JP5089424B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner including an indoor unit having an air cleaning function for purifying indoor air.

  Some conventional air conditioners have a deodorizing function, for example, adsorb odor components with an air cleaning pre-filter provided at an air inlet of an indoor unit, or have an oxidative decomposition function provided in the middle of an air passage. Odor components are adsorbed by the deodorizing unit.

  However, since the air conditioner with a deodorizing function removes odor components contained in the air sucked from the suction port and deodorizes it, the odor components contained in the indoor air and the odor adhering to curtains, walls, etc. The component could not be removed.

  Therefore, an odorous component contained in the indoor air is provided by providing an electrostatic atomizer in the air passage of the indoor unit, and blowing out the electrostatic mist generated by the electrostatic atomizer with a nanometer-size electrostatic mist. An air conditioner that removes odorous components adhering to curtains, walls, and the like has also been proposed (see, for example, Patent Document 1 or 2).

  Electrostatic atomizers include water cluster generators that discharge water into the air as fine water particles containing radicals and ions with high oxidizing power by corona discharge, and ozone generated by corona discharge. The air purifier which was made is proposed (for example, refer patent document 3, 4 or 5).

JP 2005-282873 A JP 2006-234245 A JP 2006-25816 A JP 2006-170467 A JP-A 64-7964

  An apparatus for generating corona discharge has a needle-like discharge electrode and a ground electrode to which a negative high voltage is applied, and an electric field is generated in the direction toward the tip of the discharge electrode by generating corona discharge between the discharge electrode and the ground electrode. This electric field gives negative charges to various particulate matter such as dust contained in the air, cigarette smoke and dust, and oily smoke generated during cooking, and a part of the charged particulate matter is applied to the ground electrode by Coulomb force. Adhere to.

  Therefore, as the air cleaning device is filled with such particulate matter, that is, when such discharge operation is performed in a state where the air is dirty, the ground electrode is contaminated with the particulate matter as compared with the discharge in clean air. Is inevitable. Therefore, there is a problem that the ground electrode becomes more noticeable even though the air cleaner is required as the air becomes more severe, and the period during which normal operation is possible decreases.

  The present invention has been made in view of such problems of the prior art, and detects the degree of dirt in the air and appropriately controls the capability of the electrostatic atomizer according to the degree of dirt. An object of the present invention is to provide an air conditioner that can normally operate an electrostatic atomizer over a long period of time.

In order to achieve the above object, the invention according to claim 1 of the present invention is an air conditioner including an indoor unit having an air cleaning function for purifying indoor air, the discharge electrode and the discharge electrode. And an electrostatic atomizer that generates a corona discharge between the discharge electrode and the counter electrode to detect electrostatic mist, and detects the degree of contamination of room air And a dirt sensor that directly detects the degree of dirt in the room air, and an activity amount sensor that indirectly detects the degree of dirt in the room air by detecting the amount of human activity. It comprises at least one, and provides one threshold value for the degree of contamination detected by the contamination detection means, and when the contamination level is smaller than the threshold value, the electrostatic atomizer is operated normally, while the contamination level is higher than the threshold value. If larger, the electrostatic atomizer Controls ON / OFF of the electrostatic atomizing device to limit the force, and displaying the contamination of the indoor air.

According to a second aspect of the present invention, the threshold value is the first threshold value, a second threshold value that is greater than the first threshold value is provided for the contamination level detected by the contamination detection means, and the contamination level is the first threshold value . When it is larger than the threshold value of 2, the electrostatic atomizer is stopped .

According to a third aspect of the present invention, in the case where the dirt detection unit is configured by both the dirt sensor and the activity sensor, the dirt sensor and the activity sensor are weighted, and the activity sensor The degree of dirt detected by the dirt sensor is more reflected in the control of the electrostatic atomizer than the amount of activity detected.

According to a fourth aspect of the present invention, the electrostatic atomizer includes a Peltier element, and the discharge electrode is cooled and condensed by the Peltier element.

The invention according to claim 5 is characterized in that the indoor unit has a ventilation fan, and the number of revolutions of the ventilation fan is controlled according to the degree of dirt detected by the dirt detection means.

  According to the present invention, the capacity of the electrostatic atomizer is controlled according to the amount of particulate matter in the room air detected by the dirt detector, that is, the degree of dirt. For example, when the degree of dirt is small, the electrostatic atomizer However, if the contamination level is high, the electrostatic atomizer can be operated normally for a long period of time. The air purifying function such as deodorization can be maintained and maintained.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
The air conditioner is composed of an outdoor unit and an indoor unit that are usually connected to each other by refrigerant piping. FIGS. 1 and 2 show the indoor unit of the air conditioner according to the present invention.

  As shown in FIGS. 1 and 2, the indoor unit has a front suction port 2a and a top suction port 2b as suction ports for sucking room air into the main body 2, and the front suction port 2a has a movable front panel that can be opened and closed. 4 (hereinafter simply referred to as the front panel). When the air conditioner is stopped, the front panel 4 is in close contact with the main body 2 and closes the front suction port 2a. The front panel 4 moves in a direction away from the main body 2 to open the front suction port 2a.

  Inside the main body 2, a prefilter 5 is provided on the downstream side of the front suction port 2 a and the upper surface suction port 2 b for removing dust contained in the air, and a front suction is provided on the downstream side of the prefilter 5. Air is blown from the heat exchanger 6 for exchanging heat with the indoor air sucked from the mouth 2a and the upper surface suction port 2b, the indoor fan 8 for conveying the heat exchanged by the heat exchanger 6, and the indoor fan 8. The upper and lower blades 12 change the air blowing direction up and down, and the left and right blades 14 change the air blowing direction left and right. Further, the upper portion of the front panel 4 is connected to the upper portion of the main body 2 via a plurality of arms (not shown) provided at both ends thereof, and a drive motor connected to one of the plurality of arms ( By driving and controlling the air conditioner, the front panel 4 moves forward from the position when the air conditioner is stopped (closed position of the front suction port 2a) during the air conditioner operation. Similarly, the upper and lower blades 12 are connected to the lower portion of the main body 2 through a plurality of arms (not shown) provided at both ends thereof.

  In addition, a ventilation fan unit 16 for ventilating room air is provided at one end of the indoor unit (on the left side when viewed from the front of the indoor unit and on the bypass channel 22 side of a partition wall 46c described later). In addition, an electrostatic atomizer 18 having an air cleaning function that generates electrostatic mist and purifies indoor air is provided behind the ventilation fan unit 16.

  FIG. 1 shows a state in which a main body cover (not shown) covering the front panel 4 and the main body 2 is removed, and FIG. 2 clearly shows a connection position between the indoor unit main body 2 and the electrostatic atomizer 18. Therefore, the electrostatic atomizer 18 accommodated in the main body 2 is separated from the main body 2. The electrostatic atomizer 18 actually has the shape shown in FIG. 3 and is attached to the left side of the main body 2 as shown in FIG. 1 or FIG.

  As shown in FIGS. 2 to 4, the electrostatic atomizer 18 includes a main channel that communicates from the front suction port 2 a and the upper suction port 2 b to the blowout port 10 via the heat exchanger 6, the indoor fan 8, and the like. 20, a high-voltage transformer 24 and a bypass blower fan 26 serving as a high-voltage power source are provided on the upstream side of the bypass flow path 22 and are provided in the middle of the bypass flow path 22 that bypasses the heat exchanger 6 and the indoor fan 8. An electrostatic atomizing unit 30 and a silencer 32 that are provided and have a heat radiation portion 28 that promotes heat radiation of the electrostatic atomization unit 30 are provided on the downstream side of the bypass flow path 22. Therefore, in the state where the high voltage transformer 24, the bypass blower fan 26, the heat radiating unit 28, the electrostatic atomizing unit 30, and the silencer 32 are arranged in order from the upstream side, the casing 34 constituting a part of the bypass flow path 22 is arranged. Contained. By housing in the casing 34 in this way, the assembly is improved and the flow path is formed by the casing 34, so that space is saved and the flow of air by the bypass blower fan 26 is changed to a high voltage that is a heat generating part. The transformer 24 and the heat radiating section 28 can be reliably applied and cooled, and the electrostatic mist generated from the electrostatic atomization unit 30 can be reliably introduced into the air outlet 10 of the air conditioner. Electric mist can be discharged into the air-conditioned room.

  Further, the casing 34 is arranged in the vertical direction so that the direction of the airflow flowing through the inside of the casing 34 is parallel to the direction of the airflow flowing through the main flow path 20 when viewed from the front of the indoor unit body 2. As a result, it can be disposed adjacent to the position overlapping the ventilation fan unit 16 when viewed from the front of the indoor unit main body 2, and further space saving is achieved.

  The high-voltage transformer 24 is not necessarily accommodated in the casing 34, but is cooled by the ventilation of the bypass flow path, so that it is accommodated in the casing 34 from the viewpoint of suppressing temperature rise or saving space. preferable.

  Here, a conventionally known electrostatic atomizing unit 30 will be described with reference to FIGS. 5 and 6.

  As shown in FIG. 5, the electrostatic atomization unit 30 includes a plurality of Peltier elements 36 having a heat radiating surface 36a and a cooling surface 36b, and the above-described heat radiating portion connected in thermal contact with the heat radiating surface 36a. (E.g., radiation fins) 28, a discharge electrode 38 installed in thermal contact with the cooling surface 36b via an electrical insulating material (not shown), and a predetermined distance from the discharge electrode 38. It is comprised with the counter electrode 40 arrange | positioned.

  Further, as shown in FIG. 6, the Peltier drive power supply 44 and the high voltage transformer 24 are electrically connected to the control unit 42 (see FIG. 1) disposed in the vicinity of the ventilation fan unit 16, and the Peltier element 36 and the discharge electrode 38 are electrically connected to the Peltier drive power supply 44 and the high voltage transformer 24, respectively.

  In addition, in order to discharge the high voltage from the discharge electrode 38 as the electrostatic atomizing unit 30 and generate the electrostatic mist, the counter electrode 40 may be omitted. For example, if one terminal of a high-voltage power supply is connected to the discharge electrode 38 and the other terminal is connected to the frame, the portion close to the discharge electrode 38 of the frame-connected structure and the discharge electrode 38 Will be discharged between. In such a configuration, the frame-connected structure can be regarded as the counter electrode 40.

  In the electrostatic atomization unit 30 configured as described above, when the control unit 42 controls the Peltier drive power supply 44 to cause a current to flow through the Peltier element 36, heat is transferred from the cooling surface 36b toward the heat radiation surface 36a, and the discharge electrode 38 is discharged. Condensation occurs on the discharge electrode 38 due to a decrease in temperature. Further, when the high voltage transformer 24 is controlled by the control unit 42 and a high voltage is applied to the discharge electrode 38 to which the condensed water has adhered, a discharge phenomenon occurs in the condensed water, and electrostatic mist having a particle size of nanometer size is generated. Occur. In the present embodiment, since a negative high voltage power source is used as the high voltage transformer 24, the electrostatic mist is negatively charged.

  In the present embodiment, as shown in FIG. 7, the main flow path 20 includes a rear wall 46 a of the base frame 46 constituting the main body 2, and both side walls extending forward from both ends of the rear wall 46 a ( 7 shows only the left side wall 46b, a rear wall 48a of the rear guider 48 formed below the underframe 46, and both side walls extending forward from both ends of the rear wall 48a (left side in FIG. 7). 48b, a partition wall separating the bypass channel 22 from the main channel 20 by one side wall (left side wall) 46b of the underframe 46 and one side wall (left side wall) 48b of the rear guider 48. 46c is constituted. Further, the bypass suction port 22a of the bypass channel 22 is formed on one side wall 46b of the frame 46, while the bypass outlet 22b of the bypass channel 22 is formed on one side wall 48b of the rear guider 48.

  In the case of an air conditioner, during cooling, the low-temperature air that has passed through the heat exchanger 6 of the indoor unit has a high relative humidity, and the electrostatic atomizer 18 includes a Peltier element 36 for replenishing moisture. In this case, dew condensation is likely to occur not only on the pin-shaped discharge electrode 38 of the Peltier element 36 but also on the entire Peltier element 36. On the other hand, at the time of heating, the high-temperature air that has passed through the heat exchanger 6 has a low relative humidity, so there is a very high possibility that no condensation will occur on the discharge electrode 38 of the Peltier element 36.

  Thus, as in the above configuration, the main flow path 20 and the bypass flow path 22 are separated by the partition wall 46c, and an electrostatic atomizer 18 that generates electrostatic mist is provided in the bypass flow path 22. Air that has not passed through and that has not been adjusted in temperature and humidity is supplied to the electrostatic atomizer 18. Thereby, safety is improved by effectively preventing the occurrence of condensation on the entire Peltier element 36 of the electrostatic atomization unit 30 during cooling. Moreover, electrostatic mist can be reliably generated during heating.

  The bypass passage 22 includes a bypass suction pipe 22c, a casing 34, and a bypass outlet pipe 22d, and the bypass suction pipe 22c having one end connected to the bypass suction port 22a formed in the frame side wall 46b is located on the left side ( The bypass outlet 22d, which extends in a direction substantially orthogonal to the left side wall 46b and extends in a direction substantially parallel to the front panel 4, is connected to one end of the casing 34 and further connected to the other end of the casing 34. The other end of the rear guider 48 is connected to the bypass outlet 22b of the side wall 48b. Thus, by comprising a part of bypass channel 22 with casing 34, space saving can be achieved, and electrostatic atomization unit can be formed via bypass outlet pipe 22d by comprising these in series. The electrostatic mist can be reliably attracted from 18 toward the main flow path 20, and the electrostatic mist can be discharged into the air-conditioned room.

  The bypass suction port 22a is located between the prefilter 5 and the heat exchanger 6, that is, downstream of the prefilter 5 and upstream of the heat exchanger 6, and is sucked from the front suction port 2a and the upper suction port 2b. Since the dust contained in the air is effectively removed by the pre-filter 5, it is possible to prevent the dust from entering the electrostatic atomizer 18. Thereby, it can prevent effectively that dust accumulates on the electrostatic atomization unit 30, and can discharge | release electrostatic mist stably.

  As described above, in the present embodiment, the prefilter 5 serves as a prefilter for the electrostatic atomizer 18 and the main flow path 20, but this requires maintenance to clean only the prefilter 5. Since it is not necessary to care for each separately, the care can be simplified. Furthermore, in an air conditioner equipped with a pre-filter automatic cleaning device as will be described later, the pre-filter 5 does not require special care, and can be made maintenance-free.

  On the other hand, the bypass air outlet 22b is positioned in the vicinity of the air outlet 10 on the downstream side of the heat exchanger 6 and the indoor fan 8, and the electrostatic mist discharged from the bypass air outlet 22b rides on the air flow in the main flow path 20. It spreads and fills the entire room. The bypass outlet 22b is arranged on the downstream side of the heat exchanger 6 as described above. If the bypass air outlet 22b is arranged on the upstream side of the heat exchanger 6, since the heat exchanger 6 is made of metal, the electrostatic mist that is charged particles is This is because most of the heat exchanger 6 (approximately 80 to 90% or more) is absorbed. In addition, the bypass outlet 22b is arranged on the downstream side of the indoor fan 8. If the bypass outlet 22b is arranged on the upstream side of the indoor fan 8, turbulent flow exists in the indoor fan 8 and passes through the indoor fan 8. This is because a part (about 50%) of the electrostatic mist is absorbed in the process of air colliding with various parts of the indoor fan 8.

  In addition, the main flow path 20 side of one side wall 48b of the rear guider 48 provided with the bypass outlet 22b is given a predetermined speed to the air flow by the indoor fan 8, so that the main flow path 20 side of the side wall 48b is bypassed. A pressure difference is generated on the side of the path 22, a negative pressure portion in which the main channel 20 side is relatively low in pressure relative to the bypass channel 22, and air is attracted from the bypass channel 22 toward the main channel 20. Accordingly, the bypass blower fan 26 has a small capacity, and the bypass blower fan 26 may not be provided in some cases.

  Further, the bypass outlet pipe 22d is provided on the partition wall 46c (side wall 48b of the rear guider 48) so as to be directed in a direction substantially orthogonal to the air flow in the main channel 20 at the junction with the main channel 20 (bypass outlet 22b). It is connected. This is because the electrostatic atomization unit 30 generates the electrostatic mist by utilizing the discharge phenomenon as described above, so that the discharge sound is inevitably accompanied and the discharge sound has directivity. is there. Therefore, by connecting the bypass passage 22 to the front panel 4 substantially parallel to the front panel 4 at the junction of the bypass passage 22 and the main passage 20 (bypass outlet 22b), a person in front of the indoor unit or diagonally forward Thus, it is possible to reduce the noise by configuring so that the discharge sound is not directed as much as possible.

  Further, as shown in FIG. 8, when the bypass outlet pipe 22 d is inclined with respect to the partition wall 46 c at the junction with the main flow path 20 and connected so as to be directed upstream with respect to the air flow in the main flow path 20, It is effective in reducing noise due to further discharge noise.

  In addition, even when the direction in which the bypass outlet pipe 22d is directed is connected to the downstream direction of the air flow in the main flow path 20, if the extension line does not come out from the outlet 10, it will occur. Since the amount of discharge sound that goes out directly from the air outlet 10 is small and does not directly enter the user's ear, a noise reduction effect can be achieved.

  As described above, the main flow path 20 and the bypass flow path 22 are separated by the partition wall 46 c, and the electrostatic atomizer 18 that generates electrostatic mist bypasses the heat exchanger 6 and communicates with the main flow path 20. Since the air that has not been passed through the heat exchanger 6 and has not been adjusted in temperature and humidity is supplied to the electrostatic atomizer 18 because it is provided in the path 22, the Peltier element 36 of the electrostatic atomization unit 30 is used during cooling. Effectively preventing the occurrence of dew condensation on the whole, safety is improved, and electrostatic mist can be reliably generated during heating, regardless of the operation mode of the air conditioner, that is, the season The electrostatic mist can be generated stably regardless of the above.

  Next, an air conditioner further provided with a prefilter automatic cleaning device having a suction device that sucks and removes dust adhering to the prefilter 5 will be described. The ventilation fan unit 16 will be described with reference to FIG. 9. Even if the ventilation fan unit 16 is dedicated to ventilation, the ventilation fan unit 16 also serves to supply air to a suction device provided in an indoor unit having a pre-filter automatic cleaning device. May be. The ventilation fan unit 16 shown in FIG. 9 is incorporated in the suction device 58 of the automatic prefilter cleaning device on the bypass flow path 22 side of the partition wall 46c. However, since the automatic prefilter cleaning device is already known, see FIG. While briefly explaining. The detailed structure and operation method of the pre-filter automatic cleaning device are not particularly limited.

  As shown in FIG. 10, the pre-filter automatic cleaning device 50 includes suction nozzles 52 that are slidable along the surface of the pre-filter 5, and the suction nozzles 52 are installed at the upper and lower ends of the pre-filter 5. The pair of guide rails 54 can smoothly move left and right while maintaining a very narrow gap with the prefilter 5, and dust adhering to the prefilter 5 is sucked and removed by the suction nozzle 52. Further, one end of a bendable suction duct 56 is connected to the suction nozzle 52, and the other end of the suction duct 56 is connected to a suction device 58 having a variable suction amount. Further, an exhaust duct 60 is connected to the suction device 58 and led out to the outside.

  Further, a belt (not shown) that is slidable along the suction nozzle 52 is wound around the suction nozzle 52 in the vertical direction. A slit-like nozzle opening having a length substantially equal to the vertical length of the filter 5 is formed, while a slit-like suction hole having a length of, for example, 1/4 of the vertical length of the prefilter 5 is formed in the belt. ing.

  The automatic prefilter cleaning device 50 configured as described above sequentially cleans the cleaning ranges A, B, C, and D of the prefilter 5 as necessary. When the range A is suction-cleaned, the belt is driven and the suction holes are driven. In the state where the position is fixed to the position of the range A, the suction nozzle 52 is driven from the right end to the left end of the prefilter 5 while sucking, whereby the horizontal range A of the prefilter 5 is suction-cleaned.

  Next, the belt is driven to fix the suction hole at a position in the range B, and the suction nozzle 52 is driven from the left end to the right end of the prefilter 5 while sucking in this state, so that the horizontal direction of the prefilter 5 is now achieved. A range B is suction-cleaned. Similarly, the areas C and D of the pre-filter 5 are also cleaned by suction.

  Dust adhering to the pre-filter 5 and sucked by the suction nozzle 52 is discharged to the outside through the suction duct 56, the suction device 58, and the exhaust duct 60.

  Further referring to FIG. 9, an opening 62 is formed in the suction path of the suction device 58, and a damper 64 for opening and closing the opening 62 is provided. The ventilation fan unit 16 includes the damper 64. When the opening 62 is opened, it is used for ventilation. When suction cleaning is performed, the opening 62 is closed by a damper 64 and used for sucking dust from the suction hole of the belt. That is, the same suction device 58 is used to realize the suction cleaning function and the ventilation function.

  Although the exhaust duct 60 is not shown in FIG. 9, the exhaust duct 60 is connected to the exhaust port 58 a of the suction device 58.

  FIG. 11 shows an electrostatic atomizer 18A that does not have a casing 34, and this electrostatic atomizer 18A is incorporated in the indoor unit body 2 as shown in FIG. Alternatively, it is incorporated into a broken line region 18B shown in FIG. 12 (substantially the same position as the electrostatic atomizer unit 30 and the silencer 32 provided on the downstream side of the bypass flow path 22 in the electrostatic atomizer 18 shown in FIG. 9). It is. These are disposed at a position overlapping the ventilation fan unit 16 when the electrostatic atomizer 18A is viewed from the front or top surface of the indoor unit, and the electrostatic atomizer 18A is disposed at the opening 62 and the damper 64 of the ventilation fan unit 16. Is disposed in a portion where the suction air by the ventilation fan unit 16 flows.

  More specifically, the electrostatic atomizing device 18A of FIG. 11 includes an electrostatic atomizing unit 30 having a heat radiating portion 28 and a silencer 32 integrally attached, and the electrostatic atomizing unit 30 portion excluding the heat radiating portion 28; The silencer 32 is accommodated in each housing (unit housing 66 and silencer housing 68), and one of the bypass blowing pipes 22d is connected to and communicated with the silencer housing 68, and the other of the bypass blowing pipes 22d is connected to the main flow path 20. Communicate. In this case, the housing portion 22e that is separated from the main flow path 20 by the partition wall 46c and formed between the left side surface of the main body cover (not shown) and in which the ventilation fan unit 16, the electrostatic atomizer 18A, and the like are disposed is described above. In addition to the bypass suction pipe 22c and the casing 34, the bypass blow-out pipe 22d is also accommodated to constitute the bypass flow path 22.

  As described above, the bypass blow-out pipe 22d can reduce noise in a direction directed to the air flow of the main flow path 20. However, this is not always necessary, and the bypass blower pipe 22d directly bypasses the silencer housing 68. You may connect to the outlet 22b. Thereby, the structure of 18 A of electrostatic atomizers can be simplified more. However, it is the same as the bypass outlet pipe 22d that consideration of the direction is necessary for noise reduction.

  Thereby, the air sucked into the main body 2 through the prefilter 5 is sucked into the accommodating portion 22e from the bypass suction port 22a on the downstream side of the prefilter 5, and the direction of the airflow is the air flowing through the main channel 20 The indoor unit main body 2 flows in the accommodating portion 22e in parallel with the flow direction when viewed from the front. Thus, the heat radiating portion 28 is cooled by the air flowing through the housing portion 22e, and taken into the electrostatic atomizing unit 30 through an opening (not shown) formed in the unit housing 66.

  With this configuration, the space around the ventilation fan unit 16 that overlaps the ventilation fan unit 16 when viewed from the front or top surface of the indoor unit becomes the bypass flow path 22, and the ventilation fan unit 16, the electrostatic atomizer 18 </ b> A, etc. Space can be saved by effectively utilizing the accommodating portion 22e. In this configuration, the high voltage transformer 24 is disposed at an arbitrary portion in the housing portion 22e such as the ventilation fan unit 16 and the electrostatic atomizer 18A, and the bypass blower fan 26 is not provided.

  Further, the bypass flow path 22 is described in detail above by configuring the bypass flow path 22 so that the air flow flows in parallel with the air flow passing through the main flow path 20 as viewed from the front. Thus, since the main flow path 20 and the bypass flow path 22 can be branched with a simple configuration of the partition wall 46c, the bypass flow path 22 can be easily formed, and the number of parts can be reduced.

  Furthermore, by setting it as this structure, the prefilter of the electrostatic atomizer 18A and the prefilter of the main flow path 20 can be shared by the prefilter 5. Since the sharing effect is as described above, the details are omitted here.

  Note that an opening 46d may be formed in the vicinity of the lower portion of the frame 46 corresponding to the rear portion of the ventilation fan unit 16 so that a pipe (not shown) connecting the indoor unit and the outdoor unit can be drawn out. The bypass suction port 22a described above is one opening in the housing portion 22e formed in the partition wall 46c (the frame side wall 46b) in order to suck air into the housing portion 22e, and communicates with the outside of the indoor unit through the prefilter 5. However, in the opening 46d formed in the lower part of the underframe 46, the accommodating portion 22e is an opening that directly communicates with the outside of the indoor unit and sucks ambient air. In such a case, the accommodating portion 22e serves as a bypass flow path that also bypasses the prefilter 5. Accordingly, the air sucked into the electrostatic atomizer 18A flows from the opening 46d and does not pass through the prefilter 5, so that a separate prefilter for the electrostatic atomizer 18A is provided as necessary. Just do it. Further, even in the configuration in which the opening 46d is formed, the electrostatic atomizer 18A is disposed at a position overlapping the ventilation fan unit 16 when viewed from the front or top surface of the indoor unit, and the housing portion 22e is effectively used. Similarly, space saving can be achieved.

  As described above, the main flow path 20 side of the bypass outlet 22b is a negative pressure part that is attracted by the pressure difference generated by the indoor fan 8 being given a predetermined speed to the air flow. Even if the bypass blower fan 26 is not provided, the heat radiating portion 28 is cooled by the air drawn toward the main passage 20 from the accommodating portion 22e which is a bypass passage via the bypass outlet pipe 22d, and the electrostatic atomizing unit 30 is provided. The electrostatic mist generated by the above is attracted to the main channel 20 and can be discharged into the air-conditioned room. Further, since the heat dissipating part 28 is arranged in the vicinity of the opening 62 and the damper 64 as shown by the broken line area 18B, the air is sucked into the opening 62, so that it is also cooled by the air sucked by the ventilation fan unit 16. .

  As shown in FIG. 12, by disposing the heat radiating portion 28 of the electrostatic atomizer 18 </ b> A close to the opening 62 provided in the suction device 58, the heat radiating portion is caused by the air sucked into the opening 62. 28 is further cooled, and heat dissipation from the electrostatic atomization unit 30 is promoted. Further, when a ventilation-only fan is used as the ventilation fan unit 16, the damper 64 is not provided. Therefore, by disposing the heat radiating unit 28 close to the suction port of the ventilation fan unit 16, the heat radiating unit 28 is efficiently arranged. To be cooled.

  As described above, according to the above configuration, the container 22e is provided with the electrostatic atomizer 18A that separates the main channel 20 and the container 22e serving as the bypass channel by the partition wall 46c and generates electrostatic mist. Therefore, since air that has not passed through the heat exchanger 6 and is not adjusted in temperature and humidity is supplied to the electrostatic atomizer 18A, dew condensation occurs on the entire Peltier element 36 of the electrostatic atomizer unit 30 during cooling. Effectively preventing this from occurring, safety is improved, and electrostatic mist can be reliably generated during heating, and it is quiet regardless of the operation mode of the air conditioner, that is, regardless of the season. Electric mist can be generated stably.

(Control method of electrostatic atomizer)
Next, a method for controlling the electrostatic atomizers 18 and 18A configured as described above in accordance with the output of the dirt detecting means will be described.

  While operating the air conditioner, it is preferable to operate the electrostatic atomizers 18 and 18A as much as possible in order to deodorize and purify the air-conditioned room, but if the indoor air is contaminated with various particulate matter such as dust, A part of the charged dust or the like adheres to the counter electrode 40 so that the counter electrode 40 becomes dirty and the capacity of the electrostatic atomizers 18 and 18A is reduced. In the worst case, the electrostatic atomizers 18 and 18A May become unusable. The above control is performed to avoid such a situation and maintain the deodorization and purification performance for a long period of time.

  As the dirt detection means, a gas sensor that directly detects the degree of dirt in indoor air, a dirt sensor such as an optical dust sensor, an activity amount sensor that indirectly detects the degree of dirt in indoor air, and the like are used. The gas sensor can directly detect various gas components such as odor gas, CO2, and water vapor. For example, when a resident in an air-conditioned room smokes, particulate matter such as cigarette smoke and dust is released at the same time as the odor gas, and when the occupant cooks, odor gas, water vapor, etc. At the same time, since various particulate matter such as oily smoke accompanying cooking is released, the correlation between the output of the gas sensor and the concentration of particulate matter in the air in the air-conditioned room is extremely high. For this reason, in a normal living environment, the presence or absence of particulate matter can be detected accurately with a gas sensor. Such a gas sensor may be mounted on, for example, the power supply board of the indoor unit, or attached in the vicinity of the remote control (remote control device) light receiving unit of the indoor unit.

  First, the case where a gas sensor that directly detects indoor dirt is used as the dirt detection means will be described with reference to the block diagram of FIG. 13 and the flowchart of FIG.

  As shown in FIG. 13, a gas sensor (hereinafter referred to as a dirt sensor) 70 is connected to a control unit 72 provided in the indoor unit via a drive circuit 74, and a display unit 76 is further connected to the control unit 72. Yes. The control unit 72 includes a storage unit 78, and a first threshold value and a second threshold value for the degree of contamination are set in the storage unit 78. The display unit 76 displays the degree of air contamination. For example, the LED display is used to display a plurality of colors such as red (large), orange (medium), and green (clean) in descending order of the degree of air contamination. Since it is displayed or displayed according to the number of lit LEDs, the user can check the display unit 76 and easily know the state of the degree of air contamination.

  The indoor dirt level detected by the dirt sensor 70 is input to the control unit 72 via the drive circuit 74, and is compared with the first threshold value or the second threshold value set in the storage unit 78, and according to the comparison result. The capabilities of the electrostatic atomizers 18 and 18A are controlled.

  More specifically with reference to the flowchart of FIG. 14, when the air conditioner is in operation in step S <b> 1, the degree of dirt in the room is detected by the dirt sensor 70 in step S <b> 2. In the next step S3, the degree of contamination of the detected room air is compared with the first threshold, and if it is smaller than the first threshold, the room air is determined to be “clean”, and in step S4, the electrostatic The atomizers 18 and 18A are operated (continuous operation), and “green” is lit on the display unit 76.

  On the other hand, if it is determined in step S3 that the detected degree of contamination of the indoor air is equal to or greater than the first threshold value, the process proceeds to step S5, where the detected degree of contamination of the indoor air is greater than the first threshold value. Compared to threshold. If it is smaller than the second threshold, it is determined that the degree of contamination of the room air is “medium (normal)”, and the electrostatic atomizers 18 and 18A are intermittently operated in step S6, and the display unit 76 “Orange” lights up. In this case, the capacity of the electrostatic atomizers 18 and 18A is set to, for example, an operation rate of 50%, and the operation for about 1 second and the stop for about 1 second are repeated. The effect of the generated electrostatic mist (indoor deodorization purification) and the antifouling effect of the electrostatic atomizers 18 and 18A are made compatible.

  On the other hand, if it is determined in step S5 that the detected degree of contamination of the indoor air is equal to or greater than the second threshold value, the operation of the electrostatic atomizers 18 and 18A is stopped in step S7, and the air is very dirty. The electrostatic atomizers 18 and 18A are protected.

  Then, in step S4, step S6 or step S7, the continuous operation, intermittent operation or stop of the electrostatic atomizers 18 and 18A is continued for a predetermined time to control the capacity. The degree of air contamination is detected again.

  Thus, by controlling the capability of the electrostatic atomizers 18 and 18A in detail using two threshold values, the effect of the electrostatic mist generated by the electrostatic atomizers 18 and 18A (indoor deodorization purification) and static While satisfying both the antifouling effects of the electroatomizers 18 and 18A, it is possible to prevent various charged particulate substances from adhering to the counter electrode 40, and the electrostatic atomizers 18 and 18A can be stably provided over a long period of time. It can be operated.

  In addition, when operation | movement of the electrostatic atomizers 18 and 18A is stopped in step S7, the state where indoor air is dirty will be left unattended. If it is left as it is, it may take time to wait for the dirt to decrease due to natural ventilation, etc., so that the indoor unit body 2 can be provided with a ventilation function such as the ventilation fan unit 16 as shown in FIG. It is desirable to have a function that works with other ventilation fans. Thereby, the indoor air can be quickly purified to the degree of contamination at which the electrostatic atomizers 18 and 18A are operated. Similarly, when the operation rate is reduced by controlling the capabilities of the electrostatic atomizers 18 and 18A in step S6, purification of room air can be promoted if ventilation is performed by the ventilation fan unit 16 or the like. .

  In addition, as a method for controlling the capabilities of the electrostatic atomizers 18 and 18A, the above description is performed by changing the operation rate between operation and stop. However, the present invention is not limited to this, and the electrostatic atomizers 18 and 18A It may be performed by changing the discharge voltage.

  Next, a case where an activity amount sensor that indirectly detects indoor air contamination is used as the contamination detection means, for example, a human body detection sensor is used as the activity amount sensor will be described. The method of indirectly detecting the degree of indoor air contamination is less accurate than the method of detecting it directly, but the human body detection sensor is used to detect the position of the person and control the temperature and direction of the air conditioning. In this case, it is very easy to use it as an activity amount sensor as it is, and it can be used to stably operate the electrostatic atomizers 18 and 18A over a long period of time while suppressing an increase in cost. it can.

  FIG. 15 shows an indoor unit having a plurality of (for example, five) sensor units 80, 82, 84, 86, and 88 attached to the upper part of the front panel 4. FIG. FIG. 15B shows a state where the sensor cover 90 is attached.

  The sensor unit 80 includes a circuit board, a lens attached to the circuit board, and a human body detection sensor mounted inside the lens, and this configuration includes other sensor units 82, 84, 86, and 88. The same applies to. Furthermore, the human body detection sensor is configured by, for example, an infrared sensor that detects the presence or absence of a person by detecting infrared radiation emitted from the human body, and a pulse that is output in response to a change in the amount of infrared detected by the infrared sensor. The presence or absence of a person is determined by the circuit board based on the signal.

FIG. 16 shows human body position determination areas detected by the sensor units 80, 82, 84, 86, and 88. The sensor units 80, 82, 84, 86, and 88 each have a person in the next area. Can be detected.
Sensor unit 80: area A + C + D
Sensor unit 82: Area B + E + F
Sensor unit 84: area C + G
Sensor unit 86: Area D + E + H
Sensor unit 88: area F + I

  That is, the area that can be detected by the sensor units 80 and 82 and the area that can be detected by the sensor units 84, 86, and 88 are partially overlapped, and the number of sensor units 80, 82, 84, which are smaller than the number of the areas A to I. 86 and 88 are used to detect the presence or absence of a person in each of the areas A to I. Since the applicant of the present application has already proposed the estimation of the presence / absence of a person in each of the areas A to I (see, for example, Japanese Patent No. 3963935), the description thereof is omitted.

Here, the “activity amount” described above will be described.
A person's activity level is a concept that indicates the degree of human movement, and is classified into multiple activity levels, for example, “rest”, “high activity level”, “medium activity level”, and “low activity level”. being classified.

  “Relax” refers to a situation where a person is still in the same place, such as relaxing on the sofa, watching TV, or operating a computer. When sustained, the amount of dust generated is very small. The amount of activity “Large” means that the activity is in a wide area such as indoor cleaning, and the amount of dust generated is extremely large. The activity amount “medium” means that the activity is in a narrow area such as cooking. Dust is generated to some extent, but it cannot be said that it is extremely large. The activity amount “small” means that there is little activity in the same place such as a meal and the amount of dust generated is small.

  In this embodiment, since the activity level of a person is determined for each block including a plurality of areas, this block will be described first.

Each of the areas A to I is divided into the following three blocks located on the left side, the center, and the right side as viewed from the indoor unit.
First block: areas A, C, G
Second block: areas D, E, H
Third block: areas B, F, I

Next, a method for classifying human activity will be described in detail with reference to the flowchart of FIG.
First, in step S11, the reaction frequency (with output pulse) of each sensor unit 80, 82, 84, 86, 88 is measured every predetermined time T1, and in step S12, it is determined whether or not the number of measurement has reached the predetermined number. To do. The predetermined time T1 is the same as the predetermined cycle in the above-described determination of the presence / absence of a person, but here, for example, it is set to 2 seconds, for example, and the predetermined number of measurement times is set to 15 times, for example. Assuming that 15 measurements are collectively referred to as 1 unit measurement (measurement for 30 seconds). Further, the “measurement number” here is the number of measurements in any one of the areas A to I, and the same measurement is performed for all the areas A to I.

  If it is determined in step S12 that the number of measurements has not reached the predetermined number, the process returns to step S11. If it is determined that the number of measurements has reached the predetermined number and one unit measurement has been completed, four unit measurements ( It is determined whether the measurement for 2 minutes has been completed. In step S13, if 4-unit measurement is not completed, the process returns to step S11. If 4-unit measurement is completed, the process proceeds to step S14.

  In step S14, the total reaction frequency of the sensor units 80, 82, 84, 86, and 88 in the four unit measurement (the last four unit measurements including the current one unit measurement) reaches a predetermined number (for example, five times). If the predetermined number has been reached, in step S15, the total number of unit measurements (p, which will be described in detail later) after being determined as “small amount of activity” is cleared, and then in step S16 Transition.

  In step S16, it is determined whether the total reaction frequency of the sensor units 80, 82, 84, 86, 88 in all the areas A to I has reached a predetermined number (for example, 40 times), and has reached the predetermined number. In this case, in step S17, all the blocks determined to be present except for the block determined to be “rest” are determined to be “high activity amount”. On the other hand, if the predetermined number has not been reached, in step S18 A block to which a region in which the total reaction frequency of the sensor units 80, 82, 84, 86, and 88 of the 4-unit measurement has reached a predetermined number belongs is determined as “active amount”. After the activity amount determination in step S17 or step S18, in step S19, 1 is subtracted from the unit measurement number (q), and the process returns to step S11. That is, the block to which the region where the total reaction frequency of each sensor unit 80, 82, 84, 86, 88 exceeds a predetermined number and is determined to be “high activity amount” or “medium activity amount” in four consecutive unit measurements Further, after the next one unit measurement, if the total response frequency of the four unit measurement at that time exceeds a predetermined number, it is determined that the activity level is “high” or “active level”.

  If it is determined in step S14 that the total reaction frequency of the sensor units 80, 82, 84, 86, and 88 is less than a predetermined number by measuring four units, whether or not the block to which the region belongs is “rest” in step S20. If it is not “rest”, it is determined in step 21 that “activity is small”. In the next step S22, the total number of unit measurements (p) after being determined as “small amount of activity” is counted, and in step S23, 60 units are measured after being determined as “low amount of activity” (measurement for 30 minutes). ) Is finished.

  If it is determined in step S23 that the 60 unit measurement has not been completed, the process proceeds to step S19. On the other hand, if it is determined that the 60 unit measurement has been completed, only the area is in the block to which the area belongs. As long as it is determined as “rest” in step S24, the process proceeds to step S19. In other words, by moving to step S19, each block becomes “active mass” according to the total reaction frequency of each sensor unit 80, 82, 84, 86, 88 in the past four unit measurements including the next one unit measurement. It is newly determined as “large”, “medium amount of activity”, “small amount of activity”, or “rest”.

  At the beginning of activity amount measurement after the air conditioner is turned on, the activity amount in any region is unknown, but according to this flowchart, each region A to I is not measured until 4 units measurement is completed from the start of measurement. In the block to which “active activity amount”, “medium activity amount”, or “activity amount small” is determined, and the measurement of 60 units is completed, the determination of “rest” is performed. Therefore, since there is no “rest” block for a while after the start of measurement, NO is determined in step S20, and “small amount of activity” is determined in step S21. After that, the block that has been continuously determined as “active amount small” is determined as “rest” in step S24 after the end of the measurement of 60 units, and then the sensor units 80, 82, 84, 86, and 88 of 4 units are measured. If the total reaction frequency is less than the predetermined number, it is determined as “rest”.

  Note that the reason for clearing the total number of unit measurements (p) after it is determined that “activity is small” in step S15 is that the determination of “rest” is based on the determination of “activity is small”. It is.

In summary, each of the sensor units 80, 82, 84, 86, 88 functions not only as a human body detection means but also as an activity amount detection means. According to the flowchart of FIG. For example, it is determined as follows.
(1) Rest A block that has only sensor response frequency less than 5 times / 2 minutes lasted for 30 minutes or more (2) High activity amount The sum of sensor response frequencies in all regions A to I is 40 times / 2 minutes, When the sensor response frequency continues at least 5 times in 2 minutes in at least one area, all blocks except the block that is determined to be “rest” (3) Activity amount Sum of sensor response frequencies in all areas A to I If the sensor response frequency is less than 40 times / 2 minutes, the block to which the sensor response frequency lasts 5 times or more in 2 minutes belongs. (4) Activity level is small. block

  As described above, the method for classifying the amount of human activity in each of the areas A to I using a plurality of human body detection sensors has been described. However, the areas A to I are classified in this way, and are substantially the same as the flowchart of FIG. It is also possible to control the electrostatic atomizers 18 and 18A.

  That is, in step S3 in the flowchart of FIG. 14, it is determined whether or not there is an activity amount “large” and “medium” region in any of the regions A to I. If there is no area, the process proceeds to step S4. On the other hand, if any of the areas A to I has an activity amount “large” or “medium” area, any of the areas A to I is selected in step S5. It is determined whether or not there is an activity amount “large” region, and if there is no activity amount “large” region, the process proceeds to step S6. If there is an activity amount “large” region, step S7 is performed. You can move to.

  Further, in the present invention, the room in which the indoor unit is installed as one block, the amount of activity of the person in the block is classified using one human body detection sensor, and substantially the same as the flowchart of FIG. The electrostatic atomizers 18 and 18A can also be controlled.

  More specifically, the first and second thresholds are set for the reaction frequency of one human body detection sensor, and the amount of activity in the room in which the indoor unit is installed is set to “large”, “medium”, “rest” according to the reaction frequency. (Including small activity amount) ”. The reaction frequency of the human body detection sensor may be the sum of the sensor reaction frequencies within a predetermined time, or may be the duration of the sensor reaction frequency within a predetermined time.

Further, the soil index Ng and Na can be set in the soil sensor and the activity amount sensor, respectively, and the electrostatic atomizers 18 and 18A can be controlled according to the soil index Ng and Na. For example, it is set as follows.
(I) For dirt sensor
Dirt degree “Large”: Dirt index Ng = 2
Contamination degree “medium”: Contamination index Ng = 1
Contamination degree “clean”: Dirt index Ng = 0
(Ii) Activity sensor
Activity amount “Large”: Dirt index Na = 2
Activity amount “Medium”: Dirt index Na = 1
Activity amount “small” or “rest”: dirt index Na = 0

  Next, a control method of the electrostatic atomizers 18 and 18A according to the soil index Ng and Na will be described with reference to the flowchart of FIG.

  First, when the air conditioner is in operation in step S31, in step S32, the dirt level of the indoor air is detected by the dirt sensor 70, and the dirt index Ng is set according to the detected dirt degree. In the next step S33, the activity amount in the room is detected by the activity amount sensor, and the dirt index Na is set according to the detected activity amount.

  In step S34, the two set dirt indexes Ng and Na are added to obtain a dirt index N (N = Ng + Na). In step S35, it is determined whether N = 0. If N = 0, the degree of dirt detected by the dirt sensor is “clean” and the amount of activity detected by the activity quantity sensor is “small” or “rest”. As the control devices 18 and 18A are operated (continuous operation), “green” is lit on the display unit 76.

  On the other hand, if it is determined in step S35 that N = 0, the process proceeds to step S37 to determine whether N = 1. If it is determined that N = 1, the degree of dirt detected by the dirt sensor is “clean”, but the activity amount detected by the activity sensor is “medium”, or the activity quantity detected by the activity sensor is Even if “small” or “rest”, since the degree of contamination detected by the contamination sensor is “medium”, it is determined that the indoor air is somewhat dirty, and in step S38, the electrostatic atomizers 18 and 18A are intermittent. As the system is operated, “orange” is lit on the display unit 76. In this case, the capacity of the electrostatic atomizers 18 and 18A is set to, for example, an operation rate of 50%, and the operation for about 1 second and the stop for about 1 second are repeated. The effect of the generated electrostatic mist (indoor deodorization purification) and the antifouling effect of the electrostatic atomizers 18 and 18A are made compatible.

  On the other hand, if it is determined in step S37 that N = 1 is not satisfied, N ≧ 2, so that the degree of dirt detected by the dirt sensor is “high” or the amount of activity detected by the activity quantity sensor is “large”. Or, the degree of dirt detected by the dirt sensor is “medium” and the amount of activity detected by the activity quantity sensor is “medium”. The operation of the electroatomizers 18 and 18A is stopped to protect the electrostatic atomizers 18 and 18A.

  Thus, by finely controlling the capabilities of the electrostatic atomizers 18 and 18A by the dirt sensor and the activity amount sensor, the effect of the electrostatic mist generated by the electrostatic atomizers 18 and 18A (indoor deodorization purification) and While satisfying both the antifouling effects of the electrostatic atomizers 18 and 18A, it is possible to prevent various charged particulate substances from adhering to the counter electrode 40, and the electrostatic atomizers 18 and 18A stably over a long period of time. Can be operated.

  In step S36, step S38 or step S39, the capacity of the electrostatic atomizers 18 and 18A is continuously controlled, intermittently operated, or stopped for a predetermined time, and then the process returns to step S32. In step S33, the activity amount of the person in the room is detected again by the activity amount sensor.

  The dirt sensor 70 is highly accurate because it directly detects dirt such as cigarette smoke and cooking oil and dirt, whereas the activity sensor detects the amount of human activity, and the greater the amount of activity, the more dirty the room. The degree of contamination is detected indirectly by estimating that the degree is large, and the accuracy is relatively low. In addition, since there may be occasional changes in the amount of activity even in daily life, the output of the activity amount sensor is used as a reference, but it is preferable that it is not immediately reflected in the control.

Therefore, with the dirt sensor 70 as the main detection means and the activity amount sensor as the dirt detection assist detection means, the sensors are weighted as follows, and the degree of dirt detected by the dirt sensor is compared with the activity amount detected by the activity amount sensor. Can also be reflected in the control of the electrostatic atomizers 18 and 18A.
(I) For dirt sensor
Dirt degree “Large”: Dirt index Ng = 4
Contamination degree “medium”: Contamination index Ng = 2
Contamination degree “clean”: Dirt index Ng = 0
(Ii) Activity sensor
Activity amount “Large”: Dirt index Na = 2
Activity amount “Medium”: Dirt index Na = 1
Activity amount “small” or “rest”: dirt index Na = 0

  When the sensors are weighted in this way, if N = 0 or 1 is determined in step S35 of the flowchart of FIG. 18, the process proceeds to step S36, and if N = 2 is determined in step S37, the process proceeds to step S38. If it is determined in step S37 that N = 2 is not satisfied (N ≧ 3), the process proceeds to step S39, where the electrostatic atomizers 18 and 18A are controlled in accordance with the dirt index N.

  In this way, it is possible to further reduce the possibility of erroneous detection by performing weighted control using the highly accurate dirt sensor 70 as the main detection means and the activity amount sensor as the dirt detection assist detection means, The effect of the electrostatic mist generated by the electrostatic atomizers 18 and 18A (indoor deodorization purification) and the contamination prevention effect of the electrostatic atomizers 18 and 18A are further balanced.

  If an optical dust sensor is used as the dirt sensor 70 in place of the gas sensor, it is not necessary to provide an activity amount sensor because indoor dust can be directly detected.

  In the above embodiment, two threshold values are set for the degree of contamination of room air, and the electrostatic atomizers 18 and 18A are controlled to repeat continuous operation, intermittent operation or stop according to the degree of contamination of room air. It is also possible to set one threshold value for the degree of contamination of the room air, and to control the electrostatic atomizers 18 and 18A to be ON / OFF according to the degree of contamination of the room air. In this case, the display unit 76 displays the degree of indoor air contamination in two colors. In addition, three or more threshold values may be provided, and the intermittent operation (operation rate) of the electrostatic atomizers 18 and 18A may be controlled more finely. In this case, the display unit 76 indicates the degree of contamination of room air. Displayed in 4 or more colors.

  In this way, the number of thresholds can be set arbitrarily, but the smaller the number, the more precise control of air cleaning by the electrostatic atomizers 18 and 18A is reduced, but it becomes possible to suppress an increase in cost with a simple configuration, As the number increases, the configuration becomes more complicated, but fine control of air cleaning by the electrostatic atomizers 18 and 18A becomes possible.

  Further, the rotation speed of the ventilation fan provided in the ventilation fan unit 16 is controlled according to the degree of contamination of the indoor air, and when the degree of contamination is large, the rotation of the ventilation fan is increased, thereby purifying the room air more quickly. In addition, the operating rate of the electrostatic atomizers 18 and 18A increases, and the indoor purification action by the electrostatic mist also increases.

  As described above, as described in some configurations, the capacity of the electrostatic atomizers 18 and 18A is controlled according to the amount of particulate matter in the room air detected by the dirt detecting means, that is, the degree of dirt, for example, the degree of dirt Is small, the electrostatic atomizers 18 and 18A are operated as usual, while when the degree of contamination is large, the electrostatic atomizers 18 and 18A are operated with their capacities limited. The electric atomizers 18 and 18A can be operated normally, and the air purification function such as deodorization by electrostatic mist can be maintained and continued.

  The air conditioner according to the present invention can normally operate the electrostatic atomizer over a long period of time by controlling the electrostatic atomizer in accordance with the degree of dirt in the room air detected by the dirt detector. In particular, it is extremely useful as an air conditioner for general household use.

The perspective view of the indoor unit of the air conditioner based on this invention which shows the state which removed a part 1 is a schematic longitudinal sectional view of the indoor unit of FIG. The perspective view of the electrostatic atomizer provided in the indoor unit of FIG. The front view which shows a part of frame of the indoor unit of FIG. 1, and an electrostatic atomizer Schematic configuration diagram of electrostatic atomizer Block diagram of electrostatic atomizer The perspective view which shows the attachment state of the electrostatic atomizer with respect to an indoor unit main body The perspective view of the modification which shows the attachment state of the electrostatic atomizer with respect to an indoor unit main body 1 is a side view of the indoor unit in FIG. 1 showing the positional relationship between the electrostatic atomizer and the ventilation fan unit. The perspective view of the pre-filter automatic cleaning apparatus provided in the indoor unit of FIG. The perspective view which shows the modification of an electrostatic atomizer The side view of the indoor unit of FIG. 1 which shows the positional relationship of the electrostatic atomizer of FIG. 11, and a ventilation fan unit. Block diagram showing control circuit of electrostatic atomizer Flow chart showing control method of electrostatic atomizer The indoor unit is equipped with a human body detection sensor and the front panel opens the front opening, (a) is a perspective view thereof, (b) is a side view thereof. Schematic showing the human body position determination area detected by the human body detection sensor shown in FIG. Flow chart showing how to classify human activity Flow chart showing another control method of electrostatic atomizer

Explanation of symbols

2 indoor unit body, 2a front suction port, 2b top suction port, 4 front panel,
5 Pre-filter, 6 Heat exchanger, 8 Indoor fan, 10 Air outlet,
12 upper and lower blades, 14 left and right blades, 16 ventilation fan unit,
18, 18A electrostatic atomizer, 20 main flow path, 22 bypass flow path,
22a Bypass inlet, 22b Bypass outlet, 22c Bypass inlet pipe,
22d bypass outlet, 22e housing, 24 high voltage transformer,
26 bypass fan, 28 heat radiating section, 30 electrostatic atomizing unit,
32 Silencer, 34 Casing, 36 Peltier element, 36a Heat radiation surface,
36b cooling surface, 38 discharge electrode, 40 counter electrode, 42 control part,
44 Peltier drive power supply, 46 underframe, 46a rear wall, 46b side wall,
46c Bulkhead, 48 Rear guider, 48a Rear wall, 48b Side wall,
50 Pre-filter automatic cleaning device, 52 Suction nozzle, 54 Guide rail,
56 suction duct, 58 suction device, 58a exhaust port, 60 exhaust duct,
62 opening, 64 damper, 66 unit housing,
68 Silencer housing, 70 Dirt sensor, 72 Control unit,
74 drive circuit, 76 display unit, 78 storage unit,
80, 82, 84, 86, 88 Sensor unit, 90 Sensor cover.

Claims (5)

An air conditioner provided with an indoor unit having an air cleaning function for purifying indoor air, comprising a discharge electrode and a counter electrode disposed apart from the discharge electrode, the discharge electrode and the counter electrode An electrostatic atomizer that generates a corona discharge in between to generate an electrostatic mist, and a dirt detection means for detecting the degree of dirt in the room air,
The dirt detection means comprises at least one of a dirt sensor that directly detects the degree of dirt in indoor air, and an activity amount sensor that indirectly detects the degree of dirt in room air by detecting the amount of human activity, and the dirt One threshold is provided for the degree of contamination detected by the detection means, and when the degree of contamination is less than the threshold, the electrostatic atomizer is operated normally, while when the degree of contamination is greater than the threshold, the electrostatic atomization is performed. An air conditioner that controls ON / OFF of the electrostatic atomizer so as to limit the capacity of the apparatus and displays the degree of contamination of indoor air . The threshold value is set as a first threshold value, and a second threshold value greater than the first threshold value is provided for the contamination level detected by the contamination detection unit. When the contamination level is greater than the second threshold value, the electrostatic fog The air conditioner according to claim 1 , wherein the air conditioner is stopped . When the dirt detection means is composed of both the dirt sensor and the activity amount sensor, the dirt sensor and the activity amount sensor are weighted, and the dirt sensor detects the activity amount detected by the activity amount sensor. The air conditioner according to claim 1 or 2, wherein the dirty degree is more reflected in the control of the electrostatic atomizer. The air conditioner according to claim 1 , wherein the electrostatic atomizer includes a Peltier element, and the discharge electrode is cooled and condensed by the Peltier element. Having said indoor unit ventilation fan, an air conditioner according to any one of claims 1 to 4 wherein the stain detecting means and controlling the rotational speed of the ventilation fan in accordance with the dust concentration was detected Machine.

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