upper part of FIG. Along with this, as shown in the lower part of FIG. 3, the fine bubbles 12 repeat adiabatic compression and adiabatic expansion. When the bubble 12 is adiabatically compressed, the gas-liquid interface between the bubble 12 and the bubble 12 and the stored water 11 becomes a high-temperature and high-pressure reaction field, and the bubble 12 is crushed. That is, the bubble 12 collapses due to pressure. The pressure in the bubble 12 rises to, for example, 5 MPa to 100 MPa.

  When the bubbles 12 are crushed, water molecules located at the gas-liquid interface between the bubbles 12 and the stored water 11 are thermally decomposed into hydroxy radicals having strong oxidizing power. In general, the oxidation potential of a hydroxy radical is higher than the binding energy of an organic substance. Therefore, ethylene, bacteria, and the like contained in the bubbles 12 are quickly decomposed to generate carbon dioxide, water, and the like. At this time, hydroxy radicals are also generated from water molecules of water vapor contained in the bubbles 12 and contribute to the decomposition of the organic matter. The vibrator 50 corresponds to radical generating means for generating hydroxy radicals in the stored water 11.

  Due to the above-described action, the bubbles 12 in which the internal organic matter is decomposed rise in the stored water 11. Specifically, for example, a bubble group formed by crushing the bubbles 12 rises in the stored water 11. And it leaves | separates from the water surface of the stored water 11 as the air purified upwards. Thus, the air purified in the water tank 10 flows through the air duct 60 and is blown out from the air outlet 61 to the room 9. At this time, the blower fan 62 may be driven to assist the blowing. Further, the pump 29 may be driven so as to assist the suction of the air in the room 9 into the aspirator 21.

  The air circulation in the purification apparatus 1 that sucks air in the room 9 and purifies it in the stored water 11 and blows it out to the room 9 is driven by any one of the water pump 28, the pump 29, and the blower fan 62 or a combination of a plurality of drives. Can be performed.

  According to the above-described configuration and operation, the bubble generator 20 takes in the air in the room 9 as the purification target gas into the stored water 11 as the fine bubbles 12, and the hydroxy radicals generated around the bubbles 12 by the vibrator 50 The organic matter in the bubbles 12 can be decomposed. Therefore, the organic substance can be decomposed by hydroxy radicals from the entire area of the gas-liquid interface surrounding the fine bubbles 12 to reliably purify the air. In this way, the air purification performance can be improved.

  Further, the generation of hydroxy radicals can be easily performed by irradiating the stored water 11 with ultrasonic waves from the vibrator 50. That is, cavitation in which the fine bubbles 12 become cavitation species is generated by the ultrasonic wave irradiated to the stored water 11 by driving the vibrator 50. When the fine bubbles 12 are crushed by this cavitation, hydroxy radicals can be easily generated around the bubbles 12. Therefore, the air purification performance can be easily improved.

  The lifetime of the hydroxy radical is as short as, for example, about 1 / 1,000,000 second. However, since the hydroxy radical is generated around the fine bubbles 12, it is possible to reliably decompose the organic matter.

  As a conventional technique, for example, there is an ethylene gas reforming method disclosed in Japanese Patent Application Laid-Open No. 2005-261428. In this method, a gas containing ethylene gas is passed through the breathable water retaining body while irradiating the breathable water retaining body to which water droplets are attached with an ultraviolet light emitting tube, and ethylene gas is passed through the hydroxyl radicals generated in the water droplets. It is reformed to ethane and water.

  In this method, since ultraviolet rays are easily absorbed by water, the ultraviolet light emitting tube and the breathable water retaining body are arranged close to each other, for example, within a distance of 10 mm or less. Further, since the emission intensity of the ultraviolet light emitting tube is lowered at 10 ° C. or lower, a heater is provided between the ultraviolet light emitting tube and the breathable water retaining body.

  For these reasons, the conventional method has a problem that the ventilation of a gas containing ethylene gas tends to be hindered. In addition, there is a problem that the temperature of the air purified by heating with the heater rises and the indoor temperature easily rises. When storing fresh agricultural products such as vegetables in the room, it becomes difficult to maintain freshness.

  According to the purification apparatus 1 of the present embodiment, there is an advantage that the ventilation of the air that is the purification target gas is difficult to be inhibited and the temperature of the air blown into the room 9 is also difficult to increase.

  In addition, the air conditioner 70 has a drain pipe 71, so that condensed water generated when the air conditioner 70 cools the air in the room 9 is introduced into the water tank 10 through the drain pipe 71. It has become.

  According to this, when the air purified in the water tank 10 is supplied from the outlet 61 to the room 9, the air brings the water vapor from the water tank 10 into the room 9 by touching the stored water 11. When the air conditioner 70 cools the air in the room 9, the water vapor in the room 9 becomes condensed water, and the condensed water is introduced into the water tank 10 through the drain pipe 71. Therefore, the water taken out from the water tank 10 can be returned to the water tank 10.

(Second Embodiment)
Next, a second embodiment will be described with reference to FIG.

  The second embodiment is different from the first embodiment in that it has a configuration in which ozone is mixed into bubbles. In addition, about the part similar to 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  As shown in FIG. 4, the purification device of this embodiment includes an ozone generator 90. The ozone generator 90 can be, for example, ozone generating means having an ultraviolet lamp. The ozone generated by the ozone generator 90 is mixed into the air flowing through the intake pipe 27 via, for example, the pump 29. Therefore, when the water pump 28 is driven and the bubbles 12 are emitted from the aspirator 21, ozone is mixed in the bubbles 12.

  According to the configuration of the present embodiment, the same effects as those of the first embodiment can be obtained. Further, by mixing ozone into the bubbles 12, hydroxy radicals can also be generated by reacting ozone with the stored water 11 around the bubbles 12. Ozone alone has high oxidizing power, but coexists with water, that is, becomes ozone water, thereby generating hydroxy radicals with higher oxidizing power.

  Therefore, the amount of hydroxy radicals generated can be increased and the air can be purified more reliably. Moreover, the organic matter contained in the stored water 11 can be easily decomposed into carbon dioxide, water, etc., and the stored water 11 can also be purified reliably.

(Third embodiment)
Next, a third embodiment will be described with reference to FIG.

  The third embodiment is different from the first embodiment in that it has a configuration that also purifies the water in the water tank that contains aquatic organisms. In addition, about the part similar to 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  As shown in FIG. 5, in the container 8 of the present embodiment, a water tank 101, which is a water tank for storing seafood 102 that is an aquatic organism, is disposed. In the purification device of the present embodiment, the water pump 28 supplies water in the water tank 101 to the aspirator 21 through the water conduit 126.

  Further, in the air duct 60, a water conduit 226 for returning water from the water tank 10 to the water tank 101 is disposed. The upstream end of the water conduit 226 opens into the upper stored water 11 in the water tank 10. On the other hand, the downstream end of the water conduit 226 opens into the water in the water tank 101.

  The water pump 28 and the water conduit 126 correspond to water tank water introduction means for introducing the water in the stored water tank into the water storage tank. The water conduit 226 corresponds to stored water deriving means for deriving the stored water in the water storage tank into the storage water tank. The water guide pipe 226 is not limited to the pipe disposed in the air duct 60, and the water duct 10 and the water tank 101 may communicate with each other outside the air duct 60.

  Further, the downstream end of the water conduit 226 is not limited to one that opens into the upper water in the water tank 101. For example, the downstream end of the water conduit 226 may be located above the water surface of the water tank 101. In the case of such an arrangement, it is preferable to provide a pump means in the water conduit 226 or provide a check valve at the downstream end of the water conduit 226.

  Also in the purification apparatus of the present embodiment, the pump 29, the blower fan 62, the air conditioner 70, the drain pipe 71, the environment sensor 80, and the like described in the first embodiment may be employed. Further, the ozone generator 90 described in the second embodiment may be adopted.

  In the purification apparatus having the above-described configuration, when the water pump 28 is driven, a large number of fine bubbles 12 are generated in the stored water 11 by the action of the aspirator 21. At this time, the water containing the organic matter in the water tank 101 is supplied to the aspirator 21 through the water conduit 126 and the air containing the organic matter in the room 9 is sucked through the intake pipe 27. Therefore, a water stream containing organic matter in which a large number of fine bubbles 12 containing organic matter are formed is ejected from the aspirator 21 into the water tank 10.

  In the water tank 10, by irradiating the stored water 11 with ultrasonic waves by the vibrator 50, hydroxy radicals are generated in the stored water 11 when the fine bubbles 12 in the stored water 11 are crushed. By this hydroxy radical, the organic matter in the bubbles 12 is decomposed, and the organic matter in the stored water 11 brought from the water tank 101 is also decomposed. In this way, the air in the bubbles 12 and the stored water 11 are purified.

  The bubbles 12 in which the organic matter in the interior is decomposed rise in the stored water 11 and leave as air purified upward from the water surface of the stored water 11. Thus, the air purified in the water tank 10 flows through the air duct 60 and is blown out from the air outlet 61 to the room 9. On the other hand, the stored water 11 in which organic substances contained during the ascending in the water tank 10 are decomposed flows into the water conduit 226 at the upper part in the water tank 10 and is returned to the water tank 101 as purified water.

  At this time, a part of the purified air bubbles 12 also flows into the water conduit 226 and aeration in the water tank 101 can be performed. Even if there is no inflow of the bubbles 12 into the water conduit 226, a large number of fine bubbles 12 are formed in the stored water 11, so that water having an extremely high dissolved oxygen concentration is supplied to the water tank 101. Can do.

  According to the purification device of the present embodiment, the same effects as those of the first embodiment can be obtained. Furthermore, the stored water 11 in the water tank 10 contains organic substances, and the organic substances in the stored water 11 are also decomposed by the hydroxy radicals generated by the ultrasonic waves oscillated by the vibrator 50. That is, air purification and water purification can be performed simultaneously in the water tank 10.

  Further, a water guide pipe 126 that introduces water in the water tank 101 containing the seafood 102 into the water tank 10, and a water guide pipe 226 that guides the stored water 11 into the water tank 101 is provided. And the water in the water tank 101 is introduce | transduced in the water tank 10 with the water conduit 126, The stored water 11 will contain organic substance, and the organic substance contained in the water conduit 226 by the hydroxy radical was decomposed | disassembled here. The stored water 11 is led into the water tank 101.

  According to this, purification of the air in the room 9 of the container 8 and purification of the water in the water tank 101 can be performed simultaneously. Since the lifetime of hydroxy radicals generated in the water tank 10 is extremely short, the hydroxy radicals are not brought into the room 9 or the water tank 101. Therefore, the hydroxy radical does not adversely affect the seafood 102 in the aquarium 101.

  Further, the water conduit 226 guides the stored water 11 including the bubbles 12 into the water tank 101. According to this, the water in the water tank 101 can be aerated by the clean bubbles 12 purified in the water tank 10.

  Although the aquatic organism in the aquarium 101 was the seafood 102 which is a marine animal, it is not limited to this. For example, it may be a plant such as seaweed.

  Moreover, although the pipe member was employ | adopted for each tank water introduction means and the stored water derivation means, it is not limited to this. For example, when the water tank 10 and the water tank 101 are arranged adjacent to each other in the room 9, a porous partition plate having water permeability may be used for the water tank water introducing means and the stored water deriving means.

(Other embodiments)
The preferred embodiments of the present invention have been described above, but the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention.

  In each of the embodiments described above, the vibrator 50 that oscillates ultrasonic waves is used as the radical generating means, but the invention is not limited to this. For example, a configuration in which bubbles generated by a bubble generator are so-called nano bubbles having a diameter of less than 1 μm may be adopted. Since nanobubbles have a very large specific surface area, they are crushed by interfacial tension. Hydroxyl radicals are generated when the nanobubbles are crushed, the organic matter in the nanobubbles is decomposed, and the air in the nanobubbles is purified.

  Moreover, in each said embodiment, although the aspirator 21 was used for the bubble generator 20, it is not limited to this. For example, the indoor air pumped by the pump may be ejected into the stored water through the porous body to form bubbles in the stored water.

  Moreover, in each said embodiment, although the air which is purification object gas was made into the air of the room | chamber interior 9 of the movable container 8, it is not limited to this. For example, the air in the room of a stationary warehouse or house may be used, or the air in the room of a mobile vehicle.

  Moreover, in each said embodiment, although the purification apparatus was the structure which purifies the air of the room 9 and returns it to the room 9, it is not limited to this. For example, the outdoor air may be purified and blown into the room.

  Moreover, in each said embodiment, although the purification apparatus was arrange | positioned outdoors, it is not limited to this. The purification device may be disposed indoors.

  Moreover, in each said embodiment, although purification object gas was air, it is not limited to this. For example, it may be a gas such as nitrogen gas or helium gas purged in the chamber of the machine.

1 Purification device 10 Water tank (water tank)
11 Reserved water 12 Bubbles 20 Bubble generator (bubble generation means)
50 vibrator (radical generation means, ultrasonic irradiation means)

Claims (7)

A water tank (10) for storing the stored water (11) therein;
Bubble forming means (20) for forming fine bubbles (12) of the gas to be purified containing organic matter in the stored water;
Radical generating means (50) for generating hydroxy radicals in the stored water,
The organic radicals in the bubbles are decomposed by hydroxy radicals generated around the bubbles ,
A blowout port (61) for blowing out the purification target gas separated from the stored water into the room (9);
Cooling means (70) for cooling the gas in the room;
A purification apparatus comprising: condensed water introduction means (71) for introducing condensed water generated when the cooling means cools the indoor gas into the water storage tank . The stored water contains organic matter,
The purification apparatus according to claim 1 , wherein organic substances in the stored water are also decomposed by hydroxy radicals generated by the radical generating means. Aquarium water introduction means (126) for introducing water in the aquarium (101) that accommodates the aquatic organism (102) into the reservoir;
A stored water deriving means (226) for deriving the stored water into the containing water tank,
The water stored in the water storage tank is introduced into the water storage tank by the water tank water introducing means, so that the stored water contains organic matter,
The purifying apparatus according to claim 2 , wherein the stored water deriving unit derives the stored water obtained by decomposing an organic substance contained by hydroxy radicals into the stored water tank. A water tank (10) for storing the stored water (11) therein;
Bubble forming means (20) for forming fine bubbles (12) of the gas to be purified containing organic matter in the stored water;
Radical generating means (50) for generating hydroxy radicals in the stored water,
The organic radicals in the bubbles are decomposed by hydroxy radicals generated around the bubbles ,
The stored water contains organic matter,
The organic substance in the stored water is also decomposed by the hydroxy radical generated by the radical generating means,
Aquarium water introduction means (126) for introducing water in the aquarium (101) that accommodates the aquatic organism (102) into the reservoir;
A stored water deriving means (226) for deriving the stored water into the containing water tank,
The water stored in the water storage tank is introduced into the water storage tank by the water tank water introducing means, so that the stored water contains organic matter,
The purifying apparatus, wherein the stored water deriving means derives the stored water, in which organic substances contained by hydroxy radicals are decomposed, into the stored water tank . The purifying apparatus according to claim 3 or 4 , wherein the stored water deriving means derives the stored water containing the bubbles into the water tank. The purification apparatus according to any one of claims 1 to 5, wherein the radical generating unit is an ultrasonic irradiation unit that irradiates the stored water with ultrasonic waves. The said bubble formation means mixes ozone in the inside of the said bubble to form, The purification apparatus as described in any one of Claim 1 thru | or 6 characterized by the above-mentioned.

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