JP2006006563A - Mist generator and air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mist generator and an air conditioner capable of operating appropriately in response to surrounding atmosphere of the apparatuses. <P>SOLUTION: A controller examines a detection content of each sensor and determines whether or not a level 4 detection exists. When a level 4 sensing is sensed at any of the sensors (if step T1 is YES), mist generation amount is turned to "strong" and wind volume is also turned to "strong" (step T2). When a level 4 sensing is not found in the detection contents of the sensors (if the step T1 is NO), whether or not a level 3 sensing exists is then determined. By doing so, the apparatuses operate according to each sensing level and can operate appropriately (efficiently). <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a mist generator and an air conditioner including the mist generator.

  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 through which air taken in is passed. The air taken into the machine passes through a filter to remove dust contained in the air (see, for example, Patent Document 1).

However, in the air cleaner as disclosed in Patent Document 1, although dust and the like contained in the air are removed, microbacteria that cannot be sterilized by the filter are sterilized and odors are deodorized. It is not possible. 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 Patent Document 2, a liquid having a sterilizing action and a deodorizing action is accommodated in a water storage section, and a mist generated using the liquid is discharged to the outside of 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, once the operation is started, the operation is continued regardless of changes in the atmosphere such as temperature and humidity outside the device. On the other hand, for example, the activity (activity range) of fungi and viruses present in the air varies depending on the temperature and humidity, and dust that has fallen on the floor (stacked on the floor) rises with the movement of a person. In other words, since the necessity to clean the air changes according to the atmosphere outside the machine, it is said that the air cleaner as described above is appropriately operated according to the atmosphere outside the machine. It may be difficult. In addition, a dedicated liquid for generating mist must be accommodated in the water storage section, which is troublesome.

The present invention has been made under such a background, and an object thereof is to provide a mist generating apparatus and an air conditioner that can perform an appropriate operation according to the atmosphere around the apparatus.
Another object of the present invention is to provide a mist generator and an air conditioner that can achieve a sterilizing function and a deodorizing function without preparing a dedicated liquid.

  In order to achieve the above object, the invention according to claim 1 is a mist generating device (12) for discharging mist, a water storage section (15) capable of storing water, and a reservoir in the water storage section. Electrode (35) for electrolyzing the generated water to generate electrolyzed water, information detecting means for detecting atmosphere information (3A, 3B, 3C, 10B) around the apparatus, and the information detecting means The bubble generation mechanism (13, 18, 20, 21) for generating bubbles in the electrolyzed water of the water storage unit, which is controlled according to the atmosphere information, and the bubbles generated by the bubble generation mechanism are in the atmosphere A mist generating device comprising: mist discharging means (4) for discharging mist generated by flipping when released to the outside of the device.

The alphanumeric characters in parentheses indicate corresponding components in the embodiments described later. The same applies hereinafter.
According to this configuration, mist is generated and released outside the apparatus according to the atmosphere information. For example, if the mist is discharged outside the apparatus according to the atmosphere information that the atmosphere around the apparatus is dirty, it is possible to perform an appropriate operation according to the atmosphere and to save a useless operation. .

  In addition, electrolyzed water containing hypochlorous acid (HClO) and active oxygen having a bactericidal action and a deodorizing action by electrolyzing water (for example, tap water) stored in the water storage part by energizing the electrodes Can be generated. And by generating a bubble by a bubble generation mechanism with respect to this generated electrolyzed water, it is possible to generate a mist having a bactericidal action and a deodorizing action. By discharging this mist outside the apparatus, a dedicated mist can be generated. A sterilizing function and a deodorizing function can be achieved without preparing a liquid.

The invention according to claim 2 is characterized in that the information detection means includes a temperature detection means (10B) for detecting the temperature around the apparatus and a humidity detection means (10B) for detecting the humidity around the apparatus. The mist generator (12) according to claim 1.
According to this configuration, mist is generated and released outside the apparatus according to the detected temperature and humidity around the apparatus. In general, the atmosphere in which fungi and viruses are likely to be active is determined by temperature and humidity. In other words, when the air around the apparatus reaches a temperature and humidity at which fungi and viruses are likely to be active, appropriate (efficient) operation can be performed by generating mist and releasing it from the apparatus.

The invention according to claim 3 is characterized in that the information detecting means includes an operation detecting means (3A) for detecting the movement of the object surrounding the apparatus. The mist generating apparatus (12) according to claim 1 or 2, It is.
According to this configuration, mist is generated and released outside the apparatus in accordance with the movement of the thing around the apparatus. For example, dust that has fallen on the floor (stacked on the floor) causes a flow of air due to the movement of a person, and the dust flows up by this air flow, and the air becomes dirty. That is, when a thing moves around the apparatus, it is possible to perform an appropriate (efficient) operation by generating a mist and releasing it from the apparatus.

The movement around the apparatus is, for example, the movement of a person or the movement of a pet.
The invention according to claim 4 is characterized in that the information detection means includes gas detection means (3B) for detecting the presence of a predetermined gas around the apparatus. It is a mist generator (12) of description.
According to this configuration, in response to the presence of a predetermined gas around the device, mist is generated and released outside the device. Therefore, it is possible to perform an appropriate (efficient) operation according to the presence of gas.

The invention according to claim 5 is characterized in that the information detection means includes dust detection means (3C) for detecting that a predetermined amount or more of dust is floating around the apparatus. It is a mist generator (12) in any one of.
According to this configuration, when a predetermined amount or more of dust is floating around the apparatus, mist is generated and discharged outside the apparatus. Therefore, it is possible to perform an appropriate (efficient) operation according to the dust floating.

  The invention according to claim 6 is characterized in that the mist discharging means includes a wind supply means (4) for discharging the generated mist to the outside of the apparatus, and the bubble generating mechanism (13, The mist generating device (12) according to any one of claims 1 to 5, wherein the amount of foam generated by 18, 20, 21) and the strength of wind by the wind supply means are adjusted (T1 to T9). It is.

  According to this configuration, the amount of mist generated and the strength of the wind are adjusted according to the degree of necessity for generating mist, that is, the atmosphere information. For example, if the temperature and humidity around the device are extremely susceptible to fungi and viruses, a large amount of mist is generated, and the wind force for releasing the mist to the outside of the device is increased. A large amount of mist can be diffused far away, and the sterilizing function and deodorizing function are improved. In this way, more appropriate (efficient) operation can be performed according to the atmosphere around the apparatus.

Invention of Claim 7 is provided with the mist generator (12) in any one of Claims 1-6, It is an air conditioner (1) characterized by the above-mentioned.
According to this structure, the air conditioner which produces the effect similar to the mist generator in any one of Claims 1-6 can be provided.

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. In addition, a human sensor 3 </ b> A that detects the movement of an object outside the machine (mainly a person) and a gas detection sensor that detects the presence of a predetermined gas outside the machine above the front plate 3 in order from the left. 3B and a dust detection sensor 3C that detects dust floating in the air outside the machine (details will be described later).

  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. Above the right cylinder 10 is provided a temperature / humidity detection sensor 10B that detects the temperature and humidity outside the machine (details will be described later), and a vent 11 is formed on the side surface. Further, a through hole 10 </ b> C communicating with the space in the right cylinder portion 10 is formed in the front side portion (front side of the filter 6) of the right side wall forming the opening 7. With this configuration, when the fan 4 is rotated, outside air is sucked into the right cylinder portion 10 from the vent hole 11, and as shown by the 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. The mist generated from the mist generating device 12 is discharged outward from the spray port 14 formed on the upper end surface of the left cylinder portion 10.

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.
Referring to FIGS. 4 to 6, 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 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.

  Among the partition walls constituting the side surface of the insertion member 17, a portion from the upper end to the lower end portion of the left surface wall 19 </ b> A that partitions the left surface of the electrolytic chamber 19 in the insertion member 17, and a right wall 19 </ b> B that partitions the right surface of the electrolytic chamber 19. The part from the upper end to the lower end of the battery and the part from the upper end to the lower end of the rear wall 19C that defines the rear surface of the electrolysis chamber 19 constitute a substantially U-shaped attaching / detaching part 191 formed integrally. is doing. A plurality of water holes 17B are formed in the left wall 19A, the right wall 19B, and the rear wall 19C, respectively.

  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.

  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). In addition, a guide member 26 is disposed above the lid 16, and 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 left and right. . 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.

  In plan view, a connection box 39 for connecting the pair of electrode plates 35 and the water level detection electrode 36 to a power source is disposed on the right side of the mist generating device 12 (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. .

  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.

  Further, on both left and right end portions of the front wall 19D that partitions the front surface of the electrolysis chamber 19, a locking claw 19E that protrudes rearward is formed, and the front end portion of the portion that partitions the left wall 19A of the detachable portion 191, In addition, a locking hole 19F for hooking and locking the corresponding locking claw 19E is formed at the front end portion of the portion defining the right wall 19B. Thereby, the detachable part 191 can be removed, the electrolysis chamber 19 is opened, and maintenance in the electrolysis chamber 19 (for example, a mineral content (so-called scale) contained in water attached to the electrode plate 35 or the water level detection electrode 36). Etc.).

  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.

When a predetermined voltage (for example, 10 V) is applied to the pair of electrode plates 35 so as to have opposite polarities in a state where the water is stored in the water storage tank 15, water between the pair of electrode plates 35 is present. Current flows through 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 hypochlorous acid (HClO) and active oxygen having a bactericidal action and a deodorizing action can be generated. Further, energization is performed to the water level detection electrode 36 and one of the pair of electrode plates 35, and the water in the water storage tank 15 has a predetermined water level (the lower end of the water level detection electrode 36 depending on the energization state at that time). It is possible to detect whether the water level is less than the water level.

  Further, 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 pressure in the bubble generation chamber 18 is supplied by the pressure. Water is agitated and a 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.
Further, 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, and water is stored via the transparent cover 32. Bubbles generated in the water in the tank 15 can be visually recognized. Further, 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. You can also brightly illuminate the water.

  Further, a discharge port 25 for discharging the mist generated in the water storage tank 15 to the outside of the water storage tank 15 is formed in the lid 16 at a position above the small hole 24. The discharge port 25 faces the rear part of the first compartment 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 hits the inner wall surface of the guide member 26 (first compartment 28) above the outlet 25 and spreads over the entire first compartment 28, and then communicates with the mist. It is discharged from the spraying port 14 through the mouth 30 to the outside of the apparatus.

  Thus, when generating mist, the above-mentioned electrolyzed water is generated in parallel. That is, mist having a bactericidal action and a deodorizing action can be generated by sending air to the generated electrolyzed water from the air pump 13 through the air supply path 20 and generating bubbles. If the mist having the sterilizing action and the deodorizing action generated in this way is discharged from the spray port 14 to the outside of the apparatus, a sterilizing function and a deodorizing function are achieved using tap water without preparing a dedicated liquid. be able to. By releasing a mist having a bactericidal action outside the machine, allergy can be suppressed.

  Further, since the spray port 14 is disposed in the vicinity of the exhaust port 9, mist discharged from the spray port 14 to the outside of the apparatus can be mixed into the air discharged from the exhaust port 9 (exhaust port 9). Can be released to the outside by wind released from the air). 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.

FIG. 7 is a block diagram showing an electrical configuration of the air purifier 1.
The human sensor 3A, the gas detection sensor 3B, the dust detection sensor 3C, the temperature / humidity detection sensor 10B, the motor 5 and the air pump 13 are connected to the control unit 60. The control unit 60 is mainly configured by a microcomputer including a CPU, a ROM, and the like, and is input from a human sensor 3A, a gas detection sensor 3B, a dust detection sensor 3C, and a temperature / humidity detection sensor 10B as described later. In response to the signal, the operation of the motor 5 and the air pump 13 is controlled.

The human sensor 3 </ b> A detects the movement of things around the outside of the apparatus, and uses, for example, an infrared sensor, and mainly detects the movement of a person.
The gas detection sensor 3B detects the presence of gas by, for example, reading a change in electrical resistance of the sensor caused by the gas. The gas is a so-called reducing gas such as methane or ethane. For example, the presence of tobacco smoke or an insecticide can be detected.

The dust detection sensor 3C detects, for example, that a predetermined amount or more of dust is floating in the air by irradiating light into the air in a predetermined space and reading the light disturbance or the amount of light irradiation. To do.
The temperature / humidity detection sensor 10B includes, for example, a thermistor and detects temperature and relative humidity in the air.

  The situation in which the air cleaner 1 should be operated varies depending on the state of air outside the machine. That is, in general, it can be said that an efficient operation is to operate the air purifier when the air is dirty and to stop the operation when the air is clean. Moreover, energy saving can also be achieved by performing such an operation. Therefore, in this embodiment, the human sensor 3A, the gas detection sensor 3B, the dust sensor 3C, and the temperature / humidity detection sensor 10B are provided and operated as follows.

In the air cleaner 1, when an operation unit (not shown) is operated by the user, the motor 5 is driven, the fan 4 is rotated, and air cleaning is started. During the cleaning operation, mist is released in response to detection by each sensor.
For example, the temperature / humidity detection sensor 10B will be described as an example.
FIG. 8 is a diagram for explaining the state of air in which fungi and viruses are likely to be active. A region 61 in which fungi are generally active is indicated by an area 61, and viruses are generally active. An easy range is indicated by region 62.

That is, mold fungi are likely to be active when the humidity is about 65% or more regardless of temperature. On the other hand, the virus is active when the temperature is about 10 to 12 ° C. or less, and when the humidity is 45% or less, the virus is active even when the temperature is high as the humidity decreases.
In such a state where mold fungi and viruses are active, it is desirable to release mist out of the aircraft. Therefore, the air cleaner 1 is controlled as follows according to the detection of the temperature / humidity detection sensor 10B.

FIG. 9 is a flowchart showing a control procedure of the control unit 60 according to detection by the temperature / humidity detection sensor 10B.
First, it is determined whether or not the temperature outside the apparatus detected by the temperature / humidity detection sensor 10B is 12 ° C. or less. And if temperature is 12 degrees C or less (it is YES at step S1), while energizing the pair of electrode plates 35 and generating electrolyzed water, the air supply path 20 is supplied from the air pump 13 to the generated electrolyzed water. Air is sent through and bubbles are generated, so that a mist having a sterilizing action and a deodorizing action is generated (step S2). The mist discharged from the spray port 14 to the outside of the apparatus is discharged to the outside by the wind discharged from the exhaust port 9.

  If the outside temperature is higher than 12 ° C. (NO in step S1), it is further determined whether or not the temperature is 25 ° C. or less. If the temperature outside the apparatus is greater than 12 ° C. and 25 ° C. or less (YES in step S3), it is then determined whether the humidity is 35% or less or greater than 65%. If the humidity is 35% or less or greater than 65%, mist is discharged outside the apparatus in the same manner as above (YES in step S4 → S2).

If the temperature outside the apparatus is higher than 25 ° C. (NO in step S3), it is further determined whether or not the humidity is 25% or less or higher than 65%. If the humidity is 25% or less or greater than 65%, the mist is discharged to the outside in the same manner as above (YES in step S5 → S2).
On the other hand, when the temperature outside the apparatus is greater than 25 ° C. and the humidity is greater than 25% and 65% or less (NO in step S5), the energization to the pair of electrode plates 35 is stopped and the electrolyzed water is discharged. Is stopped and the supply of air from the air pump 13 is also stopped. Then, the release of mist to the outside of the machine is stopped (step S6). Similarly, when the temperature outside the apparatus is 25 ° C. or lower and the humidity is higher than 35% and 65% or lower (NO in step S4), the release of mist to the outside of the apparatus is stopped.

In this way, mist is discharged outside the apparatus according to the detection contents of the temperature / humidity detection sensor 10B. That is, since the mist is released when it is considered that the temperature and humidity outside the apparatus are substantially included in the region 61 or the region 62 shown in FIG. 8, it is possible to discharge the mist appropriately (effectively).
For other sensors, mist is released in response to detection. That is, for the human sensor 3A, the gas detection sensor 3B, and the dust detection sensor 3C, the pair of electrode plates 35 are energized to generate electrolyzed water in response to the respective detections. Air is sent from the air pump 13 to the electrolyzed water, mist is generated, and discharged outside the apparatus. As a result, an appropriate operation according to the atmosphere outside the machine is possible.

As described above, in this embodiment, mist is generated according to the atmosphere information around the apparatus detected by the human sensor 3A, the gas detection sensor 3B, the dust detection sensor 3C, and the temperature / humidity detection sensor 10B. Since it is discharged out of the apparatus, it is possible to perform an appropriate (efficient) operation.
In addition, the electrode 35 is energized to electrolyze water (for example, tap water) stored in the water storage tank 15, thereby containing hypochlorous acid (HClO) and active oxygen having a sterilizing action and a deodorizing action. By generating electrolyzed water and generating bubbles in the electrolyzed water, it is possible to generate mist having a bactericidal action and a deodorizing action. By discharging this mist to the outside of the apparatus, a sterilizing function and a deodorizing function can be achieved without preparing a dedicated liquid.

In this embodiment, the description has been made assuming that the strength and the amount of mist generated from the air cleaner 1 (exhaust port 9) to the outside of the device are constant, but these may be controlled as follows. Is possible.
FIG. 10 is a flowchart showing a control procedure of the control unit 60 according to another embodiment of the present invention.

As other embodiment, the control part 60 divides the detection content of each sensor into the level of 1-4, and controls the driving | operation of the air cleaner 1 according to the detection level. The level of detection in the control unit 60 is performed according to the frequency of detection by each sensor and the content of detection.
For example, in the detection of the temperature / humidity detection sensor 10B, in the diagram showing the temperature and humidity outside the apparatus as shown in FIG. 8, the range in which fungi and viruses are active is divided into four areas. Then, the area where mold fungus and virus are most likely to be active is designated as level 4 area, the area where mold fungus and virus are likely to be active is designated as level 3, and the area where mold fungus and virus are likely to be active is designated as level 4. Region 2 is defined as a level 1 region where mold and virus activity is not so active. Then, the detection content is divided into levels 1 to 4 depending on which level the detection content of the temperature / humidity detection sensor 10B is included in.

  Further, for example, in the detection by the human sensor 3A, the detection level is classified according to the frequency of the number of detections per unit time. Specifically, one unit is defined as detecting a movement of an object 3 or more times in 10 seconds. If this unit continues 5 or more times, level 4 is obtained. Level 2 and level 1 if once (if not consecutive) are divided into levels 1 to 4. The same detection is also performed in the other sensors (gas detection sensor 3B and dust detection sensor 3C).

The level classification of the detection contents of each sensor is not limited to the above, and various changes can be made.
During operation of the air purifier 1, first, the control unit 60 determines whether or not there is level 4 detection among the detection contents of each sensor. If any of the sensors has level 4 detection (YES in step T1), the voltage applied to the pair of electrode plates 35 is raised, and the concentration is high (hypochlorous acid or active oxygen is abundant). Electrolyzed water is generated and the amount of air sent from the air pump 13 is increased, and a large amount of mist containing a large amount of hypochlorous acid and active oxygen is generated and released to the outside of the aircraft ( The amount of mist generated is considered “strong”). Further, by increasing the rotational speed of the motor 5, the momentum of the wind discharged from the exhaust port 9 to the outside of the machine increases (the air volume is made “strong”) (step T2). Thereby, mist with a higher bactericidal effect and deodorizing effect diffuses far away.

  In this description, the amount of air discharged from the exhaust port 9 to the outside of the machine is controlled in four stages of “strong”, “medium”, “weak”, and “fine” by increasing / decreasing the rotational speed of the motor 5. Is done. Further, the amount of mist generated is controlled in two stages, “strong” and “weak”. When the amount of mist generated is “strong”, the voltage applied to the pair of electrode plates 35 is increased as described above. Highly concentrated electrolyzed water is generated, and the amount of air sent from the air pump 13 is increased, so that a large amount of mist containing a large amount of hypochlorous acid and active oxygen is generated. When the amount of mist generated is “weak”, the voltage applied to the pair of electrode plates 35 is reduced, electrolyzed water having a relatively low concentration is generated, and the amount of air sent from the air pump 13 is reduced. As a result, a mist with relatively little hypochlorous acid and active oxygen is generated (small amount compared to the case of “strong”).

If there is no level 4 detection in any of the detection contents of any sensor (NO in step T1), it is then determined whether or not level 3 detection exists. If level 3 detection is present (YES in T3), the amount of wind from the exhaust port 9 is set to “medium”, and the amount of mist generated is set to “weak” (step T4).
Further, if there is no level 3 detection in any of the detection contents of any sensor (NO in step T3), it is then determined whether or not level 2 detection exists. If level 2 detection is present (YES in T5), the amount of wind from the exhaust port 9 is set to “weak”, and the amount of mist generated is set to “weak” (step T6).

  Further, if there is no level 2 detection in any detection content of any sensor (NO in step T5), it is then determined whether or not level 1 detection exists. If level 1 detection is present (YES in T7), the air volume from the exhaust port 9 is set to “Fine”, and energization to the pair of electrode plates 35 is stopped to generate electrolyzed water. Is stopped and the supply of air from the air pump 13 is also stopped. And the discharge | release of mist is stopped (step T8).

  In addition, when there is no level 1 detection in any of the detection contents of any sensor (when no detection is detected in any of the sensors), the energization to the pair of electrode plates 35 is stopped and the electrolyzed water is stopped. The generation is stopped, the supply of air from the air pump 13 is also stopped, and the discharge of mist is stopped. And the drive of the motor 5 is stopped and discharge | release of the wind from the exhaust port 9 is also stopped.

As described above, in this embodiment, since the amount of mist generated and the strength of the air volume are adjusted according to the degree of necessity of generating mist, more appropriate (efficient) operation can be performed. .
The present invention is not limited to the embodiment described above, and various modifications can be made within the scope of the claims.

  For example, in the above description, the generated mist is discharged to the outside by the wind discharged from the exhaust port 9, but the mist generating device 12 is provided with a mist discharging fan, and the rotation of the fan Thus, the mist may be discharged to the outside of the machine.

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 a block diagram which shows the electric constitution of an air cleaner. It is a figure for demonstrating the state of the air in which fungi and a virus are easy to act. It is a flowchart which shows the control procedure of the control part according to the detection of a temperature / humidity detection sensor. It is a flowchart which shows the control procedure of the control part concerning other embodiment of this invention.

Explanation of symbols

3A Human sensor 3B Gas detection sensor 3C Dust detection sensor 4 Fan 9 Exhaust port 10B Temperature / humidity detection sensor 12 Mist generator 13 Air pump 15 Water storage tank 18 Foam generation chamber 20 Air supply path 21 Supply port 35 Electrode plate

Claims (7)

A mist generator for discharging mist,
A water reservoir that can store water;
An electrode for electrolyzing water stored in the water storage section to generate electrolyzed water;
Information detection means for detecting atmosphere information around the device;
A bubble generation mechanism for generating bubbles in the electrolyzed water of the water storage unit, which is controlled according to the atmosphere information detected by the information detection means,
A mist generating device comprising: mist discharging means for discharging the mist generated when the bubbles generated by the bubble generating mechanism bounce when released to the atmosphere. The information detecting means is
Temperature detection means for detecting the temperature around the device;
The mist generating apparatus according to claim 1, further comprising humidity detecting means for detecting humidity around the apparatus.   3. The mist generating apparatus according to claim 1, wherein the information detecting means includes an operation detecting means for detecting movement of things around the apparatus.   The mist generator according to any one of claims 1 to 3, wherein the information detection means includes gas detection means for detecting the presence of a predetermined gas around the apparatus.   5. The mist generating apparatus according to claim 1, wherein the information detecting means includes dust detecting means for detecting that a predetermined amount or more of dust is floating around the apparatus. The mist discharge means includes a wind supply means for discharging the generated mist to the outside of the apparatus,
The mist generator according to any one of claims 1 to 5, wherein the amount of bubbles generated by the bubble generation mechanism and the strength of the wind by the wind supply means are adjusted according to the detected atmosphere information.   An air conditioner comprising the mist generator according to any one of claims 1 to 6.

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