JP4371919B2 - Air conditioner and electrolyzed water spray device - Google Patents

Description

  The present invention relates to an air conditioner such as an air purifier, a humidifier, and an air conditioner, and an electrolyzed water spray device.

  As an air conditioner for taking in air outside the machine, performing a predetermined process and discharging it to the outside of the machine to perform indoor air conditioning, a fan that is rotated to take air outside the machine into the machine, There is known an air purifier including a filter that passes when outside air is taken into the apparatus. The air taken into the machine passes through a filter to remove dust contained in the air (see, for example, Patent Document 1).

However, with an air cleaner as disclosed in Patent Document 1, dust and the like contained in the air are removed, but the air cannot be sterilized or deodorized. Then, the air cleaner provided with the disinfection function and the deodorizing function is proposed (refer patent document 2).
In the air purifier as disclosed in this Patent Document 2, a liquid having a sterilizing action and a deodorizing action is accommodated in a water storage part, and the mist generated using the liquid is discharged outside the machine, Can be sterilized or deodorized.
JP 2003-102816 A JP 2003-79714 A

However, in the air cleaner as disclosed in Patent Document 2, a dedicated liquid having a sterilizing action or a deodorizing action or a dedicated liquid for generating a mist having a sterilizing action or a deodorizing action is used in the water storage section. Must be housed. Therefore, it is necessary to prepare the dedicated liquid as described above, which is troublesome.
Therefore, the applicant of the present application has proposed a configuration that can achieve a sterilizing function and a deodorizing function without preparing a dedicated liquid (Japanese Patent Application No. 2004-176032). In this configuration, for example, in a state where tap water is stored in a water storage tank of a mist generating device disposed in the housing of the air purifier, a pair of electrode plates are energized to perform sterilization and deodorization. Electrolyzed water containing free residual chlorine such as hypochlorous acid (HClO) and active oxygen is generated. Then, the air pump is driven to send air into the water storage tank, and bubbles are generated in the generated electrolyzed water, thereby generating mist having a sterilizing action and deodorizing action, and supplying the generated mist to the outside of the machine. To do.

In the case where mist of electrolyzed water is generated in the manner as described above, if a pair of electrode plates are energized continuously, the free residual chlorine concentration (electrolyzed water concentration) becomes too high and is supplied outside the machine. Mist may adversely affect human body. Therefore, the electrode plate is energized intermittently to prevent the electrolytic water concentration from becoming too high.
FIG. 13 is a time chart showing a specific example of a mode in which energization to the electrode plate is intermittently performed.

  In the mode shown in FIG. 13 (a), after energizing the electrode plate for a predetermined electrolysis period T1 (for example, 4 minutes), energization to the electrode plate for a predetermined non-electrolytic period T2 (for example, 86 minutes). This cycle is repeated with one cycle of 90 minutes of intermittent control such as turning off. During this time, the air pump is always driven at a constant rotational speed, and a constant amount of air is sent into the water storage tank per unit time, so that bubbles are always generated in the electrolyzed water in the water storage tank.

  When energization to the electrode plate is started in a state where the electrolyzed water concentration is A1, the electrolyzed water concentration gradually increases, and the electrolyzed water concentration becomes A2 when the electrolysis period T1 elapses. Thereafter, when the energization to the electrode plate is stopped, only the air pump is driven until the non-electrolytic period T2 elapses. During the non-electrolytic period T2, bubbles are generated in the electrolyzed water in the water storage tank, so that the amount of contact of electrolyzed water with air increases, and as a result, the electrolyzed water concentration gradually decreases. Then, when the non-electrolytic period T2 has elapsed, the electrolyzed water concentration again decreases to A1, and then energization to the electrode plate is started, whereby the electrolyzed water concentration increases again. By repeating such intermittent control, the average value of the concentration of the electrolyzed water in the water storage tank becomes AV.

  Here, in order to change the supply amount of mist (the amount of air supplied to the water storage tank), a configuration is possible in which the drive of the air pump can be switched between strong and weak. According to such a configuration, by switching the driving of the air pump to “strong”, it is possible to increase the amount of bubbles generated in the electrolyzed water and increase the amount of mist generated. And the deodorizing effect can be further improved.

  Assuming that the change in the electrolyzed water concentration as shown by the solid line in FIG. 13A is a change mode when the air pump drive is “weak”, the electrolyzed water concentration in the case where the air pump drive is “strong”. The change is as shown by a broken line in FIG. That is, even when the driving of the air pump is switched to “strong”, the change in the amount of contact with the electrolytic water has little influence on the electrolytic water concentration during the electrolysis period T1, and the driving of the air pump is “weak” The concentration of electrolyzed water increases at approximately the same rate. On the other hand, during the non-electrolytic period T2, the rate of driving of the air pump is larger than the case where the driving of the air pump is “weak” due to the increase in the contact amount of the electrolyzed water with the air accompanying the increase in bubbles generated in the electrolyzed water in the water storage tank The electrolyzed water concentration decreases. In such a case, the concentration of the electrolyzed water in the water storage tank gradually decreases as a whole, and the sterilizing effect and the deodorizing effect are lowered.

  Therefore, as shown in FIG. 13B, a configuration is conceivable in which the electrolysis period T1 is changed according to the strength / weakness of the driving of the air pump. That is, as shown by a broken line in FIG. 13B, the non-electrolytic period when the drive of the air pump is “strong” while keeping the time (for example, 90 minutes) of intermittent control for the electrode plate constant. By extending the electrolysis period T1 in accordance with the decreasing rate of the electrolyzed water concentration in T2, the electrolyzed water concentration is set to A1 when the non-electrolytic period T2 has elapsed. According to such a configuration, the concentration of the electrolyzed water in the water storage tank gradually decreases as a whole, and the sterilizing effect and the deodorizing effect are not reduced.

However, in the configuration as described above, the average value of the concentration of the electrolyzed water in the water storage tank becomes a value (BV) larger than the average value AV when the air pump drive is “weak”, so The supplied mist may adversely affect the human body.
The present invention has been made in view of such a background, and is an air that can prevent the average concentration of electrolyzed water from changing in accordance with the change in the amount of air supplied to the water storage unit in order to generate mist of electrolyzed water. It aims at providing a harmony machine and an electrolyzed water spraying apparatus.

  In order to achieve the above object, an invention according to claim 1 is an air conditioner (1) for performing air conditioning by taking in air outside the machine, performing a predetermined process, and discharging it outside the machine. A water storage section (15) capable of storing water, an electrode (35) for electrolyzing water stored in the water storage section to generate electrolyzed water, and supplying air to the water storage section, A bubble generation mechanism (18, 20) for generating bubbles in the water stored in the water storage unit, and the bubbles generated by the bubble generation mechanism are released into the atmosphere from the surface of the water stored in the water storage unit. Mist supply means (14, 25, 28, 30) for supplying the mist generated by blowing bubbles when being blown to the outside of the machine, and the concentration of electrolyzed water is increased by electrolysis using the electrodes. From the concentration increase period (T1) and the bubble generation mechanism Electrolytic mist supply control means (100) for supplying mist of electrolytic water from the mist supply means while alternately repeating the concentration reduction period (T2) for reducing the concentration of electrolytic water by supplying air to the water storage section. And an air amount changing means (100, S2, S5) for changing the amount of air supplied from the bubble generating mechanism to the water reservoir, and according to the amount of air supplied from the bubble generating mechanism to the water reservoir. And an electrolyzed water concentration adjusting means (100, S3, S6) for adjusting the concentration of electrolyzed water generated during the control of the electrolytic mist supply control means by changing the concentration decreasing period. It is an air conditioner.

The alphanumeric characters in parentheses indicate corresponding components in the embodiments described later. The same applies hereinafter.
According to this configuration, the amount of air supplied from the bubble generating mechanism to the water storage section can be changed by the air amount changing means during the control by the electrolytic mist supply control means. Even when the amount of air supplied to the water storage unit is changed during the control of the electrolytic mist supply control means, the same concentration (A2) as before the air amount is changed during the concentration increase period (electrolysis period T1). The concentration of electrolyzed water can be increased until the concentration reduction period (non-electrolysis period T2) is changed according to the changed amount of air. The same density (A1) as before the change can be obtained.

Therefore, the average value of the electrolyzed water concentration in the water reservoir can be made constant (almost constant) regardless of the change in the amount of air supplied to the water reservoir, and the average of the electrolyzed water with the change in the air amount It is possible to prevent the concentration from changing.
According to a second aspect of the present invention, the electrolytic mist supply control means (100) performs the bubble generation mechanism (18, 20) while performing electrolysis with the electrode (35) during the concentration increase period (T1). From the above, air may be supplied to the water storage section (15).

  Even in such a configuration, during the concentration increase period (electrolysis period T1), the change in the amount of contact with the electrolyzed water has little effect on the electrolyzed water concentration, and the change in the amount of air supplied to the water storage section The electrolyzed water concentration increases at almost the same rate regardless of the presence or absence. Therefore, even if air is supplied to the water storage unit during the concentration increase period, it takes time to increase the electrolyzed water concentration to the predetermined concentration (A2), and the concentration increase period is not extended.

  Therefore, as in the invention described in claim 3, the electrolyzed water concentration adjusting means (100, S3, S6) is not changed from the bubble generating mechanism (18, 20) without changing the concentration increasing period (T1). By changing only the concentration reduction period (T2) according to the amount of air supplied to the water storage section (15), the concentration of the electrolytic water generated during the control of the electrolytic mist supply control means (100) is changed. Even if it is the structure which adjusts, the electrolyzed water density | concentration at the time of a fixed density | concentration increase period (electrolysis period T1) passes the said predetermined density | concentration (A2) irrespective of the presence or absence of the change of the air quantity supplied to a water storage part. )

  Invention of Claim 4 contains the dirt detection means (105) for detecting the dirt of the air taken in into the said air conditioner (1), The said air quantity change means (100, S2, S5) is the said 4. The amount of air supplied from the bubble generating mechanism (18, 20) to the water reservoir (15) is changed according to the detection result of the dirt detecting means. It is an air conditioner of crab.

According to this configuration, when the air taken into the air conditioner is dirty, the amount of air supplied from the bubble generation mechanism to the water storage unit is automatically increased, and bubbles generated in the electrolyzed water are increased. The Thereby, since the generation amount of mist can be increased, the sterilization effect and the deodorizing effect of the air by mist can be improved more.
According to a fifth aspect of the present invention, the air amount changing means (100, S2, S5) is responsive to a predetermined operation (106) from the foam generating mechanism (18, 20) to the water storage section (15). The air conditioner (1) according to any one of claims 1 to 3, wherein the amount of supplied air is changed.

According to this configuration, the user can increase the amount of air supplied from the bubble generation mechanism to the water storage unit and increase the amount of bubbles generated in the electrolyzed water by performing the predetermined operation. Thereby, since the generation amount of mist can be increased, the sterilization effect and the deodorizing effect of the air by mist can be improved more.
The invention according to claim 6 is characterized in that the electrode (35) can electrolyze tap water stored in the water storage section (15) to generate electrolyzed water containing hypochlorous acid. It is an air conditioner (1) in any one of Claims 1-5.

According to this configuration, by storing tap water in the water storage part, tap water containing chlorine can be electrolyzed to generate hypochlorous acid (free residual chlorine) having a bactericidal action and a deodorizing action. If mist is generated using electrolyzed water containing hypochlorous acid, tap water can be used to achieve a sterilizing function and a deodorizing function.
The invention according to claim 7 includes a water storage section (15) capable of storing water, an electrode (35) for electrolyzing water stored in the water storage section to generate electrolyzed water, and the water storage section. And a bubble generating mechanism (18, 20) for generating bubbles in the water stored in the water reservoir, and water in which the bubbles generated by the bubble generating mechanism are stored in the water reservoir. Mist supply means (14, 25, 28, 30) for supplying mist generated by blowing bubbles when released from the water surface to the atmosphere to the outside of the machine, and electrolysis by the above electrodes While alternately repeating a concentration increase period (T1) for increasing the concentration of electrolyzed water and a concentration decrease period (T2) for decreasing the concentration of electrolyzed water by supplying air from the bubble generation mechanism to the water storage part, Electrolyzed water from the mist supply means Electrolytic mist supply control means (100) for supplying a strike, air amount changing means (100, S2, S5) for changing the amount of air supplied from the bubble generating mechanism to the water reservoir, and the bubble generating mechanism The electrolytic water concentration adjusting means (100) for adjusting the concentration of the electrolyzed water generated during the control of the electrolytic mist supply control means by changing the concentration decreasing period according to the amount of air supplied to the water reservoir from , S3, S6).

  According to this configuration, it is possible to provide an electrolyzed water spray device that exhibits the same effect as that of the first aspect of the invention.

Embodiments of the present invention will be specifically described below with reference to the drawings.
FIG. 1 is a perspective view showing an external configuration of an air purifier 1 according to an embodiment of the present invention. 2 is a schematic cross-sectional view seen along the arrow AA shown in FIG. 1, and FIG. 3 is a schematic cross-sectional view seen along the arrow BB shown in FIG. The description will be made assuming that the right back side in FIG. 1 is the rear and the left front side is the front.

  With reference to FIGS. 1-3, this air cleaner 1 is installed indoors, for example, takes in the air outside a machine, performs the process which cleans the air, and discharges it outside the machine. It is for air cleaning. The outer shape of the air purifier 1 is partitioned by a thin housing 2 having a length in the front-rear direction shorter than that in the left-right direction. A substantially rectangular front plate 3 is attached to the front surface of the housing 2.

  Inside the housing 2, an axial line is arranged to extend in the front-rear direction, a fan 4 that is rotated to take outside air into the machine, and a rotating shaft 5 </ b> A is attached to the fan 4 to rotate the fan 4. For this purpose, a motor 5 to be driven and a filter 6 that passes when outside air is taken into the machine are provided (in FIG. 3, the fan 4, the rotary shaft 5A and the motor 5 are omitted). Yes.)

  The filter 6 captures dust contained in the passing air and cleans the air, and is detachably mounted in a substantially rectangular opening 7 formed on the front surface of the housing 2. The thickness of the filter 6 is smaller than the depth of the opening 7, and the filter 6 is attached to the rear portion of the opening 7. The front plate 3 is arranged so that a certain space is formed in front of the filter 6, and an intake port 8 for taking in air into the housing 2 is formed on the lower end surface and the left and right end surfaces thereof. Yes.

  The fan 4 is a so-called sirocco fan, and when the fan 4 is rotated, air flows from the front side (one side in the axial direction) to the fan 4 side, and the air is discharged in the radial direction. ing. Therefore, when the fan 4 is rotated, as indicated by an arrow D1 in FIGS. 2 and 3, outside air passes through the filter 6 from the intake port 8 and is taken into the housing 2 and flows toward the fan 4 side. It will be.

  The housing 2 is formed with a cylindrical portion 10 having a substantially elliptical cross section extending from the upper end to the lower end of the housing 2 at the front end portions of the left and right side portions thereof. A space in one (for example, the right side) of the cylindrical portion 10 is partitioned from other spaces in the housing 2 (spaces in which the fan 4 and the motor 5 are disposed) by a partition wall 10A disposed in the housing 2. ing. A vent hole 11 is formed on the side surface of the right cylinder portion 10. In addition, a through hole 10 </ b> B that communicates with the space in the right cylinder portion 10 is formed in the front portion (front side of the filter 6) of the right side wall that forms the opening 7. With such a configuration, when the fan 4 is rotated, outside air is sucked into the right cylinder 10 from the vent hole 11 and, as shown by an arrow D3 in FIG. It is guided forward, passes through the filter 6 and is taken into the housing 2.

On the upper surface of the housing 2, a plurality of exhaust ports 9 are formed on an extension line in the radial direction of the fan 4 (in the flow path of the air discharged by the fan 4) and cleaned by passing through the filter 6. The air is discharged in the radial direction by the fan 4 and discharged upward from the exhaust port 9 as indicated by an arrow D2 in FIG.
A mist generating device 12 for generating mist is disposed at the upper end of the other (for example, the left side) cylindrical portion 10. An air pump 13 for sucking air in the housing 2 (air after passing through the filter 6) is arranged at the lower part in the housing 2, and the mist generator 12 uses the air sucked from the air pump 13. Mist can be generated. Mist generated from the mist generating device 12 is supplied to the outside from the spray port 14 formed on the upper end surface of the left cylinder portion 10 upward. The air pump 13 preferably has a suction port located on an extension line in the radial direction of the fan 4 (in a flow path of air discharged by the fan 4).

FIG. 4 is an enlarged cross-sectional view showing an enlarged cross section in the vicinity of the left cylinder portion 10 in FIG. 5 is a cross-sectional view taken along the arrow CC shown in FIG. 4, and FIG. 6 is a cross-sectional view taken along the arrow DD shown in FIG. 7 is a cross-sectional view taken along the arrow EE shown in FIG.
Referring to FIGS. 4 to 7, mist generating device 12 has an opening at the upper end surface and can store a prescribed amount (for example, about 160 cc) of water, and a storage tank 15 of this storage tank 15. A lid 16 for closing the opening on the upper end surface is provided. A hollow insertion member 17 made of resin and having a plurality of water passage holes 17A, 17B, and 17C is attached to the lower surface of the lid 16. If the lid 16 is put on the upper end of the water storage tank 15 so that the insertion member 17 is inserted into the water storage tank 15 in a state where the water is stored in the water storage tank 15, the insertion member 17 is inserted into the water in the water storage tank 15. The water in the water storage tank 15 flows into the insertion member 17 through the water passage holes 17A, 17B, and 17C. In the insertion member 17, a bubble generation chamber 18 and an electrolysis chamber 19 that extend in the vertical direction are partitioned and formed so as to be aligned in the front-rear direction.

  The lid 16 is formed with a concave portion recessed upward at a position facing the bubble generation chamber 18 so as to extend in the left-right direction. The space in the concave portion extends from the air pump 13 to the mist generating device 12. An air supply path 20 is provided for supplying the sent air into the water storage tank 15 (in the bubble generation chamber 18). A supply port 21 for supplying air from the air pump 13 is disposed on the right side of the air supply path 20, and a rubber packing 22, for example, is attached to the peripheral portion of the supply port 21. . The right end of the air supply path 20 is open in the left-right direction, and the right end of the air supply path 20 is pressed against the packing 22 so that air supplied from the air pump 13 is supplied from the supply port 21 to the air supply path. It can be sent to 20 without leaking.

  When the air pump 13 is driven in a state where water is stored in the water storage tank 15, the air sent through the air supply path 20 is supplied into the bubble generation chamber 18, and the water in the bubble generation chamber 18 is supplied by the pressure. As a result of stirring, a large number of bubbles are generated. In the lower part of the front surface of the insertion member 17, an overhanging portion 23 is formed for projecting forward and extending the foam generating chamber 18 forward. A part of the foam generated in the foam generating chamber 18 is It flows out of the insertion member 17 through a large number of small holes 24 formed on the upper surface of the overhanging portion 23. The diameter of the foam generated in the foam generation chamber 18 is, for example, about 0.1 to 10 mm, and the diameter of the small hole 24 is, for example, about 0.5 mm. Therefore, the diameter of the bubble flowing out from the small hole 24 is about 0.1 to 0.5 mm.

  The bubbles flowing out from the small holes 24 float through the water in the water storage tank 15 outside the insertion member 17 and enter the atmosphere (in the air in the water storage tank 15) from the water surface in the water storage tank 15. To be released. At this time, mist is generated by blowing bubbles. In the lid 16, a discharge port 25 for discharging mist generated in the water storage tank 15 to the outside of the water storage tank 15 is formed at a position above the small hole 24.

  The large number of water passage holes 17 </ b> C formed on the bottom surface of the overhang portion 23 have the same area as the small hole 24 or smaller than the area of the small hole 24. Further, the number of water holes 17C is smaller than the number of small holes 24. According to such a configuration, the bubbles generated in the bubble generation chamber 18 are discharged from the small holes 24 into the water in the water storage tank 15 (outside the bubble generation chamber 18) rather than the water flow holes 17C. Cheap. Therefore, all or most of the bubbles generated in the bubble generating chamber 18 are discharged from the small holes 24, and therefore mist can be generated more satisfactorily.

  In addition, since the area of the water passage hole 17C is equal to or smaller than the area of the small hole 24, even if bubbles generated in the bubble generation chamber 18 are released from the water passage hole 17C, the size of the bubbles is small. Is less than or equal to the size of the bubbles released from the. Therefore, since it is possible to prevent bubbles having a predetermined size or more from being generated from the bubble generation chamber 18, it is possible to generate mist more satisfactorily.

  The large number of water passage holes 17A and 17B formed on the bottom and side surfaces of the electrolysis chamber 19 each have an area larger than the area of the water passage hole 17C. According to such a configuration, water in the water storage tank 15 enters and exits the electrolysis chamber 19 through the relatively large water passage hole 17 </ b> A compared to the water passage hole 17 </ b> C formed in the bottom surface of the bubble generation chamber 18. Therefore, water circulation to the electrolysis chamber 19 is good and electrolysis efficiency is good.

  The width in the left-right direction of the electrolysis chamber 19 is slightly smaller than the width in the left-right direction of the water storage tank 15, and the left side wall 19A that defines the left side of the electrolysis chamber 19 and the right side wall 19B that defines the right side are opposed to each other. It is close to the inner surface of the water storage tank 15. The width in the left-right direction of the bubble generation chamber 18 is smaller than the width in the left-right direction of the electrolysis chamber 19, and the bubble generation chamber 18 is disposed on the left front side of the electrolysis chamber 19. A front wall 19C that partitions the front surface of the electrolysis chamber 19 projects to the right (see FIG. 7).

  According to such a configuration, it is the front wall 19C that bubbles that flow out from the small hole 24 wrap around the rear side of the electrolysis chamber 19 and travel toward the electrode plate 35 side through the water holes 17A and 17B. Since it can regulate, it can prevent that the performance of electrolysis falls by a bubble contacting electrode board 35. Therefore, electrolysis can be performed more favorably to generate electrolyzed water, and mist can be generated using the electrolyzed water, so that the sterilizing effect and deodorizing effect can be improved.

Moreover, the electrolysis chamber 19 can be enlarged by adopting a configuration in which the electrolysis chamber 19 protrudes to the right side of the bubble generation chamber 18. Therefore, a sufficient space for arranging the electrode plate 35 and the water level detection electrode 36 in the electrolysis chamber 19 can be secured.
A guide member 26 for guiding the mist discharged from the discharge port 25 to the spray port 14 is disposed above the lid 16. The inside of the guide member 26 is partitioned into a first partition chamber 28 and a second partition chamber 29 by a partition plate 27 extending to the left and right, and the discharge port 25 faces the rear portion of the first partition chamber 28. A communication port 30 communicating with the spray port 14 is formed at the front end portion of the upper surface of the guide member 26. The discharge port 25 of the lid 16 and the communication port 30 of the guide member 26 are arranged at positions that are shifted in the horizontal direction (positions that do not overlap in the vertical direction), so that the first compartment 28 is a buffer chamber. It is supposed to function as. That is, the mist that has flowed into the first compartment 28 from the outlet 25 strikes the inner wall surface of the guide member 26 (first compartment 28) above the outlet 25, spreads over the entire first compartment 28, and communicates thereafter. It is discharged from the spraying port 14 through the mouth 30 to the outside of the apparatus.

  According to such a configuration, even when a relatively large droplet mist is generated, the droplet mist is attached to and captured by the inner wall surface of the first compartment 28 and has a relatively small mist (for example, a diameter). Only about 2 nm to 10 μm). Since the relatively small mist has an active Brownian motion, after being supplied from the spraying port 14 to the outside of the apparatus, it spreads further and easily enters fibers such as clothing.

In addition, by adopting a configuration in which the water storage tank 15 communicates with the outside of the machine via the first compartment 28, it is possible to make it difficult for the sound generated when bubbles blow in the water storage tank 15 to leak outside the machine. , Can improve the silencing effect.
Further, when the water tank 15 is tilted and the water in the water tank 15 leaks from the discharge port 25 as in the case where the air conditioner 1 falls, the leaked water is received by the first compartment 28. Therefore, it is possible to prevent leaking out of the machine immediately.

  In this embodiment, the water storage tank 15 is formed of a transparent member, and a transparent cover 32 is attached to an opening 31 formed in a part (front side) of the left cylinder portion 10. According to such a configuration, since the inside of the water storage tank 15 can be seen through the transparent cover 32, bubbles generated in the water in the water storage tank 15 can be visually recognized. However, the configuration is not limited to a configuration in which the entire water storage tank 15 is formed of a transparent member. For example, a portion facing the transparent cover 32 of the water storage tank 15 forms a transparent portion by being formed of a transparent member. It may be.

  A light emitting element 33 (for example, an LED element such as a blue LED) that emits light upward is disposed below the water storage tank 15. According to such a configuration, since the light in the water storage tank 15 can be illuminated brightly by causing the light emitting element 33 to emit light (because the outline of the bubbles can be illuminated), the transparent cover 32 is interposed. When the inside of the water storage tank 15 is viewed, bubbles generated in the water in the water storage tank 15 can be easily seen.

  In this embodiment, the light emitting element 33 is located between the front end of the insertion member 17 (the front end of the overhang portion 23) and the front wall of the water storage tank 15 in a plan view. The generated light does not interfere with the bubble generation chamber 18 (the overhang portion 23). Thereby, it can prevent that the light irradiated toward a bubble is interrupted | blocked by the bubble generation chamber 18, and it becomes difficult to visually recognize a bubble.

As shown by a two-dot chain line in FIG. 7, the transparent cover 32 is a front surface that defines the front surface of the insertion member 17 that is inserted into the water storage tank 15, in particular, the upper part of the overhanging portion 23 of the foam generation chamber 18. Opposite the wall 18A. The front surface of the front wall 18 </ b> A is a plane having an area larger than the area of the transparent cover 32.
According to such a configuration, when the bubbles rising in the water stored in the water storage tank 15 are viewed from outside the apparatus through the transparent cover 32 and the transparent water storage tank 15, the front surface of the front wall 18A is in the background. It becomes easy to visually recognize the bubbles. In particular, by making the area of the front surface of the front wall 18 </ b> A larger than the area of the transparent cover 32, it is possible to make bubbles easier to visually recognize. In addition, if the insertion member 17 (at least the part facing the transparent cover 32 on the front surface of the front wall 18A) is colored in a blue color or the like, the bubbles are more easily visible. However, the front surface of the front wall 18A is not limited to a flat surface, and may be a curved surface, for example.

  In the electrolysis chamber 19, a pair of electrode plates 35 and a water level detection electrode 36 each held by an electrode holding member 34 are arranged. The pair of electrode plates 35 and the water level detection electrode 36 are formed, for example, by coating platinum on titanium or ruthenium-based material and coating iridium on the outside thereof. The pair of electrode plates 35 are arranged at regular intervals in the left-right direction at the bottom of the electrolysis chamber 19, and the lower ends of the terminals 37 elongated in the vertical direction are coupled to each electrode plate 35. . The water level detection electrode 36 is long in the vertical direction, and its lower end is located at the bottom of the electrolysis chamber 19 (above the lower ends of the pair of electrode plates 35). The upper ends of the two terminals 37 and the water level detection electrode 36 pass through the lid 16 and face the second compartment 29. Three pins 38 that pass through the wall surface and protrude rightward from the guide member 26 are attached to the right wall surface of the second compartment 29, and the two terminals 37 and the water level detection electrode 36 are connected to each other. Each upper end is connected to a separate pin 38 via wiring.

  A connection box 39 for connecting the pair of electrode plates 35 and the water level detection electrode 36 to the power source is disposed on the right side of the guide member 26. In the connection box 39, three jacks 40 for inserting the three pins 38 are disposed, and each jack 40 is connected to a power source via a wiring. By inserting the three pins 38 protruding rightward from the guide member 26 into the corresponding jacks 40, it becomes possible to energize the pair of electrode plates 35 and the water level detection electrode 36. .

When the air purifier 1 is continuously operated, a predetermined voltage (for example, for example, about 3 to 10 minutes every hour) so that the pair of electrode plates 35 have opposite polarities to each other. 10V) is applied, and current flows through the water between the pair of electrode plates 35. When the pair of electrode plates 35 is energized with the tap water containing chlorine stored in the water storage tank 15, the following electrochemical reaction occurs between the anode, cathode and electrode plates.
(Anode side)
4H ₂ O-4e ⁻ → 4H ⁺ + O ₂ ↑ + 2H ₂ O
2Cl ⁻ → Cl ₂ + 2e ⁻
H ₂ O + Cl ₂ ⇔HClO + H ⁺ + Cl ⁻
(Cathode side)
4H ₂ O + 4e ⁻ → 2H ₂ ↑ + 4OH ⁻
(Between electrode plates)
H ⁺ + OH ⁻ → H ₂ O
By the electrochemical reaction as described above, electrolyzed water containing free residual chlorine such as hypochlorous acid (HClO) having a bactericidal action and a deodorizing action and active oxygen can be generated. By supplying air to the generated electrolyzed water from the air pump 13 through the air supply path 20 and generating bubbles, it is possible to generate mist having a bactericidal action and a deodorizing action. If the mist having the sterilizing action and the deodorizing action generated in this way is supplied from the spray port 14 to the outside of the apparatus, the sterilizing function and the deodorizing function are achieved using tap water without preparing a dedicated liquid. be able to. By supplying a mist having a bactericidal action outside the apparatus, allergy can be suppressed.

  In particular, in this embodiment, the bubble generation chamber 18 and the electrolysis chamber 19 are partitioned so that bubbles generated in the bubble generation chamber 18 do not contact the electrode plate 35. Thereby, it can prevent that the performance of electrolysis falls because the bubble which generate | occur | produced contacts the electrode plate 35. FIG. Therefore, electrolysis can be performed more favorably to generate electrolyzed water, and mist can be generated using the electrolyzed water, so that the sterilizing effect and deodorizing effect can be improved.

Further, air from which dust or the like has been removed by passing through the filter 6 is sucked by the air pump 13 to generate bubbles, so that dust or the like contained in the air enters the bubble generation chamber 18 and the small holes 24 are clogged. Can be prevented.
Further, since the spray port 14 is disposed relatively near the exhaust port 9, the mist supplied from the spray port 14 to the outside of the apparatus can be mixed into the air discharged from the exhaust port 9. Therefore, air mixed with mist having a sterilizing action and a deodorizing action spreads in a relatively wide range outside the apparatus, and the sterilizing effect and the deodorizing effect can be further improved.

  Moreover, since the electrolysis of the water in the water storage tank 15 can be performed intermittently if the configuration is such that energization to the pair of electrode plates 35 is performed intermittently as in the above embodiment, It is possible to prevent the electrolyzed water concentration (hypochlorous acid concentration, etc.) of the water in the tank 15 from becoming too high. Each time energization to the pair of electrode plates 35 is performed once, the polarity of the voltage applied to these electrode plates 35 may be switched.

  During continuous operation of the air purifier 1, the air sent from the air pump 13 to the bubble generation chamber 18 via the air supply path 20 may be continuously supplied or may be supplied intermittently. It may be. In the case of continuous supply, the water in the water storage tank 15 decreases by about 1 cc per hour. Therefore, when a prescribed amount (for example, 160 cc) of water is put into the water storage tank 15 and the air cleaner 1 is continuously operated, the water in the water storage tank 15 will last for about 7 days. In the case where air is intermittently supplied from the air pump 13 to the bubble generation chamber 18, the air may be supplied alternately to the energization of the pair of electrode plates 35, or the pair of electrodes Air may be supplied after a predetermined time (for example, 3 to 10 minutes) has elapsed since the start of energization of the plate 35.

  The water level detection electrode 36 and one of the pair of electrode plates 35 are energized continuously or intermittently. Depending on the energized state at that time, the water in the water storage tank 15 has a predetermined water level (water level). It is detected whether it is less than the water level at the lower end of the detection electrode 36. That is, when the water in the water storage tank 15 is at a level equal to or higher than the lower end of the water level detection electrode 36, a current flows between the water level detection electrode 36 and the one electrode plate 35. When it is detected that the water level is equal to or higher than the predetermined water level and the water in the water storage tank 15 is lower than the lower end of the water level detection electrode 36, no current flows between the water level detection electrode 36 and one of the electrode plates 35. Therefore, it is detected that the water in the water storage tank 15 is less than the predetermined water level.

  In this embodiment, since the lower end of the water level detection electrode 36 is located above the lower end of the electrode plate 35, when it is detected that the water in the water storage tank 15 is lower than the predetermined water level, The pair of electrode plates 35 is immersed in the water in the water storage tank 15. Therefore, when it is detected that the water in the water storage tank 15 is lower than the predetermined water level, the pair of electrode plates 35 are not immersed in the water in the water storage tank 15 if such a configuration is used. It can prevent being energized in the state.

  Hooks 41 for connecting the guide member 26 to the water storage tank 15 are respectively attached to the front surface and the back surface of the upper end portion of the water storage tank 15. Each hook 41 is rotatable in a vertical plane along the front-rear direction around the rotation shaft 41A, and is guided in a state where each tip is rotated to the highest position (the state shown in FIG. 5). The guide member 26 is pressed against the water storage tank 15 by being caught by the lower end edge of the member 26. In this state, the lid 16 is sandwiched between the upper end of the water storage tank 15 and the lower end of the guide member 26, and the water storage tank 15, the lid 16 and the guide member 26 are integrally connected.

  The upper part of the left cylinder portion 10 of the housing 2 (the portion surrounding the mist generating device 12) constitutes a cover 2A that can be attached to and detached from the housing 2. An operation portion 42 that is operated when removing the cover 2A from the housing 2 is attached to the upper rear side of the cover 2A. The operation portion 42 is exposed to the rear side through the rear surface of the cover 2A through the claw portion 44 that can be engaged with the engagement hole 43 formed in the housing 2, and forward when the cover 2A is removed from the housing 2. A pressing portion 45 that is pressed toward the front, and an elastic deformation portion 46 that is elastically deformed as the pressing portion 45 is pressed and rotates the claw portion 44 forward. When the pressing portion 45 is pressed and the claw portion 44 is rotated forward, the engagement of the claw portion 44 with the engaging hole 43 is released, and the cover 2 </ b> A can be removed from the housing 2. When the cover 2A is removed from the housing 2, the mist generating device 12 is exposed to the outside of the machine.

  When the mist generating device 12 is slid to the left in the horizontal direction with the cover 2A removed from the housing 2, the three pins 38 come out of the corresponding jacks 40, and the right end of the air supply path 20 is connected to the supply port 21 (packing). 22). In this way, after removing the mist generating device 12 from the air cleaner 1, if the two hooks 41 are rotated to disengage the leading end from the guiding member 26, the guiding member 26 is removed from the water storage tank 15. Can be removed. When the guide member 26 is removed from the water storage tank 15, it is possible to further remove the lid 16 from the water storage tank 15. By removing the cover 16 from the water storage tank 15 so as to be removed from the water storage tank 15, It becomes possible to supply water into the tank 15. Thus, by making the insertion member 17 detachable with respect to the inside of the water storage tank 15, the insertion member 17 is removed from the water storage tank 15, and an electrical component or the like (for example, an electrode plate 35) The water tank 15 can be replenished with no other parts (empty state). Therefore, it is possible to easily and safely supply water to the water storage tank 15.

  In this embodiment, as described above, since the lower end of the water level detection electrode 36 is located above the lower end of the electrode plate 35, a notification that the water in the water storage tank 15 is less than the predetermined water level (water storage When the notification that water should be replenished in the tank 15) is performed, the lower end portion of the insertion member 17 is still immersed in the water in the water storage tank 15. Even in such a case, when the insertion member 17 is removed from the water storage tank 15 in order to supply water to the water storage tank 15, the water in the bubble generating chamber 18 flows out into the water storage tank 15 through the water passage hole 17C. The water in the electrolysis chamber 19 flows out into the water storage tank 15 through the water passage hole 17A. Therefore, the insertion member 17 is removed from the water storage tank 15 with water in the bubble generation chamber 18 or the electrolysis chamber 19, and the water in the bubble generation chamber 18 or the electrolysis chamber 19 is outside the water storage tank 15. Spilling can be prevented.

In this embodiment, since the pair of electrode plates 35 and the water level detection electrode 36 are disposed in the insertion member 17, the electrode plate 35 and the water level detection can be performed even when the insertion member 17 is extracted from the water storage tank 15. It is possible to prevent external contact with the electrode for water 36 and protect the electrode plate 35 and the water level detection electrode 36.
After replenishing the water into the water storage tank 15, the insertion member 17 is inserted into the water storage tank 15 so that the opening of the water storage tank 15 is closed with the lid 16, and a guide member 26 is disposed above the lid 16. By rotating the one hook 41, each hook 41 can be engaged with the guide member 26, and the water storage tank 15, the lid 16, and the guide member 26 can be integrally connected. Thereafter, the integrated mist generating device 12 is inserted into the housing 2 so as to slide rightward, thereby inserting the three pins 38 into the corresponding jacks 40 and the right end of the air supply path 20. Can be pressed against the packing 22 to attach the mist generator 12 to the air cleaner 1.

In this embodiment, the water tank 15 can be removed from the air cleaner 1 and water can be easily put into the water tank 15.
In particular, when the water storage tank 15 is attached to and detached from the air purifier 1, the pin 38 and the air supply path 20 can be attached to and detached from the air purifier 1 at the same time. Work becomes easier.

  Moreover, since the connection part (jack 40) with respect to the air cleaner 1 of the pin 38 and the connection part (supply port 21) with respect to the air cleaner 1 of the air supply path 20 are arrange | positioned above the water storage tank 15, It is possible to prevent the water in the water storage tank 15 from flowing back to the air pump 13 side through the bubble generation mechanism such as the air supply path 20, and the water in the water storage tank 15 is applied to the pins 38 and the jacks 40, resulting in poor conduction. Can be prevented.

  Furthermore, since the connection part (jack 40) with respect to the air cleaner 1 of the pin 38 and the connection part (supply port 21) with respect to the air cleaner 1 of the air supply path 20 are mutually arrange | positioned, the water storage tank 15 (mist) When attaching and detaching the generator 12) to and from the air cleaner 1, it is easy to attach and detach by observing these two connecting parts at the same time and attaching and detaching while paying attention to the connection state of these connecting parts. It can be carried out.

  FIG. 8 is a diagram for explaining the configuration of the insertion member 50 according to a modification of the above embodiment, and shows a cross section when the vicinity of the left cylinder portion 10 is cut by a vertical plane along the front-rear direction. A sectional view seen from the side is shown. FIG. 9 is a cross-sectional view taken along the arrow FF shown in FIG. The insertion member 50 has substantially the same configuration as the insertion member 17 according to the above-described embodiment, except that a part of the insertion member 50 forms an attachable / detachable portion 51. Therefore, since the configuration other than the configuration related to the detachable portion 51 is the same as the configuration of the above embodiment, the same reference numerals are given to the drawings and the description thereof is omitted.

  With reference to FIGS. 8 and 9, among the partition walls constituting the side surface of the insertion member 50, the portion from the upper end to the lower end portion of the left side wall 50 </ b> A that defines the left side of the electrolysis chamber 19 and the right side of the electrolysis chamber 19 are A portion from the upper end to the lower end portion of the right wall 50B to be divided and a portion from the upper end to the lower end portion of the rear wall 50C to define the rear surface of the electrolysis chamber 19 are formed in a substantially U shape in plan view. The detachable part 51 is configured. A plurality of water holes 52 are formed in each of the left wall 50A, the right wall 50B, and the rear wall 50C.

  Locking claws 53 that protrude rearward are formed on the left and right ends of the front wall 50D that partitions the front surface of the electrolysis chamber 19, and the front end of the section that partitions the left wall 50A of the detachable section 51, and the right Locking holes 54 for hooking and locking the corresponding locking claws 53 are formed at the front end portions of the portions defining the face wall 50B. Thus, if the detachable part 51 is configured to be detachable, by removing the detachable part 51, the electrolysis chamber 19 is opened and maintenance in the electrolysis chamber 19 (for example, the electrode plate 35 and the water level detection electrode 36). Removal of mineral content (so-called scale) contained in the water adhering to the water.

  The lower ends of the pair of electrode plates 35 disposed in the electrolysis chamber 19 have substantially the same height, and are positioned below the lower end of the water level detection electrode 36. Further, the lower end portion of the detachable portion 51 is located near the lower end of the electrode plate 35 or below the lower end of the electrode plate 35. Therefore, by removing the attaching / detaching portion 51, the periphery of the electrode plate 35 and the water level detecting electrode 36 can be widely released, and the electrode plate 35 and the water level detecting electrode 36 can be easily attached to and detached from the electrolysis chamber 19. Maintenance can be performed more easily.

FIG. 10 is a block diagram showing an electrical configuration of the air cleaner 1.
The operation of the air cleaner 1 is controlled by a control unit 100 including a microcomputer. The control unit 100 includes a CPU 101, a ROM 102, a RAM 103, a timer 104, and the like.
The control unit 100 includes a dirt sensor 105 for detecting dirt in the air taken into the aircraft from the intake port 8 and a user's operation to drive the air pump 13 in a plurality of stages (for example, “strong” and “weak”). The signal from the air amount changing operation unit 106 for changing the amount of air supplied into the water storage tank 15 is input respectively. As the dirt sensor 105, for example, a sensor that irradiates light from the air inlet 8 into the machine and detects dirt based on the light transmittance can be adopted.

Further, the motor 5, the air pump 13, the electrode plate 35, the light emitting element 33, and the like are connected to the control unit 100 as control targets.
FIG. 11 is a time chart showing an operation mode during continuous operation of the air cleaner 1.
FIG. 11A shows an operation mode of the air cleaner 1 when the air pump 13 is driven “weak”. As shown in FIG. 11A, when the drive of the air pump 13 is set to “weak”, the energization to the electrode plate 35 is turned on for a predetermined electrolysis period T1 (for example, 4 minutes), This cycle is repeated, with one cycle of 90 minutes of intermittent control that turns off the energization to the electrode plate 35 during the non-electrolytic period T2 (for example, 86 minutes). During this time, the air pump 13 is constantly driven at a constant rotational speed, and bubbles are constantly generated in the electrolyzed water in the water storage tank 15 by sending a constant amount of air per unit time into the water storage tank 15. .

  When energization to the electrode plate 35 is started in a state where the electrolyzed water concentration (free residual chlorine concentration) is A1, the electrolyzed water concentration gradually increases, and the electrolyzed water concentration becomes A2 when the electrolysis period T1 elapses. Thereafter, when the energization to the electrode plate 35 is stopped, only the air pump 13 is driven until the non-electrolytic period T2 elapses. During the non-electrolytic period T2, bubbles are generated in the electrolyzed water in the water storage tank 15, so that the amount of contact of electrolyzed water with the air increases, and as a result, the electrolyzed water concentration gradually decreases. Then, when the non-electrolytic period T2 elapses, the electrolyzed water concentration decreases again to A1, and then the energization of the electrode plate 35 is started, whereby the electrolyzed water concentration increases again. By repeating such intermittent control, the average value of the electrolytic water concentration in the water storage tank 15 becomes AV.

FIG. 12 is a flowchart showing a flow of control performed by the control unit 100 based on an input signal from the dirt sensor 105 or the air amount changing operation unit 106 during continuous operation.
As shown in FIG. 12, during the continuous operation, the control unit 100 monitors whether or not the driving of the air pump 13 is set to “strong” based on the input signal from the air amount changing operation unit 106. (Step S1). When the driving of the air pump 13 is set to “strong” (YES in step S1), the control unit 100 drives the air pump 13 to “strong” (step S2) and sets the non-electrolytic period T2 56 minutes is set (step S3).

  When the driving of the air pump 13 is set to “weak” (NO in step S1), the control unit 100 stains air taken into the air purifier 1 based on the input signal from the dirt sensor 105. It is monitored whether or not the amount is greater than or equal to a predetermined amount (step S4). When the amount of dirt is less than the predetermined amount (NO in step S4), the control unit 100 drives the air pump 13 with “weak” (step S5) and sets the non-electrolytic period T2 to 86 minutes (step S5). Step S6). On the other hand, when the amount of dirt is equal to or greater than the predetermined amount (YES in step S4), the control unit 100 drives the air pump 13 "strong" (step S2) and sets the non-electrolytic period T2 to 56 minutes. (Step S3).

In this way, until the operation of the air purifier 1 is finished (until YES in step S7), the control unit 100 performs step S1 based on the input signals from the air amount changing operation unit 106 and the dirt sensor 105. The control of ~ S6 will be repeated.
The control that repeats steps S1 to S6 is not limited to a configuration that is always performed during continuous operation of the air purifier 1, and for example, a process (electrolytic mist process) that repeats the control of steps S1 to S6 is executed. The configuration may be such that it is executed when an operation is performed. In this case, the electrolytic mist process may be performed for a predetermined time, or the amount of dirt of air taken into the air cleaner 1 is determined based on the input signal from the dirt sensor 105. The configuration may be such that it is executed until the amount is below the fixed amount.

  The change in the electrolyzed water concentration when the driving of the air pump 13 is “strong” is as shown in FIG. Even when the driving of the air pump 13 is switched to “strong”, during the electrolysis period T1, the change in the contact amount of the electrolytic water with respect to the air has a small influence on the electrolytic water concentration, and the driving of the air pump 13 is “weak” The concentration of electrolyzed water increases at approximately the same rate. On the other hand, during the non-electrolytic period T2, due to an increase in the amount of contact of the electrolyzed water with the air accompanying an increase in bubbles generated in the electrolyzed water in the water storage tank 15, the driving of the air pump 13 is less than when the drive is “weak”. The electrolyzed water concentration decreases at a large rate. Even in such a case, the non-electrolysis period T2 is set to a value corresponding to the decreasing rate of the electrolyzed water concentration (for example, 56 minutes shorter than when the driving of the air pump 13 is “weak”). When the electrolysis period T2 elapses, the electrolyzed water concentration is A1. According to such a configuration, the concentration of the electrolyzed water in the water storage tank 15 gradually decreases as a whole, and the sterilizing effect and the deodorizing effect are not reduced.

  When the driving of the air pump 13 is “strong”, the intermittent control as described above is repeated, so that the average value of the concentration of the electrolyzed water in the water storage tank 15 is AV. As described above, the average value of the concentration of the electrolyzed water in the water storage tank 15 is constant (AV) regardless of whether or not the amount of air supplied to the water storage tank 15 is changed (the air pump 13 is switched between strong and weak). . Therefore, it can prevent that the average density | concentration of electrolyzed water changes with the change of air quantity.

  In this embodiment, when the dirt sensor 105 detects a dirt of a predetermined amount or more (when the air taken into the air conditioner 1 is dirty), the amount of air supplied to the water storage tank 15 is automatically set. The bubbles generated in the electrolyzed water are increased. Thereby, since the generation amount of mist can be increased, the sterilization effect and the deodorizing effect of the air by mist can be improved more.

In this embodiment, the user can increase the amount of air supplied to the water storage tank 15 and increase the amount of bubbles generated in the electrolyzed water by operating the air amount changing operation unit 106. Thereby, since the generation amount of mist can be increased, the sterilization effect and the deodorizing effect of the air by mist can be improved more.
The present invention is not limited to the contents of the above embodiments, and various modifications can be made within the scope of the claims.

For example, as long as the spray port 14 is configured to supply mist from the vicinity of the exhaust port 9 through which the cleaned air is discharged, the spray port 14 is not limited to the position as in the above embodiment, but is formed at another position. May be.
The air for generating bubbles in the water in the water storage tank 15 is not limited to the configuration in which the air pump 13 is used to guide the water to the water storage tank 15 side. For example, the air is released by the fan 4 without using the air pump 13. A part of the air may be directly guided to the water storage tank 15 side.

During the electrolysis period T1, the configuration may be such that the driving of the air pump 13 is stopped. Further, during the non-electrolytic period T2, if the concentration of the electrolyzed water is reduced as a whole, the energization to the electrode plate 35 is not completely turned off, for example, a voltage lower than that during the electrolysis period T1. May be applied.
In the said embodiment, although the air cleaner 1 was demonstrated as an example of an air conditioner, this invention is applicable not only to an air cleaner but other air conditioners, such as a humidifier and an air conditioner.

  Moreover, it is also possible to provide an electrolyzed water spray apparatus by applying this invention to the apparatus which does not have an air conditioning function.

It is a perspective view which shows the external appearance structure of the air cleaner which concerns on one Embodiment of this invention. It is the schematic sectional drawing seen along arrow AA shown in FIG. It is the schematic sectional drawing seen along arrow BB shown in FIG. It is an expanded sectional view which expands and shows the cross section of the vicinity of the left cylinder part in FIG. It is sectional drawing seen along the arrow CC shown in FIG. It is sectional drawing seen along the arrow DD shown in FIG. It is sectional drawing seen along the arrow EE shown in FIG. It is a figure for demonstrating the structure of the insertion member which concerns on the modification of the said embodiment, Comprising: Sectional drawing which looked at the cross section when the vicinity of the left cylinder part was cut | disconnected by the vertical surface along the front-back direction from the left side Is shown. It is sectional drawing seen along arrow FF shown in FIG. It is a block diagram which shows the electrical structure of this air cleaner. It is a time chart which shows the operation | movement aspect in the continuous driving | operation of this air cleaner. It is a flowchart which shows the flow of control which a control part performs based on the input signal from a dirt sensor or an air quantity change operation part during a continuous driving | operation. It is a time chart which shows the specific example of the aspect which performs electricity supply to an electrode plate intermittently.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Air cleaner 14 Spraying port 15 Water storage tank 18 Foam generation chamber 20 Air supply path 25 Discharge port 28 1st division chamber 30 Communication port 35 Electrode plate 100 Control part 105 Dirt sensor 106 Air quantity change operation part T1 Electrolytic period T2 Non-electrolysis period

Claims (7)

An air conditioner for performing air conditioning by taking in air outside the machine, performing predetermined processing and discharging it outside the machine,
A water reservoir that can store water,
An electrode for electrolyzing water stored in the water storage section to generate electrolyzed water;
A bubble generating mechanism for supplying air to the water storage unit and generating bubbles in the water stored in the water storage unit;
Mist supply means for supplying the mist generated when the bubbles generated by the bubble generation mechanism are released from the water surface of the water stored in the water storage unit to the atmosphere to the outside. ,
A concentration increasing period for increasing the concentration of electrolyzed water by performing electrolysis with the electrode and a concentration decreasing period for decreasing the concentration of the electrolyzed water by supplying air from the bubble generating mechanism to the water reservoir are alternately repeated. Meanwhile, electrolytic mist supply control means for supplying mist of electrolyzed water from the mist supply means,
An air amount changing means for changing the amount of air supplied from the bubble generating mechanism to the water reservoir;
Electrolyzed water concentration that adjusts the concentration of the electrolyzed water generated during the control of the electrolytic mist supply control means by changing the concentration reduction period according to the amount of air supplied from the bubble generating mechanism to the water reservoir. An air conditioner comprising adjusting means.   2. The air conditioner according to claim 1, wherein the electrolytic mist supply control means supplies air from the bubble generating mechanism to the water storage unit while performing electrolysis with the electrode during the concentration increasing period. Machine.   The electrolytic water concentration adjusting means changes the concentration decreasing period only in accordance with the amount of air supplied from the bubble generating mechanism to the water storage unit without changing the concentration increasing period, thereby supplying the electrolytic mist supply. The air conditioner according to claim 1 or 2, wherein the concentration of electrolyzed water generated during the control of the control means is adjusted. Including dirt detecting means for detecting dirt of air taken into the air conditioner,
The air amount changing means changes the amount of air supplied from the bubble generating mechanism to the water storage section according to the detection result of the dirt detecting means. The air conditioner described in Crab.   The said air quantity change means changes the air quantity supplied to the said water storage part from the said foam generation mechanism in response to predetermined | prescribed operation, The any one of Claims 1-3 characterized by the above-mentioned. Air conditioner.   The air conditioner according to any one of claims 1 to 5, wherein the electrode can generate electrolyzed water containing hypochlorous acid by electrolyzing tap water stored in the water storage section. . A water reservoir that can store water,
An electrode for electrolyzing water stored in the water storage section to generate electrolyzed water;
A bubble generating mechanism for supplying air to the water storage unit and generating bubbles in the water stored in the water storage unit;
Mist supply means for supplying the mist generated when the bubbles generated by the bubble generation mechanism are released from the water surface of the water stored in the water storage unit to the atmosphere to the outside. ,
A concentration increasing period for increasing the concentration of electrolyzed water by performing electrolysis with the electrode and a concentration decreasing period for decreasing the concentration of the electrolyzed water by supplying air from the bubble generating mechanism to the water reservoir are alternately repeated. Meanwhile, electrolytic mist supply control means for supplying mist of electrolyzed water from the mist supply means,
An air amount changing means for changing the amount of air supplied from the bubble generating mechanism to the water reservoir;
Electrolyzed water concentration that adjusts the concentration of the electrolyzed water generated during the control of the electrolytic mist supply control means by changing the concentration reduction period according to the amount of air supplied from the bubble generating mechanism to the water reservoir. An electrolyzed water spraying device comprising adjusting means.

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