JP5523689B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner that can spray reduced water in which a reducing component is dissolved.

  Conventionally, for the purpose of anti-aging or long-term storage of foods, it has been performed to use reduced water (for example, hydrogen water or ascorbic acid aqueous solution) in which a reducing component (for example, hydrogen molecule or ascorbic acid) is dissolved. Yes.

Patent Document 1 proposes a hydrogen water supply device that can produce this type of reduced water. In this type of hydrogen water supply apparatus, a part of the water to be supplied to the dwelling unit is introduced into an electrolysis tank installed outside to be water containing hydrogen gas and oxygen gas. Thereafter, water containing hydrogen gas and oxygen gas is supplied to the dwelling unit in a state where it is mixed with water to be supplied to the dwelling unit.
JP 2005-105289 A

  By the way, this kind of hydrogen water supply apparatus is supplied to a dwelling unit in a state where water containing hydrogen gas and oxygen gas is mixed with water to be supplied to the dwelling unit. However, when aiming at anti-aging or long-term preservation of food, it is desirable to spray reduced water to every corner of the space. Therefore, it is desired to atomize the reduced water and spray it as reduced water mist. In addition, in order to spread the reduced water to every corner of the space, the reduced water is supplied to an air conditioner that cleans the air in the space and adjusts the temperature and humidity, such as an air purifier, a humidifier, and an air conditioner. It is desirable to have a built-in device for generating, atomizing and spreading.

  The present invention has been made to solve the above problems, and can perform a series of treatments of generation, atomization, and spraying of reduced water, and can spray the reduced water to every corner of the space. The object is to provide an air conditioner.

An air conditioner according to one aspect of the present invention includes a water acquisition unit that acquires water for generating reduced water, and a reduced water generation unit that generates the reduced water from the water acquired by the water acquisition unit. A reduced water atomization unit for atomizing the reduced water generated by the reduced water generation unit; and a spraying unit for spraying the reduced water atomized by the reduced water atomization unit as reduced water mist. it you characterized incorporating a becomes reduced water mist apparatus.

  According to this configuration, the air conditioner can perform a series of processes for generating reduced water from water, atomizing the generated reduced water, and spraying the atomized reduced water. Further, since the reduced water can be sprayed to every corner of the space, the reduced water can be sprayed to every corner of the target article such as skin, hair, food, etc. Can provide an antioxidant effect.

In the above configuration, the reduced water generation unit includes an ascorbic acid cartridge filled with ascorbic acid, and the reduced water passes through the ascorbic acid cartridge and is reduced water in which ascorbic acid is dissolved. Ru can be configured.

  According to this configuration, since the reduced water in which ascorbic acid is dissolved is sprayed, human immunity is improved. Collagen is also produced. In addition, cold prevention and early recovery can be achieved. In addition, resistance to stress is improved. In addition, the occurrence of carcinogenic substances is suppressed.

In the above-described configuration, the water acquisition unit compresses the refrigerant gas to a high temperature and a high pressure and then dissipates the heat to make the refrigerant liquid, and the cooling unit makes the refrigerant liquid vaporize after depressurizing the refrigerant liquid. with which, by cooling by the cooling section as possible out that by condensation of moisture in the air and configured to acquire the water.

  According to this configuration, water in the air is condensed by the cooling effect of the cooling unit to acquire water. Therefore, it is not necessary for the user to replenish the apparatus with water for generating reduced water.

In the above configuration, the water acquiring section, the cooling by the cooling surface, as possible out to the configuration comprising a Peltier element that acquires the water by condensation of moisture in the air.

  According to this configuration, since the volume of the apparatus is small and water can be acquired by a Peltier element that does not generate noise and vibration, the water acquisition unit can be made compact and noise and vibration are not generated in water acquisition.

In the above configuration, the water acquisition unit includes an adsorbent that adsorbs moisture in the air, and a heater that heats the adsorbent and desorbs the moisture adsorbed on the adsorbent. It is Ru can.

  According to this configuration, the adsorbent adsorbs moisture in the air, and the moisture adsorbed on the adsorbent is used for the generation of the acidic aqueous solution. Since it can be acquired from the air without being energized, power consumption can be suppressed.

In the above configuration, the reduced water generation unit generates an acidic component in water, and generates an acidic aqueous solution containing a cation and an anion generated by ionizing the acidic component generated in the water; A reduction component generation unit that generates electrons by reducing electrons by giving electrons to the cations contained in the acidic aqueous solution, and the reduction component generated by the reduction component generation unit is dissolved in water to reduce the reduction A reduced water generating unit that generates reduced water in which components are dissolved, and the acidic aqueous solution generating unit stores water for generating the acidic aqueous solution or the acidic aqueous solution, and has a through-hole in an outer wall. And a first electrode that is in contact with the water or the acidic aqueous solution stored in the storage portion, and a through hole that communicates with the through hole in the outer wall. A second electrode sandwiching the insulating spacer between the first electrode and the first electrode, and applying a high voltage to the first electrode and the second electrode to pass through the insulating spacer. The creeping discharge is performed by introducing air into the through hole of the insulating spacer and the discharge portion comprising a high voltage application unit for performing creeping discharge in the hole to generate the raw material of the acidic component. A blowing section that generates a raw material of the acidic component in the through hole that is generated, dissolves the raw material of the acidic component generated in the through hole in the water stored in the storage section, and generates the acidic component; , Ru can be configured to include a.

  According to this structure, an acidic aqueous solution production | generation part produces | generates an acidic component in water, and produces | generates the acidic aqueous solution containing the cation and anion which the said acidic component generated in the water ionizes and generate | occur | produces. In the acidic aqueous solution generation unit, the discharge unit applies a high voltage to the first electrode and the second electrode to perform creeping discharge through the through hole of the insulating space. Moreover, a ventilation part introduces ventilation to the through-hole of an insulation space, and generates a lot of foam which passes through the through-hole of an insulating spacer from the exterior of a storage part, and spreads to the water inside a storage part. Thereby, a large amount of the raw material of the acidic component is generated in the through hole of the insulating spacer.

  And the raw material of the acidic component produced | generated by the through-hole of this insulating spacer is introduce | transduced into a storage part through the through-hole of an outer wall by the ventilation by a ventilation part, and is dissolved in the water stored by the storage part, and is made into an acidic component. The The acidic component dissolved in water is ionized in water to become a cation and an anion, and as a result, the water stored in the storage part is made into an acidic aqueous solution having a high cation concentration.

  Moreover, according to this structure, a reducing component production | generation part produces | generates a reducing component by giving an electron to the cation contained in acidic aqueous solution, and reduce | restoring. The reduced water generating unit dissolves the reduced component generated by the reduced component generating unit in water to generate reduced water in which the reduced component is dissolved.

  Therefore, a process for generating an acidic aqueous solution, a process for generating a reduced component by applying electrons to cations contained in the acidic aqueous solution generated by the process, and a reducing component generated by the process are dissolved in water. If the treatment is sequentially performed, reduced water is generated, so that the reduced water can be easily generated. Further, in the acidic aqueous solution generation part, the discharge part is arranged in a state where the through hole of the insulating spacer communicates with the through hole of the outer wall formed in the storage part, so that the discharge part and the storage part can be made compact. Since it can be integrally formed, the entire apparatus can be made compact.

In the above configuration, the outer wall has been used as the insulating spacer, the through hole of the outer wall Ru can be configured to have been used as the through hole of the insulating spacer. Further, Ru can also be configured as the outer wall is used as the first electrode. According to these configurations, the number of components of the acidic aqueous solution generating section is reduced.

In the above configuration, the cation is a hydrogen ion, and the reducing component generation unit is composed of an element having a larger ionization tendency than hydrogen, and reduces the hydrogen ion contained in the acidic aqueous solution as the reducing component. and a reducing agent to generate hydrogen molecules, an adjustment unit for adjusting the production amount of the hydrogen molecules, as possible out to the configuration with.

  According to this configuration, the reducing component generation unit is configured with an element that has a greater ionization tendency than hydrogen, and a reducing substance that generates hydrogen molecules as a reducing component by reducing cations contained in the acidic aqueous solution is used. A control unit is provided for adjusting the reduction amount of the generated hydrogen molecule.

  Therefore, the reduced water mist spraying device can easily reduce hydrogen ions contained at a high concentration in the acidic aqueous solution to generate hydrogen molecules. In addition, since the amount of hydrogen molecules generated based on hydrogen ions contained at a high concentration can be arbitrarily and easily adjusted, hydrogen water having a wide range of hydrogen concentrations can be easily generated as reduced water. it can.

In the above configuration, the reducing agent, as possible out to the configuration that is detachable to the adjusting unit. According to this configuration, when the reducing substance reduces hydrogen ions and the volume of the reducing substance decreases, the reducing substance with the reduced volume is removed from the adjustment unit, and a new reducing substance is attached to the adjustment unit. Can do.

In the above configuration, the reducing agent, as possible out to the configuration range is immersed in the acidic aqueous solution by the adjusting unit is adjustable. According to this configuration, the amount of hydrogen molecules generated can be freely adjusted by adjusting the range in which the reducing substance is immersed in the acidic aqueous solution.

The said structure WHEREIN: The said reduced water production | generation unit is equipped with the anode and cathode which electrolyze the said water acquired by the said water acquisition part, It is set as the structure which produces | generates hydrogen water as said reduced water in the said cathode. kill at.

  According to this configuration, since the functions of the acidic aqueous solution generation unit, the reduction component generation unit, and the reduced water generation unit are integrated in the anode and the cathode, the structure of the reduced water generation unit is simplified and downsized. Can be achieved. Moreover, since hydrogen water is produced as reduced water by electrolyzing water with the anode and the cathode, a reducing substance for producing a reducing component is not necessary, and the user does not need to replenish the reducing substance. .

In the above configuration, the reduced water atomizing section, as possible out be configured to include an ultrasound radiating element to atomize radiates ultrasonic waves to the reduced water. According to this configuration, droplets having a particle size of nanometer size can be dispersed.

In the above configuration, the reduced water atomizing section, generates a surface acoustic wave, wherein the surface acoustic wave as possible out to the configuration including the surface acoustic wave generating unit for atomizing the reduced water. According to this configuration, since the vibration surface on which the surface acoustic wave propagates can be positioned at the same height as the water surface of the reducing water, the apparatus can be made compact.

In the above configuration, the reduced water atomizing section, as possible out to the configuration including the electrostatic atomizer for atomizing the reduced water by a high electric field generated by high voltage is applied. According to this configuration, a large amount of droplets having a nanometer size can be dispersed.

The said structure WHEREIN: The said reduced water atomization part shall be a structure provided with the pressurization part which pressurizes the said reduced water, and the small hole for inject | pouring the said reduced water pressurized by the said pressurization part. There kill in. According to this structure, a large amount of reduced water can be atomized.

In the above configuration, the spray unit, as possible out be configured to spray the reduced water for the whole space. According to this configuration, since the reducing water can be diffused and dispersed over the entire space, an antioxidant effect can be imparted to all target articles in the space.

In the above configuration, the spray unit, as possible out be configured sparging the directionally the reduced water for some space. According to this structure, since the area | region which spread | sprinks reducing water can be limited and can be sprayed, a large amount of reducing water can be sprayed to target object pinpointly.

The said structure WHEREIN: The said spreading | diffusion part is equipped with the detection part which detects presence of a human body, and it can be set as the structure which spreads the said reduced water directionally with respect to the direction of the said human body which the said detection part detected. Yes. According to this configuration, it is possible to automatically detect the presence of a human body and spray reduced water in a pinpoint direction toward the human body.

  ADVANTAGE OF THE INVENTION According to this invention, an air conditioner can produce | generate reduced water from water, can atomize the produced | generated reduced water, and can perform a series of processes which spray the atomized reduced water. Further, since the reduced water can be sprayed to every corner of the space, the reduced water can be sprayed to every corner of the target article such as skin, hair, food, etc. Can provide an antioxidant effect.

  Hereinafter, an air conditioner according to an embodiment of the present invention will be described. FIG. 1 is a block diagram illustrating an example of a functional configuration of a reduced water mist spraying device built in an air conditioner according to an embodiment of the present invention. A reduced water mist spraying device 1 shown in FIG. 1 is built in an air conditioner X, and includes a reduced water generation unit U, a water acquisition unit 3, a reduced water atomization unit 6, and a spraying unit 7. .

  In the reduced water mist spraying apparatus 1, the water acquisition unit 3 uses water for generating reduced water in which reduced components obtained by reducing cations generated by ionizing acidic components (described later) in water are dissolved. get. This eliminates the need for the user to replenish water for generating reduced water. Moreover, the reduced water atomization part 6 atomizes the reduced water produced | generated by the reduced water production | generation unit U, and the spreading | spreading part 7 makes reduced water mist the reduced water atomized by the reduced water atomization part 6 after that. Scatter as. Therefore, it is possible to spray reduced water in the space.

  In the reduced water mist spraying apparatus 1, the reduced water generation unit U generates reduced water from the water acquired by the water acquisition unit 3. Such a reduced water generating unit U includes an acidic aqueous solution generating unit 2, a reducing component generating unit 4, and a reduced water generating unit 5.

  In the reduced water generating unit U, the acidic aqueous solution generating unit 2 generates an acidic component in water, and generates an acidic aqueous solution containing cations and anions generated by ionizing the acidic component generated in water. Examples of the acidic component include hydrogen peroxide and nitric acid. When these hydrogen peroxide and nitric acid are dissolved in water, at least hydrogen ions are generated as cations.

  Moreover, the reducing component production | generation part 4 gives an electron to the cation contained in acidic aqueous solution, and reduce | generates, and produces | generates a reducing component. That is, since the acidic component is ionized in the acidic aqueous solution, the acidic aqueous solution contains at least a cation generated from the acidic component. Here, the cation generated from the acidic component is a hydrogen ion when the acidic component is hydrogen peroxide or nitric acid. In this case, the reducing component generator 4 gives electrons to hydrogen ions generated from hydrogen peroxide or nitric acid ionized by being dissolved in the acidic aqueous solution and reduces the hydrogen ions to generate hydrogen molecules as reducing components.

  Moreover, the reduced water production | generation part 5 melt | dissolves the reduced component produced | generated by the reduced component production | generation part 4 in water, and produces | generates the reduced water by which the reduced component was melt | dissolved. Here, the reduced water is hydrogen water in the present embodiment.

  Such reduced water generation unit U may include an ascorbic acid cartridge filled with ascorbic acid. That is, the ascorbic acid filled in the ascorbic acid cartridge is dissolved in the reduced water generated in the reduced water generation unit U, so that the reduced water is reduced water in which ascorbic acid is dissolved. For example, an ascorbic acid cartridge is attached to the subsequent stage of the reduced water generation unit 5, and the reduced water generated by the reduced water generation unit 5 is converted into reduced water in which ascorbic acid is dissolved and sent to the reduced water atomization unit 6. Can be. Thus, since the reduced water is reduced water in which ascorbic acid is dissolved, the following effects can be given to a person who has been sprayed with such reduced water. For example, a person's immunity improves. Collagen is also produced. In addition, cold prevention and early recovery can be achieved. In addition, resistance to stress is improved. In addition, the occurrence of carcinogenic substances is suppressed.

  FIG. 2 is a diagram illustrating an example of a specific configuration of the reduced water mist spraying apparatus. Hereinafter, the reduced water mist spraying apparatus 1 shown in FIG. 2 is referred to as “specific configuration example 1” in the present specification.

  Specific configuration examples 1 to 3 shown below mainly show various configuration examples of the water acquisition unit 3. In addition, a specific configuration example 4 shown below mainly illustrates a configuration example of the acidic aqueous solution generation unit 2. Specific configuration examples 5 to 8 shown below mainly show various configuration examples of the reduced water atomization unit.

[Specific Configuration Example 1]
In the reduced water mist spraying apparatus 1 shown in FIG. 2, the water acquisition unit 3 includes a heat radiating unit 34 that compresses the refrigerant gas to a high temperature and a high pressure and then radiates the refrigerant gas to form a refrigerant liquid. And a cooling unit 37. That is, the water acquisition unit 3 includes a heat exchanger having a heat radiating unit 34 and a cooling unit 37.

  In such a water acquisition unit 3, the heat radiating unit 34 and the cooling unit 37 are provided in the refrigeration cycle unit F. The heat radiating section 34 includes a compressor 35 that compresses the refrigerant gas to a high temperature and a high pressure, and a condenser 36 that cools the refrigerant gas to a refrigerant liquid by radiating the high temperature and pressure refrigerant.

  The cooling unit 37 includes an expansion valve 30 that depressurizes and evaporates the refrigerant liquid dried by the dryer D, an evaporator 31 that evaporates the depressurized refrigerant liquid to generate refrigerant gas, and an evaporator 31. The heat conducting member 32 provided in contact with the heat conducting member 32 and the condensed water generating part 33 provided in contact with the heat conducting member 32 are provided.

  In such a cooling unit 37, the dew condensation water generation unit 33, the heat conduction member 32, and the evaporator 31 are thermally connected, and the effect of cooling by the evaporator 31 is caused by the dew condensation water through the heat conduction member 32. The generation unit 33 is reached. As a result, the condensed water generating unit 33 is cooled, the air around the condensed water generating unit 33 is cooled, and condensed water (hereinafter simply referred to as “water”) W adheres to the surface of the condensed water generating unit 33. In addition, the dew condensation water generation part 33 and the heat conductive member 32 may be integrally formed. Further, the heat conduction member 32 may be fixed to the dew condensation water generation unit 33. Further, the heat conducting member 32 may be in contact with the dew condensation water generation unit 33. In any case, a configuration in which heat can be exchanged between the condensed water generation unit 33 and the heat conduction member 32 with high efficiency is preferable.

  The water W generated in the condensed water generation unit 33 by such a cooling unit 37 flows into the water tank T and is sucked up by the acidic aqueous solution generation unit 2. The water W sucked up by the acidic aqueous solution generation unit 2 is converted into reduced water M3 by the reduced water generation unit U, that is, the acidic aqueous solution generation unit 2, the reduced component generation unit 4, and the reduced water generation unit 5. The reduced water M3 is atomized by the reduced water atomization unit 6 and is sprayed as reduced water mist by blowing air from a blower fan configured as the spraying unit 7.

  According to such water acquisition means 3, since the water in the air is condensed by the cooling effect of the cooling unit 37 to acquire water, it is not necessary for the user to replenish water for generating the reduced water M3.

  FIG. 3 is a diagram showing a specific configuration example 2 of the reduced water mist spraying apparatus. In addition, the same code | symbol as the code | symbol shown in FIG. 2 is attached | subjected to the element same as the reducing water mist spraying apparatus 1 shown in FIG. Moreover, description is abbreviate | omitted.

[Specific Configuration Example 2]
In the reduced water mist spraying apparatus 1 shown in FIG. 3, the water acquisition unit 3 includes a Peltier element 38 that acquires water by condensing moisture in the air by cooling with the cooling surface 40.

  The Peltier element 38 includes the cooling surface 40 and the heat radiating surface 42. A condensed water generator 33 is attached to the cooling surface 40. In addition, the cooling surface 40 and the dew condensation water generation part 33 should just be thermally connected. On the other hand, heat radiation fins 43 are attached to the heat radiation surface 42.

  In such a water acquisition unit 3, when the Peltier device 38 is energized by the Peltier device power supply 41, the cooling surface 40 of the Peltier device 38 is cooled, and the cooling effect reaches the condensed water generation unit 33. Therefore, the dew condensation water generation unit 33 is also cooled, the air around the dew condensation water generation unit 33 is cooled, and the water W adheres to the surface of the dew condensation water generation unit 33. On the other hand, heat is generated from the heat radiation surface 42 of the Peltier element 38, but the heat is radiated by the heat radiation fins 43.

  The water W generated in the dew condensation water generation unit 33 by such a Peltier element 38 flows into the water tank T and is sucked up by the acidic aqueous solution generation unit 2. The water W sucked up by the acidic aqueous solution generation unit 2 is converted into reduced water M3 by the reduced water generation unit U, that is, the acidic aqueous solution generation unit 2, the reduced component generation unit 4, and the reduced water generation unit 5. The reduced water M3 is atomized by the reduced water atomization unit 6. The reduced water M3 atomized by the reduced water atomization unit 6 is sprayed as reduced water mist by blowing by a blower fan configured as the spraying unit 7.

  According to such a water acquisition part 3, since the volume of the apparatus is small and water can be acquired by the Peltier element 38 which does not generate noise and vibration, the water acquisition part 3 can be made compact and noise can be acquired in water acquisition. And vibration does not occur.

  FIG. 4 is a diagram illustrating a specific configuration example 3 of the reduced water mist spraying apparatus. In addition, the same code | symbol as the code | symbol shown in FIG. 2 is attached | subjected to the element same as the reducing water mist spraying apparatus 1 shown in FIG. Moreover, description is abbreviate | omitted.

[Specific Configuration Example 3]
In the reduced water mist spraying apparatus 1 shown in FIG. 4, the water acquisition unit 3 includes an adsorbent 45 that adsorbs moisture in the air, and a heater that heats the adsorbent 45 and desorbs moisture adsorbed on the adsorbent 45. 49. Here, the adsorbent 45 is preferably, for example, zeolite.

  In such a water acquisition unit 3, a water tank T made of a hard material such as polypropylene is provided in the lower part of the housing 51, and the upper opening Ta of the water tank T is closed by the adsorbent 44. .

  The adsorbent 44 includes a main adsorbent 45, a hard back plate 46 having water permeability such as a net disposed on the back side of the adsorbent 45, and a transparent disposed on the front side of the adsorbent 45. It is composed of a wet and water-impermeable film 47. The back plate 46 is supported by a receiving portion 48 provided in the upper opening Ta of the water tank T, the adsorbent 45 is filled on the back plate 46, and the upper end of the upper opening Ta is sealed with a film 47. ing. A heater 49 is provided in the adsorbent 44.

  The adsorbent 44 is fitted with a water transport unit 50, the lower end of the water transport unit 50 is positioned below the water tank T, and the upper end of the water transport unit 50 is the upper part of the housing 51. Is located.

  Such a water conveyance part 50 is made into the shape of a rod, and is formed with a thin hole for conveying water accumulated in the water tank T to the tip (upper end) by capillary action or a porous material. Has been.

  In such a water acquisition part 3, the water | moisture content in air is adsorb | sucked by the adsorbent 45 through the film 47, as shown with the broken line arrow. In order to desorb moisture from the adsorbent 45 that has adsorbed moisture in the air in this way, the heater 49 is energized. Then, moisture is desorbed from the adsorbent 45 heated by the heater 49. The water desorbed from the adsorbent 45 flows into the water tank T from the back plate 46 and accumulates. On the other hand, to cause the adsorbent 45 to adsorb moisture, the energization to the heater 49 is stopped.

  The water W collected in the water tank T in this way is sent to the acidic aqueous solution generation unit 2 by capillary action in the water transport unit 50. The water W sent to the acidic aqueous solution generator 2 is converted into reduced water M3 by the reduced water generator unit U, that is, the acidic aqueous solution generator 2, the reduced component generator 4, and the reduced water generator 5. The reduced water M3 is atomized by the reduced water atomization unit 6. The reduced water M3 atomized by the reduced water atomization unit 6 is sprayed as reduced water mist by blowing by a blower fan configured as the spraying unit 7.

  According to this configuration, the adsorbent 45 adsorbs moisture in the air, and the moisture adsorbed on the adsorbent 45 is used for generating the reduced water M3. Therefore, water for generating the reduced water M3 is used. Can be acquired from the air without energizing the device, so that power consumption can be suppressed.

  FIG. 5 is a diagram showing a specific configuration example 4 of the reduced water mist spraying apparatus. In addition, the same code | symbol as the code | symbol shown in FIG. 2 is attached | subjected to the element same as the reducing water mist spraying apparatus 1 shown in FIG. Moreover, description is abbreviate | omitted.

[Specific Configuration Example 4]
Hereinafter, the descriptions of “upstream” and “downstream” indicate upstream and downstream with respect to the air blown from the blower unit 26, respectively.

  In the reduced water mist spraying apparatus 1 shown in FIG. 5, the acidic aqueous solution generation unit 2 includes a storage unit 20, a discharge unit 25, and a blower unit 26. In such an acidic aqueous solution generation unit 2, the storage unit 20 is also provided as the water acquisition unit 3 shown in FIG. 1, and stores water that is a raw material of the acidic aqueous solution M1 or the acidic aqueous solution M1. Such a reservoir 20 is a tank arranged in close contact with the downstream side of the discharge part 25, and its internal space communicates with the through hole 21 a of the insulating spacer 21.

  Further, in the acidic aqueous solution generation unit 2, the discharge unit 25 is formed integrally with the storage unit 20, and an insulating spacer 21 having a minute through hole 21 a and an upstream electrode (on the upstream side of the insulating spacer 21 ( (Second electrode) 22, a downstream electrode (first electrode) 23 disposed on the downstream side of insulating spacer 21, upstream electrode 22, and downstream electrode 23, and a high voltage is applied to insulating spacer 21. A high voltage application unit 24 for generating creeping discharge in the through hole 21a and generating a raw material of an acidic component in the through hole 21a. The upstream electrode 22 and the downstream electrode 23 are made of a conductor such as metal.

  Moreover, in the discharge part 25, the insulating spacer 21 is in contact with the water or acidic aqueous solution M1 stored in the storage part 20, and is an outer wall that separates the storage part 20 from the external space. The through hole 21a of the insulating spacer 21 is a through hole in the outer wall.

  In addition, the structure shown below may be sufficient as a discharge part. That is, the downstream electrode (first electrode) 23 is in contact with the water or acidic aqueous solution M1 stored in the storage unit 20, and is an outer wall that separates the storage unit 20 from the external space. The downstream electrode 23 has a through hole (not shown) in the outer wall. The through hole 21a of the insulating spacer 21 communicates with such a through hole. Such a configuration can also provide the following effects.

  In such a discharge part 25, the insulating spacer 21 is made of a nonconductor such as a ceramic board, and is sandwiched between the upstream electrode 22 and the downstream electrode 23. In addition, the hole diameter of the through-hole 21a which the insulating spacer 21 has is about several tens of micrometers-several mm, Preferably, it is several hundred micrometers. In addition, since the through hole 21a is provided with a very small diameter of about several hundreds μm, it is ensured that water stored in the storage unit 20 enters the through hole 21a while ensuring air circulation. Can be prevented by surface tension.

  The upstream electrode 22 and the downstream electrode 23 are connected to the high voltage application unit 24. A high voltage for microplasma discharge is applied to the upstream electrode 22 and the downstream electrode 23 by the high voltage application unit 24. As a result, creeping discharge occurs in the through-hole 21 a of the insulating spacer 21 sandwiched between the upstream electrode 22 and the downstream electrode 23.

  Further, in the acidic aqueous solution generation unit 2, the air blowing unit 26 is provided on the upstream side of the discharge unit 25, and introduces air into the through hole 21 a of the insulating spacer 21. Thereby, a large amount of bubbles B can be generated from the outside of the storage unit 20 through the through-holes 21 a to the water stored in the storage unit 20, and creeping discharge is generated by the discharge of the discharge unit 25. A large amount of the raw material of the acidic component is generated in the generated through-hole 21a.

  And the raw material of the acidic component produced | generated in large quantities by this through-hole 21a was introduce | transduced into the storage part 20 arrange | positioned by communicating with the penetration part 21a by the ventilation by the ventilation part 26, and was stored by the storage part 20 Dissolved in water.

  When the acidic component is hydrogen peroxide or nitric acid as described above, examples of the raw material for the acidic component include superoxide radicals, hydroxy radicals, nitrogen oxides, and nitrate ions. The raw material of such an acidic component dissolves in the water stored in the storage unit 20 to generate hydrogen peroxide and nitric acid.

  That is, superoxide radicals and hydroxy radicals are dissolved in water to generate hydrogen peroxide, and the water stored in the storage unit 20 is transformed into water in which hydrogen peroxide is dissolved. Further, nitrogen oxides and nitrate ions dissolve in water to generate nitric acid, and the water stored in the reservoir 20 is transformed into water in which nitric acid is dissolved. When the water stored in the reservoir 20 is transformed into water in which hydrogen peroxide and nitric acid are dissolved, the hydrogen peroxide and nitric acid are ionized into cations and anions, so that at least positive The water contains hydrogen ions as ions.

  According to such an acidic aqueous solution generation unit 2, the discharge unit 25 is arranged on the upstream side of the storage unit 20 with the through hole 21 a included in the insulating spacer 21 communicating with the storage unit 20. 25 and the storage part 20 can be integrally formed in a compact manner, so that the entire apparatus can be made compact.

  Moreover, since the raw material of an acidic component is melt | dissolved in the water in the storage part 20 with high concentration by the discharge part 25 and the ventilation part 26, the acidic aqueous solution M1 in which the cation was contained in high concentration can be produced | generated.

  In the acidic aqueous solution generator 2 described above, the downstream electrode 23 is an outer wall that separates the reservoir 20 from the external space. The insulating spacer 21 is an outer wall that separates the storage portion 20 from the external space, and the through hole 21a of the insulating spacer 21 is a through hole of the outer wall.

  Moreover, in the reduced water mist spraying apparatus 1 shown in FIG. 5, the reducing component production | generation part 4 is comprised with an element with a larger ionization tendency than hydrogen, reduces the hydrogen ion contained in acidic aqueous solution M1, and uses hydrogen as a reducing component. A reducing substance 4A that generates molecules and a controller 4B that adjusts the amount of hydrogen molecules generated are provided.

  In such a reducing component generation unit 4, the reducing substance 4A is zinc in the present embodiment. In addition, the reducing substance 4A includes a substance composed of an element having a higher ionization tendency than hydrogen other than zinc. The adjusting unit 4B is detachably attached to the reducing substance 4A, and has a function of adjusting a range in which the reducing substance 4A is immersed in the acidic aqueous solution M1. In addition, the adjustment part 4B is an adjustment bar which can move up and down in the internal space of the storage part 20 in this embodiment. However, the adjustment unit 4B is not limited to a configuration that moves up and down in the internal space of the storage unit 20.

  That is, the adjustment unit 4B includes a mechanism that can adjust the range in which the reducing substance 4A is immersed in the acidic aqueous solution M1. For example, the range in which the reducing substance 4A is immersed in the acidic aqueous solution M1 may be adjusted by rotating the adjusting unit 4B to adjust the angle of the reducing substance 4A with respect to the liquid surface of the acidic aqueous solution M1. Further, the adjustment unit 4B may be rotated not by manual operation but by rotation of a motor.

  In such a reducing component generation unit 4, the reducing substance (zinc) 4 </ b> A is immersed in the acidic aqueous solution M <b> 1 as the adjusting unit (adjusting rod) 4 </ b> B moves up and down in the internal space of the storage unit 20. Is big or small.

  In the reducing substance (zinc) 40, the range immersed in the acidic aqueous solution M1 reduces hydrogen ions contained in the acidic aqueous solution M1. That is, in the reducing substance (zinc) 4A, the range immersed in the acidic aqueous solution M1 gives electrons to the hydrogen ions generated by the acidic components ionized in the acidic aqueous solution M1, and becomes itself zinc ions. As a result, hydrogen ions receive electrons and become hydrogen atoms, and two hydrogen atoms are bonded together to form hydrogen molecules.

  According to such a reducing component generation unit 4, hydrogen ions contained in the acidic aqueous solution M1 at a high concentration can be easily reduced to generate hydrogen molecules as the reducing component M2. In addition, since the amount of hydrogen molecules generated based on hydrogen ions contained at a high concentration can be arbitrarily and easily adjusted, hydrogen water having a wide range of hydrogen concentrations can be easily generated as the reduced water M3. Can do.

  Further, in the reducing water mist spraying apparatus 1 shown in FIG. 5, a reducing component supply pipe T is led out from a position corresponding to a position just above the reducing substance 4 </ b> A in the storage unit 20. And the reduced water production | generation part 5 is connected. Here, since the hydrogen molecule as the reducing component M2 has a specific gravity much smaller than that of air, the hydrogen molecule rises almost directly above the reducing material 4A. Therefore, as described above, the reducing component supply pipe T has a substantially true value of the reducing material 4A. Derived from above.

  The reducing component supply pipe T is provided with a pump 8A, and this pump 8A sends the reducing component M2 to the reduced water generator 5. Thereby, the reducing component M2 is introduce | transduced into the reducing water production | generation part 5, and the reducing water M3 is produced | generated.

  Further, in the reduced water mist spraying apparatus 1 shown in FIG. 5, a reduced water supply pipe 9 is led out from the reduced water generating section 5, and the reduced water atomizing section 6 is connected via the reduced water supply pipe 9. ing. The reduced water supply pipe 9 is provided with a pump 8B, and this pump 8B sends the reduced water M3 to the reduced water atomization section 6. The reduced water atomization unit 6 atomizes the reduced water M3 sent from the reduced water generation unit 5 by the pump 8B in a mist form. The reduced water M3 atomized by the reduced water atomization unit 6 is sprayed as reduced water mist by the spray unit 7.

  According to such a reduced water generator 1, the process of generating the acidic aqueous solution M1, the process of generating a reducing component by giving electrons to the cations contained in the acidic aqueous solution M1 generated by the process and reducing the cation, If the process which dissolves the reducing component produced | generated by the process in water is performed sequentially, since the reduced water M3 will generate | occur | produce, the reduced water M3 can be generated easily.

  FIG. 6 is a diagram showing a specific configuration example 5 of the reduced water mist spraying apparatus. In addition, the same code | symbol as the code | symbol shown in FIG. 2 is attached | subjected to the element same as the reducing water mist spraying apparatus 1 shown in FIG. Moreover, description is abbreviate | omitted.

[Specific Configuration Example 5]
In the reduced water mist spraying apparatus 1 shown in FIG. 6, the reduced water atomizing unit 6 includes a surface acoustic wave generating unit 64 that generates surface acoustic waves and atomizes the reduced water M3 by the surface elastic waves. Such a surface acoustic wave generation unit 64 is provided at one end of one surface of the substrate 61 and is constituted by a vibrator to which a high frequency power source is connected. In such a surface acoustic wave generator 64, when the vibrator vibrates, the vibration wave propagates as a surface acoustic wave on the one surface of the substrate 61.

  On the other hand, a concave water reservoir 20 is provided at the other end of the one surface of the substrate 61, and the water reservoir 20 is immersed in the water W while the water W is accumulated in the water reservoir 20. An anode 53 and a cathode 54 are provided. The anode 53 and the cathode 54 have a function of electrolyzing the water W collected in the water reservoir 20 to generate reduced water (here, hydrogen water) M3 on the cathode 54 side. That is, the anode 53 and the cathode 54 are the functions of the reduced water generation unit U, that is, the acidic aqueous solution generation unit 2, the reduced component generation unit 4, and the reduced water generation unit 5, which are described above. .

  Further, in such a reduced water generator 1, the water acquisition unit 3 includes the Peltier element 38, and when the Peltier element 38 is energized, the water acquisition unit 3 is in the air due to the cooling effect of the cooling unit 40 of the Peltier element 38. Water W is obtained by condensing the water. The acquired liquid W moves through the capillary tube 52 by capillary action and is sent to the water reservoir 20 on the substrate 61.

  According to such a reduced water generator 1, the water W acquired by energizing the Peltier element 38 is electrolyzed by the anode 53 and the cathode 54 and reduced water M3 (here, hydrogen water) on the cathode 54 side. It becomes. The reduced water M3 is atomized by the surface acoustic wave generated by the surface acoustic wave generating unit 64 and propagated on the substrate 61 to be reduced water mist. The reduced water M3 is reduced by the blower fan configured as the spraying unit 7 as reduced water mist. Be sprayed.

  According to such a reduced water mist spraying apparatus 1, since the vibration surface on which the surface acoustic wave propagates can be positioned at the same height as the water surface of the reduced water M3, the apparatus 1 can be made compact.

  In such a reduced water mist spraying apparatus 1, the water acquisition unit 3 is not limited to a configuration that acquires the water W by energizing the Peltier element 38. For example, the structure which uses the cooling part of the heat exchanger illustrated in the specific structural example 1 and the structure which uses the moisture adsorption effect by the adsorbent 45 illustrated in the specific structural example 2 can be given.

  FIG. 7 is a diagram illustrating a specific configuration example 6 of the reduced water mist spraying apparatus. In addition, the same code | symbol as the code | symbol shown in FIG. 2 is attached | subjected to the element same as the reducing water mist spraying apparatus 1 shown in FIG. Moreover, description is abbreviate | omitted.

[Specific Configuration Example 6]
In the reduced water mist spraying apparatus 1 shown in FIG. 7, the reduced water atomization unit 6 includes an ultrasonic radiation element 60 that emits ultrasonic waves to the reduced water M3 to atomize the reduced water M3. Such an ultrasonic radiating element 60 includes a substrate 61, a heat insulating layer 62, and a heating element 63.

  In the ultrasonic radiation element 60, the substrate 61 is made of, for example, a silicon substrate. The heat insulating layer 62 is formed on one surface side in the thickness direction of the substrate 61, and is made of a porous silicon layer having a sufficiently smaller thermal conductivity than the substrate 61. The heat generating layer 63 is formed on the heat insulating layer 62 and is made of a metal thin film (for example, a gold thin film) having a higher thermal conductivity and conductivity than the heat insulating layer 62.

  In such an ultrasonic radiating element 60, ultrasonic waves are generated by heat exchange between the heating element 63 and a medium (for example, air) accompanying energization of an alternating current to the heating element 63.

  By such an ultrasonic radiation element 60, ultrasonic waves are radiated to the reduced water M3 generated by the reduced water generator 5. Thereby, the liquid level of the reducing water M3 is atomized sequentially. As a result, since a large number of droplets having a particle size of nanometer size are generated, the spraying unit 7 can spray such a large amount of droplets as reduced water mist.

  FIG. 8 is a diagram illustrating a specific configuration example 7 of the reduced water mist spraying apparatus. In addition, the same code | symbol as the code | symbol shown in FIG. 2 is attached | subjected to the element same as the reducing water mist spraying apparatus 1 shown in FIG. Moreover, description is abbreviate | omitted.

[Specific Configuration Example 7]
In the reduced water mist spraying apparatus 1 shown in FIG. 8, the reduced water atomization unit 6 includes a discharge electrode 65, a counter electrode 66, a reduced water supply pipe 67 that supplies reduced water M <b> 3 to the discharge electrode 65, and a discharge electrode 65. A high voltage applying unit 68 for applying a high voltage.

  In such a reduced water atomization unit 6, the reduced water M <b> 3 that has flowed into the reduced water supply pipe 67 passes through the reduced water supply pipe 67 and is sent to the tip 65 a of the discharge electrode 65.

  When a high voltage is applied between the discharge electrode 65 and the counter electrode 66 by the high voltage application unit 68 in a state where the reduced water M3 is supplied to the discharge electrode 65 in this way, the discharge electrode 65 and the counter electrode An electric field is generated between the first electrode 66 and the reduced water M3 supplied to the tip 65a of the discharge electrode 65.

  As a result, a Coulomb force acts between the reducing water M3 supplied to the tip 65a of the discharge electrode 65 and the counter electrode 66, and the liquid level of the reducing water M3 rises locally in a cone shape. The tail cone T is where the liquid surface of the reduced water M3 rises locally in a conical shape.

  When the tailor cone T is formed in this way, electric charges concentrate on the tip of the tailor cone T, the electric field strength at the tip of the tailor cone T increases, and the Coulomb force generated at the tip of the tailor cone T increases. Then, the tailor cone T grows further.

  When the tailor cone T grows in this way and the charge concentrates on the tip of the tailor cone T and the density of the charge becomes high, the reduced water M3 at the tip of the tailor cone T has a large energy (charge with a high density). Repulsion force) and repeats splitting and scattering (Rayleigh splitting) exceeding the surface tension. As a result, a large amount of reduced water M3 having a nanometer size particle size is generated.

  According to such a reduced water mist spraying apparatus 1, droplets having a nanometer size can be sprayed in large quantities as reduced water mist by the spraying unit 7. In addition, in the reducing water mist spraying apparatus 1 shown in FIG. 8, although the electrostatic atomization part is comprised by the discharge electrode 65 and the counter electrode 66, the counter electrode 66 does not necessarily need to be provided but discharge. The electrostatic atomization part may be comprised only by the electrode 65. FIG. Even in this case, a discharge is generated in the discharge electrode 65, and the electrostatically atomized reduced water M3 is sprayed toward the housing (not shown).

  9 and 10 are diagrams showing a specific configuration example 8 of the reduced water mist spraying apparatus. In addition, the same code | symbol as the code | symbol shown in FIG. 2 is attached | subjected to the element same as the reducing water mist spraying apparatus 1 shown in FIG. Moreover, description is abbreviate | omitted.

[Specific Configuration Example 8]
FIG. 9 is a diagram showing a specific configuration example 8 of the reduced water mist spraying device, FIG. 9A is a diagram showing a case where the reduced water mist spraying device is viewed from above, and FIG. 9B is a reduced water mist. It is a side view of a spreading device.

  In the reduced water mist spraying apparatus 1 shown in FIG. 9, the reduced water atomizing unit 6 is for injecting the pressurized water (pump) 17 that pressurizes the reduced water M3 and the reduced water M3 pressurized by the pump 17. A small hole 18.

  In the reduced water mist spraying apparatus 1 shown in FIG. 9, when the Peltier element 38 is energized, moisture in the air around the cooling surface 40 is condensed due to the cooling effect of the cooling surface 40 of the Peltier element 38, and condensed water (Water W). Such water W is sent to the water reservoir 20 on the substrate 61 through the capillary 92 by a capillary phenomenon. The water W sent to the water reservoir 20 is electrolyzed by the electrolyzing means 90 including the anode 53 and the cathode 54, and hydrogen water is generated as reduced water M3. The generated reduced water M3 is sent to the pump 17 through the capillary 92 by capillary action.

  The reduced water M3 sent to the pump 17 is pressurized, reaches the small hole 18 through the pressurized water pipe 93, and is sprayed from the small hole 18 as reduced water mist. That is, in the reduced water mist spraying apparatus 1 shown in FIG. 9, the pump 17 and the small hole 18 are the reduced water atomization unit 6 and the spray unit 7.

  According to such a reduced water mist spraying apparatus 1, the reduced water M3 can be atomized in large quantities.

  FIG. 10 is a diagram for explaining the operation of the pump (pressurizing unit) 17, FIG. 10 (a) is a diagram for explaining the operation at the time of inhaling the reduced water M 3, and FIG. 10 (b) is the reduction. The figure for demonstrating the operation | movement at the time of discharge | emission of water M3 is each shown.

  In the pump 17 shown in FIG. 10, electrodes 76 and 77 are attached to the upper and lower surfaces of the piezoelectric element 70, and an AC power source is connected to the electrodes 76 and 77. When a voltage is applied to such electrodes 76 and 77, an electric field is generated in the thickness direction of the piezoelectric element 70.

  When the direction of the electric field is the same as the direction of polarization of the piezoelectric element 70 as shown in FIG. 10B, the piezoelectric element 70 extends in the thickness direction and contracts in the radial direction. As a result, the deflection of the drive diaphragm 72 is reduced. On the other hand, as shown in FIG. 10A, when the direction of the electric field is opposite to the direction of polarization of the piezoelectric element 70, the piezoelectric element extends in the radial direction and contracts in the thickness direction. As a result, the deflection of the drive diaphragm 72 increases.

  Here, in order to change the direction of the electric field to the same direction as the polarization direction of the piezoelectric element 70 or the opposite direction, the positive and negative polarities of the electrodes 76 and 77 are alternately switched. Since the electrodes 76 and 77 are connected to an AC power source, the polarity is automatically switched.

  In this way, the drive diaphragm 72 vibrates in the thickness direction by alternately switching the direction of the electric field to the same direction as the polarization direction of the piezoelectric element 70 or the opposite direction. The vibration of the driving diaphragm 72 is transmitted to a driven diaphragm (not shown). As a result, the volume of the space 73 varies.

  When the volume of the space 73 increases as shown in FIG. 10A, the pressure inside the space 73 decreases, so the valve inside the suction pipe 75 opens and sucks the reduced water M3. On the other hand, when the volume of the space 73 decreases as shown in FIG. 10B, the pressure inside the space 73 increases, so the valve inside the discharge pipe 74 is opened and the reduced water M3 is discharged.

  In this way, by switching the direction of the electric field generated in the piezoelectric element 70, the intake of the reduced water M3 through the suction pipe 75 and the discharge of the reduced water M3 through the discharge pipe 74 are repeated, so that FIG. In the reduced water mist spraying apparatus 1 shown in FIG. 1, the reduced water M generated by electrolyzing the water accumulated in the water reservoir 20 can be pressurized and discharged to the pressurized water pipe 93.

[Specific configuration example of air conditioner]
FIG. 11 is a diagram schematically illustrating a specific configuration example of an air conditioner according to an embodiment of the present invention. The air conditioner X shown in FIG. 11 is an air conditioner used as an air conditioner. In such an air conditioner X, an air suction port 81 is provided in the upper front portion of the housing 82. Further, an air outlet 87 provided with a louver 88 is provided at the lower front portion of the housing 82. Inside the housing 82, a heat exchanger 80 and a fan 83 formed of a cross flow fan are disposed.

  In addition, a partition wall 84 is formed inside the housing 82 to form a blowing path 85 from the air suction port 81 through the fan 83 to the air blowing port 87. Here, in the inside of the housing 82, the lower rear portion is a portion partitioned from the air blowing path 5 by the partition wall 84, and when the drain pipe 89 for drainage is pulled out from the right end or the left end of the housing 82 to the outside. It is a dead space to be used. In such a dead space, the reduced water mist spraying device 1 is installed. A reduced water mist delivery pipe 86 is led out to the air outlet 87 from the reduced water mist spraying apparatus 1. Here, one end of the reduced water mist delivery pipe 86 may be opened along the louver 88 at the air outlet 87. From the air outlet 87, the reduced water M3 is sprayed as reduced water mist.

  In the air conditioner X, a plurality of human body detection sensors (detection units) 100 that detect the presence of a human body are provided at appropriate positions outside the housing 82. Here, examples of the place where the human body detection sensor 100 is to be installed include the front surface, the left side surface, and the right side surface of the housing 82. This is because the louver 88 is moved in the direction in which the human body exists. The air conditioner X also includes a motor 101 that moves the louver 88 and a microcomputer 102 that controls the entire air conditioner X, such as the motor 101. The louver 88 and the motor 101 are configured such that the louver 88 can move at least left and right with respect to the front surface of the housing 82 under the control of the microcomputer 102.

  Hereinafter, the operation of such an air conditioner X will be exemplified. That is, when the human body detection sensor 100 is not detecting a human body, the louver 88 is controlled so as to face the front surface of the housing 82. The louver 88 is preferably directed upward with respect to the front surface of the housing 82. This is because the reduced water M3 sprayed from the air outlet 87 can easily reach the entire space. As described above, since the reduced water M3 easily spreads over the entire space, the reduced water M3 is diffused and dispersed over the entire space, so that an antioxidant effect is given to all target articles in the space. be able to.

  On the other hand, when the human body detection sensor 100 detects a human body, the louver 88 is moved so as to face the direction in which the human body exists. At that time, the reduced water M3 is sprayed in the direction in which the human body exists. For example, when the human body detection sensor 100 is provided on each of the front, left, and right sides of the housing 82, the louver 88 faces each of the front, left, and right sides with respect to the front of the housing 82. Thus, the reduced water M3 is sprayed in each direction. In this way, the air conditioner X can automatically detect the presence of a human body and spray the reduced water M3 at a pinpoint in the direction in which the human body exists.

  Moreover, since the reduced water M3 can be sprayed limited to a partial area in the space, a large amount of the reduced water M3 can be sprayed to the target article at a pinpoint. The louver 88 may be moved by a human operation. Even in this case, the same effect can be obtained.

  The air conditioner X includes the reduced water mist spraying device 1 (see FIG. 6) shown in the above-described specific configuration example 5 or the reduced water mist spraying device 1 (see FIG. 9) shown in the above-described specific configuration example 8. ) Is preferable. This is because the air conditioner X can be reduced in size and weight by incorporating such a compact reduced water mist spraying device 1.

It is a block diagram which shows an example of a function structure of the reducing water mist spreading | diffusion apparatus incorporated in an air conditioner. It is a figure which shows the specific structural example 1 of a reducing water mist spraying apparatus. It is a figure which shows the specific structural example 2 of a reducing water mist spraying apparatus. It is a figure which shows the specific structural example 3 of a reducing water mist spraying apparatus. It is a figure which shows the specific structural example 4 of a reducing water mist spraying apparatus. It is a figure which shows the specific structural example 5 of a reducing water mist spraying apparatus. It is a figure which shows the specific structural example 6 of a reducing water mist spraying apparatus. It is a figure which shows the specific structural example 7 of a reducing water mist spraying apparatus. It is a figure which shows the specific structural example 8 of a reducing water mist spraying apparatus. It is a figure for demonstrating operation | movement of a pump (pressurization part). It is a figure which shows typically the example of a specific structure of the air conditioner which concerns on one Embodiment of this invention.

Explanation of symbols

X Air conditioner U Reduced water generation unit 1 Reduced water mist spraying device 2 Acidic aqueous solution generation unit 3 Water acquisition unit 4 Reduction component generation unit 4A Reductant 4B Control unit 5 Reduced water generation unit 6 Reduced water atomization unit 7 Spraying unit 17 Pump 18 Small hole 20 Storage part 25 Discharge part 21 Insulating spacer 21a Through hole 22 Upstream electrode 23 Downstream electrode 24 High voltage application part 26 Blower part 34 Heat radiation part 37 Cooling part 38 Peltier element 40 Cooling surface 45 Adsorbent 49 Heater 53 Anode 54 Cathode 60 Ultrasonic radiation element 64 Surface acoustic wave generator 65 Discharge electrode 66 Counter electrode M1 Acidic aqueous solution M2 Reducing component M3 Reduced water

Claims (19)

A water acquisition unit for acquiring water for generating reduced water;
A reduced water generation unit that generates the reduced water from the water acquired by the water acquisition unit;
A reduced water atomization unit for atomizing the reduced water generated by the reduced water generation unit;
A spraying unit for spraying the reduced water atomized by the reduced water atomization unit as reduced water mist;
Built- in reduced water mist spraying device consisting of
The reduced water generating unit is
An acidic aqueous solution generating unit that generates an acidic component in water, and generates an acidic aqueous solution containing a cation and an anion generated by ionizing the acidic component generated in the water;
A reducing component generation unit that generates electrons by reducing electrons by giving electrons to the cations contained in the acidic aqueous solution;
A reduced water generator that dissolves the reduced component generated by the reduced component generator in water to generate reduced water in which the reduced component is dissolved; and
An air conditioner characterized by Rukoto equipped with.   The reduced water generation unit includes an ascorbic acid cartridge filled with ascorbic acid, and the reduced water passes through the ascorbic acid cartridge to be reduced water in which ascorbic acid is dissolved. The air conditioner according to claim 1. The water acquisition unit includes a heat dissipating unit that radiates heat after compressing the refrigerant gas to a high temperature and high pressure, and a cooling unit that vaporizes the refrigerant liquid after depressurizing the refrigerant liquid, and
The air conditioner according to claim 1 or 2, wherein moisture in the air is condensed by cooling by the cooling unit to acquire the water.   3. The air conditioner according to claim 1, wherein the water acquisition unit includes a Peltier element that acquires moisture by condensing moisture in the air by cooling with a cooling surface.   The said water acquisition part is provided with the adsorption agent which adsorb | sucks the water | moisture content in air, and the heater which heats the said adsorption agent and desorb | sucks the said water | moisture content adsorbed by the said adsorption agent. Or the air conditioner of Claim 2. The acidic aqueous solution generator is
While storing the water for generating the acidic aqueous solution or the acidic aqueous solution, a storage portion having a through-hole formed in the outer wall;
The insulating spacer between the first electrode in contact with the water or the acidic aqueous solution stored in the reservoir, the insulating spacer having a through hole communicating with the through hole of the outer wall, and the first electrode A high voltage is applied to the second electrode sandwiching the first electrode, the first electrode, and the second electrode, and creeping discharge is performed in the through hole of the insulating spacer to generate the raw material of the acidic component A high voltage application unit, and a discharge unit comprising:
Air is introduced into the through hole of the insulating spacer, the raw material of the acidic component is generated in the through hole where the creeping discharge is performed, and the raw material of the acidic component generated in the through hole is stored. A blower unit that dissolves in the water stored in the unit to generate the acidic component;
The air conditioner according to any one of claims 1 to 5, further comprising:   The air conditioner according to claim 6, wherein the outer wall is used as the insulating spacer, and a through hole of the outer wall is used as a through hole of the insulating spacer.   The air conditioner according to claim 6, wherein the outer wall is used as the first electrode. The cation is a hydrogen ion;
The reducing component generator is
A reducing substance that is composed of an element having a greater ionization tendency than hydrogen, reduces the hydrogen ions contained in the acidic aqueous solution, and generates hydrogen molecules as the reducing component;
A regulator that regulates the amount of hydrogen molecules produced;
The air conditioner according to any one of claims 6 to 8, wherein the air conditioner is provided.   The air conditioner according to claim 9, wherein the reducing substance is detachable from the adjusting unit.   The air conditioner according to claim 9, wherein the reducing substance is adjustable in a range in which the reducing unit is immersed in the acidic aqueous solution.   The reduced water generation unit includes an anode and a cathode for electrolyzing the water acquired by the water acquisition unit, and generates hydrogen water as the reduced water at the cathode. The air conditioner as described in any one of Claims 5.   The air conditioner according to any one of claims 1 to 12, wherein the reduced water atomization unit includes an ultrasonic radiation element that radiates ultrasonic waves to the reduced water to atomize the reduced water. .   The said reduced water atomization part is provided with the surface acoustic wave generation part which generate | occur | produces the surface acoustic wave and atomizes the said reduced water with the said surface acoustic wave, The any one of Claim 1 thru | or 12 characterized by the above-mentioned. The air conditioner according to one item.   The said reduced water atomization part is equipped with the electrostatic atomization part which atomizes the said reduced water with the high electric field which generate | occur | produces when a high voltage is applied, The any one of Claim 1 thru | or 12 characterized by the above-mentioned. The air conditioner according to one item.   The reduced water atomizing section includes a pressurizing section that pressurizes the reduced water and a small hole for injecting the reduced water pressurized by the pressurizing section. The air conditioner as described in any one of thru | or 12 thru | or 12.   The air conditioner according to any one of claims 1 to 16, wherein the spraying part sprays the reduced water over the entire space.   The air conditioner according to any one of claims 1 to 16, wherein the spray unit sprays the reduced water in a directional manner with respect to a part of the space. The spray unit includes a detection unit that detects the presence of a human body,
The air conditioner according to claim 18, wherein the reduced water is sprayed in a directional manner with respect to the direction of the human body detected by the detection unit.

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